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Abstract The Rufous-collared Sparrow (Zonotrichia capensis) shows phenotypic variation throughout its distribution. In particular, the Patagonian subspecies Z. c. australis is strikingly distinct from all other subspecies, lacking the black crown stripes that characterize the species, with a uniformly grey head and overall paler plumage. We sequenced whole genomes of 18 individuals (9 Z. c. australis and 9 from other subspecies from northern Argentina) to explore the genomic basis of these color differences and to investigate how they may have evolved. We detected a single ~465-kb divergence peak on chromosome 5 that contrasted with a background of low genomic differentiation and contains the suppression of tumorigenicity 5 (ST5) gene. ST5 regulates RAB9A, which is required for melanosome biogenesis and melanocyte pigmentation in mammals, making it a strong candidate gene for the melanic plumage polymorphism within Z. capensis. This genomic island of differentiation may have emerged because of selection acting on allopatric populations or against gene flow on populations in physical and genetic contact. Mitochondrial DNA indicated that Z. c. australis diverged from other subspecies ~400,000 years ago, suggesting a putative role of Pleistocene glaciations. Phenotypic differences are consistent with Gloger’s rule, which predicts lighter-colored individuals in colder and drier climates like that of Patagonia. 

Abstract Climate change models often assume similar responses to temperatures across the range of a species, but local adaptation or phenotypic plasticity can lead plants and animals to respond differently to temperature in different parts of their range. To date, there have been few tests of this assumption at the scale of continents, so it is unclear if this is a large‐scale problem. Here, we examined the assumption that insect taxa show similar responses to temperature at 96 sites in grassy habitats across North America. We sampled insects with Malaise traps during 2019–2021 (N = 1041 samples) and examined the biomass of insects in relation to temperature and time of season. Our samples mostly contained Diptera (33%), Lepidoptera (19%), Hymenoptera (18%), and Coleoptera (10%). We found strong regional differences in the phenology of insects and their response to temperature, even within the same taxonomic group, habitat type, and time of season. For example, the biomass of nematoceran flies increased across the season in the central part of the continent, but it only showed a small increase in the Northeast and a seasonal decline in the Southeast and West. At a smaller scale, insect biomass at different traps operating on the same days was correlated up to ~75 km apart. Large‐scale geographic and phenological variation in insect biomass and abundance has not been studied well, and it is a major source of controversy in previous analyses of insect declines that have aggregated studies from different locations and time periods. Our study illustrates that large‐scale predictions about changes in insect populations, and their causes, will need to incorporate regional and taxonomic differences in the response to temperature.