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LINA DEPARTMENT
L RESOURCES AND
TV DEVOPMENT
OF MARINE FISHERIES
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A BIOLOGICAL AND FISHERIES PROFILE OF
RED DRUM, Sciaenops ocellatus
by
Linda P. Mercer
North Carolina Department of Natural Resources
and Community Development
Division of Marine Fisheries
Morehead City, NC 28577
Special Scientific Report No. 41
July 1984
This report was prepared and published as part of the State-Federal
Fisheries Management Program, Project SF-13, funded by the U. S.
Department of Commerce, National Marine Fisheries Service.
1,600 copies of this public document were printed at
cr) a cost of $2,114.70 or $1.322 per copy.
co
01 k- LIBRARY
CL__ NOAA/CCEH
1990 HOBSON AVE
CHAS. SC 2@4OS-'?(-!'@
�
PREFACE
In the early 1970s, state marine fisheries management agencies and the
National Marine Fisheries Service (NMFS) began a cooperative program to
prepare and implement .fishery management plans for coastal migratory
species and shared fisheries resources occurring in the Territorial Sea
along the Atlantic Coast of the United States. This effort, called the
State-Federal Fisheries Management Program, resulted in cooperative
management plans for species* such as the American lobster, surf clam,
striped bass, Atlantic menhaden, penaeid (southern) shrimp, pandalid
(northern) shrimp, and summer flounder, as well as development of a
cooperative statistics program in the Southeast Region of the United
States. Several of these plans have been adopted and implemented by
regional Fisheries Management Councils under the Magnuson Fishery
Conservation and Management Act of 1976 (PL 94-265). Funding for the
overall program has been provided by NMFS through the Atlantic States
Marine Fisheries Commission. Since 1980, this coordination has been
formally conducted under the Commission's Interstate Fisheries
Management Program. This red drum profile represents the initial step
in preparation of plans for cooperative management of important sciaenid
species occurring along the Atlantic Coast.
�
CONTENTS
Page
1. IDENTITY
1.1 Nomenclature . . . . . . . . . . . . . . . . . . . . . . . 1
1.2 Taxonomy . . . . . . . . . . . . . . . . . . . . . . . . . 1
1.3 Morphology . . . . . . . . . . . . . . . . . . . . . . . 3
2. DISTRIBUTION
2.1 General distribution . . . . . . . . . . . . . . . . . . . 5
2.2 Differential distribution . . . . . . . . . . . . . . . . 5
2.21 Spawn, larvae, and juveniles . . . . . . . . . . . . 5
2.22 Adults . . . . . . . . . . . . . . . . . . . . . . . 8
2.3 Determinants of distribution . . . . . . . . . . . . . . . 9
3. LIFE HISTORY
3.1 Reproduction . . . . . . . . . . . . . . . . . . . . . . . 10
3.2 Pre-adult phase . . . . . . . . . . . . . . . . . . . . . 15
3.3 Adult Rhase . . . . . . . . . . . . . . . . . . . . . . . 15
3.4 Nutrition and growth . . . . . . . . . . . . . . . . . . . 16
3.5 Behavior . . . . . . . . . . . . . . . . . . . . . . . . . 17
.3.6 Contaminants . . . . . . . . . . . . . . . . . . . . . . . 22
4. POPULATION
4.1 Structure . . . . . . . . . . . . . . . . . . . . . . . . 23
4.2 Abundance, density, mortality, and dynamics . . . . . . . 29
4.3 Community ecology . . . . . . . . . . . . . . . . . . . . 38
5. EXPLOITATION
5.1 Commercial exploitation . . . . . . . . . . . . . . . . . 38
5.11 Fishing equipment . . . . . . . . . . . . . . . . . 38
5.12 Areas fished . . . . . . . . . . . . . . . . . . . . 39
V
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5.13 Fishing seasons . . . . . . . . . . . . . . . . . . 39
5.14 Fishing operations and results . . . . . . . . . . . 46
5.15 Incidental catches . . . . . . . . . . . . . . . . . 46
5.2 Recreational exploitation . . . . . . . . . . . . . . . . 47
5.21 Fishing equipment . . . . . . . . . . . . . . . . . 47
5.22 Areas fished . . . . . . . ... . . . . . . . . . . . 47
5.23 Fishing seasons . . . . . . . . . . . . . . . . . . 48
5.24 Fishing operations and results . . . . . . . . . . . 48
6. SOCIAL AND ECONOMIC IMPLICATIONS
6.1 Values . . . . . . . . . . . . . . . . . . . . . . . . . . 50
6.2 Employment . . . . . . . . . . . . . . . . . . . . . . . . 53
6.3 Participation . . . . ... . . . . . . . . . . . . . . . . 53
6.4 Processors and product forms . . . . . . . . . . . . . . . 53
6.5 Import/export . . . . . . . . . . . . . . . . . . . . . . 54
6.6 Gear conflicts . . . . . . . . . . . . . . . . . . . . . . 54
6.7 Commercial-recreational conflicts . . . . . . . . . . . . 54
7. MANAGEMENT AND PROTECTION
7.1 Regulatory measures . . . ... . . . . . . . . . . . . . . 56
7.2 Habitat protection . . . . . . . . . . . . . . . . . . . . 64
7.3 Stocking . . . . . . . . . . . . . . . . . . . . . . . . . 69
8. CURRENT RESEARCH . . . . . . . . . . . . . . . . . . . . . . . 70
9. IDENTIFICATION OF PROBLEMS . . . . . . . . . . . . . . . . . . 71
10. ACKNOWLEDGEMENTS . . . . . . . . . . . . . . . . . . . . . . . 71
11. REFERENCES . . . . . . . . . . . . . . . . . . . . . . . . . . 73
vi
�
TABLES
f!ge
Table 1. Standard length-total length relationships for red
drum as reported in the literature . . . . . . . . . . . . 4
Table 2. Reported size and/or age at maturity for red drum . . . . 11
Table 3. Published fecundity estimates for red drum . . . . . . . . 12
Table 4. Size distribution (mm TQ of young-of-the-year red
drum by month from Atlantic coast estuaries . . . . . . . 14
Table 5. Published red drum growth rates (where necessary,
standard lengths converted to total lengths using
Harrington et al. (1979); blanks indicate no
estimates given) [from Swingle et al. 19831 . . . . . . . 18
Table 6. Published total length-at-age estimates for red
drum. (Where necessary, standard lengths converted
to total lengths using TL=12.870 + 1.177 SL
(Harrington et al.. 1979); blanks indicate no
estimates given) [modified from Swingle et al.
(1983)] . . . . . . . . . . . . . . . . . . . . . . . . . 24
Table 7. Empirical and back calculated total lengths for red
drum collected in South Carolina, Georgia, and
Florida . . . . . . . . . . . . . . . . . . . . . . . . . 25
Table 8. Estimates of von Bertalanffy growth parameters for
red drum . . . . . . . . . . . . . . . . . . . . . . . . . 27
Table 9. Published standard length-weight relationships for
red drum [Music and Pafford (1984) and Harrington
et al. (1979) are total length-weight relationships].
Weight is in g and length in mm, except cm for
Theiling and Loyacano (1976). [from Swingle et al.
(1983)] . . . . . . . . . . . . . . . . . . . . . . . . . 28
Table 10. Commercial landings of red drum by state, 1887-1983
(metric tons) . . . . . . . . . . . . . . . . . . . . . . 31
Table 11. Red drum recreational catch and effort statistics
from National Marine Fisheries Service Salt-Water
Angling Surveys, 1960-1970 . . . . . . . . . . . . . . . . 36
Table 12. Red drum recreational catch statistics from National
Marine Fisheries Service Marine Recreational Fishery
Statistics Surveys, 1980-1982 . . . . . . . . . . . . . . 37
Table 13. Percentage of Virginia red drum landings by gear
type, 1970-1983 . . . . . . . . . . . . . . . . . . . . . 40
Vii
�
Page
Table 14. Percentage of North Carolina red drum landings by
gear type, 1970-1983 . . . . . . . . . . . . . . . . . . . 41
Table 15. Percentage of South Carolina red drum landings by
gear type, 1970-1983 . . . . . . . . . . . . . . . . . . . 42
Table 16. Percentage of Georgia red drum landings by gear
type, 1970-1983 . . . ... . . . . . . . . . . . . . . . . 43
Table 17. Percentage of Florida East Coast red drum landings
by gear type, 1970-1977 . . . . . . . . . . . . . . . . . 44
Table 18. Annual commercial catch of red drum (kg) by state
and water area for the Atlantic coast, 1968-1983
and percent caught in the estuaries . . . . . . . . . . . 45
Table 19. Number of red drum caught by U. S. anglers in each
region in 1965, 1970, and 1980 by principal area
and method of fishing . . . . . . . . . . . . . . . . . . 49
Table 20. Unadjusted exvessel price of commercially-caught
red drum on the Atlantic coast by state, 1960-1982 . . . . 52
Table 21. U. S. imports and exports of red drum, 1964-1983
(from Swingle et al. 1983) . . . . . . . . . . . . . . . . 55
Table 22. Synoptic overview of present state management
systems . . . . . . . . . . o . . . . . . . ... o . . . . 57
Table 23. Summary of state habitat protection regulations,
Rhode Island to Florida . . . . . . . . o . . . . . . . . 66
Viii
�
FIGURES
Page
Figure 1. Red drum, Sciaenops ocellatus (Linnaeus), 1766
(illustration by H.L. Todd from: Goode 1884) . . . . . . 2
Figure 2. U. S. commercial landings of red drum for the
Atlantic coast and Gulf of Mexico, 1930-1983 . . . . . . 30
Figure 3. U. S. commercial landings of red drum on the
Atlantic coast by state, 1950-1983 . . . . . . . . . . . 34
Figure 4. Dockside price of red drum for the Atlantic
coast and Gulf of Mexico, 1960-1983 . . . . . . . . . . . 51
ix
�
IDENTITY
1.1 Nomenclature
The valid name for red drum is Sciaenops ocellatus (Linnaeus)
1766 (Figure 1). The following synonymy is after Jordan and
Evermann (1896):
Perca ocellata Linnaeus, 1766
Cutjanus triangulum Lacepede, 1802
Sciaena imberbis Mitchill, 1815
Corvina ocellata Cuvier and Valenciennes, 1830
Johnius ocellatus Girard, 1859
Sciaena ocellata Gunther, 1860
1.2 Taxonomy
Classification follows Greenwood et al. (1966). Taxa higher
than superorder are not included.
Superorder: Acanthopterygii
Order: Perciformes
Suborder: Percoidei
Family: Sciaenidae
Genus: Sciaenops
Species: Sciaenops ocellatus
Red drum is one of 22 members of the family Sciaenidae found
along the Atlantic and/or Gulf coasts of the United States
(Robins et al. 1980). This family is commonly known as the
drums since many of its members, including red drum, produce
drumming sounds by vibrating their swim bladders with special
muscles (Jordan and Evermann 1896; Bigelow and Schroeder 1953;
Fish and Mowbray 1970; Guest and Lasswell 1978). Chao (1978)
assessed the phylogenetic relationships of all western
Atlantic genera of Sciaenidae on the basis of swim bladder,
otoliths (sagitta and lapillus), and external morphology, and
presented a tested key to species and genera. The genus
Sciaenops is monotypic.
Red drum is the common name given Sciaenops ocellatus by the
American Fisheries Society (Robins et al. 1980). Other common
names include channel bass, puppy drum, redfish, bull redfish,
bass, red bass, sea bass, spotted bass, spottail, rat red,
pescado colorado, drum, and branded drum (Smith 1907; Jordan
et al. 1930; Hildebrand and Schroeder 1928; Shiino 1976).
�
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Figure 1. Red drum, Sciaeno ellatus (Linnaeus), 1766 (illustration by H
from: Goo e 1884
�
1.3 Morphology
The following description is that of Johnson (1978),
summarized from Jordan and Evermann (1896), Hildebrand and
Schroeder (1928), Topp and Cole (1968), Simmons (1969), Miller
and Jorgenson (1973), and Chao (1976).
D. X-I, 23-25; A. 11, 7-8; C. 9+8, procurrent rays
8-10+7-10; V. 1, 5; scales 40-45 in a lateral series;
vertebrae 10+15, pleural ribs 8, epipleural ribs 7; gill
rakers 4-5+7-9; branchiostegals 7; teeth small conical in
jaws, set in bands, outer row teeth of upper jaw slightly
enlarged; lower jaw teeth subequal; no teeth on vomer,
palatines, or tongue.
Head 2.8-3.3, depth 3.3-3.9 in SL; snout 3.3-3.8, eye
3.1-4.7, maxillary 2.5, interorbital 3.7-4.6, pectoral
fin 1.5-1.8 in head.
Body elongate, rather robust, not much compressed; back
moderately arched; ventral outline nearly straight; head
rather long and low; snout conical; mouth horizontal,
lower jaw included; lower jaw with five pores, without
barbels; maxillary almost reaching below posterior margin
of eye. Scales rather large, strongly ctenoid; no scales
on soft dorsal fin; scales of breast embedded, cycloid.
Dorsal fin continuous, with a deep notch between the
spinous and soft portions; dorsal spines rather stiff,
pungent; second anal spine thick, much shorter than
longest soft rays; posterior margin of caudal fin
straight to slightly concave; pectoral fin as long as
pelvic fin. Preopercular margin serrate in smaller
specimens, becoming entire in specimens of about 9-13 kg.
Pigmentation: May be silvery, grayish, bronze, copperyl
yellow, and sometimes almost black; often silvery or
copperish in Gulf, darker in muddy bays; each scale with
a dark center, forming rather obscure, irregular,
undulating brown stripes along scale rows; one to several
(most frequently 1) jet black spots at base of caudal and
below the soft dorsal fin above lateral line; dorsal and
caudal fins dusky; anal and pelvic fins white; outer part
of pectoral fin bright rusty.
Topp and Cole (1968) described the osteology of Sciaenops
based on a study of 21 specimens (30 mm SL-195 mm skull
length). Powles and Stender (1978) described morphometric and
meristic development of nine larval red drum (4.1-7.9 mm SL)
from South Carolina estuaries and the Cape Fear River estuary,
North Carolina. Standard length-total length relationships
were determined for red drum in Georgia (Jorgenson and Miller
1968), Texas (Harrington et al. 1979), Louisiana (Hein et al.
1980), and Mississippi (Overstreet 1983) (Table 1).
�
Table 1. Standard length-total length relationships for red drum as reported in the literature.
Size range
Location Reference (mm TL) N Relationship r
Georgia Jorgenson and 16-40 5 TL w 0.469 + 1.247 SL
Miller (1968)
SL = -0.290 + 0.799 TL
Texas Harrington et al. 92-937 8982 TL = 12.870 + 1.177 SL 0.995
(1979)
Louisiana Hein et al. (1980) 14-1135 302 SL - -2.0520 + 0.8369 TL 0.9996
Mississippi Dverstreet (1983) 175-1138 861 TL = 7.3032 + 1.1712 SL 0.9975
SL = -3.4416 + 0.8495 TL 0.9975
�
2. DISTRIBUTION
2.1 General distribution
Red drum have been reported from the Gulf of Maine off
Massachusetts to Key West, Florida, on the Atlantic coast but
are rare north of New Jersey (Smith 1898; Yokel 1966; Lux and
Mahoney 1969). Commercial landings of red drum have generally
declined along the Middle Atlantic coast and none have been
reported north of Chesapeake Bay since 1950 (Yokel 1980). Red
drum occur in the Gulf of Mexico from extreme southwest
Florida continuously along the Gulf coast to Zamora, Vera
Cruz, Mexico (Yokel 1966; Castro Aguirre 1978).
2.2 Differential distribution
2.21 Spawn, larvae, and juveniles
Observations of gravid and spent adults and collections
of larvae indicate that red drum spawn in the ocean along
beaches and in the vicinity of inlets and passes (Pearson
1929; Miles 1950; Simmons and Breuer 1962; Yokel 1966;
Hein and Shepard in press). Red drum eggs were observed
being carried into seagrass beds by tidal currents in
Redfish Bay, Texas (S. Holt and Arnold 1982).
Collections of red drum larvae (2.0 Em NL-5.2 mm SQ from
eelgrass beds on the eastern shore side of Chesapeake
Bay, approximately 37 km from the bay entrance, ani
observations of gravid adults in Tampa Bay, Florida
suggest that some spawning may occur within estuaries.
In the Gulf of Mexico red drum larvae (< 7 mm TL) and
postlarvae (7-42 mm TL) have been collected in nearshore
oceanic waters, passes and inlets to estuarine waters,
and within estuaries (Pearson 1929; Miles 1950; Yokel
1966; Jannke 1971; King 1971; Sabins and Truesdale 1974;
Richardson and Laroche 1982; Robison in press). Within
estuaries young red drum are generally found in quiet
shallow waters with grassy or slightly muddy bottoms that
1
Unpublished data on file at the Virginia Institute of Marine Science,
Gloucester Point, Virginia.
2M. Murphy and R. Taylor, Florida Department of Natural Resources, St.
Petersburg, Florida, personal communication.
�
are not greatly affected by tides (Perret et al. 1980).
A study of the distribution of young red drum (6-27 mm
SQ among different shoal-grass (Halodule wrightii) beds
in Texas found that the ecotone between seagrass and
nonvegetated bottom had significantly more red drum than
did homogeneously vegetated sites. No red drum were
found on large (>5 m across) nonvegetated sites (Holt,
Kitting, and Arnold 1983). In Tampa Bay young red drum
(8-20 mm SL) were collected along the shoreline over soft
mud to sandy bottom, often with submerged grasses or
shore grasses and little current. Larger individuals
(20-40 mm SQ were collected in bayous and backwaters
with low salinity, muddy bottom, little or no submerged
vegetation and usually some detritus. Juveniles (40-90
mm SL) were found in semiexposed areas such as river
mouths with mud to moderately sandy bottoms, little or no
coverl and moderately low salinities and currents.
Larger fish (160-250 mm SL) were found in exposed areas
of embayments and rivers with moderate currsnts, sand/mud
or rubble bottoms, and moderate salinities.
Most juvenile or immature red drum (<700-750 mm TQ
remain in Gulf of Mexico estuaries throughout the year,
but move into deeper waters of bays during winter
(Pearson 1929; Miles 1950; Simmons and Breuer 196 -2;
Breuer 1973; Loman 1978; Osburn et al. 1982).
Young-of-the-year moved out of the seagrass beds in
Redfish Bay, Texas in late November with the onset of
cold (<16*C) water temperatures (S. Holt and Arnold
1982). Tagging studies have shown that there is very
little inter-bay movement of immature red drum in Texas
(Simmons and Breuer 1962; Osburn et al. 1982) or Florida
(Ingle et al. 1962; Topp 1963). Immature red drum (100
mm-460 mm TL) have also been collected in the Gulf surf
zone in summer (Gunter 1958; Simmons and Hoese 19,59;
McFarland 1963; Heffernan 1973), and Gulf-to-bay movement
of red drum (203-254 mm TQ in Texas was noted by Simmons
(1951).
Information on the distribution of juvenile red drum on
the Atlantic coast is limited. Postlarval red trum are
found over sand and mud bottom 5in North Carolina, around
oyster bars in South Carolina, and over muddy bottoms in
3K. Peters and B. McMichael, Florida Department of Natural Resources,
personal communication.
4Unpublished data on file at the North Carolina Division of Marine
Fisheries, Morehead City, North Carolina.
5G. Ulrich, South Carolina Marine Resources Center, Charleston2 South
Carolina, personal communication.
�
6
Florida . In the Cape Fear River estuary, North Carolina
postlarval red drum accumulated in greater numbers in the
upper reaches of creeks, gradually decreasing in
densities downstream (Weinstein 1979). Setzler (1977)
demonstrated the transport of red drum larvae from 10.5
km offshore to the lower salinity waters at the head of
Doboy Sound, Georgia. In that study significantly higher
densities of red drum were caught on flood tides than on
ebb tides and larvae collected at inshore stations were
significantly larger than those from offshore. Mansueti
(1960) speculated that red drum larvae are carried
passively into Chesapeake Bay by deep sub-surface high
density water currents, and at about 5 mm TL move into
shallow water (<1.5 m).
Yokel (1966) stated that juvenile red drum have a more
pronounced seasonal pattern of distribution in Chesapeake
Bay and North Carolina than in the Gulf of Mexico, moving
into deeper areas of estuaries or the sea in the fall and
winter. Juveniles (20-90 mm TQ were collected
throughout Chesapeake Bay from September to November
(Hildebrand and Schroeder 1928; Mansueti 1960). Two
juveniles (58 and 66 mm) were collected in November and
December in the thermal plume of the Indian River Power
Plant, Indian River Bay, Delaware (Wang and Kernehan
1979). Juvenile red drum 15-391 mm. TL were collected
through December, with young-of-the-year first appearing
in September, 1972-1983 in nursery area surveys of
Pamlico Sound, No@th Carolina (Spitsbergen and Wolff
1974; Wolff 1976). Schwartz et al. (1981) listed red
drum as occurring year-round in the..._Cape Fear River
estuary. Large numbers of young red drum (up to 8 kg)
are occasionally gigged in North Carolina sounds in the
winter (Angler gigs 352 puppy drum. 1984). In South
Carolina red drum (37-100 mm) have been collected in
shallow-waters of marsh-tidal creeks and in tidal
impoundments during September through November (Bearden
1967; Smith and Moore 1979). In Georgia red drum were
collected by seines in a variety of habitats, including
beach, high marsh, tidal canals, and low- and
high-salinity tidal pools (Dahlberg 1972). Young and
juveniles were usually collected in the shallow shore
zones of the Indian River lagoon, Florida (Snelson 1983).
6
K. Peters, Florida Department of Natural Resources, personal
communication.
7Unpublished data on file at the North Carolina Division of Marine
Fisheries, Morehead City, North Carolina.
�
2.22 Adults
Information on the distribution of adult red drum has
been obtained from biologists, recreational and
commercial fishermen, and menhaden spotter pilots (Yokel
1966; Overstreet 1983). Along the Gulf coast red drum
move from the estuaries to the Gulf of Mexico at maturity
(>700 mm FL) (Yokel 1966). After spawning some of the
adults may move back into bays for a short time (Miles
1951), but on the whole less time is spent in the estuary
after maturity (Pearson 1929; Simmons and Hoese 1959).
Large schools of red drum have been observed as far as 19
km offshore (Simmons and Breuer 1962). Overstreet (1983)
reported that commercial fishermen have observed schools
of 150-250 thousand fish (2-30 million kg) in the Gulf.
Schools of red drum (5-15 kg) have been observed feeding
along the shoreline of islands or the mainland at depths
>1.2 m from low tide through flood tide. The schools
often occur near black drum, Atlantic tarpon, and pompano
and are sometimes caught under schools of blue runner at
a depth of 37 m (Anonymous 1982a). Ross et al. (1983)
captured 16 adult fish (808-1,050 mm TQ during late
autumn, winter and early spring off Freeport, Texas, 88%
of which were captured in March and April at depths of
13-22 m. Schools of red drum have been monitored
commonly at depths of approximately 40-70 m (Overstreet
1983). During summer schools of red drum are more spread
out than during spring and autumn, occurring all over
Mississippi Sound and adjacent regions (Overstreet 1983).
Adult red drum migrate seasonally along the coasts of
North Carolina and Virginia, moving inshore and north in
spring and offshore and south in fall. In Chesapeake Bay
red drum are taken from May until October and are most
abundant during spring and fall (Hildebrand and Schroeder
1928). Largest catches of citation red drum (>18 kg)
along the Outer Banks of North Carolina are Ve from
late March through May and in October-November. Large
schools of red drum have been9observed in Pamlico Sound,
North Carolina during summer. In winter they have been
caught off the coast of North Carolina in the trawl
fishery (Pearson 1932; Ross et fa. 1983) and in trawl
surveys at depths of 10-40 m. Red drum have been
8Unpublished North Carolina Saltwater Fishing Tournament data on file
at the North Carolina Office of Travel and Tourism, Raleigh, North
Carolina.
9J. Brown, North Carolina Division of Marine Fisheries, Morehead City,
North Carolina, personal communication.
10 Unpublished data on file at the North Carolina Divison of Marine
Fisheries, Morehead City, North Carolina.
�
reportel,off South Carolina in 13-26 m in winter-early
spring. In Georgia red drum >4 yr are generally found
along the beaches and in offshore waters (Music and
Pafford 1984). In the Indian River lagoon area of
Florida, red drum were reported as common in the
benthic-open shelf habitat and frequent in the surf zone,
inlets, and lagoon (Gilmore et al. 1981; Snelson 1983).
2.3 Determinants of distribution
Red drum are euryhaline, having been reported from fresh water
to salinities of 50 ppt on the Gulf coast (Gunter 1942, 1945,
1956, 1959; Kilby 1955; Simmons 1957; Briggs 1958; Springer
1960; Springer and Woodburn 1960; Tabb and Manning 1961;
Gunter and Hall 1962; Simmons and Breuer 1962; Perret 1971).
Simmons and Breuer (1962) reported that the optimum salinity
range for red, drum was 20-40 ppt. Red drum were collected on
the east coast of Florida at salinities from 0-29.9 ppt
(Springer 1960; Tagatz 1967). In North Carolina estuaries red
drum (10-391 mm TL) were collected over a salinity range of
0-22.3 ppt (Tagatz and Dudley 1961). Yokel (1966) suggested a
direct relationship between size and salinity, with juveniles
more common at low salinities and large fish preferring higher
salinities. This is typical of many species that utilize
estuaries as nursery areas (Gunter 1938, 1945).
Crocker et al. (1981) evaluated survival and growth of
juvenile red drum in fresh and salt water and found that
tolerance to fresh water was size dependent. They f ound 5%
survival in larvae (23-day-old, 6.2 mm SL), 70% for postlarvae
(34- and 47-day-old, 16.2-19.7 mm SL), and 95% for juveniles
(57-day-old, 56.9 mm SL) subjected to dechlorinated fresh
water for 96 hours. Survival in control salinities of 10 ppt
was 90% or greater. Wakeman and Wohlschlag (1983) studied
osmotic adaptation with respect to blood serum osmolality and
oxygen uptake in hatchery-reared (1.3-3.8 g) and wild juvenile
red drum. The rapid stabilization of both serum osmolalities
and standard metabolic rates indicated that red drum are well
adapted to natural rapid salinity changes.
Red drum have been collected over a temperature range of
2-33*C, although they usually move into deeper water at the
extremes (Simmons and Breuer 1962). Springer (1960) collected
red drum from 2-29*C in the St. Lucie and Indian Rivers,
Florida. Red drum (10-415 mm FL) were collected in a North
Carolina estuary from 7.5-26.8*C (Tagatz and Dudley 1961).
C. Wenner, South Carolina Marine Resources Research Institute,
Charleston, S.C., personal communication.
�
10
Gunter (1947) reported that larger juveniles and adults were
more susceptible to the effects of winter cold waves than were
smaller fish. High red drum mortality in Texas during freezes
was documented by Gunter (1941) and Gunter and Hildebrand
(1951). Red drum were killed in three out of nine severe cold
spells at Sanibel Island, Florida, but the kills were never
severe (Storey and Gudger 1936). Red drum were found dead or
dying in the power plant intake canal and on shoals that had
iced over in the lower Cape Fear River estuary, North Carolina
during the severe winters of 1976 and 1977 (Schwartz et al.
1981).
3. LIFE HISTORY
3.1 Reproduction
Size and age of red drum at sexual maturity are not well
known and apparently vary in different areas of the" range
(Pearson 1929; Gunter 1950; Miles 1951; Simmons and Breuer
1962; Yokel 1966; Hein and Shepard in press) (Table 2). On
the Atlantic coast age and size at ma@yity was determined for
the Mosquito Lagoon area of Florida. Males began maturing
at age I+ between 470-530 mm FL, and females first matured
between ages Il and III when 575-760 mm FL. Music and Pafford
(1984) collected a single ripening male (755 mm TL, age II) in
a Georgia study.
Fecundity of red drum has been estimated from both laboratory-.,
reared and wild caught fish (Table 3). Multiple spawning was'@
reported in laboratory-induced spawning experiments in which'
th5ee females (9-15 kg) in Texas produced an estimated 6.0 x
10 fertilized eggs in 52 spawns during 76 days (Arnold et al.
1977). In Florida 6experiments four females (1.68-7.95 kg)
produced 8.43 x 10 eggs during 90 @ays and eight females
(1.68-7.95 kg) produced 4.41 x 10 eggs over 100 days
(Roberts, Harpster, and Henderson 1978). Overstreet (1983)
presented a standard length-fecundity relationship for 22 red
drum (294-800 mm SL) in Mississippi as: Log F = 3.6976 +
0.0050 SL (r = 0.9539), where F is the number of oocytes
16-300 .11 m. The maximum estimated numbers of oocytes
(16-30 pm) for a 785 mm 7SL (894 mm TQ red drum in March in
that study was 6.20 x 10 (volumetric displacement method) and
9.45 x 10 7 (gravimetric method). These may be overestimates
because red drum are "resting" in March and reserve oocytes
12M. Murphy and R. Taylor. Paper presented to the Florida Cha .pt'oer of
the American Fisheries Society, Brooksville, Florida, February 8-9,
1983.
�
Table 2. Reported size and/or age at maturity for red drum.
Location Reference Size Age
Texas Pearson (1929) 750-810 mm TL 4 or 5
South Texas Gunter (1950) 406-432 mm TL
Texas Miles (1951) 750 mm 4
Texas Simmons and Breuer (1962) 700-800 mm SL 3 or 4
Louisiana Hein and Shepard (in press) 851 mm TL (females)
780 mm TL (males)
Mississippi Overstreet (1983) 550-699 mm SL
Southwest Florida Gunter (1950) 380 mm TL
Southwest Florida Yokel (1966) 630 mm FL
Tampa Bay, Florida (1) 430-490 mm FL (males) I+
610-670 mm FL (females) 1-3
Mosquito Lagoon area, 470-530 mm FL (males) 1+
Florida
575-760 mm FL (females) 2-3
M. Murphy and R. Taylor. Paper presented to Florida Chapter of the American Fisheries Society, Brooksville, Florida.
Febuary 8-9, 1983.
�
Table 3. Published fecundity estimates for red drum.
Number
Reference State Environment Size of eggs Comments
Pearson (1929) Texas wild 90 cm TL 3.4 x 10 6 Determined by volume and
weight methods.
Miles (1950) Texas wild 750-825 mm 2.5 x 10 6 "Granular stage" of
(age 5) development.
Colura (1974) Texas laboratory 26 lb 2.9 x 10 6 Second natural spawn;
estimate was probably high
because of investigator's
inability to get an even
distribution of eggs in
aliquot samples.
Arnold et al. Texas laboratory 3 fish 6.0 x 10 7 Fish were subjected to
(1977) (9-15 kg) photoperiod and temperature
regimes; produced in 52
spawns during 76 days.
Roberts, Harpster, Florida laboratory 2.1 x 10 6 Natural spawn after con-
and Henderson ditioning; 4 fema@es
(1978) produced 8.4 x 10 embryos
during a 90-day period.
Overstreet Mississippi wild 9,776.7 9 15.8 x 10 6 Based on number of eggs
(1983) >16pm by volumetric dis-
placement method.
�
13
cannot be distinguished from recruit oocytes. Furthermore,
Overstreet (1983) stated that vitellogenesis occurred in
oocytes as small as 70pm but was typically more apparent in
those >100 pm.
In the Gulf of Mexico red drum spawn from August to
mid-November with a peak in September or October (Pearson
1929; Miles 1951; Springer and Woodburn 1960; Yokel 1966;
Christmas and Waller 1973; Sabins and Truesdale 1974; Stuck
and Perry 1982; Hein and Shepard in press). Jannke (1971)
reported that spawning in southwestern Florida occurred from
mid-September through mid-February, peaking in October.
Collections of larvae and juveniles indicate that spawning
along the Atlantic coast may begin in July or possibly
earlier, and continue through December with a peak in late
September or October (Hildebrand and Schroeder 1928; Mansueti
1960; Tagatz and Dudley 1961; Yokel 1966; Williams and Deubler
1968; Mahood et al. 1?14; Spitsbergen and Wolff 1974; Wolff
1976; Weinstein 1979) (Table 4). Yokel (1966) suggested
that spawning may also occur in spring on the Florida east
coast, based on reports from anglers, commercial fishermen,
and juvenile collections. However, a study of the annual
cycle of oocyte development and gonadosomatic indices for red
drum from east-central Florida found 14 discrete spawning
season during September and October. Collections of
juveniles (35-55 mm FL) in western Pamlico Sound, North
Carolina in July (Spitsbergen and Wolff 1974) (Table 4)
suggest a late winter or spring spawning in North Carolina.
Red drum spawning has been induced in culture systems by
manipulating temperature and photoperiod combinations to
simulate optimal conditions or seasonal variations. Spawning
occurred under full-winter conditions (9 hr light and 15 hr
dark, 22-23*0 after a 7 month recycling through the four
seasons (Arnold et al. 1977). Roberts, Harpster, and
Henderson (1978) obtained successful spawning at 10 hr 15 min
light and 22-26*C after three differing regimes of photoperiod
and temperature. Holt, Godbout, and Arnold (1981) reported
that red drum stopped spawning in the laboratory when the
temperature dropped below 20'C.
Spawning in the laboratory occurred around dusk and was
preceded by color changes in the males, drumming, and nudging.
Males became dark red to bluish-gray on the dorsum above the
lateral line and pale white on the ventrum, while females
retained their characteristic reddish color. Drumming began
13 Unpublished data, North Carolina Division of Marine Fisheries,
Morehead City, N.C.
14 R. Taylor, Florida Department of Natural Resources, St. Petersburg,
Floridas personal communication.
�
Table 4. Size distribution (mm TL) of young-of-the-year red drum by month from Atlantic coast estuaries.
Author Mansueti Hildebrand -and Tagatz and Spitsbergen and Wolff Weinstein (1979) Mahood et al.
(1960) Schroeder (1928) Dudley (1961) (1974), Wolff (1976) (1974)
Locality Chesapeake Chesapeake Bay Neuse River, Pamlico Sound and Cape Fear River, Georgia
Bay N.C. tributaries, N.C. N.C.
Period 1953-1960 1921 1957-1960 1972-1975 1970-1973
1979-1983
January - - - -
February - - - - - -
March - - 47 45-88 - 92
April - - 57-76 75-145 - 105
May - - - 80-165 - 164
June - - 95-225 - -
July - 165-225 - 35-245 - -
August - - 80-85 230-330 13-15 -
September 20-60 20-52 27-62 12-390 5-30 -
October 20-75 25-53 10-85 15-335 12-40 34
November 30-84 39-90 25-71 15-75 23-47 57
December - - 34-37 55-95 23-48 -
1Unpublished data, North Carolina Division of Marine Fisheries, Morehead City, N.C.
�
15
around dusk and males swam near females and began nudging them
near their urogenital opening. Nudging and drumming reached a
peak and were followed by the release of eggs and milt. Sound
production resumed but decreased after spawning (Chapman 1967;
Arnold et, al. 1977; Guest and Lasswell 1978; Roberts,
Harpster, and Henderson 1978; Holt, Holt, and Arnold 1983).
Smith (1907) reported that only males drum.
Red drum eggs were described from laboratory spawnings by
Johnson et al. (1977) and Holt, Godbout, and Arnold (1981).
Vetter et al. (1983) investigated energy metabolism in red
drum eggs. Holt, Godbout, and Arnold (1981) reported that
laboratory-reared red drum eggs developed successfully to
feeding larvae at salinities of 10-40 ppt at 25*C, and best
conditions for hatching were 30 ppt salinity and 25'C.
3.2 Pre-adult phase
Red drum larvae were described by Pearson (1929), Jannke
(1971), Lippson and Moran (1974), Johnson et al. (1977),
Powles and Stender (1978), and Holt, Johnson et al. (1981).
Hatching in the laboratory occurred in 19-20 hr after
fertilization at 24*C (Arnold et al. 1977) and about 28-29 hr
at 22-23-C (Holt, Johnson et al. 1981). Length at hatching
was 1.71-1.79 mm SL (Holt, Johnson et al. 1981). The best
conditions for 24-hr larval survival were 30 ppt salinity and
25*C and the survival rate of 2-wk-old larvae was reduced at
20*C (Holt, Godbout and Arnold 1981). Survival rates were
greatly increased when larvae were maintained at 25*C through
the yolk-sac stage and first feeding (3 days) before being
exposed to 20% (J. Holt and Arnold 1982). Length of the
yolk-sac stage varied from 40 hr at 30*C to 84 hr at 20*C
(Holt, Johnson et al. 1981). Johnson et al. (1977) reported
that red drum larvae began feeding at 60 hr post-hatch
(23-25%). Survival was greater for those larvae offered food
on day 3 (14.0%) as compared to day 2 (3.5%) or day 4 (4.0%)
(Roberts, Morey et al. 1978).
3.3 Adult phase
Maximum age for red drum has not been determined because of
problems with age determination techniques. A maximum age
estimate of 33 years for red drum on the east coast of Florida
was base@5 on interpretation of banding patterns on otolith
sections. However, only the first three bands were
15 M. Murphy, Florida Department of Natural Resources, St. Petersburg,
Florida, personal communication.
�
16
adequately validated as annual marks. The maximum known time
at liberty shown by tagging is 12 years f or a f ish tagged at
300 mm and recovered at 18 kg (Simmons and Breuer 1976). The
IGFA record is a 40.8 kg fish (Anonymous 1983a) which
indicates that red drum longevity is probably greater than 12
years.
Parasites, diseases, mortalities, and abnormal conditions of
red drum were reviewed by Yokel (1966), Perret et al. (1980),
and Overstreet (1983).
3.4 Nutrition and growth
Crustaceans (crabs and shrimp) and f ishes are most important
in the diet of red drum in the Gulf of Mexico (Pearson 1929;
Gunter 1945; Kemp 1949; Miles 1950, 1951; Knapp 1950; Reid
1955; Darnell 1958, 1961; Inglis 1959; Springer and Woodburn
1960; Simmons and Breuer 1962; Yokel 1966; Fontenot and
Rogillio 1970; Boothby and Avault 1971; Bass and Avault 1975;
Odum and Heald 1975; Rogillio 1975; Overstreet and Heard 1978;
Matlock and Garcia@ 1983) and on the Atlantic Coast (Linton
1905; Hildebrand and Schroeder 1928; Overstreet and Heard
1978). Large red drum (430-1,020 mm SL) collected off the
beach at Sapelo Island, Georgia, fed heavily during summer on
echinoderms (five-lunuled sand dollars and sea cucumbers), in
addition to crabs and fishes (Overstreet and Heard 1978). A
preliminary study of red drum (>3.6-4.5 kg) feeding habits in
the Hatteras-Ocracoke area of North Carolina indicated that
primary food items were blue crabs (Callinectes sapidus) and
various fishes including striped mullet (Mugil cephalus), spot
(Leiostomus xanthurus), pinfish (Lagod on rhomboides), and
pigfish (Orthopristis chrysoptera).L-
Changes in food habits with size have been noted. Hildebrand
and Schroeder (1928) examined the stomach contents of 15 red
drum from Chesapeake Bay (30-1,075 mm) and reported that the
small fish fed principally on Gammarus and Mysis and the
larger ones on shrimp. Bass and Avault (1975) reported that
fish <15 mm SL fed primarily on zooplankton, fish 15-75 mm SL
fed mostly on small bottom invertebrates and young of other
fish, and fish >75 mm SL ate decapods (crabs and shrimp) and
fishes. Inglis (1959) examined fish 30-100 mm and found that
about 80% contained fish and 10% contained amphipods.
Overstreet and Heard (1978) found that penaeid and palaemonid
shrimps occurred in a higher percentage of fish <500 mm SL,
whereas blue crabs, the stomatopod Squilla empusa, and fishes
were most important in larger fish. Yokel (1966) also found
that red drum ate proportionately more crabs as they grew
larger, with fish diminishing in importance as food for the
largest red drum.
16 W. Foster. 1970. Life history aspects of the red drum, Sciaenops
ocellata. Progress Report to Sport Fishery Research Foundation.
�
17
Dietary items indicate that red drum feed over sandy to muddy
bottoms from both shallow and moderately deep water.
Grassbeds are also an important feeding area for preadult red
drum. Most feeding takes place in the early morning or
evening. Red drum have been observed "tailing" in shallow
marsh areas, rooting about with heads lowered and tails
occasionally out of water (Yokel 1966; Overstreet and Heard
1978).
Growth rates have been reported for red drum in the laboratory
(Arnold et al. 1977; Roberts, Morey et al. 1978; Holt, Godbout
and Arnold 1981; Lee et al. 1984), in ponds and raceways
(Luebke and Strawn 1973; Colura et al. 1976; Trimble 1979;
Hein and Shepard 1980; McKee 1980; Crocker et al. 1981;
Hysmith et al. 1982), and in the wild (Matlock and Weaver
1979; Perret et al. 1980; Goodrich and Matlock 1983) and were
summarized in Swingle et al. (1983) (Table 5). Growth rate
estimates for larvae and juveniles range from 0.04-1.7 mm/day.
However, the reliability and precision of some estimates are
questionable due to small sample sizes, inadequate procedural
detail, and absent, incomplete, or inappropriate statistical
analyses. The general growth pattern indicated by the
reliable estimates is sigmoidal (Swingle et al. 1983). Egg
diameter is 1 mm at spawning, and larvae are 2 mm at hatching
and grow 0.5 mm before yolk-sac depletion (Johnson et al.
1977). Larvae grow 0.2-0.5 mm/day, juveniles 0.7-1.7 mm/day,
and adults 0.5 mm/day (Swingle et al. 1983).
3.5 Behavior
Red drum migrate seasonally along the Atlantic coast (Yokel
1966). Reports from fishermen and menhaden spotter pilots
indicate that red drum typically arrive at Cape Hatteras,
North Carolina between March and April, some entering Pamlico
Sound and others proceeding up the coast. Red drum are
expected about a week later at Oregon Inlet (40 miles north of
Cape Hatteras) and three weeks to a month later in Virginia,
some entering Chesapeake Bay. Apparently in times of high
abundance and proper environmental conditions, red drum
averaging 13-14 kg were present along the New Jersey coast in
summer (May to October) (Welsh and Breder 1923). Red drum
leave Virginia in most years by October and fall fishing along
the North Carolina coast starts in August and usually ends in
November (Yokel 1966). A preliminary tagging study in Pamlico
Sound and along the Outer Banks, North Carolina indicated
movement of some red drum (ry7-447 mm TL) out of the sounds
and south along the beaches . In a tagging study of red drum
(251-600 mm TL) in Georgia, 88.6% (70 fish) of the recoveries
17 J. Ross, North Carolina Division of Marine Fisheries, Manteo, N.C.,
personal communication.
�
F.-
00
Table 5. Published red drum growth rates (where necessary, standard lengths converted to total lengths using Harrington et
al. (1979); blanks indicate no estimates given) [from Swingle et al. 1983].
State Length of Initial
and Growing growing size Temperature Salinity Growth rate
Environment reference period (days) or age (0/0 (0/00) (mm TL/day) Comments
Laboratory Florida Not given 15+ Embryo 23 30 0.36 Found no significant
Roberts, Morey, influence of stocking
et al. (1978) density (2, 10, and 20
embryos/liter) and food
density (1,5, and 10
rotifers/ml) on larval
growth using two-way
analysis of variance.
Laboratory Texas Not given 14 Embryo 20 15-30 0.24 Found no significant
Holt, Godbout, 25 15-30 0.34 influence of temperature but
and Arnold 30 15-30 0.46 did find significant influ-
(1981) ence of salinity on larval
growth using two-way
analysis of variance.
Laboratory Texas Not given 570 44 mm TL 0.70- Growth was 1.14 mm/day in
Arnold et al. 1.14 first 180 days and 0.70
(1977) mm/day in last 390 days; no
other details given.
Laboratory Texas Not given 15 Larvae 24 30 17.74pg/day Two growth periods; one
Lee et al. 28 30 30.25pg/day extending from hatching
(1984) through depletion of yolk
sac, and other beginning at
onset of active feeding.
Growth in length and weight
was significantly greater at
28*C than at 24*C.
�
Table 5. (continued)
State Length of Initial
and Growing growing size Temperature Salinity Growth rate Comments
Environment reference period (days) or age (0/0 (0/00) (mm TL/day)
Raceways Texas July-August 30 72 mm TL 35�2 1.7 Analysis of covariance used
Crocker et al. 1979 0 1.3 to test for differences in
(1981) growth between salinities,
but variance homogeneity
assumption apparently vio-
lated; conclusion of sig-
nificant difference is
questionable but growth rate
exceeded 1.0 mm/day regard-
less; 93% survival in both
treatments.
Ponds Alabama Oct. 1976- 136-946 2 days Not given, Disease problems rampant;
Trimble (1979) May 1979 presented data not statistically
weight analyzed; incomplete detail
data only on procedures used to esti-
mate size at stocking,
sampling techniques, and
growth in weight estimates.
Ponds Louisiana Oct. 1978- 79 17-42 mm TL 19 0.92 Based on 86 fish; a total
Hein and Jan. 1979 (avg) die off occurred due to cold
Shepard temperature and low water
(1980) level.
Ponds Texas Aug.-Nov., 27-37 2-6 days 1.02-1.66 No adjustments for stocking
Colura et al. 1975 rate variations (156,000 -
(1976) 880,000 larvae/ha); stocking
rate estimating procedures
not given; estimating proce--
dures for mean size at
stocking or harvest not
given; survival in ponds
very low ( 10%); few details
given.
I.-
110
�
Table 5. (continued)
State Length of Initial
and Growing growing size Temperature Salinity Growth rate
Environment reference period (days) or age (O/C) (0/00) (mm TL/day) Comments
Ponds Texas 8 June 151 272-295 mm TL 0.76-0.85 Estimating procedure not
(received Luebke and 6 Nov., 1972 clearly defined; only 13%
heated power Strawn (1973) mortality.
plant effluent)
Ponds Texas 7 Nov., 108-173 41 mm TL 0.66tO.O4 No significant influence
Hysmith et al. 1975 - (Fed) of stocking density on
(1982) 28 April, 0.35tO.O6 growth; significantly higher
(Unfed) growth in fish fed
artificial diet than in
those not fed; no indication
of reduced growth in winter;
few details on sampling
techniques.
Power plant Texas Nov. 1975- Not given 366-837 0.49tO.O5 Based on 27 recaptured
cooling lake McKee (1980) Nov. 1977 mm TL tagged fish; growth rate (Y)
decreased significantly with
increased size at tagging,
according to Y = 0.75925 -
0.00246 X (X = SL mm at
tagging).
Wild Florida 1961-1965 Not 282-655 mm 0.04-0.66 Data from 12 recaptured
Perret et al. applicable tagged fish published by
(1980) TL Ingle et al. (1962), Topp
(1962), Beaumariage (1964),
and Beaumariage and Wittich
(1966).
�
Table 5. (continued)
State Length of Initial
and Growing growing size Temperature Salinity Growth rate
Environment reference period (days) or age (O/Q 0/oo) (mm TL/day) Comments
Wild Texas Nov. 1975- Not 275-815 mm 0.43tO.O8 Based on 110 recaptured
Matlock and Sep. 1976 applicable tagged fish from Texas bays;
Weaver (1979) TL no significant difference in
growth among bays; no
apparent change in growth
with increased size at
tagging but no statistical
analyses conducted; data
obtained from fishermen.
Wild Texas June 1979 350 41 mm TL 1.03tO.O5 Based on 48 recaptured
Goodrich and May 1980 stocked fish from St.
Matlock (1983) Charles Bay; artificiallly
reared juveniles stocked out
of phase with wild fish so
identifiable by size; fish
grew through two summers in
first year so growth rate
should be greater than wild
fish.
r%3
,.2
�
22
were within 25 km of the tagging sites. Five percent (4 fish)
exhibited an average northward movement of 112.5 km and 5%
(5 fish) exhibited an average southward movement of 112.2 km
(Pafford 1981; Music and Pafford 1984). Beaumariage (1969)
reported that 91.2% of the red drum recovered during five
Schlitz tagging programs in Florida did not move significantly
from their release locations.
Tagging studies in Gulf of Mexico estuaries have indicated
little movement of subadult red drum. More than 85% of the
recaptured red drum from tagging studies in Florida bays moved
<10 km f rom the tagging site (Ingle et al. 1962; Topp 1963;
Beaumariage and Wittich 1966; Beaumariage 1969). Simmons and
Breuer (1962) reported little intrabay movement of red drum
from Aransas Bay, Texas southward. Other Texas tagging
studies have indicated broad random movements within bays
(Heffernan 1973) with little movement out of bays in which
tagged (Osburn et al. 1982). Some movement from the bays to
the Gulf along the Texas coast has been noted in fall, with a
return in spring (Pearson 1929; Gunter 1945; Miles 1950).
Immature red drum have been caught in the Gulf surf zone
(Simmons and Hoese 1959; Heffernan 1973) which indicates that
not all juveniles enter, or remain in, the bay nursery
grounds. Red drum tagged in inshore waters of Louisiana and
Mississippi were recaptured inshore (Adkins et al. 1979;
Overstreet 1983).
A Mississippi tagging study (Overstreet 1983) and observations
by commercial fishermen and menhaden spotter pilots suggest
that after leaving the estuaries large red drum undertake
extensive migrations in the Gulf of Mexico. There appears to
be a general migration along the Gulf coast from off Alab
in April toward the Breton Island and Cameron areas of
Louisiana, and by September or October the schools disappear
offshore, presumably to spawn. A few spent fish appear along
the beaches in October and November. An individual 810 mm SL
long, migrated 778 km westward after 752 days and 769 mm SL
long fish moved eastward at least 316 km within 399 days
(Overstreet 1983). The longest reported migration in the Gulf
of Mexico was from Texas to Tampa Bay (Simmons and Breuer
1976).
Carr and Chaney (1976) traced movements of a red drum with an
ultrasonic transmitter attached to its caudal peduncle, in the
Intracoastal Waterway in Florida. All movement, both north
and south, was against the tidal flow, and the fish entered
numerous side creeks and moved into a deep hole in a creek at
nightfall.
3.6 Contaminants
Red drum were included in a survey of trace elements in
fishery resources (Hall et al. 1978). Muscle and liver tissue
�
23
from red drum from the North and South Atlantic and Gulf of
Mexico were analyzed for the occurrence of 15 elements. No
interpretative comments were provided.
Trace metal poisoning was indicated as the possible cause of
death of a group of approximately 100 large (7-18 kg) red drum
in the Indian River System, Florida between June 14 and July
2, 1980. High levels of copper, zinc, arsenic, chromium,
cadmium, and mercury were found in the liver and/or gills, and
lesions in the gills resembled those from fish subjected to
experimental copper poisoning (Cardeilnac et al. 1981).
Commercial fishermen report that larff kills of red drum have
occurred several times in this area.
A survey of polychlorinated biphenyls (PCBs) in selected
finfish species determined that the mean level of PCBs in five
red drum from Texas was 0.03 ppm (range: 0.02-0.04 ppm).
This level is far below existing (5 ppm) or proposed (2 ppm)
maximum permissible levels in foodfish (Gadbois and Maney
1983).
Rabalais et al. (1981) investigated the effects of oil on red
drum eggs and larvae from an oil spill in the Bay of Campeche
which reached the south Texas coast. High larval mortality
resulted when larvae were placed in mixtures of oil and water.
When eggs were placed in oil-contaminated water from Port
Aransas jetties, over half of the hatched larvae had skeletal
anomalies.
4. POPULATION
4.1 Structure
The age/size structure of red drum populations is largely
unknown. Length-at-age estimates for the Gulf of Mexico and
Atlantic coast vary considerably (Tables 6 and 7) and some are
probably overestimates because of failure to consider time of
annulus formation, gear selection bias, recaptured tagged fish
size data reliability, small sample sizes, and unverified age
determination techniques (Swingle et al. 1983).
Length frequency, scale, and otolith techniques have been used
to age red drum (Pearson 1929; Gunter 1945; Miles 1950, 1951;
Simmons and Breuer 1962; Theiling and Loyacano 1976; Rohr
1980; Wakefield and Colura 1983; Music and Pafford 1984). The
length frequency method is generally only useful for the first
18 R. Williams. Florida Department of Natural Resources, St. Petersburg,
Florida, personal communication.
�
N-)
Table 6. Published total length-at-age estimates for red drum. (Where necessary, standard lengths converted to total
lengths using TL = 12.870 + 1.177 SL (Harrington et al. 1979); blanks indicate no estimates given)
[modified from Swingle et al. (1983)].
Age
AGE - YEARS determination
Location Reference 1 2 3 4 5 6 7 8 method
Fernandina, Fla. Welsh and 390-
Breder (1923) 590 Scales
Chandeleur Rohr (1980) 363 545 670 757 816 858 886 906 Otoliths
and Mississippi
Sounds, La.
Central coast, Tex. Pearson (1929) 300 530 630 750 840 Length frequency
Central coast, Tex. Pearson (1929) 420 520 720 780 830 Scales
Laguna Madre, Tex. Pearson (1929) 350 540 640 740 Length frequency
Aransas Bay, Tex. Miles (1950) 395 Length frequency
Aransas Bay, Tex. Miles (1951) 390- 601 660- 875 925 975-
435 710 11000 Otoliths
Upper Laguna Simmons and 325 Length frequency
Madre, Tex. Breuer (1962)
Central coast, Tex. Simmons and 540 760 Tag recapture
Breuer (1962)
Galveston Bay, Tex. Wakefield and 274 453 571 650 Scales
Colura (1983)
Matagorda Bay, Tex. Wakefield and 252 409 548 634 694 Scales
Colura (1983)
Lower Laguna Wakefield and 290 462 565 Scales
Madre, Tex. Colura (1983)
�
Table 7. Empirical and back calculated total lengths for red drum collected in South Carolina, Georgia, and Florida.
Annuli
Location Reference Method Sex 1 2 3 4 5 6
South Theiling and otoliths Combined
Carolina Loyacano (1976) *Mean length at capture 585 731 825 849 891 849
Number 15 11 3 3 26
Georgia Music and Pafford scales Combined
(1984) Mean length at capture 474 718 776
Back calculated length 403 653 746
Number 24 8 1
Males
Mean length at capture 475 711 776
Back calculated length 435 656 746
Number 9 5 1
Females
Mean length at capture 541 731
Back calculated length 412 645
Number 12 3
Florida otoliths Combined
East Coast +Back calculated length 436 606 695 746
Number 328 153 34 8
*SL converted to TL by TL 12.870 + 1.177 SL (Harrington et al. 1979)
+Fork length
I
M. Murphy, Florida Department of Natural Resources, St. Petersburg, Florida, personal communication.
�
26
few years of life. Problems with using scales and otoliths to
age red drum include circuli disconformities, closely spaced
annuli, and intermittent summer and winter annuli on scales,
and spawning checks on otoliths, particularly for fish older
than age III or IV (Rohr 1980; Music and Pafford 1984).
Mean empirical lengths and back-calculated lengths for red
drum from South Carolina, Georgia, and Florida ageing studies
are presented in Table 7. The sizes shown are sizes at the
annulus, not at the birthdate. A Florida study validated the
first three rings on otoliths as annual rings. The first
annulus forms at 14-17 months, and then annually for at least
the next two years. The regression of fork length on otolith
radius was not linear when all age groups were included, but
was linear for fish with four or fewer annuli. For older fish
the rate of increase in fork length per unit increase in
otolith ' radius declined. The fork length (FL) - otolith
radius (OR) relation for fish 2with four o1r9 fewer annuli was:
FL = 26.54 + 311.65 OR (mm) (r = 0.8475).
Back-calculated lengths for red drum in Florida were similar
to Georgia fish at first annulus, but smaller at successive
annuli. The sample size in the Georgia study was small (33
fish) and the method of age determination was not validated.
Lengths presented by Theiling and Loyacano, (1976) for 62 red
drum confined to a saltwater marsh impoundment in South
Carolina were mean lengths at capture and therefore were
greater than back-calculated lengths. The ageing method was
not validated in that study. Bearden (1967) reported that red
drum impounded in a brackish water pond in South Carolina
averaged 368 mm at age 1, 521 mm at age II, and 660 mm at age
III, but the method of age determination was not reported. A
major research need for red drum is the development of a
uniform method of age determination throughout the range.
Von Bertalanffy growth equation parameters were estimated f 26
red drum in South Carolina (Swingle et al. 1983), Florida,
Louisiana (Rohr 1980), and Texas (Swingle et al. 1983;
Wakefield and Colura 1983) (Table 8). Swingle et al. (1983)
based their estimates for South Carolina and Texas on data
from Theiling and Loyacano (1976) and Pearson (1929),
respectively, using Rafail's (1973) technique.
Numerous equations for the red drum length-weight relationship
have been published for the Gulf (Boothby and Avault 1971;
Luebke and Strawn 1973; Bass and Avault 1975; Harrington et
al. 1979; Hein et al. 1980; McKee 1980; Overstreet 1983) and
Atlantic coasts (Theiling and Loyacano 1976; Music and Pafford
19, 20 M. Murphy, Florida Department of Natural Resources, St.
Petersburg, Florida, personal communication.
�
Table 8. Estimates of von Bertalanffy growth parameters for red drum.
Area Source L- (mm TL) K t0
South Carolina Swingle ?t al. 945 0.449 -0.324
(impounded marsh) (1983)
Florida (2) 1,043 0.42 -0.149
(Mosquito Lagoon/
Upper Indian River)
Florida (2) 993 0.46 0.029
(Tampa Bay area)
Louisiana Rohr (1980) 950 0.37 -0.33
(Chandeleur and
Mississippi Sounds)
Texas Swingle st al. 1,068 0.295 0.144
(1983)
Texas Wakefield and Colura 717 0.52 -0.01
(Lower Laguna Madre) (1983)
(Matagorda Bay) 835 0.35 -0.02
(Galveston Bay) 804 0.41 -0.01
IBased on data from Theiling and Loyacano (1976).
2M. Murphy and R. Taylor, Florida Department of Natural Resources$ personal communication.
3Based on data from Pearson (1929).
�
rQ
Table 9. Published standard length-weight relationships for red drum [Music and Pafford (1984) and Harrington et al. 00
(1979) are total length-weight relationships]. Weight is in g and length in mm, except cm for Theiling and
Loyancano (1976). [from Swingle et al. (1983)].
Calculated
weight (g)
Length of 200 mm
State Area Reference N range Log a b SL fish
South Carolina Marsh Impoundment Theiling and Loyacano 54 Not given -1.29596 2.7403 186
(1976)
Georgia Estuaries Music and Pafford (1984) 103 32-1099 -4.220 2.722 ill
Mississippi Mississippi Sound Overstreet (1983) 480 143-965 -4.7358 3.0053 151
Louisiana Coastal marsh Boothby and Avault 286 240-940 -4.42161 2.83284 125
near Hopedale (1971)
Louisiana Salt marsh near Bass and Avault 568 8-183 -7.2052 4.1913 275
Caminada Pass (1975)
Louisiana Southeastern Hein et al. (1980) 308 14-1135 -5.1197 3.0523 80
coast
Louisiana Bays and gulf McKee (1980) 23 483-921 -3.435 2.54 257
Texas Heated ponds in Luebke and 47 283-411 -4.69 2.97 139
Galveston Bay Strawn (1973)
system
Texas Cooling lake near McKee (1980) 30 319-720 -3.939 2.71 198
Corpus Christi; at
tagging
Texas Bays and gulf McKee (1980) 45 312-885 -4.058 2.75 186
Texas Nine bays Harrington et al. 8319 49-814 -5.085 3.041 158
(1979)
�
29
1984) (Table 9). Differences in the regression coefficients
may be due to sample sizes, length ranges, maturity, and time
of sampling. Perret et al. (1980) concluded that the
length-weight relationships of Boothby and Avault (1971),
Luebke and Strawn (1973), Theiling and Loyacano (1976),
Harrington et al. (1979) were similar although no statistical
analysis was conducted.
4.2 Abundance, density, mortality, and dynamics
Commercial landings data have been collected from fish dealers
in each state since 1880; from 1880 to 1927, the survey was
conducted at approximately five year intervals; from 1927 to
1956, annual surveys were conducted; and since 1956, data,has
been collected on a monthly basis. It should be noted that
commercial statistics, when biased, tend to be underestimated,
due to failures in reporting which are inherent in their
collection. Landings data may reflect changes in effort and
market preferences and are not necessarily indicative of
trends in stock abundance.
Atlantic coast landings of red drum have always been lower
than Gulf of Mexico landings (Figure 2). The highest recorded
landings for the Atlantic coast were 788 mt in 1945, compared
with 1,594 mt in the Gulf of Mexico for the same year. The
highest reported landings in the Gulf were 2,410 mt in 1976.
Highest landings on the Atlantic coast in recent years
occurred in 1980 (200 mt).
Landings of red drum at the northern extreme of the range have
declined since the 1930s (Table 10). No red drum landings
have been reported for New York since 1942. A total of 93 mt
of red drum were landed in New Jersey from 1926 through 1935,
while only 21 mt were caught in the decade ending in 1945.
Since 1945 there has been only one commercial landing of red
drum (<I mt) in New Jersey in 1951.
Similar declines in landings have apparently taken place along
the coast to the south of New Jersey with the exception of the
east coast of Florida (Table 10) (Figure 3). Delaware annual
landings have never exceeded I mt and were recorded for only
six years between 1926 and 1978. Maryland red drum landings
have never exceeded 7 mt and only sporadic landings (<I mt)
have been recorded since 1959. Virginia landings were highest
in 1950 (83 mt) and did not exceed 9 mt over the past 20
years, except in 1965 (42 mt) and 1983 (22 mt). Red drum
landings in South Carolina and Georgia have fluctuated widely
and parallel each other. Highest landings in South Carolina
were from 1887 to 1908 (23-50 mt), 1936 to 1940 (38-54 mt),
and 1950 to 1956 (5-52 mt) . South Carolina landings of red
drum ranged from <1-6 mt from 1969 to 1982. Georgia landings
�
30
.8- ATLANTIC OCEAN
6-
4-
2
0
0 [fill
0
cn 26-
M
24-
22-
20- GULF OF MEXICO
18-
16- If
14-
12- -7
10-
8-
6- L
4-
2-
III I, p 11 1 111 1, 111.. 1. 111 11. 111-1
1930 1935 1940 1945 1950 1955 1960 1965 1970 1975 1980
YEAR
Figure 2. U.S. commercial landings of red drum for the
Atlantic coast and Gulf of Mexico, 1930-1983.
�
31
Table 10. Commercial landings of red drum by state, 1887-1983
(metric tons).
Florida
New New NorIh South East
Year York Je rsey Delaware Maryland Virginia Carolina Carolina Georgia Coast Total
1887 - - - - - 59 25 9 93
1888 - - - - - 64 23 10 - 97
1889 - - - - - 234 41 15 78 368
1890 - - - - - 99 40 18 78 235
1897 - - - - - 81 50 11 107 249
1902 - - - - - 65 46 16 52 179
1908 - - - - - 156- 49 69 371 645
191 - - - - - 45+ 168 214
1923 111 14 55 181
1925 2 57 - - 59
1926 6 1 - - - - - a
1927 - - - 45 3 74 123
1928 - - - - - 108 2 3 92 205
1929 - 12 1 1 4 89 5 2 98 212
1930 - 29 - 7 16 66 4 2 39 163
1931 - 2 5 10 39 1 2 52 111
1932 - 22 6 11 39 1 1 21 101
1933 - 4 3 23 - - - - 31
1934 - - 3 24 60 2 1 65 155
1935 - 18 2 16 - - - - 36
1936 - - - 2 Is 114 47 23 106 307
19 37 5 - 1 20 200 54 17 37 748
1938 2 - 1 61 241 47 12 50 414
1939 2 - 2 33 172 38 9 79 335
1940 1 - 1 30 61 39 5 84 221
19 41 - - 1 18 - - - 19
1942 7 - 1 7 - - 15
1943 2 - - - - - 2
1944 1 15 - - - - 16
1945 1 - 16 102 22 5 642 788
1946 - - II - - - - 11
1947 3: 36B
1948 1 1
1949 35 - - - - 35
1950 1 83 91 15 9 86 285
1951 2 34 83 52 9 60 240
1952 1 - 21 101 31 6 52 212
1953 9 129 25 6 58 227
1954 2 18 121 5 6 63 215
1935 - 17 61 30 3 44 155
1956 9 14 26 1 48 98
1957 - 11 63 - 49 123
1958 1 16 8 46 71
1959 5 2 59 76
1960 13 36 59 108
1961 - 5 41 52 99
1962 - - 3 28 - 68 99
1963 - - 1 32 - - 61 94
1964 - - 2 46 5 - 54 107
1965 - 42 32 - - 66 140
1966 1 16 1 69 88
1967 6 73 80
1968 5 2 75 82
1969 2 1 54 58
1970 3 67 71
1971 8 1 1 37 47
1972 3 20 1 1 58 83
1973 3 32 1 76 112
1974 7 64 1 1 62 105
1975 9 97 6 5 38 155
1976 8 76 1 3 48 136
1977 9 2 47 59
1978 1 10 2 48 61
1979 1 58 1 43 102
1980 110 2 1 87 200
1981 42 118 161
1982 1 24 1 63 89
1983 22 100 1 45 168
-Not reported
*Less than I metric ton
+Includes black drum
�
32
Table 10. (continued)
Florida
West
Year Coast Alabam Mississippi Louisiana Texas Total
18:7 - 64 131 456 -651
18 a 25 - 75 131 429 660
1889 178 29 84 143 483 916
1890 208 25 91 154 503 981
1897 107 97 90 211 519 ':' 25
1902 501 32 42 201 408 1 184
1908 276 69 ill 325 594 1,375
1918 452 10 53 257 607 1,379
1923 635 7 80 302 399 1,422
1925 - - - - - -
1926 - - - - - -
1927 352 25 108 252 567 1,304
1928 404 22 94 197 468 1.185
1929 450 48 59 202 424 1,183
1930 425 47 55 152 396 1.076
1931 424 28 45 168 392 1,057
1932 326 20 34 128 375 883
1933 - - - - - -
1934 396 30 33 223 717 1,399
1935 - - - - - -
1936 421 15 40 158 434 1,068
1937 430 30 56 204 433 1.154
1938 459 15 48 237 390 1,150
1939 412 14 75 315 213 1,030
1940 294 12 25 83 120 534
1941 - - - - - -
1942 - - - - - -
1943 - - - - - -
1944 - - - - - -
1945 587 Ito 30 270 589 1,594
1946 - - - - -
1947 - - - - -
1948 71 25 115 282 493
1949 758 51 35 218 236 1,298
1950 428 7 24 207 257 923
1951 417 20 14 174 108 733
1952 293 25 19 149 114 600
1953 239 21 28 124 232 644
1954 341 9 28 123 327 828
1955 342 9 26 156 224 757
1956 346 22 32 185 291 877
1957 303 5 25 160 229 721
1958 285 9 30 222 272 816
1959 314 8 32 222 437 1,013
1960 371 4 Is 194 320 907
1961 385 11 24 302 280 1,002
1962 593 6 35 257 317 1,209
1963 439 9 27 212 311 998
1964 317 9 23 142 203 693
1965 364 2 15 214 242 836
1966 293 3 17 242 362 916
1967 225 4 44 297 349 918
1968 321 7 98 336 420 1,182
1969 266 23 45 355 493 1,181
1970 303 16 32 358 720 1,429
1971 321 15 27 329 904 1,595
1972 383 35 25 404 666 1,513
1973 433 78 39 538 762 11850
1974 541 54 40 652 872 2,159
1975 345 34 33 618 962 1,992
1976 411 30 43 1,004 921 2,410
1977 383 30 74 651 432 1,570
1978 408 39 299 553 391 1,690
1979 338 39 88 480 313 1,258
1980 371 24 9 329 506 1,239
1981 513 17 30 408 278 1,248
1982 361 31 18 661 - 1 071
1983 350 27 11 872 1:260
-Not reported
*Less than I metric ton
+Includes black drum
�
33
ranged from 9-69 mt between 1887 and 1908, 5-23 mt from 1936
to 1940, 1-9 mt from 1950 to 1956, and <1-5 mt from 1966 to
1982. Florida and North Carolina contribute the most to east
coast landings of red drum. North Carolina landings were
highest in 1938 (241 mt) and have fluctuated between 2 and 129
mt since 1950. Florida landings peaked at 642 mt in 1945 and
have not fluctuated greatly since 1950, ranging from 37-118 mt
through 1983.
Recreational fishery statistics are available from National
Marine.Fisheries Service salt-water angling surveys conducted
at five-year intervals from 1960-1970 (Clark 1962; Deuel and
Clark 1968; Deuel 1973), regional surveys in 1974 and 1975,
and annual surveys since 1979 (Anonymous 1980; Anonymous in
press). Caution should be exercised in interpreting or
comparing the results of these surveys (Anonymous 1980).
First, estimated catches in the 1960-1970 national surveys and
1974-1975 regional surveys are subject to considerable
statistical variability. Second, although the sampling
procedures were similar for the 1960-1970 surveys, they were
considerably different from the 1974-1975 sampling procedures.
In addition, all of these surveys relied on the fisherman's
ability to identify the species caught and to recall the
numbers and average weight of each species caught, resulting
in overestimates of the catch. The magnitude of the
overestimation is not known. The sampling design of the
1979-present surveys is significantly different from previous
surveys, including both a household survey and creel census.
Although the 1979 survey results were published (Anonymous
1980), they are presently being corrected to correspond with
1980 census figures. The 1960-1970 and 1980-1982 survey
results are presented here (Tj@les 11 and 12); however, 1981
and 1982 data are preliminary.
The estimated recreational catch of red drum exceeds
commercial red drum landings. The total estimated Atlantic
coast recreational catches of red drum exceeded commercial
landings by factors of 162 in 1960, 53.3 in 1965, 85.9 in
1970, 2.7 in 1980, 2.1 in 1981, and 4.9 in 1982. Although
the 1960-1970 Salt-Water Angling Surveys resulted in
overestimates of the catch, the results of the recent annual
surveys are generally underestimates (Anonymous 1980).
The estimated weight of the recreational catch of red drum on
the Atlantic coast (17,491 mt) exceeded the Gulf coast catch
(14,941 mt) in 1960, although twice as many fish were caught
in the Gulf. Both the number and weight of red drum caught in
the Gulf exceeded the Atlantic coast catch in all other survey
21 M. Holliday, National Marine Fisheries Service, Resource Statistics
Division, Washington, D.C., personal communication.
�
34
20 DELAWARE
ot
20 MARYLAND
01
-I
80-
VIRGINIA
60-
40-
20-
0!
120- NORTH CAROLINA
100-
80-
u) 60-
0 40-
20-
CC
UJ 60-
- SOUTH CAROLINA
40-
20-
0
201 GEORGIA
120] FLORIDA EAST COAST
100
80-
60-
40-
20-
0 50 55 1.11 60 .1.1 65 76 . . . . 75' 1 T 1861 1
YEAR
Figure 3. U.S. commercial landings of red drum on the Atlantic
coast by state, 1950-1983.
�
35
years. Total Atlantic coast landings declined from 1960 to
1970, whereas Gulf coast landings increased over the same
period. Although results of the 1980 survey are not directly
comparable with previous surveys, they are lower by factors of
11.2 and 4.5 on the Atlantic and Gulf coasts, respectively,
raising the question of data set reliability. Preliminary
results of the 1981 and 1982 surveys indicate a decline in
recreational catch in 1981 and 1982 on both coasts.
Results of the salt-water angling surveys indicate that
recreational red drum landings in the Middle Atlantic region
(New York to Virginia) declined drastically from 5,176 mt in
1960 to 582 mt in 1965 and 38 mt in 1970 (Clark 1962; Deuel
and Clark 1968; Deuel 1973) (Table 11). Red drum were not
reported for the Middle Atlantic subregion in the 1980 survey;
however, the category "drums" (8.5 mt) may include red drum.
Preliminary results of the 1981 and 1982 surveys indicate that
92,000 red drum (223 mt) were caught in 1981 and 52,000 (no
weight reported) in 1982 in the Middle Atlantic region (Table
12).
South Atlantic (North Carolina to Florida) catches declined
from 1960 (12,331 mt) to 1970 (6,065 mt). In 1980 the
estimated recreational catch was 545 mt. Preliminary results
of the 1981 and 1982 recreational surveys indicated that 115
mt were caught in 1981 and 438 mt in 1982 in the South
Atlantic.
Although the results of the 1983 recreational survey are not
yet available there is some indication that red drum abundance
is increasing. In 1983 recreational fishermen reported that
small red drum (0.7-1.1 kg) returned in unprecedented numbers
to Chesapeake Bay and its tributaries, Pamlico Sound, North
Carolina, and the surf from Assateague Island to Portsmouth
Island. These fish were apparently the result of an excellent
spawn during the fall of 1981. Commercial mullet netters in
Pamlico Sound reported large numbers of small red drum (10-13
cm) in their nets in May and June, 1983, indicating that
perhaps the fall spawn in 1982 was also a good one (The Year
of the Puppy Drum. 1983).
There are no mortality estimates for Atlantic coast
populations of red drum. Instantaneous natural (M), total
(Z), and fishing (F) mortality rates have been calculated for
various estuarine populations in the Gulf of Mexico (Matlock
and Weaver 1979; Swingle et al. 1983; Green et al. in prep.).
Fishing mortality in most Gulf estuarine areas is high
relative to natural mortality (Swingle et al. 1983).
There are no estimates of maximum yield per recruit for
Atlantic coast populations of red drum. Juvenile populations
are growth overfished in Texas and possibly severely growth
overfished along the west central coast of Florida, based on
estimates of instantaneous fishing mortality (F) from tagging
studies (Swingle et al. 1983).
�
M
Table 11. Red drum recreational catch and effort statistics from National Marine Fisheries Service Salt-Water Angling
Surveys, 1960 - 1970.
Catch Number of Average Catch per angler
Survey I Weight Successful Weight Weight
Year Number kg Anglers ... lb kg Number lb kg
-------------- THOUSANDS --------------
1960 1
Middle Atlantic 456 11,400 5,171 35 25.0 11.4 13.0 325.7 147.9
South Atlantic 4,527 27,160 12,320 157 6.0 2.7 28.8 173.0 78.5
Gulf of Mexico 10,294 32,940 14,941 447 3.2 1.5 23.0 73.7 33.5
TOTAL 15,277 71,500 32,432 639 4.7 2.1 23.9 111.9 50.8
1965 2
Middle Atlantic 196 1,281 581 68 6.5 2.9 2.9 18.8 8.6
South Atlantic 4,099 15,171 6,881 151 3.7 1.7 27.1 100.5 45.6
Gulf of Mexico 6,900 28,288 12,831 558 4.1 1.9 12.4 50.7 23.0
TOTAL 11,195 44,740 20,294 777 4.0 1.8 14.4 57.6 26.1
1970 3
Middle Atlantic 97 83 38 8 0.9 o.4 12.1 10.4 4.8
South Atlantic 4,883 13,358 6,059 164 2.7 1.2 29.8 81.5 37.0
Gulf of Mexico 13,184 53,045 24,061 692 4.0 1.8 19.1 76.7 34.8
TOTAL 18,164 66,486 30,157 864 3.7 1.7 21.0 77.0 34.9
Clark 1962
2
Deuel and Clark 1968
3Deuel 1973
�
37
Table 12. Red drum recreational catch statistics from National Marine
Fisheries Service Marine Recreational Fishery Statistics Surveys,
1980-1982.
Catch Average
Survey Weight Weight
Year Number lb kg lb kg
-------------- THOUSANDS --------------
19801
South Atlantic 419 1,202 545 2.9 1.3
Gulf of Mexico 4,893 11,865 5,382 2.4 1.1
19812
Middle Atlantic 92 491 223 5.3 2.4
South Atlantic 166 254 115 1.5 0.7
Gulf of Mexico 4,194 8,631 3,915 2.0 0.9
19822
Middle Atlantic 51 - - - -
South Atlantic 516 964 438 1.8 0.8
Gulf of Mexico 7,304 16,169 7,334 2.2 1.0
1Anonymous in press.
2Preliminary data, M. Holliday, National Marine Fisheries Service, Resource
Statistics Division, Washington, D.C., personal communication.
-Not reported.
�
38
4.3 Community ecology
Juveniles may spend the first four or five years within
estuaries (Pearson 1929) where they compete with other
estuarine species for food. Food habits and distributions of
red drum were reviewed in earlier sections of this report.
Young-of-the-year red drum (15-245 mm TQ in North Carolina
estuaries were frequently collected with the bay anchovy
(Anchoa mitchilli), inland silverside (Menidia beryllina),
Atlantic silverside (M. menidia), sheepsheTd minnow (Cyprindon
variegatus), stripe@- mullet ('Mugil cephalus), menhaden
(Brevoortia tyrannus , spot (Leiostomus xanthurus), croaker
(Micropogonias undulatus), mojarras (Gerreidae), gobies
(Gobiidae), summer flounder (Pa W ichthys dentatus), and
southern flounder (P. lethostigma).--
Adult red drum occur offshore, often under schools of blue
runner (Gar-anx chrysos) and little tunny (Euthynnus
alletteratus) in the Gulf of Mexico. When near shore, schools
of red drum often occur near black drum, Atlantic tarpon, and
pompano (Overstreet 1983).
5. EXPLOITATION
Matlock (1980) reviewed the history and management of the red drum
fishery.
5.1 Commercial Exploitation
5.11 Equipment and trends in equipment
Red drum are harvested in a mixed species f ishery by a
variety of gear types, including haul seines (common and
long), fish trawls, pound nets, gill nets (drift, anchor,
set or stake, and runaround), hand lines, trammel nets,
and shrimp trawls (Matlock 1980). Purse seine catches of
red drum have been reported in the Gulf of Mexico since
1977.
The percentage of Virginia landings of red drum taken by
gear type is presented in Table 13. Pound nets and fish
trawls have accounted for the major portion of the
landings since 1977. Haul seines and gill nets
contributed significantly prior to 1977 and again in
1983.
22 Unpublished data, North Carolina Division of Marine Fisheries,
Morehead City, N.C.
�
39
Gill nets have accounted for 31-57% of red drum landings
since 1979 in North Carolina (Table 14). Common and long
haul seine catches have declined since 1977 and f ish
trawl and pound net catches have fluctuated. The
incidental catch by shrimp trawls ranged from 0.5-15.2%
of North Carolina red drum landings from 1978 to 1983.
Red drum are mainly caught by shrimp trawls, hand lines,
and gill nets in South Carolina (Table 15). Hand lines
have accounted for 100% of Georgia landings since 1978
(Table 16).
Runaround gill nets are the predominant gear in Florida,
accounting for 65.5-83.6% of the red drum catch (Table
17). Red drum are also caught by hand lines, haul seine,
and trammel nets.
5.12 Areas fished
Red drum are caught in both estuaries and oceanic waters
along the Atlantic coast, but the majority of the
commercial catch is made in estuaries (Table 18).
Juvenile red drum, which remain in or near estuaries for
the greater part of their early years, are the basis for
the commercial fishery. Estuarine areas generally
receive a high level of effort with gear which catch red
drum, such as trammel nets, gill nets, haul seines, pound
nets, and trot lines (Yokel 1966). Although Florida
landings by area of capture were fft available, most red
drum are caught in the estuaries.
5.13 Seasons
In Virginia red drum are harvested from May until October
and are most abundant during spring and fall (Hildebrand
and Schroeder 1928). Red drum are taken year-round from
North Carolina to Florida. Largest catches in North
Carolina are made in fall (October-November). In South
Carolina more red drum are landed in late spring and
summer and in Georgia in late summer and fall. Highest
landings in Florida occur in fall and early winter.
23 E. Snell, National Marine Fisheries Service Resource Statistics
Office, Miami, Florida, personal communication.
�
40
Table 13. Percentage of Virginia red drum landings by gear type, 1970-1983.
Common Sea Fyke & Total
Haul Fish Pound Gill Hand Scallop Hoop Landings
Year Seines Trawls Nets Nets Lines Dredges Nets (kg)
1970 100.0 45
1971 100.0 318
1972 54.2 1.7 30.5 13.6 2,676
1973 17.7 25.8 56.5 2,812
1974 5.7 1.3 79.0 14.0 7,121
1975 19.9 3.1 49.5 27.5 8,890
1976 35.3 5.8 22.6 34.2 8,618
1977 33.3 33.3 33.3 136
1978 14.3 61.9 23.8 953
1979 73.7 26.3 862
1980 25.0 50.0 25.0 181
1981 50.0 50.0 91
1982 56.5 36.9 1.8 2.3 2.4 854
1983 17.8 2.0 42.1 37.9 0.2 18,516
Source: Fishery Statistics of the United States, 1970-1977; NMFS Landings
Data, 1978-1983.
�
41
Table 14. Percentage of North Carolina red drum landings by gear type,
1970-1983.
Common Long Total
Haul Haul Fish Pound Gill Shrimp Hand Landings
Year Seines Seines Trawls Nets Nets Trawl Lines (kg)
1970 9.3 32.0 9.3 8.0 41.3 3,402
1971 28.5 18.0 8.1 21.5 23.8 7,802
1972 30.5 12.8 2.8 45.2 8.6 19,459
1973 25.9 30.0 11.1 14.2 18.8 31,888
1974 21.0 45.9 0.8 17.9 14.2 T 64,455
1975 17.3 31.3 30.8 11.4 9.2 96,434
1976 8.4 45.6 4.6 13.3 28.1 76,294
1977 17.3 59.9 2.5 T 19.3 8,936
1978 0.9 19.4 65.3 13.9 0.5 9,798
1979 34.0 2.0 7.3 49.5 7.2 57,561
1980 6.9 30.3 17.6 1.3 32.2 3.7 T 106,745
1981 0.5 11.9 15.1 38.8 31.0 2.7 42,375
1982 2.0 13.2 26.4 6.4 46.2 5.7 T 23,841
1983 4.1 9.5 5.5 8.7 57.0 15.2 0.1 99,732
T - Less than 0.1 percent.
Source: Fishery Statistics of the United States, 1970-1977; NMFS Landings
Data, 1978-1983.
�
42
Table 15. Percentage of South Carolina red drum landings by gear type,
1970-1983.
Fyke & Total
Shrimp Hand Haul Gill Hoop Landings
Year Trawls Lines Seines Nets Spears Nets (kg)
1970 100.0 181
1971 53.8 7.7 38.5 590
1972 100.0 544
1973 100.0 272
1974 60.9 39.1 1,043
1975 36.4 52.3 6.8 4.5 1,996
1976 8.3 91.7 544
1977 7.7 53.8 38.5 590
1978 100.0 1,939
1979 7.5 92.5 - 801
1980 48.9 51.1 1,863
1981 18.8 81.2 367
1982 0.7 11.9 86.7 0.7 1,011
1983 2.1 5.2 8.8 83.8 1,031
Source: Fishery Statistics of the United States, 1970-1977; NMFS Landings
Data 1978-1983.
�
43
Table 16. Percentage of Georgia red drum landings by gear type, 1970-1983.
Total
Hand Shrimp Gill Landings
Year Lines Trawls Nets (kg)
1970 100.0 227
1971 33.3 66.7 544
1972 100.0 1,406
1973 42.4 58.6 1,497
1974 41.9 58.1 1,406
1975 16.0 84.0 4,536
1976 54.8 43.8 1.4 3,311
1977 78.0 12.0 10.0 2,268
1978 100.0 149
1979 100.0 424
1980 100.0 677
1981 100.0 118
1982 100.0 114
1983 100.0 511
Source: Fishery Statistics of the United States, 1970-1977; NMFS Landings
Data, 1978-1983.
�
44
Table 17. Percentage of Florida East Coast red drum landings by gear type,
1970-1977.
Common Runaround Total
Haul Gill Hand Trammel Cast Landings
Year Seines Nets Lines Nets Nets (kg)
1970 6.5 76.2 16.6 0.7 66,587
1971 83.6 13.7 2.7 36,696
1972 3.0 74.5 22.4 0.1 58,241
1973 3.7 79.9 15.6 0.9 75,523
1974 8.5 65.5 24.1 1.9 62,278
1975 7.1 68.5 23.3 1.1 37,784
1976 6.3 72.1 21.0 0.6 48,081
1977 8.4 70.1 19.6 1.8 46,947
Source: Fishery Statistics of the United States, 1970-1977.
�
Table 18. Annual commercial catch of red drum (kg) by state and water area for the Atlantic coast, 1968-1983 and
percent caught in the estuaries.
Virginia North Carolina South Carolina Georgia
Year Ocean Estuary % Ocean Estuary % Ocean Estuary % Ocean Estuary %
1972 590 2,087 78 7,864 11,641 60 412 109 21 242 1,297 84
1973 499 2,313 82 14,881 16,871 53 0 281 100 508 1,191 77
1974 408 6,713 94 16,070 48,538 75 140 844 86 730 611 45
1975 1,225 7,666 91 49,533 47,643 49 632 4,980 89 272 4,232 94
1976 635 7,802 92 12,639 63,682 83 0 1,160 100 689 2,595 79
1977 45 91 67 2,858 6,078 68 58 296 84 253 1,964 89
1978 363 590 62 6,985 2,812 29 431 1,531 78 0 149 100
1979 635 227 26 12,084 45,303 79 60 741 93 0 424 100
1980 45 136 75 32,275 78,049 71 874 989 53 78 599 88
1981 45 45 50 12,648 29,727 70 23 344 94 0 118 100
1982 483 371 43 13,964 9,877 41 235 775 77 0 75 100
1983 1,836 39,814 96 31,451 64,766 67 15 293 95 0 511 100
Source: NMFS Landings Data, 1972-1983.
Ln
�
46
5.14 Fishing operations and results
There are no data on f ishing effort, selectivity, or
yield for the Atlantic coast. Matlock et al. (1977)
reported on trends in red drum abundance in Texas bays
influenced by commercial netting activities. Catch rates
for red drum in areas closed to commercial netting were
about twice as high as those from areas open to netting.
The effect of commercial netting was local; netting
removed red drum from restricted areas but did not
appreciably affect adjacent non-netted areas.
In 1984 the Texas Parks and Wildlife Commission banned
the use of plastic baits on trotlines because these baits
were thought to be selective for small (<500 mm) red
drum. Matlock et al. (1979) compared the size of red
drum landed by commercial fishermen before (1972-1974)
and after (1974-1978) the ban with the size of fish
collected during Texas Parks and Wildlife Department
trammel net surveys to determine the effect of the ban on
either the commercial catch or fish availability. Red
drum landed by commercial fishermen were significantly
larger after the ban than before. It appears that
plastic baits are selective for small red drum and that
the ban did affect the size of red drum caught.
5.15 Incidental catches
Red drum were not reported in several studies of fish
caught incidental to shrimp trawling (Anderson 1968;
Knowlton 1972; Wolff 1972; Keiser 1976). Commercial
landings statistics indicate.that the percentage of North
Carolina landings from shrimp trawls ranged from <0.1% in
1974 to 15.2% in 1983 (Table 14). In South Carolina
shrimp trawl landings ranged from 0.7-100.0% of the total
(Table 15). Prior to 1978, 12.0-100.0% of Georgia red
drum landings were caught by shrimp trawls (Table 16).
Red drum have been reported as a bycatch from shrimp and
fish trawls in the Gulf of Mexico (Swingle et al. 1983).
Red drum landings in Alabama were predominantly by shrimp
trawling, accounting for 48-95% of the landings. In
Mississippi red drum were taken as incidental bycatch in
the industrial groundfish fishery and the shrimp trawl
fishery. The percentage of red drum landings taken by
fish and shrimp trawls averaged 8 and 15%, respectively,
from 1968 through 1976. Shrimp trawls accounted for a
very minor portion of red drum landings in Louisiana and
Texas; generally <1% of annual red drum landings.
�
47
In the Gulf of Mexico large red drum have been caught by
purse seiners f ishing for blue runner. Red drum school
below blue runner and when the net is set red drum are
harvested as a bycatch (Overstreet 1983). From July 1,
1983 to April 16, 1984, 225.4 mt (497,000 lb) of red drum
were landed in observed purse seine catches from the
northern Gulf of Mexico (off the Mississippi River
delta). The catches generally consisted of large red
drum (7-8 44 and were caught 18-22 km offshore at depths
of 18-24 m.
5.2 Recreational Exploitation
5.21 Equipment and trends in equipment
Red drum are caught by bottom fishing, jigging, and
casting from shore, as well as bottom fishing, casting,
live-lining and trolling from boats (Freeman and Walford
1974, 1976a, b, c, d). Baits include soft or shedder
crabs, shrimp, clams, squid, and cut mullet, spot,
herring or menhaden, as well as artificial lures such as
spoons, jigs, weighted bucktails, feathers, plugs, and
streamer flies. Red drum are also harvested by gill
netting and gigging for home consumption. In South
Carolina 94% of the gill-net fishermen who fished in 1978
fished recreationally (Moore 1980).
5.22 Areas fished
The recreational fishery for trophy red drum (>18 kg)
which exists in the South Atlantic has been primarily a
surf fishery along the outer beaches of barrier islands
(Freeman and Walford 1974, 1976a, b, c, d; Osborne 1981;
Wongrey 1981; Ogle 1982; Arrington 1.983; Music and
Pafford 1984). Small red drum (<8 kg) are caught in the
estuaries from Chesapeake Bay to Florida (Freeman and
Walford 1976a, b, c, d; Smith and Moore 1979; Osborne
1981; Music and Pafford 1984).
24 W. Fable, National Marine Fisheries Service, Southeast Fisheries
Center, Panama City Laboratory, Panama City, Florida, personal
communication.
�
48
The numbers of red drum caught by principal area of
fishing in each region in 1965, 1970, and 1980 are
presented in Table 19. The salt-water angling surveys
indicated that 88% of the red drum caught in the Middle
Atlantic region in 1965 were caught in sounds, rivers,
and bays, whereas in 1970 only 47% were caught in
estuarine waters. More red drum (59%) were caught in the
ocean in the South Atlantic in 1965, but in 1970 and 1980
79% and 92%, respectively, were caught in sounds, rivers,
and bays. In the Gulf of Mexico more red drum were
caught in sounds, rivers, and bays than in the ocean in
all survey years.
5.23 Seasons
The fishing season for red drum is all year from Georgia
to southern Florida (Freeman and Walford 1976c, d). From
Altamaha Sound to Fort Pierce Inlet, best fishing for
small fish is August to October inshore, and for large
fish, March to May and November to January offshore.
Best fishing for small red drum from St. Lucie Inlet to
southern Florida is from April to August and from August
to November for large ones. Adult red drum generally
remain in coastal waters through the coldest months and
during late summer move offshore, presumably to spawn.
Most red drum are caught from mid-March or early April to
early December between False Cape, Virginia and Georgia.
The best fishing for large fish runs from late March to
early June and for small fish from late September to
November (Freeman and Walford 1976b). Good surf fishing
along the North Carolina coast is from March to June and
October to November (LaMonte 1951; Osborne 1981; Ogle
1982). The fishing season in Chesapeake Bay is from late
April or May to November. The best fishing for large
fish is from mid-May to mid-June and from August to
October for small fish (Freeman and Walford 1976a). The
red drum fishing season from False Cape, Virginia to
Delaware Bay extends from April or May to November and
the best fishing is from May-June and September-October
(Freeman and Walford 1974).
5.24 Fishing operations and results
Red drum catch data by month and year on the Eastern
Shore of Virginia were reported for 1955 to 1965. Catch
rates were never high but relative highs occurred during
1957 and 1962 at 0.14 fish per man-hour. More fish were
�
Table 19. Number of red drum caught by U.S. anglers in each region in 1965, 1970, and 1980 by principal area and
method of fishing.
Principal area
of fishing Principal method of fishing
Sounds, Private Party Bridge,
rivers, or or pier, Beach
Survey and rented charter or or
year Region Ocean bays boat boat jetty bank
--------------------------------------- THOUSANDS --------------------------------
1965 1 Middle Atlantic 24 172 7 35 126 28
South Atlantic 29436 1,663 1,497 235 1,965 402
Gulf of Mexico 1,332 5,568 4,841 769 890 400
1970 2 Middle Atlantic 51 46 46 - - 51
South Atlantic 10032 3,851 3,839 276 287 481
Gulf of Mexico 5.9060 8,124 7,655 1,586 1,694 2,249
1980 3 South Atlantic 26 313 318 - 43 58
Gulf of Mexico 467 3,005 4,513 51 388 431
1Deuel and Clark 1968
2Deuel 1973
3Anonymous in press
4@b
�
50
landed during May and September, but catch rates were
highest for April, June, and September. A low of 0.01
fish per man-hour occurred in 1959 (Richards 1965). A
1963 sport fishery survey in the Cape Canaveral area of
Florida found that catch per unit effort was highest in
October and April north of Cape Canaveral, and highest in
April to the south (Anderson and Gehringer 1965). Catch
per unit effort data (number and weight) for red drum
caught in the Gulf of Mexico was summarized by Perret et
al. (1980).
The National Marine Fisheries Service salt-water angling
surveys, 1960-1970, indicated that the number of red drum
per angler declined in all regions from 1965 to 1970
(Table 11). The average reported weight of fish
decreased in both the Middle and South Atlantic regions
from 1960 to 1970, but increased in the Gulf of Mexico
from 1960 to 1965 and decreased slightly from 1965 to
1970.
Davis (1980) reported that recreational fishermen caught
96% of the red drum landed in Everglades National Park
from 1972 through 1977. The mean annual yield of red
drum from park waters was 0.17 kg per acre, producing
mean annual harvests of 105,370 kg from 1972 through
1977. In the past 20 years, there has been a shif t in
age structure toward larger, mature f ish, with upward
trends in catch rates and a marked reduction in the
year-to-year variability of catch rates, possibly due to
changes in environmental conditions (Davis 1980).
6. SOCIAL AND ECONOMIC IMPLICATIONS
6.1 Values
Cato (1981) reviewed the economic values and uses of the
sciaenid fisheries in the South Atlantic and Gulf of Mexico.
A comparison of dockside value of commercial landings of
important sciaenids revealed that red drum ranks behind
weakfish, croaker, spotted seatrout, and spot. Red drum
prices increased steadily in the Gulf of Mexico and have been
consistently higher there except in 1969, 1980 and 1982
(Figure 4). Atlantic coast prices increased steadily from
1960 but dropped sharply in 1983.
Current prices have increased while deflated prices have
remained fairly stable. Red drum exvessel'prices vary from
state to state. In 1982 prices varied from 23-79 cents per
pound in North Carolina and the east coast of Florida,
respectively (Table 20).
�
51
0.70-
Gulf of Mexico
0---o Atlantic coast
0.60-
z
U-1
U
0.50-
z
0.40-
0 1 1
1 0
00
U.J
0- 10,
0.30-
LLI
0.20- o- 0.0e 1P
&P-0,V"
0 0,0 -0,
0.10- *10
1960 1965 1970 1975 1980
YEAR
Figure 4. Dockside price of red drum for the Atlantic coast and
Gulf of Nexico, 1960-1983.
�
52
Table 20. Unadjusted exvessel price of commercially-caught red drum on the
Atlantic coast by state, 1960-1982.
North South Florida
Year Virginia Carolina Carolina Georgia East Coast
------------------------- (DOLLARS/POUND) -------------------------
1960 .046 .081 - .150 .147
1961 .092 .081 .250 .150 .137
1962 .084 .081 - - .145
1963 .084 .068 - - .147
1964 .086 .089 .141 - .183
1965 .105 .119 - - .177
1966 .083 .103 .100 .123 .187
1967 .085 .097 - .135 .184
1968 .110 .069 - .222 .152
1969 .060 .085 .157 .190 .193
1970 .060 .085 .157 .190 .193
1971 .037 .100 .181 .209 .208
1972 .079 .122 .268 .202 .228
1973 .113 .111 .258 .210 .271
1974 .150 .111 .258 .210 .271
1975 .100 .101 .286 .299 .322
1976 .083 .128 .283 .329 .340
1977 .110 .136 .335 .414 .372
1978 .063 .114 .345 .649 .448
1979 .084 .172 .264 .553 .532
1980 .150 .194 .262 .643 .555
1981 .240 .201 .418 .709 .541
1982 .139 .234 .602 .669 .791
-None caught
Source: Fishery Statistics of the United States, 1960-1977; NMFS Landings
Data, 1978-1982.
�
53
6.2 Employment
There is little available information on employment in the
fisheries for red drum which are mixed species fisheries. The
commercial fishery for coastal finfish in South Carolina is
primarily a part-time activity with few, if any, full-time
employees, primarily due to major commercial interest in the
shrimp, blue crab, and oyster fisheries (Smith and Moore
1979).
6.3 Participation
There is little specific information on participation in the
fisheries for red drum. Participation in South Carolina's gig
and gill net fisheries, both of which harvest red drum, has
increased greatly in the last decade. Gig licenses increased
225% from 1971-1972 (590) to 1977-1978 (1,910) and gill net
licenses increased 306% over the same time period (705 to
2,861) (Smith and Moore 1979). Davis (1980) examined changes
in the Everglades National Park red drum and spotted seatrout
fisheries 1958-1978. The number of commercial fishermen
fluctuated between 125 and 276 from 1963 to 1978.
Recreational fishing activity increased steadily from 58,000
angler-days in 1959 to 174,000 in 1965, fell slightly in the
late 1960s, reached another peak of about 160,000 angler-days
in 1973 and 1974, and fell again to less than 100,000
angler-days in 1977.
The 1960-1970 salt-water angling surveys indicate significant
growth of marine sport fisheries in the South Atlantic reg.
pn.
The estimated nuWber of anglers increyed from 1.0 x 10 in
1960 to 1.7 x 10 in 1965 and 1.8 x 10 in 1970 (Clark 1962;
Deuel and Clark 1968; Deuel 1973). Bearden. (1969) estimated
that there were 240,500 resident anglers in South Carolina in
1968. The number of resident South Carolina participants in a
1974 survey was estimated at 347,000 people (Mabrey et al.
1977). Out-of-state participation appears to be an important
segment of South Carolina's sport fisheries. An estimated
261,000 people from North Carolina and 56,000 from Georgia
fished in South Carolina in 1974 (Mabrey et al. 1977).
6.4 Processors and product forms
In South Carolina red drum are sold to either local wholesale
or retail markets. Gill nets and hook and line were the
principal gears used to take coastal finfish for market. A
survey of licensed persons engaged in selling finfish
indicated that red drum, spotted seatrout, and flounder
comprised only 7.2% of the total reported weight of finfish
sold (Smith and Moore 1979).
�
54
Commercial landings of red drum on the Gulf Coast are mostly
sold in local markets as fresh in-the-round or gutted, with a
small percentage sold as frozen and gutted, or as fresh or
frozen fillets (Perret et al. 1980).
6.5 Import/export
Imports of juvenile red drum from Mexico are substantial and
have an impact on Texas, Louisiana, Oklahoma, and perhaps
other markets supplied from Texas and Louisiana landings.
Imports increased from 1964 (45.1 mt) to 1969 (396.2 mt) and
have since decreased (Table 21). The decline in imports from
the 1970s to the present is due to the development of seafood
markets in Mexico, new fishing regulations in Mexico, and
until recently, a declining U.S. dollar. At their peak,
imports accounted for 25% of the total U.S. supply of red
drum. Most imports are in-the-round and gutted. Frozen
fillets were imported between 1978 and 1981, and comprised
from 12 (1981) to 29% of imports (1978) (Perret et al. 1980;
Swingle et al. 1983).
Exports of red drum from the U.S. have occurred but
statistical information is unavailable before 1981 when the
National Marine Fisheries Service began inspecting drum
exports (include red drum and black drum). Drum are exported
to Nigeria, Turkey, and probably Egypt, the Mideast,
Venezuela, and Taiwan. The red drum exported are usually
adult fish because of a market preference for large fish in
the above countries and because it can be marketed at
relatively low prices. The product is shipped frozen
in-the-round or is gutted (Swingle et al. 1983).
6.6 Gear conflicts
In North Carolina gear conflicts may occur between the long
haul seine fishermen and the pound net, crab and eel pot
fishermen. Abandoned, broken-off pound net stakes and pound
net stakes left in place from season to season exclude long
haulers from large areas, especially in Core Sound. A very
large increase in the number of crab and eel pot fishermen has
resulted in ever increasing friction with haul seiners, who
cannot haul in areas filled with pots. Potters are mainly
interested in shoal waters, which long haulers need only to
bunt or harden up their seine (DeVries 1981).
6.7 Commercial-recreational conflicts
Heffernan and Kemp (1980, 1982) reviewed the conflicts in the
red drum fishery, particularly in the Gulf of Mexico.
�
55
Table 21. U.S. imports and exports of red drum, 1964-1983 (from Swingle
et al. 1983).
Imports Exports a
Year Total In-the-round Frozen Fillets
---------------------------- Metric Tons ----------------------------
1983 110.8 79.8 30.9
1982 128.5 115.9 12.6 -
1981 65.5 57.5 8.1 997.9
1980 162.3 135.2 27.1 N.A.
1979 .164.1 133.2 30.8 N.A.
1978 235.6 167.6 67.9 N.A.
1977 254.3 N.A. N.A. N.A.
1976 178.6 N.A. N.A. N.A.
1975 182.9 N.A. N.A. N.A.
1974 217.3 N.A. N.A. N.A.
1973 335.6 N.A. N.A. N.A.
1972 282.8 N.A. N.A. N.A.
1971 272.0 N.A. N.A. N.A.
1970 381.6 N.A. N.A. N.A.
1969 396.2 N.A. N.A. N.A.
1968 101.7 N.A. N.A. N.A.
1967 4.0 N.A. N.A. N.A.
1966 14.4 N.A. N.A. N.A.
1965 49.4 N.A. N.A. N.A.
1964 45.1 N.A. N.A. N.A.
a - includes red drum and black drum
- - none exported
N.A. - not available
Source: E. Barry, National Marine Fisheries Service, New Orleans, personal
communication; J. Dougherty, NMFS, St. Petersburg, personal
communication.
�
56
Conservationists and recreational fishermen complained of
overharvest of f ish by commercial interest prior to 1900,
continuing to the present. State legislatures enacted various
regulations which closed portions of estuarine areas to the
use of nets and seines during seasonal periods with the intent
to protect spawning fish. From the 1930s to the 1970s,
legislation was directed toward reducing commercial f ishing
pressure on bay stocks by imposing size limits, opening and
closing various bay and Gulf waters, and establishing gear
restrictions in relation to -mesh sizes, length of nets, and
their seasonal use. Growing netting pressure and reported
declines in available stocks led to the prohibition of the use
of monofilament nets in Louisiana in 1977 and Texas in 1980.
The Texas legislature passed a bill in 1981 prohibiting the
commercial sale of Texas-caught red drum for two years. Davis
(1982) discussed management conflicts in Everglades National
Park and Matlock (1982) discussed conflicts between user
groups of red drum in Texas. At the urging of recreational
fishermen in Florida regulations and legislation have been
introduced to ban gill netting for red drum; however, none of
it has passed.
7. MANAGEMENT AND PROTECTION
7.1 Regulatory measures
The fisheries for red drum have been conducted almost entirely
within the internal waters of the states and in the
territorial sea which extends 5.6 km (3 n mi) offshore on the
Atlantic coast. Therefore, management has been by individual
state regulation. The State of Maryland passed a saltwater
angling license bill, May 22, 1984, for fishing in Maryland
tidal waters of Chesapeake Bay and tributaries and is the only
state on the Atlantic coast that requires saltwater anglers to
be licensed. The monies collected by the license will be
dedicated for recreational fishing enhancement and anglers
will be given the opportunity to have input concerning the
content of the fisheries management program adopted by the
Maryland Department of Natural Resources. The State of
Virginia is also considering a saltwater angling license.
Regulations and methods of promulgating them vary among states
and are summarized in Table 22. The only regulations
specifically dealing with red drum are size limits in North
Carolina and Florida, and daily possession limits in Virginia
and North Carolina.
The Atlantic States Marine Fisheries Commission (ASMFC)
administers a cooperative agreement with the National Marine
Fisheries Service (NMFS) entitled the Interstate Fisheries
Management Program (ISFMP). This program provides funding to
�
57
Table 22. Synoptic overview of present state management systems.
Rhode
Island Connecticut
Administrative Rhode Island Connecticut
organization Department of Department of
Environmental Environmental
Management Protection
Legislative Rhode Island Connecticut
organization Marine Fisheries Commissioner
Council Environmental
Protection
Licenses Commercial Commercial
Size None None
restrictions
Limits None None
Gear None None
restrictions
Conservation None None
regulations
�
58
Table 22. Continued
New York
Administrative New York State Department of Environmental
organization Conservation
Legislative New York Fish and Game Laws, Article 13
organization Marine and Coastal Resources
Licenses Commercial
non-resident
beam and otter
trawl
Size None
restrictions
Limits None
Gear Trawl prohibited from Great South Bay,
restrictions Moriches Bay, Shinnecock Bay; seasonally
in Peconic Bays. Gill nets restricted
from Peconic Bays; haul seines limited in
lengths in these same bays and cannot be
fished from midnight Thursday to 6:00 p.m.
Sunday. Nets and trawls may not be set in
western Long Island Sound Apr. 1 - Nov. 1.
Gill nets prohibited in central and
western Long Island Sound.
Conservation None
regulations
�
59
Table 22. Continued
New Jersey Delaware
Administrative New Jersey Department Division of Fish and
organization of Environmental Wildlife
Protection, Division Department of Natural
of Fish, Game and Resources and Environ-
Wildlife, Marine mental Control
Fisheries Adminis- d
tration, Bureau of
Marine Fisheries
Legislative New Jersey Statutes, Delaware State
organization Title 23, Chapter 28 Legislature
Licenses Fyke nets - $1, $4, $30 None
Haul seines - $25
Bait seines - $3
(50' - 150')
Gill nets -
anchored - $13
drift - $20
run around - $20
Pound nets $ 25
$ 50
$100
Otter trawl $100
Beam trawl $100
Purse seine $100
Size None None
restrictions
Limits None
Gear Trawls and purse Trawls prohibited in
restrictions seines restricted from Delaware Bay. Gill nets,
within 2 miles of coast- fyke nets and seines
line. Seasons for gill allowed. Purse seines
nets, fyke nets, haul prohibited within 3 miles
seines. of coast.
Conservation None None
regulations
�
60
Table 22. Continued.
Maryland Virginia
Administrative Maryland Department Virginia Marine
organization of Natural Resources Resources Commission
Legislative Natural Resources Marine Resources of
organization Article, Annotated the Commonwealth Code
Code of Maryland of Virginia of 1950,
Title 4, Subtitle 1, Title 28.1
Title 08, Subtitle 02,
Chapter 05 Fish
Licenses Otter trawl - $100 Commercial
Beam trawl - $100
Fyke or hoop
nets - $50
Gill nets- <200 yds $100
>200 yds $200
Recreational - $5
in Chesapeake Bay
Size None None
restrictions
Limits None No more than two
<32" TL
Gear Trawling prohibited Trawling prohibited in
restrictions within I mile of Chesapeake Bay. Pound
Maryland shoreline in net mesh <2" (s.m.) and
Atlantic Ocean. haul seine mesh <3"
Numerous gear and area mesh (s.m.) prohibited.
restrictions. Trawling prohibited
within 3-mi. limit from
Cape Charles north to
Maryland line in Sep.
and Oct.
Conservation Secretary of Natural None
regulations Resources has authority
to adopt rules and
regulations relating to
taking, possession,
transportation, exporting,
processing, sale or ship-
ment necessary to conser-
vation.
�
61
Table 22. Continued
North Carolina
Administrative North Carolina Department of Natural
organization Resources and Community Development,
Division of Marine Fisheries; Marine
Fisheries Commission
Legislative North Carolina Administrative Code,
organization Title 15, Chapter 3.
Licenses Vessels without motors,
any length, when used with other
licensed vessel - no license
Vessels, not over 18' - $1/foot
Vessels, over 18' to 38' - $1.50/foot
Vessels, over 38' - $3/foot
Non-resident vessels - $200 in addition
to above fee
requirement
Finfish processor - $100
Unprocessed finfish dealer - $50
Size 14" TL minimum
restrictions
Limits No more than two >32" TL; in New Hanover
County, none >20 lbs.
Gear Trawling for finfish prohibited in internal
restrictions coastal waters. No purse seine for food
fish. Many specific net regulations for
areas and seasons.
Conservation Secretary, acting upon advise of Director
regulations of Marine Fisheries, may close area to
trawling if in coastal fishing waters,
samples become composed primarily of
juvenile finfish of major economic
important. No person shall remove red drum
from any boat hook, gaff, spear, gig, or
similar device.
�
62
Table 22. Continued
South Carolina Georgia
Administrative South Carolina Wildlife Georgia Department of
organization and Marine Resources Natural Resources
Legislative Section 50-5-20 Georgia Code 27-4-110
organization
Licenses Land and sell $25 Commercial fishing
Commercial boat license license (personal)
<18' - $20 $10.25 for any sales of
>18' - $25 catch
Gill nets Nontrawler license
haul seines <18' - $5
$10/100 yds -@'18' - $5 + $.50/foot
Trawler license - $50
for 18' + $3/additional
foot
No license for seines
<300' unless catch is
sold.
Size None None
restriction
Limits None None
Gear Seine mesh less than Gill netting prohibited
restrictions 2k" prohibited in Georgia waters. Seine
Purse seining for food mesh restrictions:
fish permitted in minimum of 114" for seines
ocean greater than less than 100'; minimum
300 yds from beach. mesh size of 2Y'
(stretched mesh) for
100' - 300' maximum
length.
Conservation None None
regulations
�
63
Table 22. Continued
Florida
Administrative Marine Fisheries Commission
organization
Legislative Chapter 370, Florida Statutes; additional
organization 220 state laws that apply on a local
level; all local laws will become Rules
of the Marine Fisheries Commission by
July 1, 1985.
Licenses License to sell:
Resident - $25 annually
Non-resident - $100 annually
Alien - $150 annually
Wholesale seafood dealer
Resident - $300 annually
Non-resident - $500 annually
Alien - $750 annually
Retail seafood dealer
Resident - $25 annually
Non-resident - $200 annually
Alien - $250 annually
Size 12" FL minimum
restrictions
Limits None
Gear Purse seining and stop netting prohibited.
restrictions Numerous local gear and area restrictions.
Conservation None
regulations
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64
the Atlantic coastal states to coordinate interjurisdictional
fisheries management and develop fishery management plans
(FMPs) for species occurring in the territorial sea.
The Magnuson Fishery Conservation and Management Act (MFCMA)
provides for the conservation and exclusive management by the
Federal government of all fishery resources within the United
States Fishery Conservation Zone (FCZ). The FCZ extends from
the territorial sea to 370 km (200 n mi) from shore. Fishery
management in the FCZ is based on fishery management plans
developed by regional Fishery Management Councils (FMC).
The National Park Service retains the authority to manage fish
primarily through the establishment of coastal and nearshore
national parks and national monuments such as Everglades
National Park in Florida.
7.2 Habitat protection
Red drum are dependent on estuaries for at least the first few
years of lif e. Larvae and juveniles are generally found in
shallow waters, in areas not greatly affected by tides, with
grassy or muddy bottoms and moderate salinities (Section 2.1).
Yokel (1966) concluded that red drum abundance varied directly
with estuarine size. States which have relatively high annual
landings also have large estuaries. North Carolina and the
east coast of Flordia are the leading producers of red drum on
the Atlantic Coast and they also have the largest estuaries of
the states from North Carolina south. There is considerable
variation in this relationship, but the general trend supports
the supposition of the importance of estuaries and shallow
marine areas to the production of red drum (Yokel 1966).
Davis (1980) suggested that changes in the red drum fishery in
Everglades National Park 1972-1977, which included a shift in
age structure toward larger, mature fish and increased catch
rates, resulted from increased salinities from drainage
control. The Texas Department of Water Resources has
ihvestigated the effects of freshwater inflow upon Texas bays
and estuaries. A comparison of annual harvest rates of red
drum with seasonal freshwater inflows revealed a positive
response between harvest and increased inflow in spring
(April-June), fall (September-October), and late fall
(November-December). High inflow in winter (January-March)
and summer (July-August) was negatively correlated with catch
rate (Anonymous 1982b).
Estuarine habitats have deteriorated rapidly since
approximately 1940, mostly as a result of industrial and human
population growth. The National Estuary Study, completed in
1970, indicated that 73% of the Nation's estuaries had been
moderately or severely degraded (Gusey 1978, 1981). Damage
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65
and/or destruction of estuaries has largely been by dredging
and filling for waterfront property, dredging of navigation
channels, construction of causeways and bridges, installation
of ports and marinas, alteration of freshwater flow, and
pollution. Unfortunately the effects of habitat alterations
have rarely been quantified.
In recent years the coastal states have enacted coastal zone
management laws to regulate dredge and fill activities and
shoreline developement (Table 23). The Federal government
also has some jurisdiction over the estuarine-marine habitat.
The Office of Coastal Zone Management (OCZM) has authority
through National Marine Sanctuaries, pursuant to Title III of
the Marine Protection, Research, and Sanctuaries Act (MPRSA).
The OCZM Estuarine Sanctuary program has designated Rookery
Bay in Collier County,.Florida, and the Apalachicola River and
Bay in Franklin County, Florida, as estuarine sanctuaries.
The OCZM also sets standards for approving and funding state
coastal zone management programs. The Environmental
Protection Agency may provide protection to fish communities
through the granting of National Pollutant Discharge
Elimination System (NPDES) permits for the discharge of
pollutants into ocean waters, and the conditioning of those
permits so as to protect valuable resources. The U. S. Army
Corps of Engineers has jurisdiction over the disposal of
dredged material, pursuant to both the Clean Water Act and the
MPRSA. The Fish and Wildlife Service, under the Fish and
Wildlife Coordination Act, reviews and comments on proposals
for work and activities in or affecting navigable waters that
are sanctioned, permitted, assisted, or conducted by Federal
agencies. The review focuses mainly on potential damage to
fish and wildlife, and their habitat.
The Envionmental Assessment Branch of the NMFS is required to
assess potential impacts on fishery resources of projects
submitted to the Corps of Engineers for permits, and to
recommend whether a project should be approved, denied, or
modified. Fiscal year 1981 (October 1980 - September 1981)
was the first year NMFS quantified the cumulative acreage of
habitat involved in the Corps of Engineers permit program in
the Southeast Region of the United States. NMFS made
recommendations on 1,380 permit applications involving 7,272
ha (17,969 acres); 18% were proposed for dredging, 36% for
filling, and 46% for impounding. NMFS did not object to
alteration of 1,861 ha (4,598 acres), recommended against
altering 5,411 ha (13,371 acres), and recommended that 1,345
ha (3,324 acres) either be restored or modified from upland
habitat to mitigate the losses that were permitted. Thus, the
NMFS efforts conserved 6,756 ha (16,695 acres) of habitat
(Lindall and Thayer 1982). NMFS is also involved in the
review of Congressionally authorized Federal projects. NMF S
has adopted a new habitat conservation policy which will
enhance its overall role in habitat conservation from a
previously advisory role based primarily on the policies
�
Table 23. Summary of state habitat protection regulations, Rhode Island to Florida.
Administrative Legislative
State organization authorization Regulations
Rhode Island Rhode Island Chapter 279, Public Permits required for
Department of Environmental Laws of 1971, Sect. 1, coastal zone development,
Management and Coastal Title 46, General Laws aquaculture, dredge and
Resources Management of Water and Navigation. fill operations.
Council Chapter 23 Coastal
Resources Management
Council.
Connecticut Connecticut Department "The Coastal Management Permits required to dredge
of Environmental Act" Section 22-a-90 fill or construct
Protection to 22a-96 structures in both fresh
and salt water. Permit
required to work in
regulated wetland areas.
New York Department of Environmental Environmental Conservation Regulates activities in and
Conservation, Bureau of Law Article 25, Tidal adjacent to tidal wetlands
Tidal Wetlands Wetlands Act, Part 661. and requires permits for
Land use regulations of such activities.
tidal wetlands.
New Jersey Department of Environmental Wetlands Act of 1970 Regulates activities in the
Protection, Division of NJSA 13:9A-1 et seq., coastal zone and requires
Coastal Resources Coastal Area facilities permits for such activities.
Review Act NJSA 13:19-1 et
seg., Waterfront Development
Law, NJSA 12:5-3, Beaches
and Harbors Bond Act of 1977
PL 77-209, Shore Protection
Legislation NJSA 12:6A-1
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Table 23. (continued)
Administrative Legislative
State organization authorization Regulations
Delaware Delaware Department Sect. 1, Title 7, Regulates use of wetlands
of Natural Resources Delaware Code, and their upland border
and Environmental Control, Chapter 66. Wetlands. and provide penalties for
Division of Environmental violations.
Control, Wetlands Section
Maryland Maryland Department of Natural Resources Article, Regulates activities in
Natural Resources, Tidewater Code of Maryland tidal wetlands areas.
Administration; Maryland
Department of Health and
Mental Hygiene, Office of
Environmental Programs
Virginia Virginia Marine Resources The Wetlands Act Regulates alterations to
Commission; County Section 62.1-13.20., tidal marshes, sand and
wetlands boards Code of Virginia mud flats, subaqueous
bottoms, and sand dunes.
North Carolina North Carolina Department NC Dredge and Fill Law Requires permits to dredge
of Natural Resources and (GS 113-229), Coastal or fill in or about
Community Development, Area Management Act estuarine waters.
Office of Coastal (CAMA) (GS 113A100) Establishes areas of
Management; Coastal Resources environmental concern.
Commission; Coastal Resources Permits required for
Advisory Council coastal zone development.
Division of Marine Fisheries North Carolina Administra- Prohibits the use of bottom-
tive Code, Chapter 3, disturbing gears and severely
Section .1400 restricts or prohibits
excavation and/or filling
activities in nursery areas for
young finfish and crustaceans.
South Carolina South Carolina Coastal Zone -Coastal Zone Management Directs permit activities
Managment Council and Planning Act in areas of wetlands,
beaches, and dunes.
�
M .
00
Table 23. (continued)
Administrative Legislative
State organization authorization Regulations
Georgia Georgia Department of Coastal Marshlands Requires permits to dredge,
Natural Resources, Protection Act of 1970 fill, remove drain, or other-
Coastal Resources Division, (Gs. L. 1970, p. 939, 1.) wise alter any,marshlands.
Coastal Protection Section
Shore Assistance Act of Requires permits for a
1979 (Gs. L. 1979, 1.) structure, shoreline
engineering activity, or
land alteration in
beaches, sand bars, and
sand dunes in Georgia.
Florida Florida Department Chapter 253, Florida Regulates dredge, fill, and
of Natural Resources Statutes structures on state sub-
merged lands (below mean
high water). Provides for
acquisition of conservation
lands and tidally influenced
areas.
Chapter 258, F.S. Establishes aquatic pre-
serves and regulates
activities within preserves.
Florida Department of Chapter 403, F.S. Permitting of activities
Environmental Regulation (including dredge and fill)
which affect water quality.
Florida Department of Chapter 380, F.S. Administer and set standards
Community Affairs for "Development of Regional
Impact". Protects regional
or statewide resources from
poorly conceived development
activities.
�
69
developed in response to the Fish and Wildlife Rordination
Act and the National Environmental Policy Act The new
policy will: (1) ensure that habitat is fully considered in
a.11 of NMFS' programs and activities; (2) focus NMFS' habitat
conservation activities on species for which the agency has
management or protection responsibilities under the MFCMA, the
Marine Mammal Protection Act, and the Endangered Species Act;
(3) lay the foundation for management and research cooperation
on habitat issues; and (4) strengthen NMFS' partnerships with
the states and the regional FMCs on habitat issues.
7.3 Stocking
Red drum, a highly sought game and f ood f ish, has been the
target of numerous mariculture experiments. Investigations on
grow out of red drum were initiated in 1947 and continued
intermittently for 20 years in South Carolina ponds tidally
stocked with wild fish (Lunz 1951, 1956; Bearden 1967). The
red drum portion of the harvested crops was only 15 kg/ha/yr.
at maximum, but Bearden (1967) noted that the impounded red
drum averaged 860 g when I year old. In a more recent study,
South Carolina ponds yielded 52 kg/ha/yr of red drum with
year-old drum averaging 950 g and ranging from 800-1,070 g
(Theiling and Loyacano 1976).
Red drum, fed commercial feed or killed forage fish in Texas
ponds,, exhibited potential for higher yield and survival
during grow out. Luebke and Strawn (1973) reported that yield
for red drum reached 308 kg/ha with 96% survival and increase
in mean weight f rom 186 g to 641 g. Red drum averaging 0. 5 g
were produced in Texas by rearing 2- to 6-day-old larvae in
ten 0.1-ha ponds for 27 to 60 days with 20% survival and 29.7
kg/ha yield. Red drum stocked at a larger size (638-1,484 g)
and given supplemental feed did not grow (Colura et al 1976).
Lasswell et al. (1977) reported excellent growth (2 kg/yr) of
juveniles stocked in Texas reservoirs.
Juvenile red drum were reared to marketable size (454 g) in
0.08 ha brackish-water ponds in Alabama. The yield when
harvested from 394-715 days old ranged from 787-2,292 kg/ha
with 1-33% of the drum marketable at harvest. The cost of
feed approached the dock value of whole red drum, posing an
economic barrier -in Alabama for mariculture of red drum
(Trimble 1979).
25
Federal Register 48(228):53142-53148, November 25, 1983.
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70
The development of spawning techniques (Colura 1974; Arnold et
al. 1977; Roberts, Harpster, and Henderson 1978) enhanced the
mariculture potential for red drum. Roberts, Morey, et al.
(1978) investigated the effects of' delayed feeding, stocking
density, and food density on survival, growth and production
of larval red drum in Florida. The tolerances of eggs,
larvae, and postlarvae of red drum to ammonia and nitrite were
investigated by Holt and Arnold (1983). Crocker et al. (1981)
evaluated survival and growth of juveniles in fresh and salt
water.
The use of stocking as a potential management tool in Texas
resulted from the declining trend in red drum abundance in
Texas and the development of techniques to spawn and rear red
drum in captivity (Matlock 1984). During 1975-1982 Texas bays
were stocked with over 56 million red drum eggs (15%), fry
(80%), and fingerlings (5%). To assess the success of
fingerling stockings, 49,194 were tagged. The success of
these stockings has not yet been evaluated. With the
completion of the John Wilson Hatchery at Corpus Christi, the
Texas Parks and Wildlife Department is involved in a
comprehensive red drum restoration project (Sasser 1983). The
impact of the stocking on the coastal fishery resource will be
evaluated in on-going monitoring programs. The Texas Parks
and Wildlife Department has recently produced a hybrid cross
between the red drum and black drum which may have potential
as a freshwater sport fish (Anonymous 1983b).
Historically, stocking of hatchery fish into coastal waters to
improve catch has generally been a failure. The value of
artificially propogated sciaenids in the management of
sciaenid stocks can best be realized through: (1) descriptions
of previously undescribed early life stages, (2) bioassay, and
(3) introduction of tagged, known-age stocks to determine
growth, migratory patterns, and exploitation rate. Stocking
of large numbers of sciaenid larvae, fry, or fingerlings into
the coastal area is not advocated unless they are stocked in
water where they: (1) previously did not exist and an
opportunity exists for filling an underutilized niche, (2) had
existed but populations had reached such low levels that
inadequate spawning stocks remain, (3) habitat alterations had
eliminated spawning, growing or fishing grounds, or (4) water
quality persistently prevented successful spawning or
year-class survival (Tatum 1981).
8. CURRENT RESEARCH
There is little ongoing research on red drum on the Atlantic coast.
The Maryland Tidewater Administration, the Virginia Institute of
Marine Science, and the North Carolina Division of Marine Fisheries
�
71
(NCDMF) conduct juvenile fish surveys in the.estuaries to monitor
finfish stocks. The NCDMF also samples the commercial fisheries in
order to monitor adult finfish stocks and will begin an adult
estuarine fish survey in 1984. A tagging study and population
assessment of red drum in Georgia estuaries is being conducted by
the Georgia Coastal Resources Division. The Florida Department of
Natural Resources is completing a study on life history, age and
growth, mortality, and yield per recruit of red drum, is examining
habitat loss in three Florida estuaries and changes in the
fisheries of those estuaries, and is tagging red drum (ages I-IV).
The National Park Service monitors juvenile finfish stocks and
conducts a creel survey of the recreational fishery in Everglades
National Park. The U.S. Fish and Wildlife Service is conducting a
two-year resource assessment study of the commercial fishery,
which includes red drum, in Everglades National Park. NMFS
conducts annual marine recreational fishery statistics surveys and
commercial fishery statistics are collected by state and Federal
port agents.
9. IDENTIFICATION OF PROBLERS
The Interstate Fisheries Management Program Sciaenid Technical
Committee has identified the following immediate red drum research
needs: (1) stock identification; (2) validation of uniform ageing
techniques throughout the range; and (3) tagging studies to
estimate fishing and total mortality. Improved catch and effort
statistics for both the commercial and recreational fisheries are
needed to measure stock density. Long-term monitoring needs
include: (1) determination of habitat preferences ' growth rates,
and food habits of larval and juvenile red drum; (2) assessment of
the effects of environmental factors on stock density; and (3)
yield modeling. The effectiveness of controlling fishing mortality
and minimum size in managing the fisheries needs to be examined.
10. ACKNOWLEDGERENTS
I wish to thank the following members of the Interstate Fisheries
Management Program Sciaenid Technical Committee for providing
information from their States and for their suggestions and
constructive reviews of the manuscript: Christopher Ordzie, Rhode
Island Division of Fish and Wildlife; Robert Sampson, Connecticut
Department of Environmental Protection; Alice Weber, New York
Department of Environmental Conservation; Paul Hamer, New Jersey
Division of Fish, Game and Wildlife; Richard Seagraves, Delaware
Division of Fish and Wildlife; Charles Frisbie, Maryland Tidewater
Administration; Herbert Austin and John A. Musick, Virginia
Institute of Marine Science; Douglas DeVries, North Carolina
Division of Marine Fisheries; Glenn Ulrich South Carolina Wildlife
and Marine Resources Center; James Music, ;eorgia Coastal Resources
�
72
Division; Roy 0. Williams, Florida Department of Natural Resources;
Stuart J. Wilk, NMFS Northeast Fisheries Center, Sandy Hook
Laboratory; and John V. Merriner, NMFS Southeast Fisheries Center,
Beaufort Laboratory. The following individuals provided additional
information: Katy West, North Carolina Division of Marine
Fisheries; Paul Anninos, Virginia Marine Resources Commission; Pam
Lunsford and John Williams, Maryland Department of Natural
Resources; Andrew Applegate, South Carolina Wildlife and Marine
Resources Department; Ronald Essig, Georgia Department of Natural
Resources; Ron Taylor and Mike Murphy, Florida Department of
Natural Resources; Mark Holliday and Richard Schween, NMFS Resource
Statistics Division; and Guy Davenport, NMFS Technical Information
and Management Services. Sharon Sanchez typed the manuscript.
Figures were prepared by Val and Henry Page. Mary McGimsey of the
North Carolina Office of Public Affairs designed the cover layout.
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73
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