A taxonomic revision of the Asian keelback snakes, genus Amphiesma (Serpentes: Colubridae: Natricinae), with description of a new species.

The Asian keelback snakes (genus Amphiesma) are a widely distributed group of Old World natricines, inhabiting a variety of niches and exhibiting significant morphological variation. Recent molecular phylogenies suggest that this genus is not monophyletic, and that additional cryptic diversity is also likely present. We conducted a phylogenetic analysis of the group based on 3162 bp of one mitochondrial gene (Cyt. b) and three nuclear genes (C-mos, Rag1, NT3), sampling 18 species in addition to those sequenced in previous works. All analyses consistently show that Amphiesma consists of three distinct, monophyletic lineages with strong support. We divide Amphiesma into three genera, Amphiesma, Hebius, and Herpetoreas. The genus Amphiesma is monotypic, Herpetoreas contains three species, and Hebius comprises the remaining 39 species. On the basis of a combination of molecular analyses and external morphological comparisons, we describe a new species in the Herpetoreas group from China as H. burbrinki sp. nov. Several other species are shown to be non-monophyletic or contain significant levels of intraspecific genetic diversity. Another Old World natricine genera, Xenochrophis is also found to be non-monophyletic. Our results indicate that further taxonomic revisions are needed in Natricinae, at multiple levels. 

RT-qPCR analysis of dexB and galE gene expression of Streptococcus alactolyticus in Astragalus membranaceus fermentation.

Streptococcus alactolyticus strain FGM, isolated from chicken cecum, was used to increase the extract yield of polysaccharides during Astragalus membranaceus fermentation. It was previously demonstrated that polysaccharides from fermented A. membranaceus by S. alactolyticus had some similar properties to those from A. membranaceus in terms of its ability to help heal hepatic fibrosis in rats and modulate immunopotentiation of broiler chicken. However, methods to increase the yield of the polysaccharides during fermentation of A. membranaceus are not well understood. In this paper, we investigated the involvement of uridine diphosphate (UDP)-glucose 4-epimerase (galE) and glucan-1,6-α-glucosidase (dexB) during A. membranaceus fermentation through real-time reverse transcription quantitative PCR. The galE and dexB genes of S. alactolyticus were cloned by homology-based cloning and the genome walking method for the first time, and the 3D structure of dexB was analyzed by Swiss-PdbViewer 4.0.1 software. The expression of both the galE and dexB genes in A. membranaceus fermentation was studied using the determined ideal reference gene ldh for transcript normalization. The results showed that these two genes were both highly induced and peaked after 12 h of fermentation. The expression level of galE was stepwise increased from 48 to 72 h, while dexB transcripts were markedly increased at 60 h and decreased by 72 h. These data suggested that dexB and galE of S. alactolyticus strain FGM were involved in the regulation of A. membranaceus fermentation and they might play some roles in the increase of polysaccharides.