Comparative Analysis of Ecological and Germination Niches in Native and Invasive Populations of Amaranthus albus

Invasive species serve as natural experiments to study adaptive evolution over contemporary time scales, as their native and invasive populations are exposed to different climatic settings and hence may experience strong selection pressures. In the life cycle of plants, germination stands as a cornerstone; thus, when invasive plant species encounter new surroundings, it is primarily expected that their germination niche will adapt to align with the thermal characteristics of the environment. However, adaptive responses in germination traits, specifically in cardinal temperatures, have not been explored. The objective of this study is to compare the Amaranthus albus (tumble pigweed) germination thermal niche and ecological niche between its native and invaded ranges. Considering geographic areas and climatic conditions, populations of A. albus were gathered from both cold and warm habitats in its native range (US) and its invaded range (Israel), with populations being at least 20 km apart from each other. First, populations were grown under similar conditions in a common garden experiment until seed production. The progeny seeds produced were then subjected to a set of germination trials under gradually changing temperature regimes. Cardinal temperatures and thermal niches for each population were estimated and analyzed in relation to the local climatic conditions of their respective habitats. Finally, a germination window was calculated to characterize the germination of a population throughout the year within its habitat. The invaded range studied here represents a subset of the species’ native range, with the A. albus establishing in similar climatic surroundings. Similarly, the germination niche for the native range was wider than for the invaded range. Thermal differentiation is evident in both native and invaded ranges. Populations from colder habitats exhibit lower base temperatures than those from warmer ones. This association was more evident for native populations. The remarkable variability observed within the germination pattern completely disappeared in the ‘germination window’ produced by those models, resulting in a similar pattern across the year for all populations. Our findings demonstrate the capability of species to adapt to new environmental conditions that may arise due to climatic changes. It emphasizes the role of cardinal temperatures, specifically the base temperature, as a potential adaptive characteristic.