Ecological dynamics of moa extinctions reveal convergent refugia that today harbour flightless birds.

Human settlement of islands across the Pacific Ocean was followed by waves of faunal extinctions that occurred so rapidly that their dynamics are difficult to reconstruct in space and time. These extinctions included large, wingless birds called moa that were endemic to New Zealand. Here we reconstructed the range and extinction dynamics of six genetically distinct species of moa across New Zealand at a fine spatiotemporal resolution, using hundreds of thousands of process-explicit simulations of climate-human-moa interactions, which were validated against inferences of occurrence and range contraction from an extensive fossil record. These process-based simulations revealed important interspecific differences in the ecological and demographic attributes of moa and established how these differences influenced likely trajectories of geographic and demographic declines of moa following Polynesian colonization of New Zealand. We show that despite these interspecific differences in extinction dynamics, the spatial patterns of geographic range collapse of moa species were probably similar. It is most likely that the final populations of all moa species persisted in suboptimal habitats in cold, mountainous areas that were generally last and least impacted by people. We find that these refugia for the last populations of moa continue to serve as isolated sanctuaries for New Zealand's remaining flightless birds, providing fresh insights for conserving endemic species in the face of current and future threats.

Reconstructing colonization dynamics to establish how human activities transformed island biodiversity.

Drivers and dynamics of initial human migrations across individual islands and archipelagos are poorly understood, hampering assessments of subsequent modification of island biodiversity. We developed and tested a new statistical-simulation approach for reconstructing the pattern and pace of human migration across islands at high spatiotemporal resolutions. Using Polynesian colonisation of New Zealand as an example, we show that process-explicit models, informed by archaeological records and spatiotemporal reconstructions of past climates and environments, can provide new and important insights into the patterns and mechanisms of arrival and establishment of people on islands. We find that colonisation of New Zealand required there to have been a single founding population of approximately 500 people, arriving between 1233 and 1257 AD, settling multiple areas, and expanding rapidly over both North and South Islands. These verified spatiotemporal reconstructions of colonisation dynamics provide new opportunities to explore more extensively the potential ecological impacts of human colonisation on New Zealand's native biota and ecosystems.