Rapid expansion into new territory is fundamental to population persistence, ecological dominance, and evolutionary success. Every race for space is initiated by founding populations, yet how their initial spatiotemporal conditions shape the outcome remains unclear. Here, by combining nonlinear theory with quantitative microbial experiments, we show that collective motility can overturn the classical logic of priority effects. Populations expanding by individual motility retain the expected advantage of an earlier start or a larger initial footprint. By contrast, under collective motility, nonlinear density-dependent feedback enables initially lagging populations to accelerate, transforming early deficits into long-term competitive advantage. Optimization predicts that this advantage is maximized when the delay scales log-linearly with initial density. We validate this scaling behavior across diverse swarming microbes, revealing a general regulatory strategy for competitive range expansion. Competition and evolution experiments further show that this behavior is adaptive and robustly preserved. Together, our results establish a quantitative framework linking the initial organization of founding populations to final spatial outcomes, helping explain how organisms regulate early dynamics to shape ecological success in space.
Wavelet analysis of human recombination rates demonstrates divergence on fine scales
Background: Recombination rates can be estimated across the genome, underpinning genetic analyses such as identification of regions under selection. Accurate recombination mapping requires observing a