Diversity of the T4-like Myoviruses Community in Response to Salinity in Saline Lakes of the Qinghai-Tibetan Plateau

1 Introduction Viruses are the most abundant biological entities on Earth.They can influence the succession of individual microbial populations,biogeochemical cycles of C/N and,ultimately,microbial community structure through killing

Recombination of T4-like Phages and Its Activity against Pathogenic Escherichia coli in Planktonic and Biofilm Forms

The increasing emergence of multi-drug resistant Escherichia coli(E.coli)has become a global concern,primarily due to the limitation of antimicrobial treatment options.Phage therapy has been considered as a promising alternative for treating infections caused by multi-drug resistant E.coli.However,the application of phages as a promising antimicrobial agent is limited by their narrow host range and specificity.In this research,a recombinant T4-like phage,named WGqlae,has been obtained by changing the receptor specificity determinant region of gene 37,using a homologous recombination platform of T4-like phages established by our laboratory previously.The engineered phage WGqlae can lyse four additional hosts,comparing to its parental phages WG01 and QL01.WGqlae showed similar characteristics,including thermo and pH stability,optimal multiplicity of infection and one-step growth curve,to the donor phage QL01.In addition,sequencing results showed that gene 37 of recombinant phage WGqlae had genetically stable even after 20 generations.In planktonic test,phage WGqlae had significant antimicrobial effects on E.coli DE192 and DE205 B.The optical density at 600 nm(OD600)of E.coli in phage WGqlae treating group was significantly lower than that of the control group(P\0.01).Besides,phage WGqlae demonstrated an obvious inhibitory effect on the biofilm formation and the clearance of mature biofilms.Our study suggested that engineered phages may be promising candidates for future phage therapy applications against pathogenic E.coli in planktonic and biofilm forms.

池塘养殖条件下牙鲆(Paralichthys olivaceus)甲状腺轴和生长轴关键激素的变化规律

通过统计学、酶联免疫学等方法研究3个池塘中养殖牙鲆(Paralichthys olivaceus)的生长状况、血清四碘甲状腺素(T4)和三碘甲状腺原氨酸(T3)、生长激素(GH)、类胰岛素生长因子-I(IGF-Ⅰ)和温度的周年变化规律。结果显示,在365 d的养殖过程中,3个池塘牙鲆体重和体长持续增长且体重日增长率和体长日增长率在温度较高的夏末秋初出现较高值。3个池塘牙鲆血清中T3、T4含量变化整体趋势一致,血清T4浓度在夏末出现最高值,T3浓度在秋初出现最高值,滞后于T4。IGF-I水平最高值出现在温度较高的夏末、秋初滞后于GH最高值夏初。牙鲆血清中T3、T4、GH和IGF-I 4种激素含量变化和生长率变化规律大体一致,呈现明显的周年变化规律。

一株宽宿主谱裂解性大肠杆菌噬菌体的进化分析

裂解性噬菌体能够特异性裂解细菌,本研究分析了一株从自然界中分离的宽宿主谱裂解性大肠杆菌噬菌体的种属和进化关系。前期用Adams双层平板琼脂法从猪场污水中分离纯化出一株裂解性噬菌体v B_Eco M_JS09,裂解谱分析能够裂解禽致病性大肠杆菌和产肠毒素大肠杆菌。扩增分析gene18、gene 23序列,并根据gp18和gp23氨基酸序列构建系统进化树,分析JS09的遗传进化关系。结果表明噬菌体v B_Eco M_JS09基因组为ds DNA,属于有尾噬菌体目、肌尾噬菌体科、T4-like噬菌体、T-evens亚群。其gp18氨基酸序列与大肠杆菌噬菌体RB69同源性最高,为100%;gp23氨基酸序列与大肠杆菌T4噬菌体同源性最高为96%。该结果为禽致病性大肠杆菌和产肠毒素大肠杆菌的防控提供了生物学基础。

饲料蛋白对翘嘴鲌生长和内分泌激素的影响

选择健康的翘嘴鲌(Culter alburnus)为试验鱼,以红鱼粉为蛋白源,配制5个蛋白水平的等能、等必需氨基酸(EAA)平衡关联度的半精制饲料,又以豆粕替代鱼粉,大豆蛋白分别替代不同水平的鱼粉蛋白,配制5个EAA关联度的等蛋白、等能的半精制饲料,探讨饲料蛋白对鱼类生长和内分泌激素等的影响。结果表明:饲料蛋白水平对翘嘴鲌的特定增重率(SGR)具有显著影响(p<0.05),40.89%饲料蛋白组的SGR显著高于31.04%、35.51%饲料蛋白组(p<0.05),但与46.62%和50.33%饲料蛋白组没有显著性差异(p>0.05)。血清T3水平与饲料蛋白水平正相关(p<0.05)。血清GH水平与饲料蛋白水平和生长负相关(p<0.05),血清IGF-I水平与饲料蛋白水平和生长正相关(p<0.05)。适宜蛋白水平通过提高翘嘴鲌血清T3和IGF-I的水平来调控生长。当大豆蛋白分别替代54.0%的鱼粉蛋白时,翘嘴鲌的SGR与对照组差异显著(p<0.05)。翘嘴鲌血清T3与饲料大豆蛋白对鱼粉蛋白的替代量负相关(p<0.05)。40.5%和54.0%替代组的血清GH显著高于对照组(p<0.05),且与饲料中豆粕对鱼粉替代水平正相关(p<0.01),与生长负相关(p<0.05)。血清IGF-I与饲料中大豆蛋白对鱼粉蛋白替代量负相关(p<0.05),与生长正相关(p<0.05)。大豆蛋白的替代亦通过对内分泌激素的影响来调控生长。

肌尾噬菌体科T4类噬菌体的研究进展

噬菌体是一种能够裂解并杀死细菌的病毒,目前其作为鉴定细菌工具、应用于细菌分型及研发新型抗菌生物制剂等已成为研究热点。在肌尾噬菌体科中的T4类噬菌体属是现代遗传学和分子生物学的主要模型系统,对T4类噬菌体进行深入研究更具重要意义。本文从T4类噬菌体的分类,形态特征,与宿主的作用模式,以及从其应用及生物学意义方面进行综述,以期对T4类噬菌体有更深入了解。

一株新分离的肠杆菌噬菌体的快速遗传鉴定及其宿主识别基因的快速克隆(英文)

以大肠杆菌8099为宿主自医院污水中分离出一株肠杆菌噬菌体IME08,其遗传物质经RNA酶、DNA酶处理证实其为DNA,用限制性内切酶处理该DNA证实其为双链DNA。利用随机引物PCR技术扩增并克隆该噬菌体基因组的随机片段,经测序后同源比对,判断该噬菌体是一株新的T4-like噬菌体。根据4株T4-like噬菌体(T4,JS98,T2及K3)宿主识别基因(g37)5'端的高度保守序列,采用随机PCR与巢式PCR结合的"基因组跳跃"策略快速克隆出了该噬菌体的宿主识别基因g37和g38。