Source–sinks, metapopulations, and forest reserves: conserving northern flying squirrels in the temperate rainforests of Southeast Alaska

Winston P. Smith; David K. Person; Sanjay Pyare

doi:10.1017/CBO9780511842399.021

19 - Source–sinks, metapopulations, and forest reserves: conserving northern flying squirrels in the temperate rainforests of Southeast Alaska

Published online by Cambridge University Press: 05 July 2011

David K. Person and

Edited by

Anita T. Morzillo and

John A. Wiens

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Winston P. Smith: Affiliation:
Forestry Sciences Laboratory, USA
David K. Person: Affiliation:
Alaska Department of Fish and Game
Sanjay Pyare: Affiliation:
University of Alaska Southeast
Jianguo Liu: Affiliation:
Michigan State University
Vanessa Hull: Affiliation:
Michigan State University
Anita T. Morzillo: Affiliation:
Oregon State University
John A. Wiens: Affiliation:
PRBO Conservation Science

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Summary

Reserves are a common strategy used to ensure the viability of wildlife populations, but their effectiveness is rarely empirically evaluated. The Tongass National Forest implemented a conservation plan (TLMP) in 1997 to maintain biological diversity across Southeast Alaska, the cornerstone of which was an integrated system of large, medium, and small old-growth reserves (OGRs). Small OGRs were intended to facilitate functional connectivity between larger reserves and ensure well-distributed populations of forest-dependent wildlife. The northern flying squirrel (Glaucomys sabrinus) was selected as an indicator of wildlife communities that operate at small spatial scales because its abundance has been correlated with old-growth forest structure and processes and because of specific habitat requirements for efficient locomotion. Previous research predicted that small OGRs were unlikely to support flying squirrels over a 100-year time horizon. Consequently, the presence and persistence of flying squirrels in small OGRs depended on dispersal from larger reserves. Using data from telemetry experiments, we determined effective distances immigrants could move through landscapes composed of old-growth and managed forests. Effective distance accounted for the resistance of habitats such as clearcuts that are difficult for flying squirrels to traverse. We used findings of previous studies to parameterize a logistic population growth model incorporating dispersal to determine the number of dispersers necessary to enable a flying squirrel population in a small OGR to persist for 25 and 100 years. We combined that information with a function relating the probability of successful dispersal with effective distance to estimate the maximum effective distances between OGRs that would ensure flying squirrels colonize and persist in small OGRs for 25 and 100 years. Our findings underscore the essential role of immigration in sustaining sinks and facilitating metapopulation viability among unsustainable fragmented populations (i.e., sinks). They also demonstrate the extent to which permeability of landscape elements can influence the probability of dispersal and functional connectivity of subpopulations in a managed matrix.

Type: Chapter
Information: Sources, Sinks and Sustainability , pp. 399 - 422

DOI: https://doi.org/10.1017/CBO9780511842399.021 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2011

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References

Alaback, P. B. (1982). Dynamics of understory biomass in Sitka spruce-western hemlock forests of Southeast Alaska. Ecology 63: 1932–1948.CrossRef Google Scholar

Allee, W. C., Emerson, A. E., Park, O., Park, T. and Schmidt, K. P. (1949). Principles of Animal Ecology. Saunders, Philadelphia, PA.Google Scholar

Baum, K. A., Haynes, K. J., Dillemuth, F. P. and Cronin, J. T. (2004). The matrix enhances the effectiveness of corridors and stepping stones. Ecology 85: 2671–2676.CrossRef Google Scholar

Beier, P. (1993). Determining minimum habitat areas and corridors for cougars. Conservation Biology 7: 94–108.CrossRef Google Scholar

Bender, D. J., Contreras, T. A. and Fahrig, L. (1998). Habitat loss and population decline: a meta-analysis of the patch size effect. Ecology 79: 517–533.CrossRef Google Scholar

Bidlack, A. L. and Cook, J. A. (2001). Reduced genetic variation in insular northern flying squirrels (Glaucomys sabrinus) along the North Pacific Coast. Animal Conservation 4: 283–290.CrossRef Google Scholar

Burkey, T. V. (1989). Extinction in nature reserves: the effect of fragmentation and the importance of migration between reserve fragments. Oikos 55: 75–81.CrossRef Google Scholar

Carey, A. B. (2000). Ecology of northern flying squirrels: implications for ecosystem management in the Pacific Northwest, USA. In Biology of Gliding Mammals (Goldingay, R. L. and Scheibe, J. S., eds.). Filander Verlag, Fürth, Germany: 45–66.Google Scholar

Carroll, C., Noss, R. F., Paquet, P. C. and Schumaker, N. H. (2003). Use of population viability analysis and reserve selection algorithms in regional conservation plans. Ecological Applications 13: 1773–1789.CrossRef Google Scholar

Concannon, J. A. (1995). Characterizing structure, microclimate, and decomposition of peatland, beachfront, and newly-logged forest edges in southeastern Alaska. Dissertation, University of Washington, Seattle, WA.

Davis, G. L. and Howe, R. W. (1992). Juvenile dispersal, limited breeding sites, and the dynamics of metapopulations. Theoretical Population Biology 41: 184–207.CrossRef Google Scholar

Deal, R. L. and Farr, W. A. (1994). Composition and development of conifer regeneration in thinned and unthinned natural stands of western hemlock and Sitka spruce in Southeast Alaska. Canadian Journal of Forestry Research 24: 976–984.CrossRef Google Scholar

DeMars, D. J. (2000). Stand-Density Study of Spruce–Hemlock Stands in Southeastern Alaska. General Technical Report PNW-496, USDA Forest Service, Portland, OR.CrossRef Google Scholar

Demboski, J. R., Jacobsen, B. K. and Cook, J. A. (1998). Implications of cytochrome b sequence variation for biogeography and conservation of the northern flying squirrels (Glaucomys sabrinus) of the Alexander Archipelago, Alaska. Canadian Journal of Zoology 76: 1771–1777.CrossRef Google Scholar

DeMeo, T., Martin, J. and West, R. A. (1992). Forest Plant Association Guide: Ketchikan Area, Tongass National Forest. USDA Forest Service, Alaska Region R10-MB-210, USDA Forest Service, Juneau, AK.Google Scholar

Everest, F. H., Swanston, D. N., Shaw III, C. G., Smith, W. P., Julin, K. R. and Allen, S. D. (1997). Evaluation of the Use of Scientific Information in Developing the 1997 Forest Plan for the Tongass National Forest. General Technical Report PNW-GTR-415, USDA Forest Service, Portland, OR.CrossRef Google Scholar

Fahrig, L. and Merriam, G. (1985). Habitat patch connectivity and population survival. Ecology 66: 1762–1768.CrossRef Google Scholar

Fahrig, L. and Merriam, G. (1994). Conservation of fragmented populations. Conservation Biology 8: 50–59.CrossRef Google Scholar

FEMAT (Forest Ecosystem Management Assessment Team) (1993). Forest Ecosystem Management: An Ecological, Economic, and Social Assessment. US Department of Agriculture, US Department of the Interior (and others), Portland, OR.Google Scholar

Ferreras, P. (2001). Landscape structure and asymmetrical inter-patch connectivity in a meta-population of the endangered Iberian lynx. Biological Conservation 100: 125–136.CrossRef Google Scholar

Flaherty, E. A., Smith, W. P., Pyare, S. and Ben-David, M. (2008). Experimental trials of the northern flying squirrel (Glaucomys sabrinus) traversing managed rainforest landscapes: perceptual range and fine-scale movements. Canadian Journal of Zoology 86: 1050–1058.CrossRef Google Scholar

Flynn, R. W., Schumacher, T. V. and Ben-David, M. (2004). Abundance, Prey Availability, and Diets of American Martens: Implications for the Design of Old-Growth Reserves in Southeast Alaska. Final Report, US Fish and Wildlife Service Grant DCN 70181-1-G133. Alaska Department of Fish and Game, Douglas, AK.Google Scholar

Foley, P. (1994). Predicting extinction times from environmental stochasticity and carrying capacity. Conservation Biology 8: 124–137.CrossRef Google Scholar

Frankham, R. (1998). Inbreeding and extinction: island populations. Conservation Biology 12: 665–675.CrossRef Google Scholar

Fryxell, J. M., Falls, J. B., Falls, E. A. and Brooks, R. J. (1998). Long-term dynamics of small-mammal populations in Ontario. Ecology 79: 213–225.CrossRef Google Scholar

Fuller, T., Munguia, M., Mayfield, M., Sánchez-Cordero, V. and Sarkar, S. (2006). Incorporating connectivity into conservation planning: a multi-criteria case study from Central Mexico. Biological Conservation 133: 131–142.CrossRef Google Scholar

Hanski, I. (1994). Patch-occupancy dynamics in fragmented landscapes. Trends in Evolution and Ecology 9: 131–135.CrossRef Google Scholar PubMed

Hanski, I. and Gilpin, M. (1991). Metapopulation dynamics: brief history and conceptual domain. Biological Journal of the Linnean Society 42: 17–38.CrossRef Google Scholar

Hanski, I. K., Stevens, P. C., Ihalempiä, P. and Selonen, V. (2000). Home-range size, movements, and nest-site use in the Siberian flying squirrel,Pteromys volans. Journal of Mammalogy 81: 798–809.2.3.CO;2>CrossRef Google Scholar

Harris, A. S. and Farr, W. A. (1974). The Forest Ecosystem of Southeast Alaska. 7. Forest Ecology and Timber Management. General Technical Report PNW-25, USDA Forest Service, Portland, OR.Google Scholar

Hokkanen, H., Tőrmälä, T. and Vuorinen, H. (1982). Decline of the flying squirrel (Pteromys volans L.) populations in Finland. Biological Conservation 23: 273–284.CrossRef Google Scholar

Julin, K. R. and Caouette, J. P. (1997). Options for defining old-growth timber volume strata: a resource assessment. In Assessments of Wildlife Viability, Old-Growth Timber Volume Estimates, Forested Wetlands, and Slope Stability (Shaw III, C. G., technical coordinator). General Technical Report PNW-GTR-392, USDA Forest Service, Portland OR: 24–37.CrossRef Google Scholar

Kramer, M. G., Hansen, A. J., Taper, M. L. and Kissinger, E. J. (2001). Abiotic controls on long-term windthrow disturbance and temperate rain forest dynamics in Southeast Alaska. Ecology 82: 2749–2768.CrossRef Google Scholar

Leroux, S., Schmiegelow, F. K. A., Cumming, S. G., Lessard, R. B., and Nagy, J. (2007). Accounting for system dynamics in reserve design. Ecological Applications 17: 1954–1966.CrossRef Google Scholar

MacDonald, S. O. and Cook, J. A. (1996). The land mammal fauna of southeast Alaska. Canadian Field Naturalist 110: 571–598.Google Scholar

Mitchell, S. J. (1995). A synopsis of windthrow in British Columbia: occurrence, implications, assessment and management. In Wind and Trees (Coutts, M. P. and Grace, J., eds.). Cambridge University Press, Cambridge, UK: 448–459.CrossRef Google Scholar

Nowacki, G. J. and Kramer, M. G. (1998). The Effects of Wind Disturbance on Temperate Rain Forest Structure and Dynamics of Southeast Alaska. General Technical Report PNW-GTR-421, USDA Forest Service, Portland, OR.CrossRef Google Scholar

Odom, R. H., Ford, W. M., Edwards, J. W., Stihler, C. W. and Menzel, J. M. (2001). Developing a habitat model for the endangered Virginia northern flying squirrel (Glaucomys sabrinus fuscus) in the Allegheny Mountains of West Virginia. Biological Conservation 99: 245–252.CrossRef Google Scholar

O’Grady, J. J., Brook, B. W., Reed, D. H., Ballou, J. D., Tonkyn, D. W. and Frankham, R. (2006). Realistic levels of inbreeding depression strongly affect extinction risk in wild populations. Biological Conservation 133: 42–51.CrossRef Google Scholar

Opdam, P. (1991). Metapopulation theory and habitat fragmentation: a review of holarctic breeding bird studies. Landscape Ecology 5: 93–106.CrossRef Google Scholar

Opdam, P., Rijsdijk, G. and Hustings, F. (1985). Bird communities in small woods in an agricultural landscape: effects of area and isolation. Biological Conservation 34: 333–352.CrossRef Google Scholar

Pulliam, H. R. (1988). Sources, sinks, and population regulation. American Naturalist 132: 652–661.CrossRef Google Scholar

Pyare, S. and Smith, W. P. (2005). Functional Connectivity of Tongass Old-Growth Reserves: An Assessment Based on Flying Squirrel Movement Capability. Project Report, Juneau Fish and Wildlife Field Office, Ecological Services, US Fish and Wildlife Service, Juneau, AK [available at ].Google Scholar

Pyare, S., Smith, W. P. and Shanley, C. (2010). Den selection by northern flying squirrels in fragmented landscapes. Journal of Mammalogy 91: 886–896.CrossRef Google Scholar

Reed, D. H. (2004). Extinction risk in fragmented habitats. Animal Conservation 7: 181–191.CrossRef Google Scholar

Richards, W. H., Wallin, D. O. and Schumaker, N. H. (2002). An analysis of late-seral forest connectivity in western Oregon. Conservation Biology 16: 1409–1421.CrossRef Google Scholar

Rolstad, J. (1991). Consequences of forest fragmentation for the dynamics of bird populations: conceptual issues and the evidence. Biological Journal of the Linnean Society 42: 149–163.CrossRef Google Scholar

Ruckelshaus, M., Hartway, C. and Kareiva, P. (1997). Assessing the data requirements of spatially explicit dispersal models. Conservation Biology 11: 1298–1306.CrossRef Google Scholar

Scheibe, J. S., Smith, W. P., Basham, J. and Magness, D. (2006). Cost of transport in the northern flying squirrel, Glaucomys sabrinus. Acta Theriologica 51: 169–178.CrossRef Google Scholar

Schumaker, N. H. (1996). Using landscape indices to predict habitat connectivity. Ecology 77: 1210–1225.CrossRef Google Scholar

Searby, H. W. (1968). Climate of Alaska. Climatography of the United States No. 60-49. Climates of the States, Alaska. US Department of Commerce, Environmental Science Service Administration, Environmental Data Service.Google Scholar

Selonen, V. and Hanski, I. K. (2003). Movements of the flying squirrel Pteromys volans in corridors and in matrix habitat. Ecography 26: 641–651.CrossRef Google Scholar

Selonen, V. and Hanski, I. K. (2004). Young flying squirrels (Pteromys volans) dispersing in fragmented forests. Behavioral Ecology 15: 564–571.CrossRef Google Scholar

Shaw, C. G., III (1999). Use of Risk Assessment Panels During Revision of the Tongass Land and Resource Management Plan. General Technical Report PNW-460, USDA Forest Service, Portland, OR.CrossRef Google Scholar

Smith, W. P. (2007). Ecology of Glaucomys sabrinus: habitat, demography, and community relations. Journal of Mammalogy 88: 862–881.CrossRef Google Scholar

Smith, W. P. and Nichols, J. V. (2003). Demography of the Prince of Wales flying squirrel: an endemic of Southeastern Alaska temperate rainforest. Journal of Mammalogy 84: 1044–1058.CrossRef Google Scholar

Smith, W. P. and Person, D. K. (2007). Estimated persistence of northern flying squirrel populations in temperate rain forest fragments of Southeast Alaska. Biological Conservation 137: 626–636.CrossRef Google Scholar

Smith, W. P. and Zollner, P. A. (2005). Sustainable management of wildlife habitat and risk to extinction. Biological Conservation 125: 287–295.CrossRef Google Scholar

Smith, W. P., Anthony, R. G., Waters, J. R., Dodd, N. L. and Zabel, C. J. (2003). Ecology and conservation of arboreal rodents of the Pacific Northwest. In Mammal Community Dynamics in Western Coniferous Forests: Management and Conservation (Zabel, C. J. and Anthony, R. G., eds.). Cambridge University Press, Cambridge, UK: 157–206.CrossRef Google Scholar

Smith, W. P., Gende, S. M. and Nichols, J. V. (2004). Ecological correlates of flying squirrel microhabitat use and density in temperate rain forest of southeastern Alaska. Journal of Mammalogy 85: 663–674.CrossRef Google Scholar

Smith, W. P., Nichols, J. V. and Gende, S. M. (2005). The northern flying squirrel as a management indicator species of north temperate rainforest: test of a hypothesis. Ecological Applications 15: 689–700.CrossRef Google Scholar

Soulé, M. E., Estes, J. A., Berger, J. and Martinez Del Rio, C. (2003). Ecological effectiveness: conservation goals for interactive species. Conservation Biology 17: 1238–1250.CrossRef Google Scholar

Suring, L. A. (compiler) (1993). Habitat Capability Models for Wildlife in Southeast Alaska. USDA Forest Service, Alaska Region, Juneau, AK.Google Scholar

Taylor, P. D., Fahrig, L., Henein, K. and Merriam, G. (1993). Connectivity is a vital element of landscape structure. Oikos 68: 571–573.CrossRef Google Scholar

Tischendorf, L. and Fahrig, L. (2000). On the usage and measurement of landscape connectivity. Oikos 90: 7–19.CrossRef Google Scholar

USDA Forest Service (1997). Land and Resource Management Plan: Tongass National Forest. R10-MB-338dd, USDA Forest Service, Juneau, AK.Google Scholar

USDA Forest Service (2003). Tongass Land and Resource Management Plan Revision: Final Supplemental Environmental Impact Statement (FSEIS). R10-MB-481a, Volume I: Final SEIS, Appendix A, B, D, E. USDA Forest Service, Juneau, AK.Google Scholar

USDA Forest Service (2008). Land and Resource Management Plan: Tongass National Forest. R10-MB-603b, USDA Forest Service, Juneau, AK.Google Scholar

Verbeylen, G., De Bruyn, L., Adriaensen, F. and Matthysen, E. (2003). Does matrix resistance influence red squirrel (Sciuris vulgaris) distribution in an urban landscape?Landscape Ecology 18: 791–805.CrossRef Google Scholar

Vernes, K. (2001). Gliding performance of the northern flying squirrel (Glaucomys sabrinus) in mature mixed forests of eastern Canada. Journal of Mammalogy 82: 1026–1033.2.0.CO;2>CrossRef Google Scholar

Wiens, J. A. (1995). Habitat fragmentation: island vs. landscape perspectives on bird conservation. Ibis 137: S97–S104.CrossRef Google Scholar

Wiens, J. A., Stenseth, N. C., Van Horne, B. and Ims, R. A. (1993). Ecological mechanisms and landscape ecology. Oikos 66: 369–380.CrossRef Google Scholar

Wilcove, D. S., McLellan, C. H. and Dobson, A. P. (1986). Habitat fragmentation in the temperate zone. In Conservation Biology: The Science of Scarcity and Diversity (Soulé, M. E., ed.). Sinauer Associates, Sunderland, MA: 237–256.Google Scholar

Wilson, T. M. (2003). Sex and the Single Squirrel: A Genetic View of Forest Management in the Pacific Northwest. USDA Forest Service, Pacific Northwest Research Station, Portland, OR. Science Findings 51: 1–5.Google Scholar

Wilson, T. M. (2010). Limiting factors for northern flying squirrels (Glaucomys sabrinus) in the Pacific Northwest: a spatio-temporal analysis. PhD dissertation, Union Institute and University, Cincinnati, OH.

With, K. A. and Crist, T. O. (1995). Critical thresholds in species’ responses to landscape structure. Ecology 76: 2446–2459.CrossRef Google Scholar

Zar, J. H. (1999). Biostatistical Analysis, 4th edition. Prentice-Hall, Upper Saddle River, NJ.Google Scholar

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19 - Source–sinks, metapopulations, and forest reserves: conserving northern flying squirrels in the temperate rainforests of Southeast Alaska

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