Invasion History

First Non-native North American Tidal Record: 1986
First Non-native West Coast Tidal Record: 1986
First Non-native East/Gulf Coast Tidal Record:

General Invasion History:

Corbula amurensis (Asian Brackish-water Clam) is native to estuarine habitats of the Northwest Pacific from the Russian Far East to southern China (Coan 2002). Outside of its native range, it is only known from the San Francisco Bay estuary, California (Carlton et al. 1990, Cohen 2005).

North American Invasion History:

Invasion History on the West Coast:

Corbula amurensis was first collected in Grizzly Bay, in the inner brackish regions of the San Francisco estuary in 1986. By late 1987, it had spread upstream to the outer edge of the Sacramento-San Joaquin Delta (Winder et al. 2011). From 1999 through 2005, the bivalve biomass, dominated by C. amurensis, decreased by 2 orders of magnitude. This was attributed to a cold phase of the El Nino-La Nina oscillation, with increased upwelling and decreased sea-surface temperatures, favoring native cold-water predators, such as shrimp (Crangon spp.), juvenile Dungeness crab (Metacarcinus magister), and English Sole (Parophrys vetulus), resulting in increased predation, decreased bivalve biomass and grazing, and resulting blooms of phytoplankton (Cloern et al. 2007).

Ballast water is the most likely mode of transport for this bivalve to San Francisco Bay, since it has a planktonic larva, spending ~17-19 days in the water column (Nicolini and Penry 2005). However, this species could be spread outside the Bay by other modes of transport. Newly settled larvae and early juveniles secrete byssus threads which can attach to solid particles or surfaces, or to other clams, forming clumps (Nicolini and Penry 2005). Juveniles can be transported in accumulated sediment within fouling communities, and were found in surveys of surplus cargo ships moored in Suisun Bay, which were about to be towed to Texas for ship-breaking (Davidson et al. 2008).

Description

Potamocorbula amurensis is commonly known as the Asian Brackish-water Clam, Overbite Clam, and Brackish-water Corbula. It is a small, thin-shelled bivalve, reaching 20-25 mm length. The shell is triangular to ovate in shape, with the umbos slightly projecting. The right valve is decidedly larger than the left (whence the name Overbite Clam). The beaks are slightly anterior to the midline of the shells, located at about 41% of the length from the anterior to posterior end. The anterior and posterior ends are sharply rounded. The beaks are smooth, while the rest shell surface has low, irregular ribs. The hinge plate is narrow. The right valve has a narrow tooth, which is attached to the shell wall below the hinge-line. The left valve has a long, weakly projecting chondrophore (a spoon-shaped structure, containing the cartilaginous portion of the ligament connecting the shells) that is conspicuously divided, and with a very small tooth on its posterior end. The anteroventral hinge margin is swollen into a low tooth medially. The pallial line has a small posterior sinus. The shell is white on the interior and exterior, but the exterior is covered with a brown periostracum. This is smooth in younger clams, but wrinkled and worn around the margins in older ones. (Description from: Carlton et al. 1990; Coan et al. 2000; Coan 2002; Cohen 2005; Coan and Valentich-Scott in Carlton 2007; Hallan et al. 2013)

This clam is characteristic of intertidal and shallow-water mud, sand, or clay, often in brackish and estuarine waters (Carlton et al. 1990; Cohen 2005). The planktonic larvae of CP amurensis are described by Nicolini and Penry (2000).

Taxonomy

Taxonomic Tree

Kingdom:		Animalia
Phylum:		Mollusca
Class:		Bivalvia
Subclass:		Heterodonta
Order:		Myoida
Superfamily:		Myoidea
Family:		Corbulidae
Species:		amurensis

Synonyms

Corbula amplexa (Adams, 1862)
Corbula frequens (Yokoyama, 1922)
Corbula pustulosa (Yokoyama, 1922)
Corbula sematensis (Yokoyama, 1922)
Corbula vladivostokensis (Bartsch, 1929)
Potamocorbula amurensis (Habe, 1955)
Corbula amurensis (Coan, 2002)

Potentially Misidentified Species

Corbula luteola
A southern California species, reaching Monterey Bay in warmer years

Ecology

General:

Potamocorbula amurensis has separate sexes and matures at about 4 mm in length (Parchaso and Thompson 2002), although adults can grow to 20-25 mm (Cohen 2005). Adults mature at a few months age and produce 220,000 eggs (Cohen 2005). Eggs and sperm are released into the water column where they are fertilized. Within 24 hours at 15°C the larvae pass through a blastula stage, reaching a trochophore stage. By 48 hours, they have grown shells and reached the straight-hinge veliger stage. After day 7, the larvae swim less actively, and by day 17, they begin to metaphose and settle at ~ 135 μm in diameter. Viable gametes were produced at 5-25 PSU, and development was fastest at 15 PSU (Nicolini and Penry 2000). Reproduction appears to occur year-round in the San Francisco Bay estuary, and regional variations in peak reproduction appear to reflect water flow and availability of food (suspended organic matter and phytoplankton food), rather than seasonal temperature (Nicolini and Penry 2000; Parchaso and Thompson 2002; Miller and Stillman 2013). At downstream sites in San Pablo Bay, reproduction was most active in dry years, probably reflecting upstream transport of food-rich ocean waters, while at upstream sites in Suisun Bay, reproduction was greatest in wet years when the flux of nutrients and suspended organic matter was greatest (Parchaso and Thompson 2002).

Potamocorbula amurensis occur in sand, mud, and clay substrates, usually with about two-thirds of their body in the sediment, and usually in shallow subtidal environments, though they can be abundant on intertidal mudflats (Carlton et al. 1990; Cohen 2005). It has broad environmental tolerances though it seems most successful under conditions typical of large estuaries with extensive brackish-water regions. The broad latitudinal range of this clam suggests that its temperature tolerance greatly exceeds the seasonal range occurring in San Francisco Bay (Carlton et al. 1990, Cohen 2005). Experimental studies of adult/juvenile temperature tolerance, temperature-salinity interactions, and temperature-salinity effects on larval development are highly desirable. Adult clams are found at 1-30+ PSU, and tolerate a temperature range of 8-23°C in the San Francisco Bay estuary (Carlton et al. 1990; Cohen 2005). Feeding rates and metabolism were highest at a high salinity (28 PSU), compared to a control salinity (13-14 PSU) and low salinity (2 PSU), reflecting higher costs of osmoregulation at high salinity (Paganini et al. 2010).

Food:

Phytoplankton, Detritus

Consumers:

Crabs, Ducks

Competitors:

Bivalves, Zooplankton

Trophic Status:

Suspension Feeder

SusFed

Habitats

General Habitat	Unstructured Bottom	None
General Habitat	Salt-brackish marsh	None
Salinity Range	Oligohaline	0.5-5 PSU
Salinity Range	Mesohaline	5-18 PSU
Salinity Range	Polyhaline	18-30 PSU
Tidal Range	Subtidal	None
Tidal Range	Low Intertidal	None
Vertical Habitat	Endobenthic	None

Tolerances and Life History Parameters

Minimum Temperature (ºC)	8	Field observations, San Francisco Bay (Carlton et al. 1990)
Maximum Temperature (ºC)	23	Field observations, San Francisco Bay (Carlton et al. 1990)
Minimum Salinity (‰)	0.1	Experimental, 30 days survival (Carlton et al. 1990).
Maximum Salinity (‰)	32	Field observations, San Francisco Bay (Carlton et al. 1990)
Minimum Reproductive Temperature	6	Field observations, ripe eggs and sperm seen (Parchaso and Thompson 2002)
Maximum Reproductive Temperature	23	Field observations, ripe eggs and sperm seen (Parchaso and Thompson 2002)
Minimum Reproductive Salinity	2	Survival of 24 hr old larvae (Nicolini and Penry 2000).
Maximum Reproductive Salinity	25	Survival of 24 hr old larvae (Nicolini and Penry 2000).
Minimum Duration	17	Fertilization to settling, 15 C (Nicolini and Penry 2000).
Maximum Duration	19	Fertilization to settling, 15 C (Nicolini and Penry 2000).
Minimum Length (mm)	None	None
Maximum Length (mm)	27.5	Carlton et al. 1990
Broad Temperature Range	None	Cold temperate-Warm temperate
Broad Salinity Range	None	Tidal Limnetic-Euhaline

General Impacts

Corbula amurensis has been listed by the Invasive Species Specialist Group of the World Conservation Union (IUCN) as one of the '100 worst invasive species.' So far, San Francisco Bay is the only area that this clam has invaded, but its ecological and economic impacts may be wide-ranging.

Economic Impacts

From a human economic point of view, the impacts of the Corbula invasion are mixed. Filtering by the clams has resulted in increased water clarity in the Delta, probably with some aesthetic and recreational benefits. Some recreationally and aesthetically important species, such as sturgeon and diving ducks may be benefiting from increased food supplies, but negative effects from concentrated toxins on the populations and human consumers will be more difficult to detect. Declines in many recreationally important fish stocks, as well as native endangered species, have been attributed, in part to the food-web changes, although these effects are difficult to separate from the many other human impacts on the inner Bay-Delta system. The Corbula invasion is seen as contributing to a general phenomenon of 'Pelagic Organism Decline', in which the energy and nutrients from primary production (phytoplankton) are being shifted from the pelagic foodweb (phytoplankton > small zooplankton > small fishes > gamefishes) to a benthic foodweb (bivalves and other filter feeders > crabs and shrimp > bottom feeding fishes), which is less desirable economically (Sommer et al. 2007; MacNally 2010; Glibert et al. 2011; Winder and Jassby 2011).

Ecological Impacts

The invasion of C. amurensis has had dramatic effects on the San Francisco Bay estuary. A flood in 1986 may have assisted its invasion by eliminating much of the dry-season benthic community from the upstream portions of the estuary. Within a year of its first detection, huge biomasses of this clam had developed, largely replacing the previous dry-season benthic community, which had included the introduced bivalve Mya arenaria (Softshell Clam), the introduced filter-feeding amphipods Monocorophium acherusicum and Ampelisca abdita, and the introduced polychaete Streblospio benedicti. Corbula’s dominance of the benthos has continued through successive periods of drought and flood, owing to its great tolerance of salinity fluctuations (Nichols et al. 1990). In many locations in Suisun and San Pablo Bay, it now comprises 95% of the filter-feeding biomass (Nichols et al. 1990; Cohen 2005).

The development of a huge biomass of filter-feeding bivalves has dramatically altered the food-web of San Francisco Bay, by suppressing phytoplankton blooms in the upstream reaches of the estuary and diverting biomass from the plankton to the benthos, resulting in sharp decreases in chlorophyll, zooplankton biomass, and in turn, the survival of fish larvae, which depend on zooplankton (Alpine and Cloern 1992; Feyrer et al. 2003). The effects on the zooplankton include direct predation as copepod larvae (nauplii) and microzooplankton are filtered out of the water (Kimmerer et al. 1994; Greene et al. 2011) as well as food deprivation. Decreased recruitment of many species of fishes, including the economically important introduced Striped Bass (Morone saxatilis) and the endangered Delta Smelt (Hypomesus transpacificus) has been attributed, in part, to decreased food availability resulting from the huge filtering biomass of C. amurensis (Sommer 2007; MacNally 2010; Glibert et al. 2011). In South San Francisco Bay, this impact was reduced from 1999 to 2005, apparently by a cold phase of the El Nino-La Nina oscillation, resulting in reduced water temperatures, increased predation by cold water predators, greatly decreased biomass of C. amurensis and other bivalves, resulting in phytoplankton blooms (Cloern et al. 2007). However, it is not clear whether these effects have extended to the upstream parts of the estuary, including the Delta.

The invasion of C. amurensis has created a major new food source for predators, including mollusk-eating fishes, such as sturgeons, diving ducks, and others. However, as an efficient filter-feeder, C. amurensis also concentrates toxins, such as selenium, pesticides, etc., from the water column (Cohen 2005). While the invasion has resulted in increased aggregations of diving ducks, e.g. Lesser Scaup (Athya affinis), the toxin load from feeding on the clams may be contributing to decreasing success in breeding on the bird’s nesting grounds (Richman and Lovvorn 2004).

Regional Impacts

NEP-V	Northern California to Mid Channel Islands	Ecological Impact	Herbivory
By 1988, Corbula amurensis had become a dominant filter-feeder in the San Francisco Bay benthic community (Carlton et al. 1990). Its huge biomass resulted in the disappearance of the summer phytoplankton maximum, which normally occurs in years of low river flow (Alpine and Cloern 1992; Jassby et al. 2002)
NEP-V	Northern California to Mid Channel Islands	Ecological Impact	Trophic Cascade
The Corbula amurensis invasion and suppression of phytoplankton biomass has had effects throughout the estuary's food-web, resulting in diminished food supplies for other benthic filter-feeders (Nichols et al. 1990), for filter-feeding zooplankton (Kimmerer et al. 1994), and for predators on benthos and zooplankton, such as fishes (Feyrer et al. 2003). Declines in zooplankton biomass resulting from reduced phytoplankton food and direct predation by clams on copepod nauplii have apparently contributed to sharp declines in mysids and fishes (Feyrer et al. 2003). Decreased recruitment of many species of fishes, including the economically important introduced Striped Bass (Morone saxatilis) and the endangered Delta Smelt (Hypomesus transpacificus) has been attributed, in part, to decreased food availability resulting from the huge filtering biomass of C. amurensis and its predatory impact on zooplankton.The development of the large Corbula biomass has also affected the overall flow of nutrients in the ecosystem, including C0₂, which is released in the process of shell formation (Chauvaud et al. 2003) and dissolved Si (silicon), which is taken up by diatoms, whose biomass has been greatly decreased by grazing (Kimmerer 2005). The invasion has resulted in a significant increase in carbon release by the estuary (Chauvaud et al. 2003) and a sharp decrease in silica uptake (Kimmerer 2005). The decreased diatom biomass in the estuary has also resulted in increased light penetration and a shift in production to other phytoplankton, such as flagellates and cyanobacteria, and to macrophytes (larger floating and submerged plants) such as Egeria densa (Brazilian Waterweed) and Eichornia crassipes (Water Hyacinth) (Jassby 2008). The clam invasion, combined with climate change is beleived to have resulted in a shift in peak phytoplankton and zooplankton biomass to earlier times of year, resulting in a potential mismatch for larvae of Delta Smelt and other planktivorous species (Merz et al. 2018).
P090	San Francisco Bay	Ecological Impact	Herbivory
By 1988, Corbula amurensis had become a dominant filter-feeder in the San Francisco Bay benthic community (Carlton et al. 1990). Its huge biomass resulted in the disappearance of the summer phytoplankton maximum, which normally occurs in years of low river flow (Alpine and Cloern 1992; Jassby et al. 2002).
P090	San Francisco Bay	Ecological Impact	Competition
The invasion of Corbula amurensis was accompanied by declines in the previously dominant, largely introduced, dry-season benthos, including Mya arenaria, Gemma gemma, Ampelisca abdita, Monocorophium acherusicum and Streblospio benedicti (Nichols et al. 1990; Poulton et al. 2004).
P090	San Francisco Bay	Ecological Impact	Predation
The effects on the zooplankton include direct predation as copepod larvae (nauplii) are filtered out of the water (Kimmerer et al. 1994) as well as food deprivation. Predation on copepod nauplii and copepodites, together with decreases in phytoplankton abundance, have led to the decline of the formerly domonant copepod Eurytemora carolleeae (=E. affinis (Kimmerer and Lougee 2015). Grazing rates of C. amurensis on cilate microzooplankton also were significant, exceeding estimated growth rates, and potentially disrupting a link in the microbial food-web (Greene et al. 2011). Decreased recruitment of many species of fishes, including the economically important introduced Striped Bass (Morone saxatilis) and the endangered Delta Smelt (Hypomesus transpacificus) has been attributed, in part, to decreased food availability resulting from the huge filtering biomass of C. amurensis (Feyrer et al. 2003).
P090	San Francisco Bay	Ecological Impact	Trophic Cascade
The Corbula amurensis invasion and suppression of phytoplankton biomass has had effects throughout the estuary's food-web, resulting in diminished food supplies for other benthic filter-feeders (Nichols et al. 1990), for filter-feeding zooplankton (Kimmerer et al. 1994), and for predators on benthos and zooplankton, such as fishes (Feyrer et al. 2003). Declines in zooplankton biomass resulting from reduced phytoplankton food and direct predation by clams on copepod nauplii have apparently contributed to sharp declines in mysids and fishes (Feyrer et al. 2003). Decreased recruitment of many species of fishes, including the economically important introduced Striped Bass (Morone saxatilis) and the endangered Delta Smelt (Hypomesus transpacificus) has been attributed, in part, to decreased food availability resulting from the huge filtering biomass of C. amurensis and its predatory impact on zooplankton.The development of the large Corbula biomass has also affected the overall flow of nutrients in the ecosystem, including C0₂, which is released in the process of shell formation (Chauvaud et al. 2003) and dissolved Si (silicon), which is taken up by diatoms, whose biomass has been greatly decreased by grazing (Kimmerer 2005). The invasion has resulted in a significant increase in carbon release by the estuary (Chauvaud et al. 2003) and a sharp decrease in silica uptake (Kimmerer 2005). The decreased diatom biomass in the estuary has also resulted in increased light penetration and a shift in production to other phytoplankton, such as flagellates and cyanobacteria, and to macrophytes (larger floating and submerged plants) such as Egeria densa (Brazilian Waterweed) and Eichornia crassipes (Water Hyacinth) (Jassby 2008). Since the invasion of C. amurensis, the peak of phytoplankton productivity has shifted to earlier in the year, shifting the peak of zooplankton abundance, resulting in a possible mismatch between the availability of prey and the larval period of the Delta Smelt (Merz et al. 2016).
P090	San Francisco Bay	Ecological Impact	Food/Prey
Since its invasion, Corbula amurensis had become a major prey item for sturgeon and diving ducks, such as the Lesser Scaup (Athya affinis). Numbers of scaup aggregating in San Pablo and Suisun Bay increased following the invasion (Richman and Lovvorn 2004). During a period of colder water, in 1999-2004, the abundance of C. amurensis and other bivalves decreased, apparently as a result of an influx of cool-water predators, including shrimp (Crangon sp.), Dungeness Crabs (Metacarcinus magister) and English Sole (Parophrys vetulus) (Cloern et al. 2007). Corbula amurensis has become the dominant prey item of the White Sturgeon (Acipenser transmontanus), but the poorer food quality of the invading clams, and a reduction in benthic diversity, have led to a dietary shift including an increased consumpiton of fish (Zeug et al. 2014).
P090	San Francisco Bay	Ecological Impact	Toxic
Corbula amurensis efficiently concentrates toxins, such as selenium, pesticides, etc., from the water column (Cohen 2005; Lee et al. 2006). While the invasion has resulted in increased aggregations of diving ducks, e.g. Lesser Scaup (Athya affinis), the toxin load from feeding on the clams may be contributing to decreasing success in breeding on the bird's nesting grounds (Richman and Lovvorn 2004).
P090	San Francisco Bay	Economic Impact	Fisheries
Some recreationally and aesthetically important species, such as sturgeon (Cohen 2005) and diving ducks (Richman and Lovvorn 2004) may be benefiting from increased food supplies, but negative effects from concentrated toxins on the populations and human consumers will be more difficult to detect. Declines in many recreationally important fish stocks, such as Striped Bass (Morone saxatilis), as well as native endangered species, such as Delta Smelt (Hypomesus transpacificus) have been attributed, in part to the food-web changes (Feyrer et al. 2003), although these effects are difficult to separate from the many other human impacts on the inner Bay-Delta system.
P090	San Francisco Bay	Economic Impact	Aesthetic
Filtering by the clams has resulted in increased water clarity in the Delta, probably with some aesthetic and recreational benefits. Some recreationally and aesthetically important species, such as sturgeon and diving ducks may be benefiting from increased food supplies, but negative effects from concentrated toxins on the populations and human consumers will be more difficult to detect.
NEP-V	Northern California to Mid Channel Islands	Ecological Impact	Competition
The invasion of Corbula amurensis was accompanied by declines in the previously dominant, largely introduced, dry-season benthos, including Mya arenaria, Gemma gemma, Ampelisca abdita, Monocorophium acherusicum and Streblospio benedicti (Nichols et al. 1990; Poulton et al. 2004).
NEP-V	Northern California to Mid Channel Islands	Ecological Impact	Predation
The effects on the zooplankton include direct predation as copepod larvae (nauplii) are filtered out of the water (Kimmerer et al. 1994) as well as food deprivation. Grazing rates of C. amurensis on cilate microzooplankton also were significant, exceeding estimated growth rates, and potentially disrupting a link in the microbial food-web (Greene et al. 2011). Decreased recruitment of many species of fishes, including the economically important introduced Striped Bass (Morone saxatilis) and the endangered Delta Smelt (Hypomesus transpacificus) has been attributed, in part, to the decreased food availability resulting from the huge filtering biomass of C. amurensis (Feyrer et al. 2003).
NEP-V	Northern California to Mid Channel Islands	Ecological Impact	Food/Prey
Since its invasion, Corbula amurensis had become a major prey item for sturgeon and diving ducks, such as the Lesser Scaup (Athya affinis). Numbers of scaup aggregating in San Pablo and Suisun Bay increased following the invasion (Richman and Lovvorn 2004). During a period of colder water, in 1999-2004, the abundance of C. amurensis and other bivalves decreased, apparently as a result of an influx of cool-water predators, including shrimp (Crangon sp.), Dungeness Crabs (Metacarcinus magister) and English Sole (Parophrys vetulus) (Cloern et al. 2007).
NEP-V	Northern California to Mid Channel Islands	Ecological Impact	Toxic
Corbula amurensis efficiently concentrates toxins, such as selenium, pesticides, etc., from the water column (Cohen 2005; Lee et al. 2006). While the invasion has resulted in increased aggregations of diving ducks, e.g. Lesser Scaup (Athya affinis), the toxin load from feeding on the clams may be contributing to decreasing success in breeding on the bird's nesting grounds (Richman and Lovvorn 2004).
NEP-V	Northern California to Mid Channel Islands	Ecological Impact	Habitat Change
Intense grazing of phytoplankton by Corbula amurenisis has affected the sediment by adding large quantities of pseudofeces, increasing the amount of suspended particles (Carlton et al. 1990). Grazing by C. amurenisis has decreased phytoplankton biomass, potentially increasing water clarity, and favoring submersed vegetation (Jassby 2008). Pseudofeces, bound by mucus, produced by Corbula, as well as the mucus produced by other native and introduced deposit feeding and tube-building benthos, contributes to a surface layer of flocculent fluff, which may trap much more phtyoplankton than is actually consumed by the animals (Jones et al. 2009).
NEP-V	Northern California to Mid Channel Islands	Economic Impact	Fisheries
Some recreationally and aesthetically important species, such as sturgeon (Cohen 2005) and diving ducks (Richman and Lovvorn 2004) may be benefiting from increased food supplies, but negative effects from concentrated toxins on the populations and human consumers will be more difficult to detect. Declines in many recreationally important fish stocks, such as Striped Bass (Morone saxatilis), as well as native endangered species, such as Delta Smelt (Hypomesus transpacificus) have been attributed, in part to the food-web changes (Feyrer et al. 2003), although these effects are difficult to separate from the many other human impacts on the inner Bay-Delta system.
NEP-V	Northern California to Mid Channel Islands	Economic Impact	Aesthetic
Filtering by the clams has resulted in increased water clarity in the Delta, probably with some aesthetic and recreational benefits. Some recreationally and aesthetically important species, such as sturgeon and diving ducks may be benefiting from increased food supplies (Richman and Lovvorn 2004) but negative effects from concentrated toxins on the populations and human consumers will be more difficult to detect (Cohen 2005).
P090	San Francisco Bay	Ecological Impact	Habitat Change
Intense grazing of phytoplankton by Corbula amurenisis has affected the sediment by adding large quantities of pseudofeces, increasing the amount of suspended particles (Carlton et al. 1990). Grazing by C. amurenisis has decreased phytoplankton biomass, potentially increasing water clarity, and favoring submersed vegetation (Jassby 2008). Pseudofeces, bound by mucus, produced by Corbula, as well as the mucus produced by other native and introduced deposit feeding and tube-building benthos, contributes to a surface layer of flocculent fluff, which may trap much more phtyoplankton than that actually consumed by the animals (Jones et al. 2009).
CA	California	Ecological Impact	Competition
The invasion of Corbula amurensis was accompanied by declines in the previously dominant, largely introduced, dry-season benthos, including Mya arenaria, Gemma gemma, Ampelisca abdita, Monocorophium acherusicum and Streblospio benedicti (Nichols et al. 1990; Poulton et al. 2004)., The invasion of Corbula amurensis was accompanied by declines in the previously dominant, largely introduced, dry-season benthos, including Mya arenaria, Gemma gemma, Ampelisca abdita, Monocorophium acherusicum and Streblospio benedicti (Nichols et al. 1990; Poulton et al. 2004).
CA	California	Ecological Impact	Food/Prey
Since its invasion, Corbula amurensis had become a major prey item for sturgeon and diving ducks, such as the Lesser Scaup (Athya affinis). Numbers of scaup aggregating in San Pablo and Suisun Bay increased following the invasion (Richman and Lovvorn 2004). During a period of colder water, in 1999-2004, the abundance of C. amurensis and other bivalves decreased, apparently as a result of an influx of cool-water predators, including shrimp (Crangon sp.), Dungeness Crabs (Metacarcinus magister) and English Sole (Parophrys vetulus) (Cloern et al. 2007)., Since its invasion, Corbula amurensis had become a major prey item for sturgeon and diving ducks, such as the Lesser Scaup (Athya affinis). Numbers of scaup aggregating in San Pablo and Suisun Bay increased following the invasion (Richman and Lovvorn 2004). During a period of colder water, in 1999-2004, the abundance of C. amurensis and other bivalves decreased, apparently as a result of an influx of cool-water predators, including shrimp (Crangon sp.), Dungeness Crabs (Metacarcinus magister) and English Sole (Parophrys vetulus) (Cloern et al. 2007). Corbula amurensis has become the dominant prey item of the White Sturgeon (Acipenser transmontanus), but the poorer food quality of the invading clams, and a reduction in benthic diversity, have led to a dietary shift including an increased consumpiton of fish (Zeug et al. 2014).
CA	California	Ecological Impact	Habitat Change
Intense grazing of phytoplankton by Corbula amurenisis has affected the sediment by adding large quantities of pseudofeces, increasing the amount of suspended particles (Carlton et al. 1990). Grazing by C. amurenisis has decreased phytoplankton biomass, potentially increasing water clarity, and favoring submersed vegetation (Jassby 2008). Pseudofeces, bound by mucus, produced by Corbula, as well as the mucus produced by other native and introduced deposit feeding and tube-building benthos, contributes to a surface layer of flocculent fluff, which may trap much more phtyoplankton than is actually consumed by the animals (Jones et al. 2009)., Intense grazing of phytoplankton by Corbula amurenisis has affected the sediment by adding large quantities of pseudofeces, increasing the amount of suspended particles (Carlton et al. 1990). Grazing by C. amurenisis has decreased phytoplankton biomass, potentially increasing water clarity, and favoring submersed vegetation (Jassby 2008). Pseudofeces, bound by mucus, produced by Corbula, as well as the mucus produced by other native and introduced deposit feeding and tube-building benthos, contributes to a surface layer of flocculent fluff, which may trap much more phtyoplankton than that actually consumed by the animals (Jones et al. 2009).
CA	California	Ecological Impact	Herbivory
By 1988, Corbula amurensis had become a dominant filter-feeder in the San Francisco Bay benthic community (Carlton et al. 1990). Its huge biomass resulted in the disappearance of the summer phytoplankton maximum, which normally occurs in years of low river flow (Alpine and Cloern 1992; Jassby et al. 2002), By 1988, Corbula amurensis had become a dominant filter-feeder in the San Francisco Bay benthic community (Carlton et al. 1990). Its huge biomass resulted in the disappearance of the summer phytoplankton maximum, which normally occurs in years of low river flow (Alpine and Cloern 1992; Jassby et al. 2002).
CA	California	Ecological Impact	Predation
The effects on the zooplankton include direct predation as copepod larvae (nauplii) are filtered out of the water (Kimmerer et al. 1994) as well as food deprivation. Grazing rates of C. amurensis on cilate microzooplankton also were significant, exceeding estimated growth rates, and potentially disrupting a link in the microbial food-web (Greene et al. 2011). Decreased recruitment of many species of fishes, including the economically important introduced Striped Bass (Morone saxatilis) and the endangered Delta Smelt (Hypomesus transpacificus) has been attributed, in part, to the decreased food availability resulting from the huge filtering biomass of C. amurensis (Feyrer et al. 2003)., The effects on the zooplankton include direct predation as copepod larvae (nauplii) are filtered out of the water (Kimmerer et al. 1994) as well as food deprivation. Predation on copepod nauplii and copepodites, together with decreases in phytoplankton abundance, have led to the decline of the formerly domonant copepod Eurytemora carolleeae (=E. affinis (Kimmerer and Lougee 2015). Grazing rates of C. amurensis on cilate microzooplankton also were significant, exceeding estimated growth rates, and potentially disrupting a link in the microbial food-web (Greene et al. 2011). Decreased recruitment of many species of fishes, including the economically important introduced Striped Bass (Morone saxatilis) and the endangered Delta Smelt (Hypomesus transpacificus) has been attributed, in part, to decreased food availability resulting from the huge filtering biomass of C. amurensis (Feyrer et al. 2003).
CA	California	Ecological Impact	Trophic Cascade
The Corbula amurensis invasion and suppression of phytoplankton biomass has had effects throughout the estuary's food-web, resulting in diminished food supplies for other benthic filter-feeders (Nichols et al. 1990), for filter-feeding zooplankton (Kimmerer et al. 1994), and for predators on benthos and zooplankton, such as fishes (Feyrer et al. 2003). Declines in zooplankton biomass resulting from reduced phytoplankton food and direct predation by clams on copepod nauplii have apparently contributed to sharp declines in mysids and fishes (Feyrer et al. 2003). Decreased recruitment of many species of fishes, including the economically important introduced Striped Bass (Morone saxatilis) and the endangered Delta Smelt (Hypomesus transpacificus) has been attributed, in part, to decreased food availability resulting from the huge filtering biomass of C. amurensis and its predatory impact on zooplankton.The development of the large Corbula biomass has also affected the overall flow of nutrients in the ecosystem, including C0₂, which is released in the process of shell formation (Chauvaud et al. 2003) and dissolved Si (silicon), which is taken up by diatoms, whose biomass has been greatly decreased by grazing (Kimmerer 2005). The invasion has resulted in a significant increase in carbon release by the estuary (Chauvaud et al. 2003) and a sharp decrease in silica uptake (Kimmerer 2005). The decreased diatom biomass in the estuary has also resulted in increased light penetration and a shift in production to other phytoplankton, such as flagellates and cyanobacteria, and to macrophytes (larger floating and submerged plants) such as Egeria densa (Brazilian Waterweed) and Eichornia crassipes (Water Hyacinth) (Jassby 2008). The clam invasion, combined with climate change is beleived to have resulted in a shift in peak phytoplankton and zooplankton biomass to earlier times of year, resulting in a potential mismatch for larvae of Delta Smelt and other planktivorous species (Merz et al. 2018)., The Corbula amurensis invasion and suppression of phytoplankton biomass has had effects throughout the estuary's food-web, resulting in diminished food supplies for other benthic filter-feeders (Nichols et al. 1990), for filter-feeding zooplankton (Kimmerer et al. 1994), and for predators on benthos and zooplankton, such as fishes (Feyrer et al. 2003). Declines in zooplankton biomass resulting from reduced phytoplankton food and direct predation by clams on copepod nauplii have apparently contributed to sharp declines in mysids and fishes (Feyrer et al. 2003). Decreased recruitment of many species of fishes, including the economically important introduced Striped Bass (Morone saxatilis) and the endangered Delta Smelt (Hypomesus transpacificus) has been attributed, in part, to decreased food availability resulting from the huge filtering biomass of C. amurensis and its predatory impact on zooplankton.The development of the large Corbula biomass has also affected the overall flow of nutrients in the ecosystem, including C0₂, which is released in the process of shell formation (Chauvaud et al. 2003) and dissolved Si (silicon), which is taken up by diatoms, whose biomass has been greatly decreased by grazing (Kimmerer 2005). The invasion has resulted in a significant increase in carbon release by the estuary (Chauvaud et al. 2003) and a sharp decrease in silica uptake (Kimmerer 2005). The decreased diatom biomass in the estuary has also resulted in increased light penetration and a shift in production to other phytoplankton, such as flagellates and cyanobacteria, and to macrophytes (larger floating and submerged plants) such as Egeria densa (Brazilian Waterweed) and Eichornia crassipes (Water Hyacinth) (Jassby 2008). Since the invasion of C. amurensis, the peak of phytoplankton productivity has shifted to earlier in the year, shifting the peak of zooplankton abundance, resulting in a possible mismatch between the availability of prey and the larval period of the Delta Smelt (Merz et al. 2016).
CA	California	Ecological Impact	Toxic
Corbula amurensis efficiently concentrates toxins, such as selenium, pesticides, etc., from the water column (Cohen 2005; Lee et al. 2006). While the invasion has resulted in increased aggregations of diving ducks, e.g. Lesser Scaup (Athya affinis), the toxin load from feeding on the clams may be contributing to decreasing success in breeding on the bird's nesting grounds (Richman and Lovvorn 2004)., Corbula amurensis efficiently concentrates toxins, such as selenium, pesticides, etc., from the water column (Cohen 2005; Lee et al. 2006). While the invasion has resulted in increased aggregations of diving ducks, e.g. Lesser Scaup (Athya affinis), the toxin load from feeding on the clams may be contributing to decreasing success in breeding on the bird's nesting grounds (Richman and Lovvorn 2004).
CA	California	Economic Impact	Aesthetic
Filtering by the clams has resulted in increased water clarity in the Delta, probably with some aesthetic and recreational benefits. Some recreationally and aesthetically important species, such as sturgeon and diving ducks may be benefiting from increased food supplies (Richman and Lovvorn 2004) but negative effects from concentrated toxins on the populations and human consumers will be more difficult to detect (Cohen 2005)., Filtering by the clams has resulted in increased water clarity in the Delta, probably with some aesthetic and recreational benefits. Some recreationally and aesthetically important species, such as sturgeon and diving ducks may be benefiting from increased food supplies, but negative effects from concentrated toxins on the populations and human consumers will be more difficult to detect.
CA	California	Economic Impact	Fisheries
Some recreationally and aesthetically important species, such as sturgeon (Cohen 2005) and diving ducks (Richman and Lovvorn 2004) may be benefiting from increased food supplies, but negative effects from concentrated toxins on the populations and human consumers will be more difficult to detect. Declines in many recreationally important fish stocks, such as Striped Bass (Morone saxatilis), as well as native endangered species, such as Delta Smelt (Hypomesus transpacificus) have been attributed, in part to the food-web changes (Feyrer et al. 2003), although these effects are difficult to separate from the many other human impacts on the inner Bay-Delta system., Some recreationally and aesthetically important species, such as sturgeon (Cohen 2005) and diving ducks (Richman and Lovvorn 2004) may be benefiting from increased food supplies, but negative effects from concentrated toxins on the populations and human consumers will be more difficult to detect. Declines in many recreationally important fish stocks, such as Striped Bass (Morone saxatilis), as well as native endangered species, such as Delta Smelt (Hypomesus transpacificus) have been attributed, in part to the food-web changes (Feyrer et al. 2003), although these effects are difficult to separate from the many other human impacts on the inner Bay-Delta system.

Regional Distribution Map

Bioregion	Region Name	Year	Invasion Status	Population Status
P093	_CDA_P093 (San Pablo Bay)	1987	Def	Estab
NEP-V	Northern California to Mid Channel Islands	1986	Def	Estab
P090	San Francisco Bay	1986	Def	Estab

Occurrence Map

OCC_ID	Author	Year	Date	Locality	Status	Latitude	Longitude
697204	Introduced Species Study	2010	2010-07-29	Mare Island Strait - Navy	Def	38.1015	-122.2695
697205	Introduced Species Study	2005	2005-10-19	Mare Island Strait - Navy	Def	38.1015	-122.2695
697304	Introduced Species Study	2005	2005-11-14	Cal Maritime Academy/Vallejo	Def	38.0661	-122.2299
697305	Introduced Species Study	2010	2010-06-11	Cal Maritime Academy/Vallejo	Def	38.0661	-122.2299
697595	Introduced Species Study	2005	2005-10-07	Benicia Waterfront	Def	38.0401	-122.1385
697596	Introduced Species Study	2010	2010-06-29	Benicia Waterfront	Def	38.0401	-122.1385
697685	Introduced Species Study	2010	2010-07-13	Port Sonoma/Petaluma R.	Def	38.1157	-122.5026
697693	Introduced Species Study	2005	2005-10-20	Port Sonoma/Petaluma R.	Def	38.1157	-122.5026
697937	Introduced Species Study	2010	2010-06-02	Port of Oakland Office	Def	37.7954	-122.2804
698199	Carlton et al. 1990; Hymanson 1991	1990		Suisun Bay	Def	38.0713	-122.0581
698200	Carlton et al. 1990; Nichols et al. 1990	1987		Suisun Bay	Def	38.0713	-122.0581
698201	W. Stephenson 1988, pers. comm. in Carlton et al. 1990	1986		Grizzly Bay	Def	38.1027	-122.0349
698859	Cohen et al. 2005 (SF Bay Area RAS)	2004	2004-05-25	Port Sonoma, San Pablo Bay	Def	38.1156	-122.5026
698866	Nichols et al., unpublished data, cited in Carlton et al. 1990	1990		Delta at Rio Vista	Def	38.1562	-121.6870
698940	Introduced Species Study	2005	2005-10-20	Point San Pablo Yacht Harbor	Def	37.9643	-122.4185
699063	Introduced Species Study	2005	2005-10-20	Petaluma River Turning Basin	Def	38.2344	-122.6354
699064	Introduced Species Study	2010	2010-07-13	Petaluma River Turning Basin	Def	38.2344	-122.6354
699279	Introduced Species Study	2005	2005-06-07	Oakland Inner Harbor - Shipping cranes	Def	37.7947	-122.3095
699334	Introduced Species Study	2010	2010-07-15	San Pablo Bay Pumphouse	Def	38.0446	-122.4326
699335	Introduced Species Study	2005	2005-10-20	San Pablo Bay Pumphouse	Def	38.0446	-122.4326
699774	Introduced Species Study	2005	2005-10-19	Mare Island Strait - Marina	Def	38.1051	-122.2667
699792	Introduced Species Study	2010	2010-06-30	Mare Island Strait - Marina	Def	38.1051	-122.2667
699847	Introduced Species Study	2005	2005-06-09	Paradise Area	Def	37.9062	-122.4768
699956	Introduced Species Study	2010	2010-05-31	Dumbarton Bridge	Def	37.5070	-122.1168
699971	Introduced Species Study	2005	2005-07-08	Point Richmond	Def	37.9212	-122.3871
699973	Introduced Species Study	2010	2010-06-11	Point Richmond	Def	37.9212	-122.3871
700004	Introduced Species Study	2005	2005-06-09	McNears Beach	Def	37.9962	-122.4556
700535	Introduced Species Study	2005	2005-06-08	Sea Plane Lagoon	Def	37.7761	-122.2998
700868	Introduced Species Study	2005	2005-10-18	Pacheco Creek Oil Pier	Def	38.0489	-122.0903
700914	Cohen and Carlton 1995	1995		South San Francisco Bay	Def	37.5457	-122.1645
701022	Carlton et al. 1990	1987		Grizzly Bay	Def	38.1027	-122.0349
701456	Introduced Species Study	2005	2005-10-19	Hercules Wharf	Def	38.0231	-122.2928
701459	Introduced Species Study	2010	2010-06-30	Hercules Wharf	Def	38.0231	-122.2928
701685	Carlton et al. 1990	1987		Sherman Lake	Def	38.0446	-121.7973
702192	Introduced Species Study	2010	2010-06-29	New York Point Marina	Def	38.0400	-121.8863
702336	Introduced Species Study	2010	2010-07-13	Ayala Cove	Def	37.8680	-122.4350
702337	Introduced Species Study	2005	2005-08-19	Ayala Cove	Def	37.8680	-122.4350
702778	Carlton et al. 1990	1987		off Berkeley	Def	37.8897	-122.3293
702781	Cohen and Carlton 1995	1995		Central San Francisco Bay	Def	37.8595	-122.3884
702983	Cohen et al. 2005 (SF Bay Area RAS)	2004	2004-05-25	Petaluma River Turning Basin, San Pablo Bay	Def	38.2355	-122.6382
703249	Introduced Species Study	2005	2005-11-15	China Camp	Def	38.0025	-122.4617
703254	Introduced Species Study	2010	2010-06-12	China Camp	Def	38.0025	-122.4617
703602	Introduced Species Study	2005	2005-06-10	Toll Plaza	Def	37.8266	-122.3166
703801	Introduced Species Study	2005	2005-06-10	Hayward Landing	Def	37.6447	-122.1543
703802	Introduced Species Study	2010	2010-06-13	Hayward Landing	Def	37.6447	-122.1543
703910	Introduced Species Study	2005	2005-10-19	Rodeo Marina	Def	38.0394	-122.2717
703913	Introduced Species Study	2010	2010-06-30	Rodeo Marina	Def	38.0394	-122.2717
703987	Introduced Species Study	2005	2005-09-07	Railroad Bridge	Def	37.4602	-121.9750
703988	Introduced Species Study	2010	2010-05-31	Railroad Bridge	Def	37.4602	-121.9750
704055	Carlton et al. 1990	1987		San Pablo Bay, deep-water station	Def	38.0816	-122.3721
704060	Carlton et al. 1990; Hymanson 1991	1990		San Pablo Bay	Def	38.0600	-122.3900
704488	Introduced Species Study	2005	2005-10-07	Martinez Marina	Def	38.0276	-122.1371
704489	Introduced Species Study	2010	2010-06-29	Martinez Marina	Def	38.0276	-122.1371
704525	Introduced Species Study	2005	2005-10-19	Napa Valley Marina	Def	38.2198	-122.3119
759602	W. Stephenson 1988, pers. comm. in Carlton et al. 1990	1986		Suisun Bay, south shore	Def	38.0502	-121.9669
759603	Carlton et al. 1990	1987		Carquinez Straits, western end	Def	38.0665	-122.2455
759604	Carlton et al. 1990; Nichols et al. 1990	1987		San Pablo Bay	Def	38.0600	-122.3900
759605	Carlton et al. 1990	1987		Point Sacramento	Def	38.0625	-121.8381
759606	Carlton et al. 1990	1987		Grizzly Bay	Def	38.1027	-122.0349
759607	Carlton et al. 1990	1987		San Pablo Bay, deep-water station	Def	38.0816	-122.3721
759608	Carlton et al. 1990	1987		off Coyote Point	Def	37.6003	-122.3142
759609	Carlton et al. 1990	1987		off Palo Alto	Def	37.4604	-122.0980
759610	Carlton et al. 1990	1987		off Hunter's Point	Def	37.7307	-122.3284
759611	Carlton et al. 1990	1988		San Pablo Bay, southern shallow-water station	Def	38.0279	-122.3097
759612	Carlton et al. 1990	1988		Point Sacramento	Def	38.0625	-121.8381
759613	Carlton et al. 1990	1988		off Berkeley	Def	37.8897	-122.3293
759614	Carlton et al. 1990	1988		off Coyote Point	Def	37.6003	-122.3142
759615	Carlton et al. 1990	1988		off Coyote Point	Def	37.6003	-122.3142
759616	Carlton et al. 1990	1988		off Palo Alto	Def	37.4604	-122.0980
759617	Carlton et al. 1990	1988		off Palo Alto	Def	37.4604	-122.0980
759618	Carlton et al. 1990	1990		Suisun Marsh	Def	38.1794	-122.0711
819066	Ruiz GM and JB Geller (2015)	2012		San Leandro	None	37.6580	-122.2217
819067	Ruiz GM and JB Geller (2015)	2012		Redwood City	None	37.5574	-122.1755
819068	Ruiz GM and JB Geller (2015)	2012		Coyote Point	None	37.5987	-122.3252
819069	Ruiz GM and JB Geller (2015)	2012		None	None
819070	Ruiz GM and JB Geller (2015)	2012		Corte Madera	None	37.9309	-122.4819
819071	Ruiz GM and JB Geller (2015)	2012		Oyster Point	None	37.6805	-122.3731
819072	Ruiz GM and JB Geller (2015)	2012		Richardson Bay	None	37.8788	-122.4759
819073	Ruiz GM and JB Geller (2015)	2012		Emeryville	None	37.8596	-122.3152
819074	Ruiz GM and JB Geller (2015)	2012		Ballena Isle	None	37.7643	-122.2978

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Zeug, Steven C.; Brodsky, Annie ; Kogut, Nina; Stewart, A. Robin; Merz, Joseph E. (2014) Ancient fish and recent invaders: white sturgeon Acipenser transmontanus diet response to invasive species- mediated changes in a benthic prey assemblage, Marine Ecology Progress Series 514: 163-174

Potamocorbula amurensis

Mollusks-Bivalves