Genetic differentiation at extreme latitudes in the socially plastic sweat bee Halictus rubicundus

The sweat bee Halictus rubicundus is an important pollinator with a large latitudinal range and many potential barriers to gene flow. Alongside typical physical barriers, including mountain ranges and oceans, the climate may also impose restrictions on gene flow in this species. The climate influences voltinism and sociality in H. rubicundus, which is bivoltine and can nest socially at lower latitudes but can be univoltine and solitary in the north of its range and at higher altitudes where the climate is cooler. Variation in voltinism due to the climate may result in differences in phenology between populations across this species geographical range. Differences in phenology could limit gene flow, rendering populations at extreme latitudes genetically isolated and potentially more vulnerable to environmental stressors. A previous study found that the Irish Sea restricts gene flow in this species, but there was no evidence that differences in phenology had a similar effect as there was no genetic differentiation between H. rubicundus populations on mainland Britain. Here we extend the previous study to consider populations of H. rubicundus at extreme northern and southern latitudes in the UK. Using 12 microsatellite markers for genotyping, we found that bees from a population in the far north of Scotland were genetically differentiated from bees collected in Cornwall in the south-west of England. In contrast, bees collected across the Irish Sea in Northern Ireland showed genetic overlap with both the Scottish and Cornish bees. Our results suggest that when populations at extreme latitudes are considered, phenology and the climate may act alongside physical barriers such as the Scottish Highlands and the Irish Sea to restrict gene flow in H. rubicundus. We discuss the implications of our results for local adaptation in the face of rapidly changing selection pressures which are likely under climate change.