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Ecology and Vulnerability Shortnosed Sturgeon
Documented observations of Shornosed Sturgeon shown in orange. Data were developed by the Natural Heritage & Endangeres Species Program as part of the BioMap2 project.
HideDocumented observations of Shornosed Sturgeon shown in orange. Data were developed by the Natural Heritage & Endangeres Species Program as part of the...
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Ecology and Vulnerability
Shortnosed Sturgeon
Background
Shortnose sturgeon can be identified by four rows of bony plates, called scutes, as well as brownish-olive bodies with white undersides. They can be difficult to... Read More
Background
Shortnose sturgeon can be identified by four rows of bony plates, called scutes, as well as brownish-olive bodies with white undersides. They can be difficult to distinguish from Atlantic sturgeon, which are similar in appearance; however, shortnose sturgeon are generally smaller (3 feet in length on average, compared to 7 feet for Atlantic sturgeon), and have wider mouths and shorter snouts 6,9. Shortnose sturgeon are a long-lived (67+ years) migratory fish that live in fresh, brackish, and salt water, and occur from the Saint John River in New Brunswick to the Indian River in Florida 5,6. They are found year-round in coastal rivers and estuaries, often along large river curves with sand or cobble bottoms 8. They are bottom feeders, primarily eating crustaceans, mollusks, and insects.
Migration
Shortnose sturgeon are semi-anadromous, primarily living in brackish and salt water, and spawning in freshwater habitat. Migration varies by latitude and is likely dependent on temperature and flow conditions. Upriver spawning movements occur in late winter in southern rivers (e.g., South Carolina) and in spring in northern rivers (e.g. Massachusetts); however, fall migrations have been observed in the Hudson River, Connecticut River, and St. John River 6. Shortnose sturgeon arrive to spawning grounds when water temperatures reach 47-48 °F (8-9 ° C) and spawning typically occurs between 48-54 °F (9-12 °C) 2,6. They reach sexual maturity at 5 to 15 years depending on location and growth rates 5. Juveniles remain in freshwater until they reach approximately 18 in (45 cm) in length, and then migrate into brackish and marine systems 5.
Human Induced Impacts
Current threats to shortnose sturgeon include habitat obstruction and degradation, pollution such as nutrient runoff from agriculture, alteration of sediment distribution patterns, and incidental catch 13. In Massachusetts, the large river main-stem dams that were constructed in the 1800s significantly reduced sturgeon’s access to spawning habitat 1,7. Because sturgeon rely on specific hydrological conditions, water flows are an important factor in determining spawning location and success, as has been demonstrated in the Connecticut River 2. Additionally, dredging and other sediment-altering activities threaten sturgeon eggs because they are vulnerable to being smothered 13. The historic demand for sturgeon caviar and flesh led to overexploitation throughout their range; they were listed under the Endangered Species Act in 1967 10. Today they are rarely the target of commercial fishing and only caught incidentally.
Climate Impacts
Shortnose sturgeon populations are already severely stressed due to a range of human activities; climate change is expected to exacerbate poor conditions and have additional negative effects. Shortnose sturgeon rely on specific temperature cues and windows of optimal conditions to initiate important life stages and events such as spawning, which increases their vulnerability to climate change 6. Dispersal behavior of juvenile shortnose sturgeon has been shown to change as temperature increases. For example, in Connecticut, juvenile sturgeon had multiple downstream dispersal events when the waters were warmer, and single-event delayed dispersal when waters were cooler 11. In addition, temperature changes and nutrient runoff can alter water oxygen levels, impacting survival. Sea level rise may alter tidally-driven river salinity and change spawning habitat structure through different erosion and deposition patterns 14. Increased saltwater intrusion threatens optimal salinity ranges, which vary by season and life stages. For shortnose sturgeon in the south Atlantic, optimal salinity ranges have been identified as between 1.75 and 3 ppt during the breeding season, up to 8 ppt during the feeding season for early life stages and up to 20 ppt for older life stages 15. Increased variability and intensity of precipitation patterns projected under future climate change is expected to alter terrestrial runoff which can lead to suffocation and mortality of eggs. Changes in runoff will also increase the delivery of chemical pollutants into streams and rivers (e.g., PCBs), which may affect juvenile survival by altering the body forms of hatchlings 3. If water velocity events are too high, sturgeon eggs may be swept away into unsurvivable conditions 2.
1. Brown, JJ, Limburg, KE, Waldman, JR, Stephenson, K, Glenn, E, Juanes, F, Jordaan, A. 2013. Fish and hydropower on the U.S. Atlantic coast: failed fisheries policies from half-way technologies. Conservation letters 6:4 280-286.
2. Buckley, J., and B. Kynard. 1985. Habitat use and behavior of pre-spawning and spawning shortnose sturgeon, Acipenser brevirostrum, in the Connecticut River. Pages 111-117 in F.P. Binkowski and S.I. Doroshov, eds. North American sturgeons: biology and aquaculture potential. Developments in Environmental Biology of Fishes 6. Dr. W. Junk by Publishers, Dordrecht, Netherlands, 163 pp.
3. Chambers, R.C., D.D. Davis, E.A. Habeck, N.K. Roy, and I. Wirgin. Toxic Effects of PCB126 and TCDD on Shortnose Sturgeon and Atlantic Sturgeon. Environmental Toxicology and Chemistry 31:2324-2337.
4. Collins, M.R., S.G. Rogers, T.I.J. Smith, and M.L. Moser. 2000. Primary Factors Affecting Sturgeon Populations in the Southeastern United States; Fishing Mortality and Degradation of Essential Habitats. Bulletin of Marine Science 66:917-928.
5. Dadswell, M.J., B.D. Taubert, T.S. Squiers, D. Marchette, and J. Buckley. 1984. Synopsis of Biological Data on Shortnose Sturgeon, Acipenser brevirostrum LeSueur 1818. NOAA Technical Report NMFS 14. FAO Fisheries Synopsis No. 140.
6. Gilbert, C.R. 1989. Species Profiles: Life Histories and Environmental Requirements of Coastal Fishes and Invertebrates (Mid-Atlantic). Atlantic and Shortnosed Sturgeons. U.S. Fish and Wildlife Service (USFWS). Biological Report 82(11.122).
7. Hall, C.J., A. Jordaan, and M.G. Frisk. 2011. The historical influence of dams on diadromous fish habitat with a focus on river herring and hydrologic longitudinal connectivity. Landscape Ecology 26:95-107.
8. Kynard, B., Horgan, M., M. Kieffer, and D. Seibel. 2000. Habitats Used by Shortnose Sturgeon in Two Massachusetts River, with Notes on Estuarine Atlantic Sturgeon: A Hierarchical Approach. Transactions of the American Fisheries Society 129:487-503.
9. Natural Heritage and Endangered Species Program (NHESP). 2015. Shortnose Sturgeon. Massachusetts Division of Fisheries and Wildlife. Atlantic Sturgeon.
10. National Oceanic and Atmospheric Administration (NOAA). Protected Resources: Shortnose Sturgeon. 2015.
11. Parker, E.L. 2007. Ontogeny and life history of shortnose sturgeon (Acipenser brevirostrum Lesueur 1818): Effects of latitudinal variation and water temperature. Doctoral Dissertations Available from Proquest. Paper AAI3275810.
12. Schlesinger, M. D., J. D. Corser, K. A. Perkins, and E. L. White. 2011. Vulnerability of at-risk species to climate change in New York. New York Natural Heritage Program, Albany, NY.
13. Shortnose Sturgeon Status Review Team (SSSRT). 2010. A Biological Assessment of shortnose sturgeon (Acipenser brevirostrum). Report to National Marine Fisheries Service, Northeast Regional Office. November 1, 2010. 417 pp.
14. Whitman, A., A. Cutko, P. De Maynadier, S. Walker, B. Vickery, S. Stockwell, and R. Houston. 2013. Climate change and biodiversity in Maine: vulnerability of habitats and priority species. Report SEI-2013-03. Manomet Center for Conservation Sciences (in collaboration with Maine Beginning with Habitat Climate Change Working Group), Brunswick, ME.
15. Jager, H.I., D.L. Peterson, D. Farrae, and M.S. Bevelhimer, 2013: A Population Model to Assess Influences on the Viability of the Shortnose Sturgeon Population in the Ogeechee River, Georgia. Transactions of the American Fisheries Society, 142, 731-746.
This species was identified as highly vulnerable to climate change because of the following factors:
- Sea level rise
- Natural barriers
- Anthropogenic barriers... Read More
This species was identified as highly vulnerable to climate change because of the following factors:
- Sea level rise
- Natural barriers
- Anthropogenic barriers such as dams
- Climate change mitigation efforts
- Specific hydrological thresholds
- Disturbance
- Physical habitat alteration
Schlesinger, M. D., J. D. Corser, K. A. Perkins, and E. L. White. 2011. Vulnerability of at-risk species to climate change in New York. New York Natural Heritage Program, Albany, NY.
This species was identified as moderately vulnerable to climate change because of the following factors:
- Exhibits a high degree of habitat specialization
- A critical... Read More
This species was identified as moderately vulnerable to climate change because of the following factors:
- Exhibits a high degree of habitat specialization
- A critical part of life cycle is associated with a single microhabitat feature with microclimates
- Maximum critical temperature for survival of some life stages likely to be exceeded
- Survival and reproduction dependent on specific or stable hydrological regimes
- Dispersal significantly limited by natural and anthropogenic barriers
- Likely disruption of environmental cues
Whitman, A., A. Cutko, P. De Maynadier, S. Walker, B. Vickery, S. Stockwell, and R. Houston. 2013. Climate change and biodiversity in Maine: vulnerability of habitats and priority species. Report SEI-2013-03. Manomet Center for Conservation Sciences (in collaboration with Maine Beginning with Habitat Climate Change Working Group), Brunswick, ME.
Related Adaptation Strategies and Actions
Related Habitats (broad)
Related Habitats (detailed)
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