Walter, G. M.; Chakraborty, A.; Cockerell, F.; Kellermann, V.; Hall, M. D.; White, C. R.; Sgro, C. M.

Latitudinal clines in thermal tolerance are routinely used as evidence of adaptation across a broad climatic gradient. However, if the strength of latitudinal clines changes with the environment, then patterns of adaptation will be unstable, and using clinal patterns to predict population responses to global change will be difficult. To test whether changes in temperature and diet influence the strength of latitudinal patterns in key traits, we sampled five populations of Drosophila melanogaster spanning 3000-km of east coast Australia, and measured stress tolerance (heat, cold and desiccation) and body size on flies that developed in six combinations of temperature (13{degrees}C, 25{degrees}C and 29{degrees}C) and diet (standard and low-calorie) treatments. We found evidence of latitudinal clines whereby populations nearer the equator had smaller wings, lower cold tolerance and greater heat tolerance. For all traits, developmental temperature determined the strength of the latitudinal cline, whereas diet had little influence. Latitudinal clines were steeper in warmer treatments, which was created by latitudinal variation in plasticity. Compared to populations from higher latitudes, lower latitude populations that developed at the warmest temperature showed smaller increases in heat tolerance, greater decreases in cold tolerance, but a better ability to maintain desiccation resistance. These results suggest that latitudinal trends in plasticity underlie environment-dependent latitudinal clines, which are likely to determine variation in population responses to global change.