| dc.description.abstract | Correct timing of phenology is crucial for the survival and growth of species in arid areas with
long dry seasons. Nevertheless, knowledge on genetic variation and adaptive patterns in
phenology in deciduous African dryland species is limited. Here we study the variation in
phenology of diploid and polypoid A. senegal trees from rangewide populations growing in a
common garden trial in Senegal and test correlations between population phenology and climate
at the site of origin. The leafing, flowering and fruiting phenology was monitored during 17
months and compared to detailed observations of the rainfall in the common garden during the
period. We found that A. senegal trees in general started development of leaves prior to the
beginning of the rainy season with flowering and fruiting initiation occurring during the rainy
season. The results lead us to conclude that is was not the rain per se that initiated leaf devel opment. We also conclude that phenology in A. senegal is under genetic control, because signif icant differences could be observed among populations and ploidy levels when grown at the same
site. In general, early leaf flushing trees had a longer growing period and performed better in
terms of growth at the tested site and the results thus support that leaf phenology influence
fitness. We further found that differences among trees in phenology seem to be associated with
differences in climate at their site of origin, because the timing of leaf development in the
common garden and the timing of the rainy season at the site of origin was significantly corre lated for the diploid trees (not for tetraploids). However, it was diploid trees from sites with a late
arriving rainy season that developed leaves earliest in the year. The environmental cues that
control leafing phenology and the associated physiological mechanisms therefore still need to be
identified in order to understand how the variation among populations has evolved, its rela tionship to local adaptation and the implication for smart transfer of seed sources as mean to
mitigate changing growing conditions related to global warming | en_US |
