Abstract
Genetic diversity and structure of populations at the edge of the species’ spatial distribution are important for potential adaptation to environmental changes and consequently, for the long-term survival of the species. Here, we combined classical population genetic methods with newly developed network analyses to gain complementary insights into the genetic structure and diversity of Acacia tortilis, a keystone desert tree, at the northern edge of its global distribution, where the population is under threat from climatic, ecological, and anthropogenic changes. We sampled A. tortilis from 14 sites along the Dead Sea region and the Arava Valley in Israel and in Jordan. In addition, we obtained samples from Egypt and Sudan, the hypothesized origin of the species. Samples from all sites were genotyped using six polymorphic microsatellite loci.Our results indicate a significant genetic structure in A. tortilis along the Arava Valley. This was detected at different hierarchical levels—from the basic unit of the subpopulation, corresponding to groups of trees within ephemeral rivers (wadis), to groups of subpopulations (communities) that are genetically more connected relative to others. The latter structure mostly corresponds to the partition of the major drainage basins in the area. Network analyses, combined with classical methods, allowed for the identification of key A. tortilis subpopulations in this region, characterized by their relatively high level of genetic diversity and centrality in maintaining gene flow in the population. Characterizing such key subpopulations may enable conservation managers to focus their efforts on certain subpopulations that might be particularly important for the population’s long-term persistence, thus contributing to species conservation within its peripheral range.
Highlights
Identifying the spatial patterns of a species’ genetic diversity can inform conservation priorities, enabling management and conservation efforts to focus on particular populations [1,2]
We examined connectivity within the population at different hierarchical levels and identified key subpopulations that may be important for maintaining gene flow and diversity at the northern edge of A. tortilis global distribution
High levels of genetic diversity were revealed across the population, in the Jordan subpopulations (Jordan_DS, Qatar, Tala Bay)
Summary
Identifying the spatial patterns of a species’ genetic diversity can inform conservation priorities, enabling management and conservation efforts to focus on particular populations [1,2]. A growing number of studies across species’ geographical ranges have reported high levels of genetic variability in peripheral areas [5,6,7] They have reported the presence of unique genotypes that are potentially important for adaptation to local or new conditions at the species’ periphery [8,9], and a relatively high persistence of populations at the periphery following range contraction [10]. Considering the potential effect of climate change on species distribution, reduced genetic variability at a species’ edge may restrict possible range expansion and potential for genetic adaptation [11]. These concerns call for the protection of peripheral populations [6,8,10]
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