两种UDP-葡萄糖脱氢酶对透明质酸生物转化的影响

分别从大肠杆菌和化脓链球菌中扩增出编码UDP-葡萄糖脱氢酶基因ecohas B和spyhas B,并将其插入T7表达载体p RX2构建重组质粒p RXEB和p RXSB。在大肠杆菌BL21(DE3)中重组表达,并对经镍柱纯化后的UDP-葡萄糖脱氢酶的酶学性质进行分析。酶学性质研究表明:spy Has B的最适反应温度是30℃,最适p H 10,最适条件下的比活力是12.2 U/mg;eco Has B的最适反应温度是30℃,最适p H 9,最适条件下的比活力是5.55 U/mg。从多杀巴氏杆菌扩增出的透明质酸合成酶基因pmuhas A分别与ecohas B和spyhas B构建共表达载体p BPAEB和p BPASB。将其转化到大肠杆菌BW25113中,经生物转化生产透明质酸(HA),并对转化条件进行了优化。结果表明:重组菌株进行透明质酸转化时,UDP-葡萄糖脱氢酶酶活力越高,稳定性越好,HA产量越高;转化条件优化后,p BPAEB/BW25113和p BPASB/BW25113在摇瓶中的产量分别是1.52和1.70 g/L,比之前报道的提高了2-3倍。     

来源于蓝藻、铜绿微囊藻的尿苷二磷酸葡萄糖脱氢酶基因的克隆和鉴定

以已知的尿苷二磷酸葡萄糖脱氢酶基因的保守区为基础,自行设计一对简并引物,该对引物从形成水华的蓝藻（Synechocystis PCC6803)铜绿微囊藻FACHB 905株(Microcystis aeruginosa FACHB 905)的基因组DNA中扩增到一个476bp的DNA片段。通过TAIL-PCR和连接介导的PCR两种方法分离该片段的侧翼序列,最后得到大小约2．5kb的DNA片段。序列分析揭示其中有一个编码462个氨基酸的开放阅读框,我们将此开放阅读框对应的蛋白命名为Mud。该Mud蛋白的氨基酸序列与蓝藻(73％相同,87％相似)和细菌(Bacillus subtilis)(51％相同,67％相似)的尿苷二磷酸葡萄糖脱氢酶氨基酸序列表现高度的同源性。将该mud基因克隆于p-GEX-4T-1融合表达载体并在大肠杆菌中表达GST—Mud融合蛋白,经过酶活力测定发现,GST—Mud蛋白具有一定的尿苷二磷酸葡萄糖脱氢酶活性。用抗GST-Mud蛋白的多抗对Maeruginosa FACHB 905的胞质蛋白组分进行Western印迹分析,结果显示一条分子量大小约49kD的专一条带,这个分子量与从基因推断出的蛋白分子量大小基本一致。综上所述,我们认为从微囊藻克隆到的Mud蛋白基因是尿苷二磷酸葡萄糖脱氢酶基因,该酶在其他生物如植物和细菌中参与多糖合成,是多糖合成的关键酶之一,而在藻类中对尿苷二磷酸葡萄糖脱氢酶开展研究却是首次报道。     

枯草芽孢杆菌葡萄糖脱氢酶基因的克隆及其序列分析

根据Lampel报道的葡萄糖脱氢酶基因序列设计合成两条引物,以野生型枯草芽孢杆菌染色体DNA为模板,PCR扩增得到含有葡萄糖脱氢酶基因的大约780bp的DNA片段,将其克隆到pUC-T载体中。序列分析表明,克隆得到的葡萄糖脱氢酶基因含有783bp,编码261个氨基酸的蛋白质。得到的基因序列与文献报道的进行比较,其核苷酸同源率为75．5％,编码氨基酸序列的同源率为83．9％。     

透明质酸生产菌溶血素S基因缺失突变菌株的构建及其特性北大核心CSCD

【目的】马链球菌兽疫亚种是工业上生产透明质酸的主要菌种,该菌能产生引起宿主细胞溶血的链球菌溶血素S(streptolysin S,SLS)毒素,因而其产品的安全性一直是人们所担心的问题。本实验的目的就是通过基因敲除的方法构建不产SLS的透明质酸生产工程菌,同时探讨溶血素sag A基因缺失对菌株透明质酸合成和其他毒力因子的影响。【方法】利用温度敏感/自杀性质粒p JR700载体系统,构建马链球菌兽疫亚种sag A基因缺失突变株;通过PCR扩增,溶血平板和SLS含量测定等方法确定sag A基因缺失;采用分光光度、SDS-PAGE和细胞毒性试验等分析方法,对野生菌株和sag A基因缺失突变菌株透明质酸含量、透明质酸分子量、溶血素Hylc、透明质酸分解酶、甘油醛-3-磷酸脱氢酶和菌体表面蛋白等相关毒力因子进行对比研究。【结果】获得了透明质酸产量提高30%而溶血活性极低的马链球菌兽疫亚种sag A基因缺失突变株。该突变株与野生菌株相比较,透明质酸分解酶活性增加而透明质酸相对分子量降低,此外,与毒力相关的表面蛋白含量、溶血素Hylc和甘油醛-3-磷酸脱氢酶活性也显著降低。细胞毒性实验结果表明,野生菌株与sag A基因缺失突变菌株的培养物上清液,对细胞活性的影响存在显著差异。【结论】在马链球菌兽疫亚种中sag A不仅是表达溶血素SLS的基因,同时sag A基因对菌株透明质酸合成、透明质酸分解酶、菌体表面蛋白、溶血素Hylc和甘油醛-3-磷酸脱氢酶等都具有调节作用。     

在兽疫链球菌中表达vgb基因和HA合成基因提高透明质酸产量

透明质酸(HA)是一种在医药及化妆品领域具有广泛应用的天然粘多糖。兽疫链球菌(Streptococcuszooepidemicus)是工业上生产透明质酸的菌种之一。透明颤菌血红蛋白(VHb)具有增强细胞摄氧的作用。对生产透明质酸的兽疫链球菌进行了基因改造:将兽疫链球菌HA的合成基因hasABC以及合成透明颤菌血红蛋白的vgb基因(Vitreoscillahemoglobingene,vgb)分别或同时插入阳性菌表达质粒pEU308中,通过电转化导入兽疫链球菌中。通过一氧化碳(CO)差光谱检测到了VHb的表达。在摇瓶实验中,同时带有hasABC和vgb基因的重组菌比野生菌的透明质酸产量提高了30％。而在发酵罐中,带有这2个基因的重组菌的透明质酸产量达到了6．9g／L,高于重组菌5．5g／L的产量。实验结果表明,vgb基因的存在促进了细胞的生长,hasABC操纵子的过表达增强了透明质酸的合成。首次将VHb导入兽疫链球菌中,获得了表达,并证明其对菌体生长及透明质酸合成有促进作用。通过研究,VHb将可以在阳性菌中获得更广泛的应用。     

噬菌体Ψ297切除酶(xis)基因的克隆和序列分析

目的：克隆噬菌体ψ297切除酶(xis)基因,并对其进行遗传与变异研究。方法：提取埃希氏大肠杆菌O157：H7菌株EH297染色体DNA,采用步移PCR方法寻找目的基因,并通过克隆、亚克隆、DNA测序等分子生物学方法获得切除酶基因,通过序列分析软件对此基因进行分析。结果：克隆获得噬菌体ψ97编码的切除酶基因(xis)的完整序列,它的长度是255bp,编码了一个84个氨基酸组成的蛋白质(xis),将它们的序列与λ噬菌体的切除酶家族的其它成员进行了比较。其结果是噬菌体ψ297的切除酶基因(xis)与噬菌体VT1-Sakai的切除酶基因(xis)只有4个核苷酸的不同,而Xis蛋白与噬菌体VT1-Sakai的Xis蛋白是一样的,与噬菌体933W的Xis蛋白只有47．2％的相似性。结论：噬菌体ψ297编码的切除酶基因(xis)与λ噬菌体的切除酶基因同源。     

来源于蓝藻、铜绿微囊藻的尿苷二磷酸葡萄糖脱氢酶基因的克隆和鉴定

以已知的尿苷二磷酸葡萄糖脱氢酶基因的保守区为基础,自行设计一对简并引物,该对引物从形成水华的蓝藻(Synechocystis PCC6803)铜绿微囊藻FACHB 905株(Microcystis aeruginosa FACHB 905)的基因组DNA中扩增到一个476 bp的DNA片段.通过TAIL-PCR和连接介导的PCR两种方法分离该片段的侧翼序列,最后得到大小约2.5 kb的DNA片段.序列分析揭示其中有一个编码462个氨基酸的开放阅读框,我们将此开放阅读框对应的蛋白命名为Mud.该Mud蛋白的氨基酸序列与蓝藻(73%相同,87%相似)和细菌(Bacillus subtilis)(51%相同,67%相似)的尿苷二磷酸葡萄糖脱氢酶氨基酸序列表现高度的同源性.将该mud基因克隆于p-GEX-4T-1融合表达载体并在大肠杆菌中表达GST-Mud融合蛋白,经过酶活力测定发现,GST-Mud蛋白具有一定的尿苷二磷酸葡萄糖脱氢酶活性.用抗GST-Mud蛋白的多抗对M.aeruginosa FACHB 905的胞质蛋白组分进行Western印迹分析,结果显示一条分子量大小约49 kD的专一条带,这个分子量与从基因推断出的蛋白分子量大小基本一致.综上所述,我们认为从微囊藻克隆到的Mud蛋白基因是尿苷二磷酸葡萄糖脱氢酶基因,该酶在其他生物如植物和细菌中参与多糖合成,是多糖合成的关键酶之一,而在藻类中对尿苷二磷酸葡萄糖脱氢酶开展研究却是首次报道.     

甲基营养菌MP688萄糖脱氢酶基因分离鉴定及性质研究

目的：鉴定甲基营养菌MP688中的葡萄糖脱氢酶基因。方法：对甲基营养菌MP688基因组序列进行比对和分析,找到与已知细菌葡萄糖脱氢酶同源性最高的基因序列mpq_2164,且该基因所编码蛋白经分析具有跨膜结构域。设计51物扩增mpq_2164和缺失跨膜区域序列的s-mpq_2164,将PCR产物克隆到表达载雄pET-15b上,在大肠杆菌BL21中完成异源重组表达,然后通过组氨酸标签镍柱亲和层析纯化,采用DCIP法测定葡萄糖脱氢酶的活力。结果：分离了甲基营养菌MP688中的葡糖糖脱氢酶基因,并实现了s-mpq_2164的高效异源重组表达;MPQ2164的氯基酸序列与已知的葡萄糖脱氢酶相似性很低,但酶活测定结果表明S-MPQ-2164具有很高的葡糖糖脱氢酶活性。结论：MPQ_2164是-个依赖于吡咯喹啉醌的葡萄糖脱氢酶,去掉跨膜结构域有利于该蛋白的异源嘉{大,     

Enhanced hyaluronic acid production in Bacillus subtilis by coexpressing bacterial hemoglobin

Bacillus subtilis strains that can produce hyaluronic acid (HA) were constructed by integrating the HA synthase gene (hasA) and the UDP-glucose dehydrogenase gene of group C Streptococcus (hasB) or of B. subtilis itself (tauD) into the amyE locus of the B. subtilis chromosome. All of the inserted genes were under the control of a strong constitutive vegII promoter of B. subtilis. Although HA production could be achieved by expressing hasA alone, coexpressing hasB or tauD with hasA could enhance HA production at least 2-fold. To replenish the energy consumed for HA biosynthesis, Vitreoscilla hemoglobin (VHb) was coexpressed with the HA-expressing genes. With the expression of VHb, not only the cell concentration was enhanced 25%, but also HA production was further increased by 100%. About 1.8 g/L of HA was obtained by the recombinant strain B. subtilis carrying VHb, hasA, and tauD genes in the expression cassette after 30 h cultivation.     

A Conserved UDP-Glucose Dehydrogenase Encoded outside the hasABC Operon Contributes to Capsule Biogenesis in Group A Streptococcus

Group A Streptococcus (GAS) is a human-specific bacterial pathogen responsible for serious morbidity and mortality worldwide. The hyaluronic acid (HA) capsule of GAS is a major virulence factor, contributing to bloodstream survival through resistance to neutrophil and antimicrobial peptide killing and to in vivo pathogenicity. Capsule biosynthesis has been exclusively attributed to the ubiquitous hasABC hyaluronan synthase operon, which is highly conserved across GAS serotypes. Previous reports indicate that hasA, encoding hyaluronan synthase, and hasB, encoding UDP-glucose 6-dehydrogenase, are essential for capsule production in GAS. Here, we report that precise allelic exchange mutagenesis of hasB in GAS strain 5448, a representative of the globally disseminated M1T1 serotype, did not abolish HA capsule synthesis. In silico whole-genome screening identified a putative HasB paralog, designated HasB2, with 45% amino acid identity to HasB at a distant location in the GAS chromosome. In vitro enzymatic assays demonstrated that recombinant HasB2 is a functional UDP-glucose 6-dehydrogenase enzyme. Mutagenesis of hasB2 alone slightly decreased capsule abundance; however, a ΔhasB ΔhasB2 double mutant became completely acapsular. We conclude that HasB is not essential for M1T1 GAS capsule biogenesis due to the presence of a newly identified HasB paralog, HasB2, which most likely resulted from gene duplication. The identification of redundant UDP-glucose 6-dehydrogenases underscores the importance of HA capsule expression for M1T1 GAS pathogenicity and survival in the human host.     

Demonstration of UDP-glucose dehydrogenase activity in cell extracts of Escherichia coli expressing the pneumococcal cap3A gene required for the synthesis of type 3 capsular polysaccharide.

The gene cluster of Streptococcus pneumoniae coding for the type 3 capsular polysaccharide contains four genes (cap3ABCD). A DNA fragment containing the cap3A gene was amplified by PCR and cloned under the control of a T7 RNA polymerase-dependent promoter. Overexpression of this gene in Escherichia coli resulted both in a 47-kDa protein in the cytoplasm of isopropyl-beta-D-thiogalactopyranoside-induced bacteria and in high levels of UDP-glucose dehydrogenase activity. These data demonstrate, in a direct experimental way, that cap3A encodes the UDP-glucose dehydrogenase of pneumococcus type 3.     

Molecular characterization of cap3A, a gene from the operon required for the synthesis of the capsule of Streptococcus pneumoniae type 3: sequencing of mutations responsible for the unencapsulated phenotype and localization of the capsular cluster on the pneumococcal chromosome.

The complete nucleotide sequence of the cap3A gene of Streptococcus pneumoniae, which is directly responsible for the transformation of some unencapsulated, serotype 3 mutants to the encapsulated phenotype, has been determined. This gene encodes a protein of 394 amino acids with a predicted M(r) of 44,646. Twelve independent cap3A mutations have been mapped by genetic transformation, and three of them have been sequenced. Sequence comparisons revealed that cap3A was very similar (74.4%) to the hasB gene of Streptococcus pyogenes, which encodes a UDP-glucose dehydrogenase (UDP-GlcDH) that catalyzes the conversion of UDP-glucose to UDP-glucuronic acid, the donor substances in the pneumococcal type 3 capsular polysaccharide. Furthermore, a PCR-generated cap3A+ gene restored encapsulation in our cap3A mutants as well as in a mutant previously characterized as deficient in UDP-GlcDH (R. Austrian, H. P. Bernheimer, E.E.B. Smith, and G.T. Mills, J. Exp. Med. 110:585-602, 1959). These results support the conclusion that cap3A codes for UDP-GlcDH. We have also identified a region upstream of cap3A that should contain common genes necessary for the production of capsule of any type. Pulsed-field gel electrophoresis and Southern blotting showed that the capsular genes specific for serotype 3 are located near the genes encoding PBP 2X and PBP 1A in the S. pneumoniae chromosome, whereas copies of the common genes (or part of them) appear to be present in different locations in the genome.     

Cloning and expression studies of the Dunaliella salina UDP-glucose dehydrogenase cDNA.

The enzyme UDP-glucose dehydrogenase (EC 1.1.1.22) converts UDP-glucose to UDP-glucuronate. Plant UDP-glucose dehydrogenase (UGDH) is an important enzyme in the formation of hemicellulose and pectin, the components of primary cell walls. A cDNA, named DsUGDH, (GeneBank accession number: AY795899) corresponding to UGDH was cloned by RT-PCR approach from Dunaliella salina. The cDNA is 1941-bp long and has an open reading frame encoded a protein of 483 amino acids with a calculated molecular weight of 53 kDa. The derived amino acids sequence shows high homology with reported plants UGDHs, and has highly conserved amino acids motifs believed to be NAD binding site and catalytic site. Although UDP-glucose dehydrogenase is a comparatively well characterized enzyme, the cloning and characterization of the green alga Dunaliella salina UDP-glucose dehydrogenase gene is very important to understand the salt tolerance mechanism of Dunaliella salina. Northern analyses indicate that NaCl can induce the expression the DsUGDH.     

Identification and characterization of UDP-glucose dehydrogenase from the hyperthermophilic archaon, Pyrobaculum islandicum

A gene encoding a UDP-glucose dehydrogenase homologue was identified in the hyperthermophilic archaeon, Pyrobaculum islandicum. This gene was expressed in Escherichia coli, and the product was purified and characterized. The expressed enzyme is the most thermostable UDP-glucose dehydrogenase so far described, with a half-life of 10 min at 90 °C. The enzyme retained its full activity after incubating in a pH range of 5.0-10.0 for 10 min at 80 °C. The temperature dependence of the kinetic parameters for this enzyme was examined at 37-70 °C. A decrease in K(m)s for UDP-glucose and NAD was observed with decreasing temperature. This resulted in the enzyme still retaining high catalytic efficiency (V(max)/K(m)) for the substrate and cofactor, even at 37 °C. These characteristics make the enzyme potentially useful for its application at a much lower temperature such as 37 °C than the optimum growth temperature of 100 °C for P. islandicum.     

Characterization of human UDP-glucose dehydrogenase. CYS-276 is required for the second of two successive oxidations

UDP-glucose dehydrogenase (UGDH) catalyzes two oxidations of UDP-glucose to yield UDP-glucuronic acid. Pathological overproduction of extracellular matrix components may be linked to the availability of UDP-glucuronic acid; therefore UGDH is an intriguing therapeutic target. Specific inhibition of human UGDH requires detailed knowledge of its catalytic mechanism, which has not been characterized. In this report, we have cloned, expressed, and affinity-purified the human enzyme and determined its steady state kinetic parameters. The human enzyme is active as a hexamer with values for Km and Vmax that agree well with those reported for a bovine homolog. We used crystal coordinates for Streptococcus pyogenes UGDH in complex with NAD+ cofactor and UDP-glucose substrate to generate a model of the enzyme active site. Based on this model, we selected Cys-276 and Lys-279 as likely catalytic residues and converted them to serine and alanine, respectively. Enzymatic activity of C276S and K279A point mutants was not measurable under normal assay conditions. Rate constants measured over several hours demonstrated that K279A continued to turn over, although 250-fold more slowly than wild type enzyme. C276S, however, performed only a single round of oxidation, indicating that it is essential for the second oxidation. This result is consistent with the postulated role of Cys-276 as a catalytic residue and supports its position in the reaction mechanism for the human enzyme. Lys-279 is likely to have a role in positioning active site residues and in maintaining the hexameric quaternary structure.     

L-(+)-lactate dehydrogenase deficiency is lethal in Streptococcus mutans.

The previously cloned gene for L-(+)-lactate dehydrogenase (LDH) from Streptococcus mutans was mutagenized in vitro. An Escherichia coli transformant which expressed a thermolabile LDH activity was identified. The ldh(Ts) gene was introduced into S. mutans on a suicide vector to create a heterodiploid expressing both wild-type and thermolabile LDH activities. Self-recombinants which had only one ldh gene were isolated. One of these clones expressed only the thermolabile LDH activity. This isolate grew well at 30 degrees C but did not grow at 42 degrees C under a variety of cultivation conditions, thereby proving that LDH deficiency is lethal in S. mutans in the absence of compensatory mutations.