Invasion History
First Non-native North American Tidal Record: 1971First Non-native West Coast Tidal Record: 1979
First Non-native East/Gulf Coast Tidal Record: 1971
General Invasion History:
Blue Catfish (Ictalurus furcatus) are native to Mississippi and Gulf of Mexico drainages north to Pennsylvania and South Dakota, south to the Gulf Coast (Alabama to the Rio Grande basin and Soto La Marina basins in New Mexico, Texas, and Mexico) (Page and Burr 1991; Froese and Paul 2018). These fish have been stocked on the Atlantic Slope from Georgia to Virginia, and have colonized estuaries in Maryland, and the Delaware River. In the interior, they have been introduced to Arizona, Colorado, Idaho, western Washington and Oregon (Lee et al. 1980; Page and Burr 1991; Fuller et al. 1999; USGS Nonindigenous Aquatic Species Program 2018). They were introduced to southern California in 1969. They were first caught in the San Francisco Bay watershed in 1978 and are established, but rare in the Sacramento-San Joaquin Delta (Cohen and Carlton 1995; Dill and Cordone 1997).
North American Invasion History:
Invasion History on the West Coast:
The first stocking of Blue Catfish in California involved a batch of 1755 fish introduced to Lake Jennings, in San Diego County, by the California Department of Fish and Game. The justifications were to provide biocontrol of the Asian freshwater clam Corbicula fluminea, and to provide trophy-sized fish for anglers. Since then, Blue Catfish were introduced to many watersheds in Southern California (Dill and Cordone 1997). In 1978, one fish was caught in the San Joaquin River, and in Clifton Court Forebay in 1986. These fish may have escaped from an aquaculture operation in the Central Valley (Dill and Cordone 1997). Blue Catfish are established but rare in the Sacramento-San Joaquin Delta (Cohen and Carlton 1995; USGS Nonindigenous Aquatic Species Program 2018). In 2017, an 830 mm fish was caught in Clear Lake, in the Sacramento River basin (http://www.foxnews.com/great-outdoors/2017/07/12/monster-catfish-reeled-in-by-california-fisherman.html).
Invasion History on the East Coast:
Blue Catfish (Ictalurus furcatus) on the East Coast, especially the Potomac River, where believed to be introduced as an accidental contaminant of stocks of Channel Catfish (I. punctatus) by the United States Fish Commission at the turn of the century (Smith 1907). However, preserved voucher specimens labelled as I. furcatus were actually I. punctatus (Burkhead et al. 1980), so these early reports are unverified. In the 1960-70s, state fisheries agencies began stocking Blue Catfish to attract trophy fishermen with giant fish. The first planting was in 1964 to Lake Marion, South Carolina, which is in the Santee-Cooper river system. Subsequent state first introductions were: Georgia (1971, Savannah River), North Carolina (1975, Cape Fear and Neuse Rivers), and Virginia (1974-1977, Rappahannock and James Rivers) (Dahlberg and Scott 1979; Jenkins and Burkhead 1993; USGS Nonindigenous Aquatic Species Program 2018). In each state, Blue Catfish rapidly dispersed up and down rivers, and was officially and informally introduced to other tributaries. In some cases, such as the Satilla River, Georgia (Bonivecchio et al. 2012) and the Northwest River, a Back Bay tributary (Tolliver 2016). Blue Catfish are believed to have migrated through brackish water in the Intracoastal Waterway.
Blue Catfish were stocked in Chesapeake Bay watershed starting in the 1980s. In 1987 they were caught at Haines Point, in the Potomac River. They were stocked in reservoirs in the Occoquan basin, a Potomac tributary in the 1980s, so this fish could have been dispersed from there, or could have migrated from the Rappahannock, during time of high river flow (Nammick and Fulton 1987). Sizes of record fishes in the James and Rappahannock estuaries were reported in fishing columns and increased through the 80s and 90s. Catfish were first stocked in the Mattaponi River in 1985, and now occur in the Pamunkey and York Rivers as well. Since 1990, abundance of Blue Catfish has fluctuated in Virginia rivers, but peak abundances have become successively larger (Greenlee and Lim 2011; Schloesser et al. 2011). By 2002 Blue Catfish were widespread and increasing in abundance in the tidal freshwater Potomac (Starnes 2002). From 2008-2010, populations of Blue Catfish have established in the fresh-oligohaline tidal regions of the Patuxent, Nanticoke, Sassafras, and Susquehanna Rivers (Maryland Department of Natural Resources 2010; Schloesser et al. 2011). On August 3, 2011, a specimen was caught at Conowingo Dam, at the head of Chesapeake Bay (USGS Nonindigenous Aquatic Species Program 2018). Blue Catfish range extensions presumably resulted from a mixture of releases by fishermen and natural dispersal. The brackish waters of Chesapeake Bay have been less of a barrier than biologists had expected, these fish have been caught at salinities as high as 15 PSU (Schloesser et al. 2011). They have apparently dispersed across the Bay, or have been introduced, to the Nanticoke River, on the Eastern shore. The first catch there was in Seaford, Delaware in 2010 (USGS Nonindigenous Aquatic Species Program 2018). Multiple record-sized fish have been caught there.
Blue Catfish were first caught in the Christiana River, a tributary of the Delaware estuary, in 2013. It has been caught several times in New Jersey and Delaware waters, n 2013-2023, and is probably established (USGS Nonindigenous Aquatic Species Program 2023). Possible vectors include the Chesapeake and Delaware Canal. or unauthorized releases.
Description
Blue Catfish (Ictalurus furcatus) are large predatory Bullhead Catfishes in the family Ictaluridae. Fish in this family have four pairs of barbels, no scales, an adipose fin, stout spines at the origins of the dorsal and pectoral fins, and abdominal pelvic fins. The tail fin of the Blue Catfish is deeply forked, with rounded lobes. The adipose fin has a short base, with its free end free at the back, and far from the caudal fin. The base of the anal fin is relatively long, and tapered rearward, with a straight edge and 30-35 rays. The pectoral spines are stout and strongly serrated. The dorsal fin is relatively short, with one spine and six soft rays. The head is broad and depressed. Adults can reach 1650 mm but are usually less than 600 mm. A 1000 mm fish can weigh 23 kg (50 lb.) Blue Catfish are blue-black above, and silver-blue. silver-gray, or white below. They lack the small black spots that usually occur on the Channel Catfish (I. punctatus). The chin barbels are pale, while the other barbels are dusky (Page and Burr 1991; Jenkins and Burkhead 1993; Murdy et al. 1997; Moyle 2002).
Taxonomy
Taxonomic Tree
Kingdom: | Animalia | |
Phylum: | Chordata | |
Subphylum: | Vertebrata | |
Superclass: | Osteichthyes | |
Class: | Actinopterygii | |
Subclass: | Neopterygii | |
Infraclass: | Teleostei | |
Superorder: | Ostariophysi | |
Order: | Siluriformes | |
Family: | Ictaluridae | |
Genus: | Ictalurus | |
Species: | furcatus |
Synonyms
Potentially Misidentified Species
Ameiurus catus (White Catfish) is native to the Atlantic Slope, and has been introduced to the San Francisco estuary and the Columbia River. The tail is forked, the pectoral spine has saw-like teeth, and the chin barbels are white. It is smaller than Blue or Channel Catfish (950 mm) (Page and Burr 1991).
Ameiurus melas
Ameiurus melas (Black Bullhead) is native to the Mississippi-Great Lakes basin and has been introduced to the San Francisco estuary and the Columbia River. The tail is squared-off, the pectoral spine lacks saw-like teeth, and the chin barbels are dark (Page and Burr 1991).
Ameiurus natalis
Ameiurus natalis (Yellow Bullhead) is native to the Atlantic Slope and Mississippi-Great Lakes basin and has been introduced to the San Francisco estuary and the Columbia River. The tail is squared-off, the pectoral spine has saw-like teeth, and the chin barbels are white or yellow (Page and Burr 1991).
Ameiurus nebulosus
Ameiurus nebulosus (Brown Bullhead) is native to the Atlantic Slope and Mississippi-Great Lakes basin and has been introduced to the San Francisco estuary and the Columbia River and Fraser Rivers. The tail is squared-off, the pectoral spine has saw-like teeth, and the chin barbels are dark. The body has dark brown mottling (Page and Burr 1991).
Ictalurus punctatus
Ictalurus punctatus (Channel Catfish) are native to the Mississippi-Gulf Basin, and the southeastern Coastal Plain, and has been introduced to the San Francisco estuary and the Columbia River. Adults are large, gray in color, sometimes with scattered dark spots. The caudal fin is deeply forked, and the anal fin has a curved edge (Page and Burr 1991).
Ecology
General:
Blue Catfish range from cold-temperate to subtropical climates. Adults have been collected at 15 PSU in the field (Schloesser et al. 2011). Their habitats include: pools, and sluggish runs over soft substrates in creeks and small to large rivers, impoundments, oxbows, and ponds (Page and Burr 1991). They are omnivorous, but because of their large size, they function as apex predators. In surveys of fish from Chesapeake tributaries, researchers reported their diet to include a lot detritus and plant matter. Fish <300 mm tend to consume more invertebrates, while large fish consume more fishes. Prey composition varied among tributaries and with season, indicating considerable opportunism (Groves and Love 2010; Schloesser et al. 2011; Schmitt et al. 2019). A DNA study of catfish gut contents indicates that Blue Catfish eat a greater quantity and variety of fishes than Channel Catfish (I. punctatus) or White Catfish (Ameiurus catus). Common prey are Menhaden (Brevoortia tyrannus), American Shad (Alosa sapidissima), River Herring (A. pseudoharengus, A. aestivalis), Gizzard Shad (Dorosoma cepedianum), White Perch (Morone americana), and Channel Catfish (Moran et al. 2016). Stable isotope studies show that during the spring migration of river herring and shad, the isotopic composition shifted from a freshwater to a marine profile, as a result of feeding on fish newly arrived from the sea (MacAvoy et al. 2000). Overall, Blue Catfish are omnivores, with one of the broadest feeding spectra known, including plant material. mollusks, fish. and such items as a whole muskrat and a wide variety of anthropogenic trash (Schmitt et al. 2019).
Food:
Fishes, invertebrates, aquaitc vegetation
Consumers:
fishes, birds, humans
Competitors:
Ameiurus catus; Ictalurus punctatus; Pylodictis olivaris
Trophic Status:
Omnivore
OmniHabitats
General Habitat | Nontidal Freshwater | None |
General Habitat | Fresh (nontidal) Marsh | None |
General Habitat | Grass Bed | None |
General Habitat | Coarse Woody Debris | None |
General Habitat | Swamp | None |
General Habitat | Tidal Fresh Marsh | None |
General Habitat | Unstructured Bottom | None |
General Habitat | Rocky | None |
Salinity Range | Limnetic | 0-0.5 PSU |
Salinity Range | Oligohaline | 0.5-5 PSU |
Salinity Range | Mesohaline | 5-18 PSU |
Tidal Range | Subtidal | None |
Vertical Habitat | Epibenthic | None |
Vertical Habitat | Nektonic | None |
Life History
Blue Catfish (Ictalurus furcatus) are large predatory freshwater catfish that do enter brackish water. The two sexes are not morphologically distinguishable. They mature at about 400-600 mm, at an age of about 4 years (Carlander 1969; Jenkins and Burkhead 1993). Spawning occurs at 21-24 C. Both sexes prepare a nest in sand or gravel and guard it. Fecundity is roughly estimated at 4,000-18, 000 eggs. Eggs and young are guarded by both sexes. They can be long-lived, a 41 kg specimen was 21 years old (Jenkins and Burkhead 1993). In Virginia tributaries of Chesapeake Bay, growth rate has decreased from 1998-2000 to 2014-2017, probably reflecting more intraspecific competition (Nepal et al. 2020).
Tolerances and Life History Parameters
Minimum Temperature (ºC) | 30.5 | Field, James River, Virginia (Fabrzio et al. 2010) |
Maximum Temperature (ºC) | None | None |
Minimum Salinity (‰) | 0 | This is a freshwater fish. |
Maximum Salinity (‰) | 9 | 15 PSU, Field, Schloesser et al. 2011. 14 PSU, experimental (Allen and Avault 1971). In careful experiments at 22 C, there was no mortality at 13 PSU and 40-70 h survival at 17 PSU. The calculated LC 50 was 15.2-15.7 PSU for 72 hours. Salinity tolerance was greater for larger fish (Nepal and Fabrizio 2019). There is a field record at 22 PSU from the James River (Tuckey et al. 2017; Nepal and Fabrizio 2019). However, 9 PSU may be the maximum for long-term survival and growth (Nepal and Fabrizio 2020). |
Minimum Reproductive Temperature | 21 | Carlander 1969 |
Minimum Reproductive Salinity | 0 | This is a freshwater fish. |
Maximum Reproductive Salinity | 2 | Perry 1973 |
Minimum Length (mm) | 400 | Carlander 1969 |
Maximum Length (mm) | 1,650 | Page and Burr 1991 |
Broad Temperature Range | None | Cold Temperate-to-Subtropical |
Broad Salinity Range | None | Limnetic-Mesohaline |
General Impacts
Blue Catfish (Ictalurus furcatus) have been introduced to many East Coast tributaries, and in the San Francisco Bay watershed. However, detailed studies of their predatory impacts and resulting implications for fisheries and conservation are largely focused on Chesapeake Bay. Blue Catfish can be giant, sometimes exceeding 23 kg (50 lbs), which makes them a major attraction for fishers. In the 1960s and 70s fisheries agencies use their large size to justify official introductions and unofficial transfers. In more recent decades, agencies are more concerned about biodiversity and conservation of native fisheries stocks, especially migratory species (MacAvoy et al. 2010; Groves and Love 2010). In Chesapeake Bay, commercial fishing of Blue Catfish is being promoted and the fish is often mentioned in restaurant advertisements (NOAA Chesapeake Bay Office 2018). The conflict between the desire to promote fisheries and the desire to prevent further introductions complicates communications with the public (Orth et al. 2020).
Blue X Channel Catfish hybrids are extensively used catfish aquaculture. In 2009, 13% of catfish hatched in US aquaculture operations were hybrids (APHIS Veterinary Services 2011).
Regional Impacts
M130 | Chesapeake Bay | Economic Impact | Fisheries | ||
Blue Catfish (Ictalurus furcatus) are popular sportfish and commercial species, and one of the Chesapeake's largest fishes (Jenkins and Burkhead 1993; Murdy et al. 1997). In the spring and summer of 1995, and 1996, catches of large fish in the James and Rappahannock were frequently mentioned in the Washington Post. As populations increased in the Potomac, record fish captured attention among local fishermen and there was uncertainty in the Maryland Department of Natural Resources as to whether recognizing record catch would encourage illegal introductions of this invasive fish (Thomsen 2010). As a new top predator, they may be reducing abundance of other fishes, particularly shads, migratory herrings (Alosa spp.), and menhaden (MacAvoy et al. 2000; Schloesser et al. 2011). Potentially, Blue Catfish and the other introduced giant catfish, Pylodictis olivaris (Flathead Catfish), may be interfering with attempts to restore American Shad (Alosa sapidissima) (Garman et al. 2010; Groves and Love 2010). Management of Blue Catfish is complicated by need to balance the recreational fishery with the need to protect native fish stocks. Some Chesapeake watermen have switched from Blue Crabs to Blue Catfish, and this invasive fish is advertised by local restaurants (NOAA Chesapeake Bay Office 2018). However, large Blue Catfish have high levels of chemical contamination making them unsafe to eat (Schloesser et al. 2011).Fish under 760 mm (30 in.) are considered safe to eat. |
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M130 | Chesapeake Bay | Ecological Impact | Predation | ||
Predation- Blue Catfish (Ictalurus furcatus) are likely to be important predators, given their size and piscivorous food habits (Carlander 1969; Jenkins and Burkhead 1993). Statistical analyses indicate that Blue Catfish have adversely affected clupeid (herring- family fishes) populations in the James and Rappahannock Rivers (Austin 1998, personal communication). Gut and isotope analyses indicate that anadromous Alosa spp. (Shad, Alewives, Blueback Herring) form a substantial fraction of the Blue Catfish’s diet, resulting in a strong marine signature in the isotope composition of the freshwater predator (MacAvoy et al. 2000). Feeding studies indicate that younger fish in the James, York, and Rappahannock Rivers (smaller than 300 mm) feed mostly on benthic invertebrates, but that larger fishes (300-600mm) feed mostly on fishes. Menhaden (Brevoortia tyrannus) was the most frequent prey species (Schloesser et al. 2011). DNA studies show that Blue Catfish feed on at least 20 species of fishes (Aguilar et al. 2017). | |||||
S050 | Cape Fear River | Ecological Impact | Predation | ||
Ictalurus furcatus (Blue Catfish) are a major predator on fishes and invertebrates in the Cape Fear River, The largest size class of individuals (<600 mm) had 31% fishes and 42% invertebrates (by weight) in their sotmachs. invertebrates, Asian Clams (Corbicula fluminea) decreased in frequency with fish size ,from 86% (by weight) for fish below 100 mm, to 33% for fish over 300 mm (Belkoski et al. 2021) |
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S050 | Cape Fear River | Economic Impact | Fisheries | ||
Blue Catfish are a major game fish in the Cape Fear River (Belkoski et al. 2021). |
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NC | North Carolina | Ecological Impact | Predation | ||
Ictalurus furcatus (Blue Catfish) are a major predator on fishes and invertebrates in the Cape Fear River, The largest size class of individuals (<600 mm) had 31% fishes and 42% invertebrates (by weight) in their stomachs. invertebrates, Asian Clams (Corbicula fluminea) decreased in frequency with fish size ,from 86% (by weight) for fish below 100 mm, to 33% for fish over 300 mm (Belkoski et al. 2021) |
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NC | North Carolina | Economic Impact | Fisheries | ||
Blue Catfish are a major game fish in the Cape Fear River (Belkoski et al. 2021), and in North Carolina generally (North Carolina Wildlife Resources Commission 2021). |
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VA | Virginia | Ecological Impact | Fisheries | ||
Blue Catfish (Ictalurus furcatus) are popular sportfish and commercial species, and one of the Chesapeake's largest fishes (Jenkins and Burkhead 1993; Murdy et al. 1997). In the spring and summer of 1995, and 1996, catches of large fish in the James and Rappahannock were frequently mentioned in the Washington Post. As populations increased in the Potomac, record fish captured attention among local fishermen and there was uncertainty in the Maryland Department of Natural Resources as to whether recognizing record catch would encourage illegal introductions of this invasive fish (Thomsen 2010). As a new top predator, they may be reducing abundance of other fishes, particularly shads, migratory herrings (Alosa spp.), and menhaden (MacAvoy et al. 2000; Schloesser et al. 2011). Potentially, Blue Catfish and the other introduced giant catfish, Pylodictis olivaris (Flathead Catfish), may be interfering with attempts to restore American Shad (Alosa sapidissima) (Garman et al. 2010; Groves and Love 2010). Management of Blue Catfish is complicated by need to balance the recreational fishery with the need to protect native fish stocks. Some Chesapeake watermen have switched from Blue Crabs to Blue Catfish, and this invasive fish is advertised by local restaurants (NOAA Chesapeake Bay Office 2018). However, large Blue Catfish have high levels of chemical contamination making them unsafe to eat (Schloesser et al. 2011).Fish under 760 mm (30 in.) are considered safe to eat. |
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VA | Virginia | Ecological Impact | Food/Prey | ||
|
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MD | Maryland | Economic Impact | Fisheries | ||
Maryland State and Chesapeake Bay Program websites encourage fishing for Blue Catfish, as a way of controlling an apex predator, but warn of toxic chemicals, especially in larger fish. https://www.chesapeakebay.net/news/blog/fishing-for-blue-catfish-is-good-for-the-bay-but-hbe-careful-when-eating-them https://www.chesapeakebay.net/news/blog/understanding-the-threat-of-invasive-catfish |
Regional Distribution Map
Bioregion | Region Name | Year | Invasion Status | Population Status |
---|---|---|---|---|
M130 | Chesapeake Bay | 1974 | Non-native | Established |
P090 | San Francisco Bay | 1979 | Non-native | Established |
G210 | Terrebonne/Timbalier Bays | 0 | Native | Established |
G200 | Barataria Bay | 0 | Native | Established |
G170 | West Mississippi Sound | 0 | Native | Established |
G190 | Mississippi River | 0 | Native | Established |
G330 | Lower Laguna Madre | 0 | Native | Established |
G260 | Galveston Bay | 0 | Native | Established |
G250 | Sabine Lake | 0 | Native | Established |
G270 | Brazos River | 0 | Native | Established |
G268 | _CDA_G268 (Austin-Oyster) | 0 | Native | Established |
G290 | San Antonio Bay | 0 | Native | Established |
G310 | Corpus Christi Bay | 0 | Native | Established |
G150 | Mobile Bay | 0 | Native | Established |
G125 | _CDA_G125 (Pensacola Bay) | 1996 | Non-native | Established |
S050 | Cape Fear River | 1979 | Non-native | Established |
S160 | St. Andrew/St. Simons Sounds | 2011 | Non-native | Established |
S120 | Savannah River | 1971 | Non-native | Established |
S150 | Altamaha River | 2010 | Non-native | Established |
M090 | Delaware Bay | 2013 | Non-native | Established |
G320 | Upper Laguna Madre | 0 | Native | Established |
G300 | Aransas Bay | 0 | Native | Established |
G280 | Matagorda Bay | 0 | Native | Established |
G240 | Calcasieu Lake | 0 | Native | Established |
G230 | Mermentau River | 0 | Native | Established |
G220 | Atchafalaya/Vermilion Bays | 0 | Native | Established |
G180 | Breton/Chandeleur Sound | 0 | Native | Established |
G160 | East Mississippi Sound | 0 | Native | Established |
S010 | Albemarle Sound | 2016 | Non-native | Established |
S166 | _CDA_S166 (Cumberland-St. Simmons) | 2011 | Non-native | Established |
S020 | Pamlico Sound | 1975 | Non-native | Established |
NA-ET3 | Cape Cod to Cape Hatteras | 1974 | Non-native | Established |
NEP-V | Northern California to Mid Channel Islands | 1979 | Non-native | Established |
CAR-I | Northern Yucatan, Gulf of Mexico, Florida Straits, to Middle Eastern Florida | 1996 | Non-native | Established |
CAR-VII | Cape Hatteras to Mid-East Florida | 1971 | Non-native | Established |
Occurrence Map
OCC_ID | Author | Year | Date | Locality | Status | Latitude | Longitude |
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