Habitat loss threatens biodiversity in tropical forests, having harmful effects on population dynamics and, ultimately, determining the evolutionary destiny of species. Thus, understanding how habitat loss affects microevolutionary processes is an important step in the conservation of genetic resources. However, few studies have explored landscape genetics for plants in tropical environments. Our study evaluated the effects of a landscape-scale reduction in forest cover on genetic diversity and structure of Euterpe edulis (Arecaceae). The research was conducted in Atlantic Forest landscapes in Northeastern Brazil. We randomly chose 16 forest sites, each located in a 13 km 2 landscape with forest cover ranging from 6 to 83 %. After a survey of adults and seedlings in each sampling site, we found a minimum of five individuals of E. edulis at nine sites and sampled leafs from all adults within a 15 9 400 m plot and all seedlings within a 2 9 400 m subplot in each sampling site. We found that the gradient of remaining forest cover at the landscape scale did not affect the genetic diversity measured by any of the descriptors analyzed and each sampling site still harbored populations with high levels of genetic variability. However, we detected the presence of two distinct genetic groups with signs of admixture; the structural pattern of these groups differed between adults and seedlings, mainly in less forested landscapes areas. We believe that E. edulis is a good example of a tropical palm that is experiencing local extirpation before suffering loss of genetic alterations.
of genetic diversity in E. edulis is the result of historical instability during the mid-Holocene and recent anthropogenic impacts, mainly those that affect important ecological process such as seed dispersal. Thus, an efficient plan for species conservation must account for human impacts and environmental suitability and also assess the genetic diversity of seedlings and adults in fragmented landscapes.
Habitat loss represents one of the main threats to tropical forests, which have reached extremely high rates of species extinction. Forest loss negatively impacts biodiversity, affecting ecological (e.g., seed dispersal) and genetic (e.g., genetic diversity and structure) processes. Therefore, understanding how deforestation influences genetic resources is strategic for conservation. Our aim was to empirically evaluate the effects of landscape‐scale forest reduction on the spatial genetic structure and gene flow of Euterpe edulis Mart (Arecaceae), a palm tree considered a keystone resource for many vertebrate species. This study was carried out in nine forest remnants in the Atlantic Forest, northeastern Brazil, located in landscapes within a gradient of forest cover (19–83%). We collected leaves of 246 adults and 271 seedlings and performed genotyping using microsatellite markers. Our results showed that the palm populations had low spatial genetic structure, indicating that forest reduction did not influence this genetic parameter for neither seedlings nor adults. However, forest loss decreased the gene flow distance, which may negatively affect the genetic diversity of future generations by increasing the risk of local extinction of this keystone palm. For efficient strategies of genetic variability conservation and maintenance of gene flow in E. edulis, we recommend the maintenance of landscapes with intermediary to high levels of forest cover, that is, forest cover above 40%.
Euterpe edulis (Arecaceae) Mart has high ecological and economic importance providing food resources for more than 58 species of birds and 20 species of mammals, including humans. E. edulis is the second most exploited nontimber product from Brazilian Atlantic Forest. Due to overexploitation and destruction of habitats, E. edulis is threatened by extinction. Euterpe edulis populations have large morphological variations, with individuals having green, red, or yellow leaf sheath. However, no study has related phenotypic distinctions between populations and their levels of genetic structure. Thus, this study aimed to evaluate the diversity and genetic structure of different E. edulis morphotypes. We sampled 250 adult individuals in eight populations with the different morphotypes. Using 14 microsatellite markers, we access genetic diversity through population genetic parameters calculated in the GenAlex program and the diveRsity package in R. We used the Wilcoxon test to verify population bottlenecks and the genetic distance of Nei and Bayesian analysis for genetic clusters. The eight populations showed low allele richness, low observed heterozygosity, and high inbreeding values (f). In addition, six of the eight populations experienced genetic bottlenecks, which would partly explain the low genetic diversity in populations. Cluster analysis identified two clusters (K = 2), with green morphotype genetically distinguishing from yellow and red morphotypes. Thus, we show, for the first time, a strong genetic structure among E. edulis morphotypes even for geographically close populations.
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