Conformational coupling,bridge helix dynamics and active site dehydration in catalysis by RNA polymerase

Molecular dynamics simulation of Thermus thermophilus (Tt) RNA polymerase (RNAP) in a catalytic conformation demonstrates that the active site dNMP–NTP base pair must be substantially dehydrated to support full active site closing and optimum conditions for phosphodiester bond synthesis. In silico mutant β R428A RNAP, which was designed based on substitutions at the homologous position (Rpb2 R512) of Saccharomyces cerevisiae (Sc) RNAP II, was used as a reference structure to compare to Tt RNAP in simulations. Long range conformational coupling linking a dynamic segment of the bridge α-helix, the extended fork loop, the active site, and the trigger loop–trigger helix is apparent and adversely affected in β R428A RNAP. Furthermore, bridge helix bending is detected in the catalytic structure, indicating that bridge helix dynamics may regulate phosphodiester bond synthesis as well as translocation. An active site “latch” assembly that includes a key trigger helix residue Tt β′ H1242 and highly conserved active site residues β E445 and R557 appears to help regulate active site hydration/dehydration. The potential relevance of these observations in understanding RNAP and DNAP induced fit and fidelity is discussed.     

Phylogenetic diversity and mutational analysis of New Delhi Metallo-β-lactamase (NDM) producing E. coli strains from pediatric patients in Pakistan

The evolution of NDM genes (bla_NDM) in E. coli is accounted for expansive multidrug resistance (MDR), causing severe infections and morbidities in the pediatric population. This study aimed to analyze the phylogeny and mutations in NDM variants of E. coli recovered from the pediatric population. Carbapenem-resistant clinical strains of E. coli were identified using microbiological phenotypic techniques. PCR technique used to amplify the bla_NDM genes, identified on agarose gel, and analyzed by DNA sequencing. The amino acid substitutions were examined for mutations after aligning with wild types. Mutational and phylogenetic analysis was performed using Lasergene, NCBI blastn, Clustal Omega, and MEGA software, whereas PHYRE2 software was used for the protein structure predictions. PCR amplification of the bla_NDM genes detected 113 clinical strains of E. coli with the contribution of bla_NDM-1 (46%), bla_NDM-4 (3.5%), and bla_NDM-5 (50%) variants. DNA sequencing of bla_NDM variants showed homology to the previously described bla_NDM-1, bla_NDM-4, and bla_NDM-5 genes available at GenBank and NCBI database. In addition, the mutational analysis revealed in frame substitutions of Pro60Ala and Pro59Ala in bla_NDM-4 and bla_NDM-5, respectively. The bla_NDM-1 was ortholog with related sequences of E. coli available at GenBank. The phylogenetic analysis indicated that the NDM gene variants resemble other microbes reported globally with some new mutational sites.     

hTNFR1在大肠杆菌中可溶性表达及纯化

将人源肿瘤坏死因子Ⅰ型受体（hTNFR1）基因克隆到pET-22b表达载体,成功构建了重组表达质粒pETH1,电转到Escherichia coli BL21（DE3）表达菌株中进行摇瓶发酵。实现了hTNFR1在大肠杆菌表达系统中的重组表达。但目的蛋白全部以包涵体的形式存在于沉淀中。为了提高hTNFR1在大肠杆菌中的可溶性表达,融合标签和分子伴侣两种策略被实施用于辅助hTNFR1的可溶性表达。结果表明,在hTNFR1的N端融合NusA标签后,hTNFR1的可溶性有一定提高;在NusA-hTNFR1基础上,过表达了7种分子伴侣,筛选出tig分子伴侣对hTNFR1蛋白可溶性表达有明显的促进作用,可溶性表达量约占总量的90％;对优化后的hTNFR1表达系统的可溶性蛋白进行Ni-NTA亲和层析纯化后,TEV蛋白酶酶切去除N端的NusA标签,结合Western blot分析鉴定,获得了大量高纯度的hTNFR1蛋白。研究结果为进一步研究hTNFR1的生理学活性及其在疾病治疗方面的应用奠定了良好基础。     

Overcoming difficulties on synthesis of cardiac troponin-I

Human cardiac troponin-I (cTnI) is one of the most sensitive and specific indicators, used in the diagnosis of myocardial infarction. To produce the protein efficiently, Escherichia coli and Pichia pastoris systems were used. Initial trials for the expression in E. coli were not successful, although different expression vectors with different promoters were tested. This led us to use P. pastoris for the expression. After several trials with two different expression strains of P. pastoris, it was concluded that P. pastoris was also not an optimal expression host for cTnI. Comprehensive analysis of the expression systems indicated that an efficient expression is only possible when the gene is optimized for expression in E. coli. For this purpose, the gene was optimized in-silico, but edited manually afterwards. It was synthesized and cloned into pQE-2 vector. Expression was performed using routine experimental conditions. Thus, cTnI could be efficiently expressed from the optimized gene in E. coli. The expression and purification were practical and may be used for commercial purposes since a total yield of 25µg highly pure protein per milliliter of culture could be obtained. The protein was in its ready-to-use form for many biological applications, including as a standard in diagnostic tests and an antigen for antibody production.     

Phosphatidylethanolamine Deficiency Impairs Escherichia coli Adhesion by Downregulating Lipopolysaccharide Synthesis,Which is Reversible by High Galactose/Lactose Cultivation

As the initiation step of bacterial infection or biofouling, bacterial adhesion on cells or substrates is generally an optimal target for antibacterial design. Phosphatidylethanolamine (PE) is the principal phospholipid in bacteria, and its function in bacterial adhesion remains unclear. In this study, four E. coli strains including two PE-deficient mutants (PE^?PC^? and PE^?PC^+?strains) and two PE-containing wild-type controls (PE?⁺?PC^? strains) were recruited to investigate the influence of PE deficiency on bacterial adhesion. We found that PE deficiency could impair E. coli adhesion on macrophages (human THP-1-derived and mouse RAW264.7 macrophages) or glass coverslips by downregulating lipopolysaccharide (LPS) biosynthesis, which could be reversible by high galactose/lactose but not glucose cultivation. The data imply that PE play important role in bacterial adhesion probably via affecting LPS biosynthesis and suggest that targeting PE biosynthesis is also a potential antibacterial strategy.