枯草芽孢杆菌耐盐突变株proA基因克隆及proBA基因渗透压调节功能研究

利用TaKaRaLAPCRTM试剂盒扩增枯草芽孢杆菌 931 5 1耐盐突变株proA基因的未知下游序列。根据测序结果 ,设计引物 ,克隆出发菌株和突变株全长proBA基因。将出发菌株和突变株的proBA基因分别转化大肠杆菌JM83(proBA- ) ,均能够与其功能互补。SDS PAGE分析其表达产物 ,有两条分子量分别约为 4 0kD和 4 5kD的新蛋白带出现。测定 4种转化子 (分别含有出发菌株和突变株proB基因的大肠杆菌 1 1 2 5 2转化子及proBA基因的大肠杆菌JM83转化子 )的耐盐能力。发现含有突变株proB或proBA基因转化子的耐盐能力 ,均比相应的含有出发菌株proB或proBA基因的转化子高。另外含有出发菌株和突变株的proBA基因转化子的耐盐能力 ,也均比相应的仅含proB基因的转化子高 ,表明枯草芽孢杆菌的ProA比大肠杆菌的ProA更为有效。测定所有JM83转化子胞内自由脯氨酸 ,发现其含量随盐浓度的上升而提高 ,其中含突变菌株proBA基因的转化子提高更为显著     

枯草芽孢杆菌耐盐突变株proA基因克隆proBA基因渗透压调节功能研究

利用TaKaRa LA PCRTM试剂盒扩增枯草芽孢杆菌93151耐盐突变株proA基因的未知下游序列。根据测序结果,设计引物,克隆出发菌株和突变株全长proBA基因。将出发菌株和突变株的proBA基因分别转化大肠杆菌JM83（proBA\+-）,均能够与其功能互补。SDSPAGE分析其表达产物,有两条分子量分别约为40kD和45kD的新蛋白带出现。测定4种转化子（分别含有出发菌株和突变株proB基因的大肠杆菌1.1252转化子及proBA基因的大肠杆菌JM83转化子）的耐盐能力。发现含有突变株proB或proBA基因转化子的耐盐能力,均比相应的含有出发菌株proB或proBA基因的转化子高。另外含有出发菌株和突变株的proBA基因转化子的耐盐能力, 也均比相应的仅含proB基因的转化子高, 表明枯草芽孢杆菌的ProA比大肠杆菌的ProA更为有效。测定所有JM83转化子胞内自由脯氨酸,发现其含量随盐浓度的上升而提高,其中含突变菌株proBA基因的转化子提高更为显著。     

渗透压调节基因proBA的融合表达对大肠杆菌耐高渗胁迫能力的影响

枯草芽孢杆菌 9315 1的渗透压调节基因proB和proA以重叠基因的方式组织 ,但是表达两个单独的蛋白质ProB和ProA。通过引物设计 ,在抗脯氨酸反馈抑制耐盐突变菌株 9315 1 14的proBA基因重叠区引入一个限制性酶切位点 ,分别扩增出proB和proA基因 ,并构建融合的proBA基因。SDS PAGE分析显示有一条新的分子质量约为85kD的蛋白带出现。相对于表达未融合的proB和proA ,proBA融合基因的表达明显提高了宿主菌大肠杆菌JM83胞内游离脯氨酸含量和其耐高渗胁迫能力     

氮离子诱变筛选内切葡聚糖酶高产菌株及其基因突变研究

目的：离子注入枯草芽孢杆菌筛选高产内切葡聚糖酶突变菌株,同时进行其酶活性研究,并克隆该基因,研究离子注入对其诱变效应。方法：低能氮离子重复注入枯草芽孢杆菌,筛选获得1株高产内切葡聚糖酶突变菌株Bac11。DNS法测定酶活性。PCR扩增获得出发菌株Bac01和突变菌株Bac11内切葡聚糖酶基因,并对核酸序列及预测氨基酸序列进行多重比对。结果：突变菌株Bac11内切葡聚糖酶活性从93.33IU提高到381.89IU。多重比对Bac01和Bac11内切葡聚糖酶基因编码区1500bp序列,当中有10个碱基发生突变,预测氨基酸序列中有5个氨基酸残基发生变化,且都在其基因纤维素结合域部分。结论：低能氮离子重复注入对枯草芽孢杆菌内切葡聚糖酶活性及其基因有明显的诱变累加效应。     

枯草芽胞杆菌突变株ZC-7中性蛋白酶催化区域氨基酸突变导致其活力提高

目的：探讨枯草芽胞杆菌突变株ZC-7高产中性蛋白酶的原因。方法：用PCR方法分别扩增突变株ZC-7与出发菌株枯草芽胞杆菌AS1．398产中性蛋白酶的编码基因,测序比较二者基因的不同;在CPHmodels Server网站进行氨基酸序列分析,模拟突变前后中性蛋自酶的二级结构。结果：对比结果显示成熟肽中有5个氨基酸位点发生突变,其中3个位于酶的催化区域内;从预测的二级结构模型上可以看到突变位点所处区域的折叠结构发生细微变化。结论：先前研究中发现枯草芽胞杆菌AS1．398和突变株ZC-7发酵液中的酶蛋白含量基本相同,因此推测高产的原因不是酶量的增加,而是突变的氨基酸使酶与底物结合的部位更加适合催化水解反应,从而提高其比活力。     

枯草芽孢杆菌L-脯氨酸合成途径中glnA、proB、proA基因功能探究

【目的】从基因水平探究枯草芽孢杆菌渗透压调节因子L-脯氨酸合成途径中glnA、proB、proA基因的功能,通过分子改造实现对代谢途径的人工扰动。【方法】从枯草芽孢杆菌WB600出发,通过向胞内引入一系列基因敲除或过表达,分别构建了proB和proA基因过表达的重组菌WB601和WB602、glnA基因缺失的重组菌WB603以及在此基础之上过表达proB基因的重组菌WB604。借助菌株胞外和胞内游离脯氨酸积累的表型分析影响途径的关键节点。【结果】在非胁迫条件下,重组菌WB601和WB602胞外脯氨酸含量分别是原始菌的2.21倍和2.82倍,单位细胞胞外脯氨酸得率分别是原始菌的4.09倍和9.80倍,胞内游离脯氨酸含量分别是原始菌的1.91倍和3.34倍;重组菌WB603胞外脯氨酸含量上升至1221.43 mg/L,是原始菌的6.28倍,单位细胞胞外和胞内游离脯氨酸得率分别为原始菌的9.13倍和3.66倍;而重组菌WB604胞外脯氨酸含量最高达1391.65 mg/L,相比菌株WB603,其胞外脯氨酸含量及单位细胞得率分别提高了13.94%和14.10%,且胞内游离脯氨酸含量提高了32.60%。在5%Na Cl胁迫条件下,重组菌WB601和WB602的胞外脯氨酸含量分别是原始菌的1.94倍和1.54倍,单位细胞胞外脯氨酸得率分别是原始菌的2.15倍和2.19倍;重组菌WB603胞外脯氨酸含量及其单位细胞得率分别是原始菌的4.16倍和7.29倍;相同条件下,相比于重组菌WB603,重组菌WB604的胞外脯氨酸含量及其单位细胞得率分别提高了32.61%和5.54%。此外,实验组菌株的胞内游离脯氨酸含量均高于非胁迫时,并达到相对平衡状态。【结论】proB和proA基因的过表达均能显著提升细胞合成脯氨酸的能力,并且能增强细胞的耐盐性;glnA基因的缺失能增强脯氨酸合成途径,提高脯氨酸的积累;两种效应的正向叠加可进一步提升细胞脯氨酸合成能力。     

短小芽孢杆菌碱性蛋白酶基因启动子的克隆、鉴定及其应用

利用TAIL-PCR(Thermal asymmetric interlaced PCR)从短小芽孢杆菌基因组中扩增到碱性蛋白酶基因编码区上游的启动子片段。对该片段的序列测定和分析表明, 此片段长797 bp, 但与基因表达有关的序列长约390 bp。对启动子片段进行不同长度的缺失突变, 以获得最小的基因启动子片段, 结果表明, 该基因起始密码子上游约160 bp的DNA片段就可以启动基因的表达。将含有该片段的碱性蛋白酶基因WApQ3插入大肠杆菌-芽孢杆菌穿梭质粒载体pSUGV4中, 构建了碱性蛋白酶基因表达质粒pSUBpWApQ3。将该质粒分别转入枯草芽孢杆菌和短小芽孢杆菌中表达, 可在胞外检测到碱性蛋白酶活性, 最高酶活分别为466.5 U/mL和3060 U/mL。     

炭疽芽胞杆菌A16D2株BA2380基因缺失突变株的构建

本课题组早期研究结果表明,炭疽芽胞杆菌BA2380蛋白可能与炭疽芽胞杆菌毒力有关,因而有必要对其功能进行深入研究。选取炭疽芽胞杆菌A16D2株为出发菌株,以其BA2380基因为目的缺失基因,参照A16D2株基因组序列及质粒pSET4s序列,利用软件设计上下游同源臂及抗性基因引物,用本实验室改造的“Golden Gate”克隆方法将3个片段同时连入温敏型穿梭载体pKMBK中(本实验室构建的受体质粒),从而构建基因打靶质粒。将该基因打靶质粒导入炭疽芽胞杆菌A16D2感受态细胞中,利用同源重组原理,筛选获得炭疽芽胞杆菌A16D2 BA2380基因缺失突变株,并对其进行验证。结果验证了本课题组构建的“Golden Gate”克隆体系进行多片段克隆的高效性,也为后续探索其基因功能奠定了基础。     

枯草杆菌碱性蛋白酶Ki 2基因的序列测定及M222A定点突变

含有枯草杆菌碱性蛋白酶Ｋｉ-２基因的１.９ｋｂＤＮＡ片段用限制酶切成几个小片段,将这些片段分别插入Ｍ１３ｍｐ１８或Ｍ１３ｍｐ１９中,用通用测序引物测得全序列。所得全序列与蛋白酶Ｅ相比较,在结构基因部分仅有８个碱基不同,由此而导致两个氨基酸的差异。此１.９ｋｂ的片段插入枯草杆菌大肠杆菌穿梭质粒Ｐｂｅ-２,得到的重组质粒转化蛋白酶缺陷型的枯草芽孢杆菌ＤＢ１０４,结果表明枯草杆菌碱性蛋白酶Ｋｉ-２基因在ＤＢ１０４中能利用自身的调控元件表达并分泌到胞外。将Ｋｉ-２蛋白酶的２２２位甲硫氨酸突变成丙氨酸,突变后的Ｋｉ-２蛋白酶具有抗氧化性,但比活性比野生型的约低１倍     

苏云金芽孢杆菌芽孢萌发相关基因gerM的克隆及功能研究

依照蜡状芽孢杆菌gerM基因的保守序列设计引物,从苏云金芽孢杆菌中扩增出640bp的DNA片段。以此为探针,从苏云金芽孢杆菌部分基因组酶切文库中成功地克隆到了一个4·5kb的DNA片段。序列分析表明,该片段包含一个完整的开放阅读框,其预测的编码产物与枯草芽孢杆菌GerM蛋白具有很高的同源性,将该基因命名为gerM。RT-PCR分析表明,gerM基因仅在芽孢形成的过程中表达。通过同源重组的策略构建了gerM基因的阻断突变株。研究表明,gerM基因的破坏影响苏云金芽孢杆菌芽孢萌发的速率和比例。     

Mutations in the Corynebacterium glutamicum proline biosynthetic pathway: a natural bypass of th proA step.

Two chromosomal loci containing the Corynebacterium glutamicum ATCC 17965 proB and proC genes were isolated by complementation of Escherichia coli proB and proC auxotrophic mutants. Together with a proA gene described earlier, these new genes describe the major C. glutamicum proline biosynthetic pathway. The proB and proA genes, closely linked in most bacteria, are in C. glutamicum separated by a 304-amino-acid open reading frame (unk) whose predicted sequence resembles that of the 2-hydroxy acid dehydrogenases. C. glutamicum mutants that carry null alleles of proB, proA, and proC were constructed or isolated from mutagenized cultures. Single proC mutants are auxotrophic for proline and secrete delta1-pyrroline-5-carboxylate, which are the expected phenotypes of bacterial proC mutants. However, the phenotypes or proB and proA mutants are unexpected. A proB mutant has a pleiotropic phenotype, being both proline auxotrophic and affected in cell morphology. Null proA alleles still grow slowly under proline starvation, which suggests that a proA-independent bypass of this metabolic step exists in C. glutamicum. Since proA mutants are complemented by a plasmid that contains the wild-type asd gene of C. glutamicum, the asd gene may play a role in this bypass.     

Identification of a mutation that relieves gamma-glutamyl kinase from allosteric feedback inhibition by proline

A 1.75-kb DNA fragment containing the entire Escherichia coli proB+ gene has been sequenced. The proB locus encodes the structural gene for gamma-glutamyl kinase (GK), the enzyme responsible for the first step in proline biosynthesis, and the primary regulatory point of the pathway. We have previously reported the nucleotide (nt) sequence of a mutant proB gene isolated from an E. coli strain resistant to the toxic analog of proline, 3,4-dehydro-DL-proline (DHP). This mutant gene encodes a GK which is refractory to allosteric feedback inhibition by proline (DHPR). Comparison of the proB+ and DHPR proB sequences revealed a single base difference, an A-T to C-G transversion localized at nt position 428 within the amino acid (aa) coding region of proB. This mutation predicts an aa change from glutamic acid in the wild-type (wt) enzyme to alanine in the DHPR enzyme.     

Analysis of the Escherichia coli proBA locus by DNA and protein sequencing

A 2.9 kb DNA fragment carrying the Escherichia coli proBA region, which encodes the first two enzymes of the proline biosynthetic pathway, was subcloned onto an expression plasmid carrying both the bacteriophage lambda PL promoter (lambda PL) and the lambda gene encoding a thermolabile cI repressor protein (cI857). Derepression of the lambda PL promoter by thermal inactivation of the cI857 repressor protein resulted in the simultaneous overproduction of the proB (gamma-glutamyl kinase) and proA (gamma-glutamyl phosphate reductase) gene products. Nucleotide sequence analysis of the proBA locus allowed gene assignments consistent with the NH2 and COOH-terminal analyses and amino acid compositions of homogeneous preparations of the proB and proA proteins. The contiguous nature of the proB and proA genes suggests that the two genes constitute an operon in which proB precedes proA.     

Identification and disruption of the proBA locus in Listeria monocytogenes: role of proline biosynthesis in salt tolerance and murine infection

Intracellular accumulation of the amino acid proline has previously been linked to the salt tolerance and virulence potential of a number of bacteria. Taking advantage of the proBA mutant Escherichia coli CSH26, we identified a listerial proBA operon coding for enzymes functionally similar to the glutamyl kinase (GK) and glutamylphosphate reductase (GPR) enzyme complex which catalyzes the first and second steps of proline biosynthesis in E. coli. The first gene of the operon, proB, is predicted to encode GK, a 276-residue protein with a calculated molecular mass of 30.03 kDa and pl of 5.2. Distal to the promoter and overlapping the 3' end of proB by 17 bp is proA, which encodes GPR, a 415-residue protein with a calculated molecular mass of 45.50 kDa (pl 5.3). Using this information, we created a chromosomal deletion mutant by allelic exchange which is auxotrophic for proline. This mutant was used to assess the contribution of proline anabolism to osmotolerance and virulence. While inactivation of proBA had no significant effect on virulence in mouse assays (either perorally or intraperitoneally), growth at low (2 to 4% NaCl) and high (>6% NaCl) salt concentrations in complex media was significantly reduced in the absence of efficient proline synthesis. We conclude that while proline biosynthesis plays little, if any, role in the intracellular life cycle and infectious nature of Listeria monocytogenes, it can play an important role in survival in osmolyte-depleted environments of elevated osmolarity.     

Nucleotide sequence of a mutation in the proB gene of Escherichia coli that confers proline overproduction and enhanced tolerance to osmotic stress

We determined the nucleotide (nt) sequence of a mutation that confers proline overproduction and enhanced tolerance of osmotic stress on bacteria. The mutation, designated as proB74, is an allele of the Escherichia coli proB gene which results in a loss of allosteric regulation of the protein product, gamma-glutamyl kinase. Our sequencing indicated that the proB74 mutation is a substitution of an A for a G at nt position 319 of the coding strand of the gene, resulting in a change of an aspartate to an asparagine at amino acid (aa) residue 107 of the predicted protein product. Rushlow et al. [Gene 39 (1984) 109-112] determined that another proB mutation (designated as DHPR), that resulted in a loss of allosteric inhibition by proline of the E. coli gamma-glutamyl kinase, was due to a substitution of an alanine for a glutamate at aa residue 143. Therefore, even though both the DHPR and the proB74 mutations caused a loss of allosteric inhibition of gamma-glutamyl kinase, they are due to different amino acid substitutions.     

Expression of Bacillus subtilis proBA genes and reduction of feedback inhibition of proline synthesis increases proline production and confers osmotolerance in transgenic Arabidopsis

Proline accumulation has been shown to correlate with tolerance to drought and salt stresses in plants. We attempt to introduce the wild-type, mutant, and fusion proBA genes derived from Bacillus subtilis into Arabidopsis thaliana under the control of a strong promoter cauliflower mosaic virus 35S (CaMV35S). The transgenic plants produced higher level of free proline than control and the overproduction of proline resulted in the increased tolerance to osmotic stress in transgenic plants. Besides, the mutation in proBA genes, which were proved to lead gamma-glutamyl kinase (gamma-GK) reduces sensitivity to the end-product inhibition and the fusion of proB and proA also result in increasing proline production and confer osmotolerance in transgenic lines.