Invasion History

First Non-native North American Tidal Record: 1871
First Non-native West Coast Tidal Record: 1871
First Non-native East/Gulf Coast Tidal Record: 1874

General Invasion History:

American Shad (Alosa sapidissima) is an anadromous fish native to the East Coast of North America. Native spawning populations range from the St. Lawrence River estuary to the St. Johns River in Florida. Spawning fish migrate up to 800 km upstream to spawn, though dams have limited that movement. Juvenile shad move downstream to estuaries and as adults range widely in coastal ocean waters (Bigelow and Schroeder 1953). American Shad were stocked unsuccessfully in the Great Lakes in 1870-1875 (Emery 1985), and the Gulf Coast in 1875-1900 (Baird 1878; Bowers 1900; USGS Nonindigenous Aquatic Species Program 2014), but plantings in the San Francisco estuary in 1871 resulted in an established population in the estuary, which later developed spawning populations north to the Columbia River (Pearcy and Fisher 2011). Migrating adults move along the coasts from Baja California, north to Alaska, and west to Kamchatka, Russia (Pearcy and Fisher 2011; Hasselman 2012a).

North American Invasion History:

Invasion History on the West Coast:

In June 1871, the first planting of 1000 fry from the Hudson River was made at Tehama on the Sacramento River, which is 443 km upstream of Sacramento. The fish were carried in milk cans and transported by rail. From 1871 to 1881, a total of 600-879,000 American Shad were stocked in the San Francisco Bay watershed. Their successful establishment may have been favored because shad have floating eggs and spawn in deep river channels, and so were less affected by the heavy siltation resulting from hydraulic mining in the watershed (Shebley 1917; Cohen and Carlton 1997; Dill and Cordone 1997). Additional plantings were made in the Columbia River in 1885-1886 (Lampman 1946). American Shad dispersed rapidly up and down the coast, reaching San Pedro Bay in the south and the Columbia River and Vancouver Island in the north by 1880 (Smith 1895; Lampman 1946; Cohen and Carlton 1995; Dill and Cordone 1997).

Adult fish range as far south as Baja California, Mexico and Kodiak Island, Alaska (Pearcy and Fisher 2011; Hasselman 2012a). Adults have strayed as far west as the Kamchatka Peninsula, Russia, but there is no evidence of spawning there (Chereshnev and Zharnikov (1989, cited by Hasselman 2012a). Spawning populations are known from the Salinas, Eel, Klamath River, Coquille River, Coos Bay, Umpqua River, Smith River and Siuslaw River. Migration occurs along the narrow continental shelf, mostly with 50 km of the shore (Pearcy and Fisher 2011).

American Shad are still established in San Francisco Bay, but have declined since the mid-20th century, though not as dramatically as Striped Bass (Morone saxatilis) (Dill and Cordone 1997; Sommer et al. 2007). The only established land-locked freshwater population of American Shad was established in Millerton Lake, a reservoir on the upper San Joaquin River, near Fresno, and ~ 400 km from the sea. The fish may have been accidentally introduced with a planting of Striped Bass in 1955-1957 (Dill and Cordone 1997).

American Shad from San Francisco Bay had reached the Columbia River by 1880. But between 1885 and 1886 additional plantings were made by the US. Fish Commission who planted 910,000 fry in the Willamette River. Spawning populations were established in the Columbia River by the 1940s (Pearcy and Fisher 2011). After 1960, the number of shad passing Bonneville Dam began to increase sharply, peaking at ~6 million fish in 2006 (Hasselman et al. 2011a). Shad have been collected as far upriver as the Granite Dam on the Snake River, Idaho, 600 km from the Ocean, but most of the spawning takes place below the Bonneville Dam. Breeding populations are known from Willapa Bay, the Chehalis River, and Puget Sound tributaries (Pearcy and Fisher 2011). Stray fish were reported in Cook Inlet and Kodiak Island in 1904 and 1926 and the Kamchatka Peninsula, Russia by 1989 (Hasselman 2012a).

Invasion History on the Gulf Coast:

Attempts were made to introduce American Shad to several Gulf of Mexico tributaries, including the Colorado River, Texas (Baird 1874) and Apalachee Bay, Florida, the Econfina-Steinhatchee River in Florida, and Suwannee River in Georgia (Bowers 1900, cited by USGS Nonindigenous Aquatic Species Program 2018). These releases appear to have been unsuccessful (USGS Nonindigenous Aquatic Species Program 2018). The very similar Alabama Shad is native in much of this range (Robins et al. 1986).

Invasion History Elsewhere in the World:

Many attempts have been made to introduce American Shad to inland waters of North America. In 1870, 5,000 American Shad were released in the Genesee River, a tributary of Lake Ontario. In the 1870s and early 1880s, nearly 3.5 million shad were released in the Great Lakes, but few fish were recovered (Emery 1985). Several releases were made in interior rivers and reservoirs, including Great Salt Lake Basin, and the Colorado River in California, mostly in the 19th century. All these releases were unsuccessful (USGS Nonindigenous Aquatic Species Program 2018). There are reports of introductions to Japan and Germany, but no details are available (Food and Agricultural Organization 2018; Froese and Pauly 2018).


Description

American Shad (Alosa sapidissima) is an anadromous fish in the herring family (Clupeidae), with an extensive ocean range and only one known landlocked population. Its body is streamlined, but deep and laterally compressed. There is a single soft-rayed dorsal fin, a soft-rayed anal fin, and the pelvic fins are abdominal. There are 15-19 dorsal rays, and 18-24 anal rays. The tail is deeply forked. The scales are large and easily loosened. The belly is keeled with prominent bony scutes (external bony plates). Adult fish can reach 760 mm. The body is dark greenish or bluish dorsally and silvery-white on the sides, with a dark spot and one or two rows of dusky lateral spots on the rear of the gill cover (Bigelow 1953; Miller1972; Eschmeyer and Herald 1983). Developmental stages are described by Jones et al. (1978) and Wang (1985).


Taxonomy

Taxonomic Tree

Kingdom:   Animalia
Phylum:   Chordata
Subphylum:   Vertebrata
Superclass:   Osteichthyes
Class:   Actinopterygii
Subclass:   Neopterygii
Infraclass:   Teleostei
Superorder:   Clupeomorpha
Order:   Clupeiformes
Suborder:   Clupeoidei
Family:   Clupeidae
SubFamily:   Alosinae
Genus:   Alosa
Species:   sapidissima

Synonyms

Alosa praestabilis (DeKay, 1842)
Clupea indigena (Mitchill, 1814)
Clupea sapidissima (Wilson in Rees, 1811)

Potentially Misidentified Species

Alosa alabamae
Alosa alabamae (Alabama Shad) is native to the Gulf of Mexico from the Suwannee River to the Mississippi. It is very similar to A. sapidissima, but differs in the number of gill rakers (Robins et al. 1986).

Clupea pallasi
Clupea pallasi (Pacific Herring) has a shallower body, with weakly developed scutes on the belly, and has no spots (Miller 1972; Eschmeyer and Herald 1983).

Dorosoma petenense
Dorosoma petenense (Threadfin Shad) is primarily a freshwater species, but juveniles and adults enter brackish and marine waters. Adults are smaller than American Shad (230 mm). This fish is distinguished by an elongated ray at the posterior corner of the anal fin (Eschmeyer and Herald 1983).

Sardinops sagax
Sardinops sagax (Pacific Sardine) has a more slender body, and bony striations on the gill cover, and one or two rows of dark spots (Miller 1972; Eschmeyer and Herald 1983).

Ecology

General:

American Shad (Alosa sapidissima) is an anadromous fish, whose adults migrate long distances along the continental shelf while feeding, and run long distances up large rivers for spawning (Bigelow and Schroeder 1953; Page and Burr 1991). Only one landlocked population is known, in Millerton Reservoir, San Joaquin River CA (Dill and Cordone 1997). Females tend to reach a larger size (3.6 kg) than males (2.7 kg). The maximum length is 760 mm, but more usually 600 mm (Froese and Pauly 2018). Adults mature at ~380-400 mm, at about 3-6 years. Females produce 100,000 to 600,000 eggs (Bigelow and Schroeder 1953; Murdy et al. 1997).

Adults usually migrate to their river of birth. Some spawn immediately on reaching freshwater, but some fish migrate as much as 630 km upstream, although dams have curtailed many of these migrations (Bigelow and Schroeder 1953; Froese and Pauly 2018). Spawning fish enter freshwater at ~10-13 F in winter to spring. Spawning dates on the east coast are as early as January in Georgia and as late and May-June in Nova Scotia (Bigelow and Schroeder 1953). In the San Francisco estuary, American Shad enter the estuary as early as the fall. Spawning runs occur in March to April-June, mostly above Rio Vista on the Sacramento River in the tidal fresh section of the river (Wang 1986). Spawning migrations in the Columbia River take place from May to July (Pearcy and Fisher 2011). The fish do not feed during the spawning migrations. Spawning takes place in sandy or pebbly shallows. After spawning, the emaciated adults either die, or return downriver to feed, and then go out to sea (Bigelow and Schroeder 1953). On the Pacific coast, most adults die after one spawning (Cohen and Carlton 1995). The eggs are semi-buoyant and move downstream along the bottom with the current. At 12-17 C, the eggs take 6-15 days to hatch into 9-10 mm yolk-sac larvae. After absorption of the yolk-sac, at ~16.5 mm, the larvae are extremely slender, but by late summer or fall the juveniles have reached 40-80 mm and resemble the adults in shape (Bigelow and Schroeder 1953). In some estuaries, they move downstream into brackish or sea water, but most of those in the San Francisco estuary remain in the fresh water of the upper Delta (Wang 1986).

As strong migrators, American Shad can avoid extremes of temperature through migration. On the Atlantic Coast, they have seasonal migrations at sea. Fish from all along the Atlantic coast gathering in the Gulf of Maine to feed in summer, often moving more than 150 km offshore. Adult fish winter in deeper offshore waters (Bigelow and Schroeder 1953). On the Pacific Coast, fish reach the highest abundance from central Oregon to Vancouver island, over the shallow continental shelf (<159 m), at sea surface temperatures of 11 to 17 C, but do not show strong southward migrations. In all their movements, American Shad move in large schools. The spawning migration into freshwater requires a physiological adaptation to freshwater, mediated by hormones. The fish meander during migration, while making this adjustment. They also cease to feed (Leggett and O'Boyle 1976).

The primary food of larvae, juveniles, and adult American Shad is zooplankton. Larval and juvenile fish feed on smaller freshwater and estuarine copepods. They switch to larger marine copepods (e.g. Calanus spp.), mysids, and euphausiids as adults. Occasionally, adults will eat small fish, but this is not a major part of their diet (Bigelow and Schroeder 1953). As noted above, feeding ceases when adults migrate into freshwater. Shad are prey for larger fishes, birds, and seals.

Food:

Copepods, mysids, fishes

Consumers:

Fishes, Birds, Seals, Humans

Trophic Status:

Carnivore

Carn

Habitats

General HabitatNontidal FreshwaterNone
General HabitatGrass BedNone
General HabitatUnstructured BottomNone
General HabitatCoarse Woody DebrisNone
General HabitatTidal Fresh MarshNone
General HabitatSalt-brackish marshNone
General HabitatRockyNone
Salinity RangeLimnetic0-0.5 PSU
Salinity RangeOligohaline0.5-5 PSU
Salinity RangeMesohaline5-18 PSU
Salinity RangePolyhaline18-30 PSU
Salinity RangeEuhaline30-40 PSU
Tidal RangeSubtidalNone
Vertical HabitatNektonicNone

Life History


Tolerances and Life History Parameters

Minimum Temperature (ºC)4Field data (Jones et al. 1978)
Maximum Temperature (ºC)30Field data (Jones et al. 1978)
Minimum Salinity (‰)0Field data (Jones et al. 1978)
Maximum Salinity (‰)35Field data (Jones et al. 1978)
Minimum Dissolved Oxygen (mg/l)3.2Field data (Jones et al. 1978)
Minimum Reproductive Temperature8Field data (Jones et al. 1978)
Maximum Reproductive Temperature26Field data (Jones et al. 1978)
Minimum Reproductive Salinity0This is a freshwater-spawning fish.
Maximum Reproductive Salinity7.5Bigelow and Schroeder 1953
Minimum Length (mm)380Froese and Pauly 2014
Maximum Length (mm)760Froese and Pauly 2014
Broad Temperature RangeNoneCold temperate-Warm temperate
Broad Salinity RangeNoneLimnetic-Euhaline

General Impacts

American Shad (Alosa sapidissima) was a highly esteemed food-fish on the East Coast, well regarded for its flesh and roe. Its introduction and establishment on the West Coast was regarded as a triumph of fish-culture in the 19th century. Successful fisheries were quickly established from San Francisco Bay to the Columbia River (Smith 1895; Dill and Cordone 1997). However, on the Pacific coast, 'the shad never quite has convinced the western palate, perhaps because of a prodigality of salmon' (Lampman 1946). The commercial net fishery for Shad ended in San Francisco Bay in 1957, but a sport fishery continues with dip nets and fly-fishing. While migrating adult shad do not feed, they will snap at an artificial fly and provide sport for fly-fishers. (Dill and Cordone 1997). Prior to the introduction of Shad into the San Francisco estuary and watershed, large planktivorous fishes were absent from the system. Thus Shad were able to fill and an empty niche (Cohen and Carlton 1995). However, in the Columbia River, where ranges of juvenile salmon (Oncorhynchus spp.) overlap with shad, competition for zooplankton prey is a concern. In coastal Pacific waters, American Shad may be competing with Pacific Herring for food (Ray Buckley, personal communication 2004; Hasselman 2012b).

Economic Impacts 

Fisheries- As noted above, American Shad was a highly esteemed food-fish at the time of its introduction to San Francisco Bay in 1874, and commercial fisheries were underway by 1883. However, shad never reached the popularity that it had on the East Coast, and few people were willing to learn the difficult skill of boning this very bony fish (Dill and Cordone 1997). Nonetheless, fisheries developed at rivers north of San Francisco Bay to the Columbia River by 1888 (Smith 1895). Fisheries on the San Francisco Bay and the West Coast were primarily for the roe. They fluctuated both with the abundance of the fish, and the price, which sometimes fell so low that the fishery was not profitable. In 1957, the state closed the fishery due to pressure from sport fishers, who were concerned about Striped Bass being caught in seine nets. Sports fisheries for Shad continue using dip nets and fly-fishing (Dill and Cordone 1997). ).

Ecological Impacts 

Impacts of American Shad on native species in the San Francisco estuary were thought to be small, because shad were believed to occupy an 'unfilled niche' (Cohen and Carlton 1995). However, abundances of this fish has increased in Oregon and Washington marine, estuarine and fresh waters, raising concern about competition for zooplankton with Pacific Herring (Clupea pallasi) and native salmon (Onorhynchus spp.) (Ray Buckley, personal communication 2004; Hasselman 2012b). The increased population of American Shad after 1988, contributed to an amplified epizootic of the protozoan parasite Ichthyophonus, a potential threat to other marine and anadromous fishes (Hershberger et al. 2010). The increased population of American Shad migrating up the Columbia River also has potential effects on the river system's foodweb by transporting nutrients from the ocean into the river and reservoirs. This import roughly matches the present importation of marine nutrients by migrating salmon, but is much smaller than the historic upstream transport by native salmon populations (Haskell 2018).


Regional Impacts

P260Columbia RiverEcological ImpactCompetition
Zooplankton predation by American Shad are expected to affect food availability for native fishes, including Pacific salmon (Oncohrynchus spp.) (Haskell et al. 2013).
P260Columbia RiverEcological ImpactPredation
The increased population of American Shad in reservoirs of the Columbia River appears to have altered the zooplankton population, reducing the abundance of large zooplankton such as Daphnia spp. American Shad are estimated to consume an average of 23% of daily zooplankton production (Haskell et al. 2013).
P260Columbia RiverEcological ImpactParasite/Predator Vector
The increased population of American Shad in reservoirs of the Columbia River appears to have amplified the population of a native protistan parasite, Ichthyophonus spp. in freshwater reservoirs of the river. The parasite is regarded as a threat to native Pacific salmon, although prevalence was very low (~4%) in spring Chinook Salmon (Hershberger et al. 2010).
P260Columbia RiverEconomic ImpactFisheries
'Several hundred thousand shad are landed annually by commercial and sport fisheries in the Columbia River (Petersen et al. 2003', cited by Pearcy and Fisher 2011).
P180Umpqua RiverEconomic ImpactFisheries
Commercial fishery, (Mullen and Conover 1973, cited by Pearcy and Fisher 2011)
P090San Francisco BayEconomic ImpactFisheries
By 1874, American Shad were abundant enough to support a small fishery in San Francisco Bay, and from 1900 to 1945, catches frequently exceeded 1 million pounds. Catches decreased in the 1950s, and the commercial fishery was banned in 1957. The sport fishery continues, by dipnet and fly-fishing (Smith 1896; Cohen and Carlton 1995).
NEP-VNorthern California to Mid Channel IslandsEconomic ImpactFisheries
By 1874, American Shad were abundant enough to support a small fishery in San Francisco Bay, and from 1900 to 1945, catches frequently exceeded 1 million pounds. Catches decreased in the 1950s, and the commercial fishery was banned in 1957. The sport fishery continues, by dipnet and fly-fishing (Smith 1896; Cohen and Carlton 1995).
NEP-IVPuget Sound to Northern CaliforniaEconomic ImpactFisheries
Commercial fisheries occurred in the Siuslaw, Umpqua, Smith, Coos, Coquille Rivers in Oregon, where shad spawned, averaging 192 metric tons per year, during 1962–72 (Mullen and Conover 1973, cited by Pearcy and Fisher 2011).
P190Siuslaw RiverEconomic ImpactFisheries
Commercial fishery, (Mullen and Conover 1973, cited by Pearcy and Fisher 2011)
P170Coos BayEconomic ImpactFisheries
Commercial fishery, (Mullen and Conover 1973, cited by Pearcy and Fisher 2011)
P160Coquille RiverEconomic ImpactFisheries
Commercial fishery, (Mullen and Conover 1973, cited by Pearcy and Fisher 2011)
P260Columbia RiverEcological ImpactTrophic Cascade
Migration by American Shad has partially replaced the transport by native Salmon of nutrients (N and P) from the marine environment to the Columbia River Basin. At present, shad import 2% of the total phosphorus load to the John Day Reservoir, on the lower Columbia. Nutrient imports by shad roughly equal those of native salmon at present, but are much smaller than those from historic salmon population (Haskell 2018).
CACaliforniaEconomic ImpactFisheries
By 1874, American Shad were abundant enough to support a small fishery in San Francisco Bay, and from 1900 to 1945, catches frequently exceeded 1 million pounds. Catches decreased in the 1950s, and the commercial fishery was banned in 1957. The sport fishery continues, by dipnet and fly-fishing (Smith 1896; Cohen and Carlton 1995)., By 1874, American Shad were abundant enough to support a small fishery in San Francisco Bay, and from 1900 to 1945, catches frequently exceeded 1 million pounds. Catches decreased in the 1950s, and the commercial fishery was banned in 1957. The sport fishery continues, by dipnet and fly-fishing (Smith 1896; Cohen and Carlton 1995).
OROregonEconomic ImpactFisheries
Commercial fishery, (Mullen and Conover 1973, cited by Pearcy and Fisher 2011), Commercial fishery, (Mullen and Conover 1973, cited by Pearcy and Fisher 2011), Commercial fishery, (Mullen and Conover 1973, cited by Pearcy and Fisher 2011), Commercial fishery, (Mullen and Conover 1973, cited by Pearcy and Fisher 2011)

Regional Distribution Map

Bioregion Region Name Year Invasion Status Population Status
NEP-V Northern California to Mid Channel Islands 1871 Def Estab
NA-S3 None 0 Native Estab
NA-ET1 Gulf of St. Lawrence to Bay of Fundy 0 Native Estab
NA-ET2 Bay of Fundy to Cape Cod 0 Native Estab
NA-ET3 Cape Cod to Cape Hatteras 0 Native Estab
CAR-VII Cape Hatteras to Mid-East Florida 0 Native Estab
GL-I Lakes Huron, Superior and Michigan 1875 Def Failed
GL-II Lake Erie 1871 Def Failed
GL-III Lake Ontario 1870 Def Failed
NEP-IV Puget Sound to Northern California 1880 Def Estab
NEP-III Alaskan panhandle to N. of Puget Sound 1876 Def Estab
NEP-II Alaska south of the Aleutians to the Alaskan panhandle 1904 Def Unk
NEP-VI Pt. Conception to Southern Baja California 1880 Def Unk
NWP-5 None 1989 Def Unk
NWP-6 None 0 Def Unk
P260 Columbia River 1880 Def Estab
P170 Coos Bay 1888 Def Estab
S180 St. Johns River 0 Native Estab
S140 St. Catherines/Sapelo Sounds 0 Native Estab
S160 St. Andrew/St. Simons Sounds 0 Native Estab
S150 Altamaha River 0 Native Estab
S120 Savannah River 0 Native Estab
S110 Broad River 0 Native Estab
S100 St. Helena Sound 0 Native Estab
S080 Charleston Harbor 0 Native Estab
S090 Stono/North Edisto Rivers 0 Native Estab
S070 North/South Santee Rivers 0 Native Estab
S060 Winyah Bay 0 Native Estab
S050 Cape Fear River 0 Native Estab
S020 Pamlico Sound 0 Native Estab
S010 Albemarle Sound 0 Native Estab
M130 Chesapeake Bay 0 Native Estab
M090 Delaware Bay 0 Native Estab
M060 Hudson River/Raritan Bay 0 Native Estab
M040 Long Island Sound 0 Native Estab
M020 Narragansett Bay 0 Native Estab
N170 Massachusetts Bay 0 Native Estab
N150 Merrimack River 0 Native Estab
N130 Great Bay 0 Native Estab
N090 Kennebec/Androscoggin River 0 Native Estab
N050 Penobscot Bay 0 Native Estab
P080 Monterey Bay 1880 Def Estab
P090 San Francisco Bay 1871 Def Estab
P110 Tomales Bay 0 Def Estab
P113 _CDA_P113 (Russian) 1895 Def Estab
P130 Humboldt Bay 1891 Def Estab
P120 Eel River 1976 Def Estab
P150 Rogue River 1883 Def Estab
P160 Coquille River 1889 Def Estab
P180 Umpqua River 0 Def Estab
P220 Siletz Bay 1942 Def Estab
P190 Siuslaw River 0 Def Estab
P270 Willapa Bay 1942 Def Estab
P280 Grays Harbor 1942 Def Estab
P284 _CDA_P284 (Hoh-Quillayute) 1942 Def Estab
P290 Puget Sound 1882 Def Estab
P297 _CDA_P297 (Strait of Georgia) 1893 Def Estab
G090 Apalachee Bay 1900 Def Failed
G080 Suwannee River 1900 Def Failed
G086 _CDA_G086 (Econfina-Steinhatchee) 1900 Def Failed
S196 _CDA_S196 (Cape Canaveral) 1900 Def Failed
G268 _CDA_G268 (Austin-Oyster) 1900 Def Failed
G270 Brazos River 1874 Def Unk
P050 San Pedro Bay 1880 Def Unk
P140 Klamath River 1891 Def Estab
P298 _CDA_P298 (Fraser) 1891 Def Estab

Occurrence Map

OCC_ID Author Year Date Locality Status Latitude Longitude

References

Precht, William F. Hickerson, Emma L.; Schmah, George P.; Aronson, Richard B. (2014) The invasive coral Tubastraea coccinea (Lesson, 1829): Implications for natural habitats in the Gulf of Mexico and the Florida Keys, Gulf of Mexico Science 2014: 55-59

Bigelow, Henry B.; Schroeder, William C. (1953) Fishes of the Gulf of Maine, Fishery Bulletin of the Fish and Wildlife Service 53: 1-577

Bottom, Daniel L., Jones, Kim K. (1990) Species composition, distribution, and invertebrate prey of fish assemblages in the Columbia River estuary, Progress in Oceanography 25: 243-270

Carl, G. Clifford, Clemens, W. A., Lindsey, C. C. (1967) Fresh-water fishes of British Columbia, British Columbia Provincial Museum: Department of Recreation and Conservation: Handbook 5: 1-192

Carlton, James T. (1989) <missing title>, <missing publisher>, <missing place>. Pp. <missing location>

Carlton, James T.; Blakeslee, April M. H.; Fowler, Amy E. (2022) Accidental associates are not symbionts: the absence of a non?parasitic endosymbiotic community inside the common periwinkle Littorina littorea (Mollusca: Gastropoda, None 167(97): Published online
https://doi.org/10.1007/s00227-020-03694-x

Chapman, Wilbert M. (1942) Alien fishes in the waters of the Pacific Northwest, California Fish and Game 28: 9-15

Chesapeake Bay Program (2007) A Comprehensive List of Chesapeake Bay Basin Species , Chesapeake Bay Program, Annapolis MD. Pp. <missing location>

Cohen, Andrew N.; Carlton, James T. (1995) Nonindigenous aquatic species in a United States estuary: a case study of the biological invasions of the San Francisco Bay and Delta, U.S. Fish and Wildlife Service and National Sea Grant College Program (Connecticut Sea Grant), Washington DC, Silver Spring MD.. Pp. <missing location>

Cook Inlet Regional Citizen's Council 2023 Seaweeds of Alaska. https://www.seaweedsofalaska.com/species.asp?SeaweedID=46



Dill, William A.; Cordone, Almo J. (1997) History And Status Of Introduced Fishes In California, 1871-1996: Conclusions, Fisheries 22(10): 15-18, 35

Dill, William A.; Cordone, Almo J. (1997) History and status of introduced fishes in California, 1871-1996, California Department of Fish and Game Fish Bulletin 178: 1-414

Emery, Lee (1985) Review of fish species introduced into the Great Lakes, 1819-1974., Great Lakes Fisheries Commission 45: 1-31

Eschmeyer, William N.; Herald, Earl S.; Hamman, Howard (1983) A field guide to Pacific coast fishes: North America, Houghton Mifflin, Boston. Pp. <missing location>

Food and Agricultural Organization 1998-2012 Database on Introductions of Aquatic Species. <missing URL>



Fowler, Henry W. (1952) A list of the fishes of New Jersey, with off-shore species, Proceedings of the Academy of Natural Sciences of Philadelphia 104: 89-151

Froese, R.; Pauly, D. (Editors). 2002-2024 FishBase.(World Wide Web electronic publication).. <missing URL>



Fuller, P.M., Nico, L.G., Williams, J.D. (1999) Nonindigenous fishes introduced into inland waters of the United States, American Fisheries Society, Bethesda, MD. Pp. <missing location>

Fuller, Pam. L.; Nico, Leo; Williams, J. D. (1999) Nonindigenous fishes introduced into inland waters of the United States, American Fisheries Society, Bethesda MD. Pp. <missing location>

Hartel, Karsten E.; Halliwell, David B.; Launer, Alan E. (2002) Inland Fishes of Massachusetts, Massachusetts Audubon Society, Lincoln MA. Pp. 328 pp.

Haskell, Craig A.; Tiffan, Kenneth F.; Rondorf, Dennis W. (2013) The effects of juvenile American Shad planktivory on zooplankton production in Columbia River food webs, Transactions of the American Fisheries Society 142: 606-620

Hasselman, Daniel J.; Hinrichsen, Richard A.; Shields, Barbara A.; Ebbesmeyer, Curtis C. (2012a) The rapid establishment, dispersal, and increased abundance of invasive American Shad in the Pacific Northwest, Fisheries 37(3): 103-114

Hasselman, Daniel J.; Hinrichsen, Richard A.; Shields, Barbara A.; Ebbesmeyer, Curtis C. (2012b) American Shad of the Pacific coast: A harmful invasive species or benign introduction, Fisheries 37(3): 115-122

Hershberger, Paul K. and 9 authors (2010) Amplification and transport of an endemic fish disease by an introduced species, Biological Invasions 12: 3665-3675

Hildebrand, Samuel F.; Schroeder, William C. (1928) Fishes of Chesapeake Bay, Unites States Bureau of Bisheries Bulletin 53(Pt. 1): 1-388

Horwitz, Richard J. (1986) Fishes of the Delaware estuary in Pennsylvania., In: Majundar, S.K., Brenner, F. J., Rhoads, A. F.(Eds.) Endangered and Threatened Species Programs in Pennsylvania.. , Philadelphia. Pp. 177-201

Jenkins, Robert E.; Burkhead, Noel M. (1993) Freshwater Fishes of Virginia, American Fisheries Society, Bethesda, MD. Pp. <missing location>

Jones, Philip W.; Martin, F. Douglas; Hardy, Jerry D., Jr. (1978) Development of fishes of the mid-Atlantic Bight. V. 1. Acipenseridae through Ictaluridae., In: (Eds.) . , Washington DC. Pp. <missing location>

Lachner, E. A., Robins, C. R., Courtenay, W. R., Jr. (1970) Exotic fishes and other aquatic organisms introduced into North America, Smithsonian Contributions to Zoology 59: 1-29

Lampman, Ben Hur (1946) Coming of the Pond Fishes, Binfords & Mort, Portland, OR. Pp. <missing location>

Lee, David S.; Gilbert, Carter R.; Hocutt, Charles H.; Jenkins, Robert E.; McAllister, Don E.; Stauffer, Jay R. (1980) Atlas of North American freshwater fishes, North Carolina State Museum of Natural History, Raleigh. Pp. <missing location>

Marcy, Barton C., Jr. (1976) Fishes of the lower Connecticut River and the effects of the Connecticut Yankee Plant, American Fisheries Society Monograph 1: 61-113

Marquis, Nicholas D.; Bishop, Theodore J.; Record, Nicholas R.; Countway, Peter D.; Fernández Robledo, José A. (2020) A qPCR-Based Survey of Haplosporidium nelsoni and Perkinsus spp. in the Eastern Oyster, Crassostrea virginica in Maine, USA, Pathogens 9(256): Published online
doi:10.3390/pathogens9040256

Mejia, Francine; Saiki, Michael K.; Takekawa, John Y. (2008) Relation between species assemblages of fishes and water quality in salt ponds and sloughs in South San Francisco Bay, Southwestern Naturalist 53(3): 335-345

Murdy, Edward O.; Birdsong, Ray S.; Musick, John A. (1997) Fishes of Chesapeake Bay, Smithsonian Institution Press, Washington, D.C.. Pp. 57-289

Page, Lawrence M.; Burr, Brooks M. (1991) Freshwater Fishes: North America North of Mexico, Houghton-Mifflin, Boston. Pp. <missing location>

Parapar, Julio Martínez-Ansemil, Enrique Caramelo, Carlos Collado, Rut Schmelz, Rüdig (2009) Polychaetes and oligochaetes associated with intertidal rocky shores in a semi-enclosed industrial and urban embayment, with the description of two new species, Helgoland Marine Research 63: 293-308
DOI 10.1007/s10152-009-0158-7

Pearcy, William G.; Fisher, Joseph P. (2011) Ocean distribution of the American shad (Alosa sapidissima) along the Pacific coast of North America, Fishery Bulletin 109(4): 440-453

Pietsch, Theodore W.; Orr, James W. (2015) Fishes of the Salish Sea: a compilation and distributional analysis, NOAA Professional Papers NMFS 18: 1-106

Richardson, J. S. et al (2000) Fish Communities of the Lower Fraser River (Canada) and a 21-year contrast, Environmental Biology of Fishes 59: 125-140

Robins, C. Richard, Böhlke, James E. (1960) Pikea sericea, a synonym of the American centrarchid fish, Micropterus salmoides, Copeia 1960(2): 147

Robins, C. Richard; Ray, G. Carleton; Douglass, John; Freund, Rudolf 1943 (1986) <missing title>, Houhgton Mifflin, Boston. Pp. <missing location>

Rodríguez, Eliaira; Ron, Ernesto; Mikolji, Iván; Fuentes, José L.; Lasso-Alcalá, Oscar M. (2022) Invasive Mozambique tilapia (Oreochromis mossambicus), dominates Southeastern Caribbean Sea island estuary, Memoria de la Sociedad de Ciencias Narturales La Salle 79(188): 75-104

Schuchert, Peter (1996) The marine fauna of New Zealand: Athecate hydroids oand their medusae (Cnidara: Hydrozoa), New Zealand Oceanographic Institute Memoir 106: 1-159

Scott, W. B.; Crossman, E. J. (1973) <missing title>, Fisheries Research Board of Canada, Ottawa. Pp. <missing location>

Shebley, W. H. (1917) Introduction of food and game fishes into the waters of California., California Fish and Game 3(1): 1-12

Smith, C. Lavett, Lake, Thomas R. (1990) Documentation of the Hudson River fish fauna, American Museum Novitates 2981: 1-17

Smith, Hugh M. (1895) A review of the history and results of the attempts to acclimatize fish and other water animals in the Pacific states., Bulletin of the U. S. Fish Commission 15: 379-472

Sol, Sean Y.; Lomax, Daniel P. ; Hanson; Amanda C.; Corbett, Catherine; Johnson, Lyndal L. (2021) Fish communities in the tidal freshwater wetlands of the Lower Columbia River, Northwest Science 94(3-3): Published online

Sytsma, Mark D.; Cordell, Jeffrey R.; Chapman, John W.; Draheim, Robyn, C. (2004) <missing title>, Center for Lakes and Reservoirs, Portland State University, Portland OR. Pp. <missing location>

USGS Nonindigenous Aquatic Species Program 2003-2022 Nonindigenous Aquatic Species Database. https://nas.er.usgs.gov/



Wang, Johnson C. S. (1986) Fishes of the Sacramento - San Joaquin Estuary and Adjacent Waters, California: A Guide to the Early Life Histories, IEP Technical Reports 9: 1-673

Wang, Johnson, C. S.; Kenehahan, Ronnie (1979) Fishes of the Delaware estuaries - a guide to the early life histories, EA Associates, Towson MD. Pp. <missing location>

Whitworth, Walter R. (1996) Freshwater fishes of Connecticut, State Geological and Natural History Survey of Connecticut 114: 33-214