Abstract
Yams (Dioscorea spp.) consist of approximately 600 species. Presently, these species are threatened by genetic erosion due to many factors such as pest attacks and farming practices. In parallel, complex taxonomic boundaries in this genus makes it more challenging to properly address the genetic diversity of yam and manage its germplasm. As a first step toward evaluating and preserving the genetic diversity yam species, we use a phylogenetic diversity (PD) approach that has the advantage to investigate phylogenetic relationships and test hypotheses of species monophyly while alleviating to the problem of ploidy variation within and among species. The Bayesian phylogenetic analysis of 62 accessions from 7 species from three regions of Cameroon showed that most Dioscorea sections were monophyletic, but species within sections were generally non-monophyletic. The wild species D. praehensilis and cultivated D. cayenensis were the species with the highest PD. At the opposite, D. esculenta has a low PD and future studies should focus on this species to properly address its conservation status. We also show that wild species show a stronger genetic structure than cultivated species, which potentially reflects the management of the yam germplasm by farmers. These findings show that phylogenetic diversity is a promising approach for an initial investigation of genetic diversity in a crop consisting of closely related species.
Highlights
One of the main challenges of conservation biology is to cope with the ongoing global biodiversity crisis
The other wild species studied, D. abyssinica and D. praehensilis, are important sources of diosgenin, a chemical used for the commercial synthesis of sex hormones, and corticosteroids that are widely used for antinflammatory, androgenic and contraceptive drugs [41, 42]
Sequence divergence was higher for the rpl32-trnl spacer (0.0–5.0) than for the rbcL region (0.0–2.5) and the same trend was observed for the number of variable characters and parsimony informative characters (Table 1)
Summary
One of the main challenges of conservation biology is to cope with the ongoing global biodiversity crisis. The loss and fragmentation of natural habitats, pollution, invasive species, overexploitation of ecosystems and climate change are dramatically affecting biodiversity [1]. Species extinctions have the potential to decrease the ecological services offered by the ecosystems to humanity, but they result in the loss of a singular genetic heritage constituted since speciation from their ancestral species. This is true of species, and of taxonomic units. Local population extinction and genetic erosion due to fragmentation can have a profound influence on the loss of evolutionary uniqueness
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