Phylogeography of Paris poliphylla var. yunnanensis based on chloroplast gene trnL-trnF sequences / 中国中药杂志

Phylogeography is a research hotspot in the field of the genetic diversity and core germplasm construction of endangered rare plants. Paris polyphylla var. yunnanensis is a rare plant species mainly distributed in China. Wild individuals have been overexploited for the last few decades because of increasing demand for such medicines. Therefore, it is great significance to study the phylogeography of P. poliphylla var. yunnanensis based on chloroplast gene trnL-trnF sequences. In this study, chloroplast genes trnL-trnF were used in the phylogeography analysis of 15 wild and 17 cultivated populations of P. polyphylla var. yunnanensis. This study revealed that based on the results of neutrality tests and mismatch analysis, the rapid expansion of wild population has not been detected in P. polyphylla var. yunnanensis. After aligning and sorting the obtained cpDNA sequences, a total of 15 haplotypes were detected in all 32 populations. One haplotype was unique to the wild population, and 5 haplotypes were unique to the cultivated population. It can be seen that the haplotype richness of cultivated population was higher than that of wild population. The wild populations of P. polyphylla var. yunnanensis were divided into two groups according to evolutionary relationship of haplotypes and distribution map of haplotypes. The haplotype of branch Ⅰ was mainly distributed in Guizhou, and the haplotype of branch Ⅱ was located in Yunnan and Huidong, Sichuan. Therefore, it's speculated that Guizhou and the west Yunnan region may be glacial refuge in the evolutionary history of wild populations of P. polyphylla var. yunnanensis, and in order to protect the wild resources more effectively, wild populations of P. polyphylla var. yunnanensis in these two areas should be included in the protection zone.

African elephant genetics: enigmas and anomalies

During the last two decades, our understanding of the genetics of African elephant populations has greatly increased. Strong evidence, both morphological and genetic, supports recognition of two African elephant species: the savanna elephant (Loxodonta africana) and the forest elephant (L. cyclotis). Among elephantids, phylogeographic patterns for mitochondrial DNA are highly incongruent with those detected using nuclear DNA markers, and this incongruence is almost certainly due to strongly male-biased geneflow in elephants. As our understanding of elephant population genetics has grown, a number of observations may be considered enigmatic or anomalous. Here, several of theseare discussed. (i) There are a number of within-species morphological differences purported to exist among elephants in different geographic regions, which would be difficult to reconcile with the low genetic differentiation among populations. (ii) Forest elephants have a higher effective population size than savanna elephants, with nuclear genetic markersmuch more diverse in the forest elephants than savanna elephants,yet this finding would need to be reconciled with thelife history of the two species. (iii) The savanna and forest elephants hybridize and produce fertile offspring, yet full genome analysis of individuals distant from the hybrid zone suggests that gene flow has been effectively sterilized for atleast ∼500,000 years. (iv) There are unexplored potentialramifications of the unusual mito–nuclear patterns among elephants. These questions are considered in light of highmale and low female dispersal in elephants, higher variance of reproductive success among males than females, and of habitat changes driven by glacial cycles and human activity