TY - CONF
T1 - Linking Individual Fish Movement to the Demographics and Genetics of Populations
AU - Roberts, James Henry
AU - Jiao, Yan
AU - Angermeier, Paul L.
AU - Albanese, Brett W.
N1 - 1-103 m). In contrast, less direct studies of dispersal (e.g., occupancy models, genetic studies) often find watershed-scale (104-105 m) connectivity among populations. This contradiction might be reconciled if mark-recapture data were analyzed using techniques that focus on the "tails", rather than the "centers", of movement-frequency distributions.
PY - 2011/9/7
Y1 - 2011/9/7
N2 - Ecological theory predicts that small dispersal rates can have large effects on population persistence and gene flow. Mark-recapture studies of individual stream fish typically conclude that movement is restricted to the reach scale (101-103 m). In contrast, less direct studies of dispersal (e.g., occupancy models, genetic studies) often find watershed-scale (104-105 m) connectivity among populations. This contradiction might be reconciled if mark-recapture data were analyzed using techniques that focus on the "tails", rather than the "centers", of movement-frequency distributions. In this study, we assessed the fit of a suite of theoretical models to published movement data from North American stream fishes representing various taxa. From best-fitting models, we extrapolated the spatial extents over which key dispersal thresholds relevant to population connectivity (e.g., 10% dispersal rate, one migrant per generation) might be reached. Study design exerted a strong influence on estimates of mean and maximum movement distance, whereas taxonomic affiliation did not. Models that allowed for intra-population heterogeneity in movement behavior generally provided a better fit to data than did those assuming homogeneity. Using heterogeneity-based models, we projected non-trivial movement over spatial extents much greater than traditional movement analyses have suggested. Such long-distance movements form the key, understudied link between individual movements and the population dynamics and evolution of stream fishes.
AB - Ecological theory predicts that small dispersal rates can have large effects on population persistence and gene flow. Mark-recapture studies of individual stream fish typically conclude that movement is restricted to the reach scale (101-103 m). In contrast, less direct studies of dispersal (e.g., occupancy models, genetic studies) often find watershed-scale (104-105 m) connectivity among populations. This contradiction might be reconciled if mark-recapture data were analyzed using techniques that focus on the "tails", rather than the "centers", of movement-frequency distributions. In this study, we assessed the fit of a suite of theoretical models to published movement data from North American stream fishes representing various taxa. From best-fitting models, we extrapolated the spatial extents over which key dispersal thresholds relevant to population connectivity (e.g., 10% dispersal rate, one migrant per generation) might be reached. Study design exerted a strong influence on estimates of mean and maximum movement distance, whereas taxonomic affiliation did not. Models that allowed for intra-population heterogeneity in movement behavior generally provided a better fit to data than did those assuming homogeneity. Using heterogeneity-based models, we projected non-trivial movement over spatial extents much greater than traditional movement analyses have suggested. Such long-distance movements form the key, understudied link between individual movements and the population dynamics and evolution of stream fishes.
KW - Dispersal rates
KW - Ecology
KW - Fish movement
UR - https://afs.confex.com/afs/2011/webprogram/Paper2873.html
M3 - Presentation
T2 - American Fisheries Society Annual Meeting (AFS)
Y2 - 18 August 2017
ER -