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Ecology and Vulnerability Brook Floater
Documented observations of Brook Floater shown in orange. Data were developed by the Natural Heritage & Endangered Species Program as part of the BioMap2 project.
HideDocumented observations of Brook Floater shown in orange. Data were developed by the Natural Heritage & Endangered Species Program as part of the...
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Ecology and Vulnerability
Brook Floater
Background
The brook floater is a freshwater mussel species that inhabits streams and rivers with low to moderate flows1. When present in fast water, they will... Read More
Background
The brook floater is a freshwater mussel species that inhabits streams and rivers with low to moderate flows1. When present in fast water, they will often be found in protected pockets behind boulders. Brook floater are never found in lakes or reservoirs. They appear to require relatively undisturbed stream reaches and have little tolerance for stressors such as dams, urban areas, and poor water quality. Brook floaters are found in Atlantic coastal rivers from South Carolina to Nova Scotia and New Brunswick. As with other mussel species, the larval phase is a parasite that requires a fish host for development, after which it will drop off to continue development as a benthic adult. Several potential host fish species for brook floaters have been identified in lab settings, but it is unknown if these are all hosts under natural conditions. Adults live partially buried in the sediment where they filter algae, bacteria, zooplankton, and sediment from the water.
Freshwater mussels in general have experienced large declines2 and the brook floater is no exception. It is one of the most endangered mussels in northeastern North America and is listed as endangered in Massachusetts1. Remaining populations in Massachusetts are fragmented and appear to consist mostly of older adults showing little evidence of recent reproduction.
Climate Impacts
Brook floaters have a high thermal tolerance so even significant warming of Massachusetts waters is not likely to reach lethal temperatures. Lethal temperature for the most sensitive developmental stage is approximately 35°C/95°F3, which is about 10°C/18°F warmer than for the coldwater fish species, brook trout, currently found in Massachusetts4. It is unknown how sublethal temperatures may affect brook floaters, although water temperature directly relates to water quality such as dissolved oxygen. As water temperature increases, the amount of dissolved oxygen that water can hold decreases5. Additionally, a lengthened growing season and increased evapotranspiration are projected to increase the frequency of short-term drought conditions6. Potentially, such changes could impact water quality in ways that affect brook floater populations7.
Because mussels require a host fish species for larval development1,7, impacts on these fish could also impact mussels. Species identified as potential hosts for brook floaters include cold to cool water species, such as blacknose dace and slimy sculpin. These fish require cooler temparatures and may be impacted by significant warming of stream water 8.
1. Nedeau, E.J. 2008. Freshwater Mussels and the Connecticut River Watershed. Connecticut River Watershed Council, Greenfield, MA.
2. Strayer, D.L., and H.M. Malcom. 2012. Causes of recruitment failure in freshwater mussel populations in southeastern New York. Ecological Applications 22:1780-1790.
3. Pandolfo, T.J., W.G. Cope, C. Arellano, R.B. Bringolf, M.C. Barnhart, and E. Hammer. 2010. Upper thermal tolerances of early life stages of freshwater mussels. Journal of the North American Benthological Society 29:959-969.
4. McCormick, J.H., K.E.F. Hokanson, and B.R. Jones. 1972. Effects of temperature on growth and survival of young brook trout, Salvelinus fontinalis. Journal of the Fisheries Research Board of Canada 29:1107-1112.
5. Watt, M.K. 2000. A hydrologic primer for New Jersey watershed management. Water Resources Investigation Report 00-4140. US Geologial Survey, West Trenton, NJ.
6. Huntington, T.G., A.D. Richardson, K.J. McGuire, and K. Hayhoe. 2009. Climate and hydrological changes in the northeastern United States: recent trends and implications for forested and aquatic ecosystems. Canadian Journal of Forest Research 39:199-212.
7. Vaughn, C.C., C.L. Atkinson, and J.P. Julian. 2015. Drought-induced changes in flow regimes lead to long-term losses in mussel-provided ecosystem services. Ecology and Evolution 5:1291-1305.
8. Pandolfo, T.J., T.J. Kwak, and W.G. Cope. 2012. Thermal tolerances of freshwater mussels and their host fishes: species interactions in a changing climate. Walkerana 15:69-82.
Although this species was identified as not vulnerable to climate change, the following factors increase vulnerability:
- Dependent on other species for dispersal
- Has... Read More
Although this species was identified as not vulnerable to climate change, the following factors increase vulnerability:
- Dependent on other species for dispersal
- Has already experienced slight variations in annual precipitation (over the last 50 years)
- Slightly impacted by changes due to human response to climate change
Sneddon, L. A., and G. Hammerson. 2014. Climate Change Vulnerability Assessments of Selected Species in the North Atlantic LCC Region. NatureServe, Arlington, VA. Available from: http://northatlanticlcc.org/projects/completing-northeast-regional-vulne...
This species was identified as extremely vulnerable to climate change because of the following factors:
- Unable to disperse long distances or move across the landscape as... Read More
This species was identified as extremely vulnerable to climate change because of the following factors:
- Unable to disperse long distances or move across the landscape as conditions change
- Very sensitive to changes in precipitation
- Anthropogenic and natural barriers prevent dispersal or shifts in species' range
- Requires specialized habitat
- Dependent on other species to create habitat
- Slightly impacted by changes due to human response to climate change
The factors below decrease this species' vulnerability to climate change:
- Has already experienced increases in annual precipitation (over the last 50 years)
- Does not require a specialized diet (eats a wide variety of foods)
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. Available from: https://connect.natureserve.org/sites/default/files/documents/ccvi_repor...
This species was identified as highly vulnerable to climate change because of the following factors:
- Requires specialized habitat
- Habitat is likely to experience... Read More
This species was identified as highly vulnerable to climate change because of the following factors:
- Requires specialized habitat
- Habitat is likely to experience significant declines (by at least two-thirds)
- Species distribution is highly fragmented because of habitat loss or populations that are very spread out across the landscape
- Temperature increases may prevent species from surviving in some life stages
- Growth or reproduction may be harmed by additional stress from high temperatures
- Dependent on stable hydrology for survival and reproduction (stream flows)
- Unable to disperse long distances or move across the landscape as conditions change
- Natural and anthropogenic barriers prevent dispersal or shifts in species' range
- Limited genetic diversity within the population (suspected)
- Sensitive to change in the timing of seasons and/or other environmental cues
- Sensitive to disruption of relationship with very few host species that is vulnerable to climate change (cold-water fish)
- Close interactions with another species may be affected by climate change (dependence for habitat or food)
- Habitat may be affected by invasive species? that are likely to increase
Whitman, A., A. Cutko, P. DeMaynadier, 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. Available from: https://www.manomet.org/sites/default/files/publications_and_tools/BwHSu...
Although this species was identified as not vulnerable to climate change, the following factors increase vulnerability:
- Dependent on other species for dispersal
- Has... Read More
Although this species was identified as not vulnerable to climate change, the following factors increase vulnerability:
- Dependent on other species for dispersal
- Has already experienced slight variations in annual precipitation (over the last 50 years)
- Slightly impacted by changes due to human response to climate change
Sneddon, L. A., and G. Hammerson. 2014. Climate Change Vulnerability Assessments of Selected Species in the North Atlantic LCC Region. NatureServe, Arlington, VA. Available from: http://northatlanticlcc.org/projects/completing-northeast-regional-vulne...
Although this species was identified as not vulnerable to climate change, the following factors increase vulnerability:
- Dependent on other species for dispersal
- Has... Read More
Although this species was identified as not vulnerable to climate change, the following factors increase vulnerability:
- Dependent on other species for dispersal
- Has already experienced slight variations in annual precipitation (over the last 50 years)
- Slightly impacted by changes due to human response to climate change
Sneddon, L. A., and G. Hammerson. 2014. Climate Change Vulnerability Assessments of Selected Species in the North Atlantic LCC Region. NatureServe, Arlington, VA. Available from: http://northatlanticlcc.org/projects/completing-northeast-regional-vulne...
This species was identified as extremely vulnerable to climate change because of the following factors:
- Sensitive to changes in temperature
- Natural and anthropogenic... Read More
This species was identified as extremely vulnerable to climate change because of the following factors:
- Sensitive to changes in temperature
- Natural and anthropogenic barriers prevent dispersal or shifts in species' range
- Has already experienced variations in annual precipitation (over the last 50 years)
- Dependent on other species for dispersal
Byers, E., and S. Norris. 2011. Climate change vulnerability assessment of species of concern in West Virginia. West Virginia Division of Natural Resources, Elkins, West Virginia. Available from: http://wvdnr.gov/publications/PDFFiles/ClimateChangeVulnerability.pdf
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