Scale-dependence of habitat sources and sinks

Jeffrey M. Diez; Itamar Giladi

doi:10.1017/CBO9780511842399.016

14 - Scale-dependence of habitat sources and sinks

Published online by Cambridge University Press: 05 July 2011

Jeffrey M. Diez and

Itamar Giladi

Edited by

Jianguo Liu ,

Vanessa Hull ,

Anita T. Morzillo and

John A. Wiens

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Jeffrey M. Diez: Affiliation:
School of Natural Resources and Environment, Michigan, USA
Itamar Giladi: Affiliation:
Ben-Gurion University of the Negev, Israel
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

Studies of population dynamics are necessarily contingent on scale, both spatial and temporal extent and grain of study. Observed population dynamics may vary across scales, and different processes may drive these patterns at different scales. Habitat sources and sinks are driven by variation in demographic vital rates such as survival, growth, and reproduction, which often vary widely across spatial and temporal scales. The knowledge that patterns may vary across scales, and different driving variables may be relevant at different scales, is intuitive to ecologists. Merging this awareness of scale with quantitative studies of population dynamics has proven difficult, however. The overall aims of this chapter are to show how scale has influenced studies of source–sink dynamics, and to highlight an emerging statistical approach for better quantifying population dynamics at different scales. After a brief review of how issues of scale are central to understanding source–sink dynamics, we show how hierarchical models can help quantify demographic variation across different scales and make predictions for sparsely populated sites. We use a brief case study of the demography of a forest herb, Hexastylis arifolia (“little brown jug”), to highlight how demographic rates and predicted population growth rates may be quantified at different scales. We conclude with a discussion of important extensions to this work, including the incorporation of dispersal, and the possible implications of scale for assessments of source–sink dynamics.

Type: Chapter
Information: Sources, Sinks and Sustainability , pp. 291 - 316

DOI: https://doi.org/10.1017/CBO9780511842399.016 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2011

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References

Apps, C. D., McLellan, B. N., Kinley, T. A. and Flaa, J. P. (2001). Scale-dependent habitat selection by mountain caribou, Columbia Mountains, British Columbia. Journal of Wildlife Management 65: 65–77.CrossRef Google Scholar

Battin, J. (2004). When good animals love bad habitats: ecological traps and the conservation of animal populations. Conservation Biology 18: 1482–1491.CrossRef Google Scholar

Berry, E. J., Gorchov, D. L., Endress, B. A. and Stevens, M. H. H. (2008). Source–sink dynamics within a plant population: the impact of substrate and herbivory on palm demography. Population Ecology 50: 63–77.CrossRef Google Scholar

Blondel, J., Dias, P. C., Ferret, P., Maistre, M. and Lambrechts, M. M. (1999). Selection-based biodiversity at a small spatial scale in a low-dispersing insular bird. Science 285: 1399–1402.CrossRef Google Scholar

Bohrer, G., Nathan, R. and Volis, S. (2005). Effects of long-distance dispersal for metapopulation survival and genetic structure at ecological time and spatial scales. Journal of Ecology 93: 1029–1040.CrossRef Google Scholar

Boughton, D. A. (1999). Empirical evidence for complex source–sink dynamics with alternative states in a butterfly metapopulation. Ecology 80: 2727–2739.Google Scholar

Boughton, D. A. (2000). The dispersal system of a butterfly: a test of source–sink theory suggests the intermediate-scale hypothesis. American Naturalist 156: 131–144.Google Scholar PubMed

Bowne, D. R. and Bowers, M. A. (2004). Interpatch movements in spatially structured populations: a literature review. Landscape Ecology 19: 1–20.CrossRef Google Scholar

Breininger, D. R. and Carter, G. M. (2003). Territory quality transitions and source–sink dynamics in a Florida scrub-jay population. Ecological Applications 13: 516–529.CrossRef Google Scholar

Breininger, D. R. and Oddy, D. M. (2004). Do habitat potential, population density, and fires influence scrub-jay source–sink dynamics?Ecological Applications 14: 1079–1089.CrossRef Google Scholar

Byers, J. E., Blakeslee, A. M. H., Linder, E., Cooper, A. B. and Maguire, T. J. (2008). Controls of spatial variation in the prevalence of trematode parasites infecting a marine snail. Ecology 89: 439–451.CrossRef Google Scholar PubMed

Caswell, H. (2001). Matrix Population Models: Construction, Analysis, and Interpretation. Sinauer Associates, Sunderland, MA.Google Scholar

Caudill, C. C. (2003). Empirical evidence for nonselective recruitment and a source–sink dynamic in a mayfly metapopulation. Ecology 84: 2119–2132.CrossRef Google Scholar

Caudill, C. C. (2005). Trout predators and demographic sources and sinks in a mayfly metapopulation. Ecology 86: 935–946.CrossRef Google Scholar

Chalfoun, A. D. and Martin, T. E. (2007). Assessments of habitat preferences and quality depend on spatial scale and metrics of fitness. Journal of Applied Ecology 44: 983–992.CrossRef Google Scholar

Ciarniello, L. M., Boyce, M. S., Seip, D. R. and Heard, D. C. (2007). Grizzly bear habitat selection is scale dependent. Ecological Applications 17: 1424–1440.CrossRef Google Scholar PubMed

Clark, J. S. (2003). Uncertainty and variability in demography and population growth: a hierarchical approach. Ecology 84: 1370–1381.CrossRef Google Scholar

Clark, J. S. (2007). Models for Ecological Data: An Introduction. Princeton University Press, Princeton, NJ.Google Scholar

Clark, J. S. and Gelfand, A. E. (eds.) (2006). Hierarchical Modelling for the Environmental Sciences. Oxford University Press, Oxford, UK.

Clark, J. S., LaDeau, S. and Ibanez, I. (2004). Fecundity of trees and the colonization–competition hypothesis. Ecological Monographs 74: 415–442.CrossRef Google Scholar

Clark, J. S., Ferraz, G. A., Oguge, N., Hays, H. and DiCostanzo, J. (2005). Hierarchical Bayes for structured, variable populations: from recapture data to life-history prediction. Ecology 86: 2232–2244.CrossRef Google Scholar

Collins, B. S., Dunne, K. P. and Pickett, S. T. A. (1985). Responses of forest herbs to canopy gaps. In The Ecology of Natural Disturbance and Patch Dynamics (Pickett, S. T. A. and White, P. S., eds.). Academic Press, London.Google Scholar

Cowen, R. K., Lwiza, K. M. M., Sponaugle, S., Paris, C. B. and Olson, D. B. (2000). Connectivity of marine populations: open or closed?Science 287: 857–859.CrossRef Google Scholar PubMed

Cowen, R. K., Paris, C. B. and Srinivasan, A. (2006). Scaling of connectivity in marine populations. Science 311: 522–527.CrossRef Google Scholar PubMed

Cronin, J. T. (2007). From population sources to sieves: the matrix alters host-parasitoid source–sink structure. Ecology 88: 2966–2976.CrossRef Google Scholar PubMed

Damman, H. and Cain, M. L. (1998). Population growth and viability analyses of the clonal woodland herb, Asarum canadense. Journal of Ecology 86: 13–26.CrossRef Google Scholar

Delibes, M., Ferreras, P. and Gaona, P. (2001). Attractive sinks, or how individual behavioural decisions determine source–sink dynamics. Ecology Letters 4: 401–403.CrossRef Google Scholar

Dias, P. C. (1996). Sources and sinks in population biology. Trends in Ecology and Evolution 11: 326–330.CrossRef Google Scholar PubMed

Dias, P. C., Verheyen, G. R. and Raymond, M. (1996). Source–sink populations in Mediterranean blue tits: evidence using single-locus minisatellite probes. Journal of Evolutionary Biology 9: 965–978.CrossRef Google Scholar

Diez, J. M. (2007). Hierarchical patterns of symbiotic orchid germination linked to adult proximity and environmental gradients. Journal of Ecology 95: 159–170.CrossRef Google Scholar

Doak, D. F. (1995). Source–sink models and the problem of habitat degradation: general models and applications to the Yellowstone grizzly. Conservation Biology 9: 1370–1379.CrossRef Google Scholar

Dupré, C. and Ehrlén, J. (2002). Habitat configuration, species traits and plant distributions. Journal of Ecology 90: 796–805.CrossRef Google Scholar

Fieberg, J. and Ellner, S. P. (2001). Stochastic matrix models for conservation and management: a comparative review of methods. Ecology Letters 4: 244–266.CrossRef Google Scholar

Gelman, A. and Hill, J. (2007). Data Analysis Using Regression and Multilevel/Hierarchical Models. Cambridge University Press, Cambridge, UK.Google Scholar

Gelman, A., Carlin, J. B. and Rubin, H. S. S. B. (2004). Bayesian Data Analysis, 2nd edition. Chapman and Hall/CRC, New York.Google Scholar

Giladi, I. (2004). The role of habitat-specific demography, habitat-specific dispersal, and the evolution of dispersal distances in determining current and future distributions of the ant-dispersed forest herb, Hexastylis arifolia. PhD dissertation, Institute of Ecology, University of Georgia, Athens, GA.

Gonzalez, V. C. (1972). The ecology of Hexastylis arifolia, an evergreen herb in the North Carolina deciduous forest. PhD dissertation, Department of Botany, Duke University, Durham, NC.

Grear, J. S. and Burns, C. E. (2007). Evaluating effects of low-quality habitats on regional population growth in Peromyscus leucopus: insights from field-parameterized spatial matrix models. Landscape Ecology 22: 45–60.CrossRef Google Scholar

Gundersen, G., Johannesen, E., Andreassen, H. P. and Ims, R. A. (2001). Source–sink dynamics: how sinks affect demography of sources. Ecology Letters 4: 14–21.CrossRef Google Scholar

Hatchwell, B. J., Chamberlain, D. E. and Perrins, C. M. (1996). The demography of blackbirds Turdus merula in rural habitats: is farmland a sub-optimal habitat?Journal of Applied Ecology 33: 1114–1124.CrossRef Google Scholar

Hobson, K. A., Wassenaar, L. I. and Bayne, E. (2004). Using isotopic variance to detect long-distance dispersal and philopatry in birds: an example with ovenbirds and American redstarts. Condor 106: 732–743.CrossRef Google Scholar

Holt, R. D. (1985). Population dynamics in two-patch environments: some anomalous consequences of an optimal habitat distribution. Theoretical Population Biology 28: 181–208.CrossRef Google Scholar

Hunter, C. M. and Caswell, H. (2005). The use of the vec-permutation matrix in spatial matrix population models. Ecological Modelling 188: 15–21.CrossRef Google Scholar

Johnson, D. M. (2004). Source–sink dynamics in a temporally heterogeneous environment. Ecology 85: 2037–2045.CrossRef Google Scholar

Kadmon, R. and Shmida, A. (1990). Spatiotemporal demographic processes in plant populations: an approach and a case-study. American Naturalist 135: 382–397.CrossRef Google Scholar

Kadmon, R. and Tielborger, K. (1999). Testing for source–sink population dynamics: an experimental approach exemplified with desert annuals. Oikos 86: 417–429.CrossRef Google Scholar

Kery, M., Gregg, K. B. and Schaub, M. (2005). Demographic estimation methods for plants with unobservable life-states. Oikos 108: 307–320.CrossRef Google Scholar

Kotliar, N. B. and Wiens, J. A. (1990). Multiple scales of patchiness and patch structure: a hierarchical framework for the study of heterogeneity. Oikos 59: 253–260.CrossRef Google Scholar

Kreuzer, M. P. and Huntly, N. J. (2003). Habitat-specific demography: evidence for source–sink population structure in a mammal, the pika. Oecologia 134: 343–349.CrossRef Google Scholar

Kunin, W. E. (1998). Biodiversity at the edge: a test of the importance of spatial “mass effects” in the Rothamsted Park Grass experiments. Proceedings of the National Academy of Sciences of the USA 95: 207–212.CrossRef Google Scholar PubMed

Lele, S. R., Dennis, B. and Lutscher, F. (2007). Data cloning: easy maximum likelihood estimation for complex ecological models using Bayesian Markov chain Monte Carlo methods. Ecology Letters 10: 551–563.CrossRef Google Scholar PubMed

Lloyd, P., Martin, T. E., Redmond, R. L., Langner, U. and Hart, M. M. (2005). Linking demographic effects of habitat fragmentation across landscapes to continental source–sink dynamics. Ecological Applications 15: 1504–1514.CrossRef Google Scholar

McGeoch, M. A. and Price, P. W. (2005). Scale-dependent mechanisms in the population dynamics of an insect herbivore. Oecologia 144: 278–288.CrossRef Google Scholar PubMed

McMahon, S. M. and Diez, J. M. (2007). Scales of association: hierarchical linear models and the measurement of ecological systems. Ecology Letters 10: 437–452.CrossRef Google Scholar PubMed

McPeek, M. A. and Holt, R. D. (1992). The evolution of dispersal in spatially and temporally varying environments. American Naturalist 140: 1010–1027.CrossRef Google Scholar

Meisel, J. E. and Turner, M. G. (1998). Scale detection in real and artificial landscapes using semivariance analysis. Landscape Ecology 13: 347–362.CrossRef Google Scholar

Milot, E., Weimerskirch, H. and Bernatchez, L. (2008). The seabird paradox: dispersal, genetic structure and population dynamics in a highly mobile, but philopatric albatross species. Molecular Ecology 17: 1658–1673.CrossRef Google Scholar

Moloney, K. A. (1988). Fine-scale spatial and temporal variation in the demography of a perennial bunchgrass. Ecology 69: 1588–1598.CrossRef Google Scholar

Murphy, M. T. (2001). Habitat-specific demography of a long-distance, neotropical migrant bird, the eastern kingbird. Ecology 82: 1304–1318.CrossRef Google Scholar

Nathan, R. (2006). Long-distance dispersal of plants. Science 313: 786–788.CrossRef Google Scholar

Nathan, R., Perry, G., Cronin, J. T., Strand, A. E. and Cain, M. L. (2003). Methods for estimating long-distance dispersal. Oikos 103: 261–273.CrossRef Google Scholar

Nystrand, M., Griesser, M., Eggers, S. and Ekman, J. (2010). Habitat-specific demography and source–sink dynamics in a population of Siberian jays. Journal of Animal Ecology 79: 266–274.CrossRef Google Scholar

O’Neill, R. V., Milne, B. T., Turner, M. G. and Gardner, R. H. (1986). A Hierarchical Concept of Ecosystems. Princeton University Press, Princeton, NJ.Google Scholar

Oostermeijer, J. G. B., Brugman, M. L., DeBoer, E. R. and DenNijs, H. C. M. (1996). Temporal and spatial variation in the demography of Gentiana pneumonanthe, a rare perennial herb. Journal of Ecology 84: 153–166.CrossRef Google Scholar

Orians, G. H. and Wittenberger, J. F. (1991). Spatial and temporal scales in habitat selection. American Naturalist 137: S29–S49.CrossRef Google Scholar

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

R Development Core Team (2008). R: A Language and Environment for Statistical Computing. R Foundation for Statistical Computing, Vienna, Austria [available at ]Google Scholar

Raudenbush, S. W. and Bryk, A. S. (2002). Hierarchical Linear Models: Applications and Data Analysis Methods. Sage Publications, London.Google Scholar

Reid, J. M., Bignal, E. M., Bignal, S., McCracken, D. I. and Monaghan, P. (2006). Spatial variation in demography and population growth rate: the importance of natal location. Journal of Animal Ecology 75: 1201–1211.CrossRef Google Scholar PubMed

Roberts, C. M. (1997). Connectivity and management of Caribbean coral reefs. Science 278: 1454–1457.CrossRef Google Scholar PubMed

Robinson, S. K., Thompson, F. R., Donovan, T. M., Whitehead, D. R. and Faaborg, J. (1995). Regional forest fragmentation and the nesting success of migratory birds. Science 267: 1987–1990.CrossRef Google Scholar PubMed

Runge, J. P., Runge, M. C. and Nichols, J. D. (2006). The role of local populations within a landscape context: defining and classifying sources and sinks. American Naturalist 167: 925–938.CrossRef Google Scholar PubMed

Schooley, R. L. and Branch, L. C. (2007). Spatial heterogeneity in habitat quality and cross-scale interactions in metapopulations. Ecosystems 10: 846–853.CrossRef Google Scholar

Shefferson, R. P., Sandercock, B. K., Proper, J. and Beissinger, S. R. (2001). Estimating dormancy and survival of a rare herbaceous perennial using mark–recapture models. Ecology 82: 145–156.Google Scholar

Sodhi, N. S., Paszkowski, C. A. and Keehn, S. (1999). Scale-dependent habitat selection by American redstarts in aspen-dominated forest fragments. Wilson Bulletin 111: 70–75.Google Scholar

Tackenberg, O. (2003). Modeling long-distance dispersal of plant diaspores by wind. Ecological Monographs 73: 173–189.CrossRef Google Scholar

Thomas, A., O’Hara, R. B., Ligges, U. and Sturtz, S. (2006). Making BUGS open. R News 6: 12–17.Google Scholar

Thomas, C. D. and Kunin, W. E. (1999). The spatial structure of populations. Journal of Animal Ecology 68: 647–657.CrossRef Google Scholar

Thompson, F. R., Donovan, T. M., DeGraaf, R. M., Faaborg, J. and Robinson, S. K. (2002). A multi-scale perspective of the effects of forest fragmentation on birds in eastern forests. In Effects of Habitat Fragmentation on Birds in Western Landscapes: Contrasts With Paradigms from the Eastern United States (George, T. L. and Dobkin, D. S., eds.). Studies in Avian Biology 25, Cooper Ornithological Society, Norman, OK.Google Scholar

Thomson, D. M. (2007). Do source–sink dynamics promote the spread of an invasive grass into a novel habitat?Ecology 88: 3126–3134.CrossRef Google Scholar PubMed

Tittler, R., Fahrig, L. and Villard, M. A. (2006). Evidence of large-scale source–sink dynamics and long-distance dispersal among wood thrush populations. Ecology 87: 3029–3036.CrossRef Google Scholar PubMed

Trakhtenbrot, A., Nathan, R., Perry, G. and Richardson, D. M. (2005). The importance of long-distance dispersal in biodiversity conservation. Diversity and Distributions 11: 173–181.CrossRef Google Scholar

Van Horne, B. (1983). Density as a misleading indicator of habitat quality. Journal of Wildlife Management 47: 893–901.CrossRef Google Scholar

Vavrek, M. C., McGraw, J. B. and Yang, H. S. (1996). Within-population variation in demography of Taraxacum officinale: maintenance of genetic diversity. Ecology 77: 2098–2107.CrossRef Google Scholar

Vellend, M., Myers, J. A., Gardescu, S. and Marks, P. L. (2003). Dispersal of Trillium seeds by deer: implications for long-distance migration of forest herbs. Ecology 84: 1067–1072.CrossRef Google Scholar

Virgl, J. A. and Messier, F. (2000). Assessment of source–sink theory for predicting demographic rates among habitats that exhibit temporal changes in quality. Canadian Journal of Zoology – Revue Canadienne de Zoologie 78: 1483–1493.CrossRef Google Scholar

Warren, R. J. (2007). Linking understory evergreen herbaceous distributions and niche differentiation using habitat-specific demography and experimental common gardens. PhD dissertation, University of Georgia, Athens, GA.

Watkinson, A. R. and Sutherland, W. J. (1995). Sources, sinks and pseudo-sinks. Journal of Animal Ecology 64: 126–130.CrossRef Google Scholar

Whigham, D. E. (2004). Ecology of woodland herbs in temperate deciduous forests. Annual Review of Ecology Evolution and Systematics 35: 583–621.CrossRef Google Scholar

Wiens, J. A. (1989). Spatial scaling in ecology. Functional Ecology 3: 385–397.CrossRef Google Scholar

With, K. A. and King, A. W. (1999). Dispersal success on fractal landscapes: a consequence of lacunarity thresholds. Landscape Ecology 14: 73–82.CrossRef Google Scholar

With, K. A., Schrott, G. R. and King, A. W. (2006). The implications of metalandscape connectivity for population viability in migratory songbirds. Landscape Ecology 21: 157–167.CrossRef Google Scholar

Zelikova, T. J., Dunn, R. R. and Sanders, N. J. (2008). Variation in seed dispersal along an elevational gradient in Great Smoky Mountains National Park. Acta Oecologica – International Journal of Ecology 34: 155–162.CrossRef Google Scholar

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