Abstract
The pepper-bark tree (Warburgia salutaris) is one of the most highly valued medicinal plant species worldwide. Native to southern Africa, this species has been extensively harvested for the bark, which is widely used in traditional health practices. Illegal harvesting coupled with habitat degradation has contributed to fragmentation of populations and a severe decline in its distribution. Even though the species is included in the IUCN Red List as Endangered, genetic data that would help conservation efforts and future re-introductions are absent. We therefore developed new molecular markers to understand patterns of genetic diversity, structure, and gene flow of W. salutaris in one of its most important areas of occurrence (Mozambique). In this study, we have shown that, despite fragmentation and overexploitation, this species maintains a relatively high level of genetic diversity supporting the existence of random mating. Two genetic groups were found corresponding to the northern and southern locations. Our study suggests that, if local extinctions occurred in Mozambique, the pepper-bark tree persisted in sufficient numbers to retain a large proportion of genetic diversity. Management plans should concentrate on maintaining this high level of genetic variability through both in and ex-situ conservation actions.
Highlights
The pepper-bark tree (Warburgia salutaris) is one of the most highly valued medicinal plant species worldwide
From the three sampling areas of W. salutaris 156 alleles were found in the 48 individuals sampled, being the number of alleles higher in Lebombo Mountains (LM) than in the other two areas (Table 2)
Observed and expected heterozygosis had similar average values in LM and Tembe River (TR) being slightly lower in Futi Corridor (FC)
Summary
The pepper-bark tree (Warburgia salutaris) is one of the most highly valued medicinal plant species worldwide. Native to southern Africa, this species has been extensively harvested for the bark, which is widely used in traditional health practices. The importance of phylogenetic data, genetic diversity, and population structure analyses to characterize the biodiversity of wild species has been well-established in numerous studies (e.g.35–39). Microsatellites (Single Sequence Repeats, SSR) are amongst the most efficient and widely used markers for these studies as they are codominant and highly polymorphic loci[40] These markers are species specific, the increasing accessibility to next-generation s equencing[41] has enabled the development of SSRs for the so-called orphan, neglected or wild crop relative species (e.g.42–45), sequencing large plant genomes still remains a challenge[46]
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