Identifying populations for management: fine-scale population structure in the New Zealand alpine rock wren (Xenicus gilviventris)

摘要

Examining the spatial genetic structure of cryptic species occupying challenging terrain can afford otherwise unattainable insights into ecological and evolutionary processes, such as population dynamics and dispersal patterns; information important for optimising conservation management. Using 13 microsatellite markers, we evaluated patterns of fine-scale gene flow and the spatial extent of genetic structuring of rock wren (Xenicus gilviventris), a threatened alpine passerine endemic to mountainous regions of the South Island, New Zealand. Through spatial autocorrelation analysis, we found that the 'genetic patch size', i.e. the distance over which individuals were not genetically independent, was surprisingly large (c. 70 km), given the rock wren's limited flight ability. By estimating recent migration rates among sampling locations we also found asymmetries in gene flow indicative of source-sink dynamics. An area with intensive deer and predator control, in the Murchison Mountains, Fiordland, appears to be a particularly important source of migrants for other populations. These findings suggest that management to maintain connectivity is required across relatively large spatial scales and source populations may be those where introduced mammals are managed.