盐生盐杆菌DNA 片段RM07的-35、-10区缺失分析

RM07DNA片段分离自嗜盐古菌——盐生盐杆菌R1,该片段不仅在嗜盐古菌内具有启动子功能,而且在大肠杆菌中也具有启动子活性。序列分析表明其上确实含有细菌启动子的-35、-10保守区。进一步通过缺失分析证实该片段就是在大肠杆菌中具启动功能的DNA片段：仅含-10区而缺失-35区的RM07a片段基本上无启动活性;而含-35和-10区的0．1kb片段RM07b具有高于RM07的启动活性。研究结果还表明,RM07片段在大肠杆菌中的启动活性是受环境因素调节的,尤其是对氯化钠浓度的提高具有明显的相关性。因此RM07片段有可能成为构建双功能表达载体的新启动子资源,同时对进一步揭示古菌的融合特征及水平基因转移具有特殊意义。     

嗜盐古菌启动子DNA片段的功能检测

将来源于嗜盐古菌染色体DNA的启动子片段RM07或RM13插入到启动子探针载体pYLZ_2的报告基因lacZ之前,通过β_半乳糖苷酶酶活性的检测,进一步确证RM07和RM13片段在大肠杆菌(Escherichia coli)中的启动功能。同时用微量热技术检测了大肠杆菌DH5α及其重组菌株在LB培养基中37℃生长过程的热输出功率。T2(pYLZ_2)、TE07(pYL726)、TE07_2(pYL702)、TE131(pYL131)和TE132(pYL132)菌株的生长速率分别比大肠杆菌DH5α降低了6.5%、11%4、1.1%4、7.5%和42.7%。当启动子启动了基因表达时,菌株的生长速率显著降低,热力学参数与酶活性检测结果有较好的一致性。微量热结果表明基因的表达比质粒DNA的复制过程需要消耗更多的能量,对细菌的生理代谢有较大改变。微量热技术为检测基因的表达和转录调控提供了新的方法和思路。     

盐生盐杆菌DNA片段RM07的-35、-10区缺失分析*

RM0 7DNA片段分离自嗜盐古菌———盐生盐杆菌R1 ,该片段不仅在嗜盐古菌内具有启动子功能 ,而且在大肠杆菌中也具有启动子活性。序列分析表明其上确实含有细菌启动子的 35、 1 0保守区。进一步通过缺失分析证实该片段就是在大肠杆菌中具启动功能的DNA片段 :仅含 1 0区而缺失 35区的RM0 7a片段基本上无启动活性 ;而含 35和 1 0区的0 1kb片段RM0 7b具有高于RM0 7的启动活性。研究结果还表明 ,RM0 7片段在大肠杆菌中的启动活性是受环境因素调节的 ,尤其是对氯化钠浓度的提高具     

具有真细菌基因启动子活性的盐生盐杆菌质粒DNA片段

利用大肠杆菌启动子探测质粒ｐＫＫ２３２－８为载体、用两组限制性内切酶ＢａｍＨＩ－ＳａｌＩ和ＨｉｎｄⅢ－ＳａｌＩ分别消化盐生盐杆菌Ｊ７（Ｈａｌｏｂａｃｔｅｒｉｕｍｈａｌｏｂｉｕｍ）的质粒ｐＨＨ２０５,在体外进行重组,转化Ｅ．ｃｏｌｉＨＢ１０１感受态细胞,在含氨苄青霉素和氯霉素的选择平板上筛选转化子,并从随机挑选的２０株转化子中,获得抗氯霉素水平达到１１０μｇ／ｍｌ的转化子Ｔ１和Ｔ２,所含重组质粒分别被命名为ｐＪＨ和ｐＪＢ。经限制性酶切分析及杂交分析表明,ｐＪＨ质粒上插入了一段来源于ｐＨＨ２０５质粒的ＤＮＡ片段,其大小为８００ｂｐ左右。通过重新转化实验进一步表明,该ＤＮＡ片段在大肠杆菌中具有启动子功能,从而证明,在古细菌（盐生盐杆菌）的质粒ＤＮＡ中存在具有真细菌（大肠杆菌）基因启动子活性的ＤＮＡ片段。     

谷氨酸棒杆菌/大肠杆菌穿梭型启动子探测载体构建

从质粒pXZ10145和pUC19出发,构建了一个谷氨酸棒杆菌/大肠杆菌穿梭载体pAK6。pAK6的大小为5684bp,带有卡那霉素和氨苄青霉素抗性选择标记,以及多克隆位点。在pAK6基础上,构建了以氯霉素乙酰转移酶为报告基因的启动子探测载体pAKC6,pAKC6的大小为6474bp。采用鸟枪法,将经Sau3AI消化的谷氨酸棒杆菌基因组片段连入pAKC6;根据谷氨酸棒杆菌对氯霉素的抗性,从中分离出两个具有启动子功能的插入片段。通过测定报告基因氯霉素乙酰转移酶的活性,对两个启动子片段在谷氨酸棒杆菌中的强度进行了初步的判断;测序后,用启动子预测软件对其结构进行了预测,证实了启动子序列的存在。     

嗜盐古菌R1中与真核同源基因rad25启动子的序列分析和启动活性研究

在盐生盐杆菌(Halobacterium halobium)R1中分析了真核同源基因rad25的转录,分析了rad25同源基因启动子片段的序列特征,用β_半乳糖苷酶基因(bgaH)为报告基因,利用启动子探针检测技术验证了rad25同源基因启动子片段在嗜盐古生菌WFD11中的启动功能;缺失分析进一步确认了rad25同源基因启动子具有嗜盐古菌启动子典型特征。从启动子和转录水平上证明盐生盐杆菌R1中真核同源基因rad25存在生物学功能,推测其可能在核苷酸切除修复(NER)起作用。     

胰蛋白酶抑制剂KSTI3基因新型真核表达载体的构建及其在盐藻中的表达

应用PCR技术扩增Nos基因、 CaMV35S 启动子片段和氯霉素抗性基因 Cat ,并与胰蛋白酶抑制剂 KSTI3 基因连接,构建真核表达载体pMDCKN-Cat。DNA序列分析结果表明:表达载体中的胰蛋白酶抑制剂 KSTI3 基因、启动子 CaMV35S 、终止子 Nos 和氯霉素抗性基因 Cat 与已知序列完全一致。采用LiAc/PEG介导法将质粒pMDCKN-Cat转化至盐藻细胞中,通过氯霉素抗性基因筛选和PCR鉴定获得转基因盐藻细胞。经Western blotting检测,在硝酸纤维素膜上出现清晰的条带,分子量为20.1kDa,证明胰蛋白酶抑制剂 KSTI3 基因在盐藻中得到成功表达。     

极端嗜盐古菌质粒pSCM201衍生穿梭表达载体的构建及应用

摘要：【目的】利用有自主知识产权的嗜盐古菌θ型复制质粒和启动子,构建在极端嗜盐古菌模式菌株西班牙盐盒菌（Haloarcula hispanica）中方便使用、功能完善的基因表达载体。【方法】以pSCM201的最小复制子为基础,通过引入莫维诺林抗性基因,大肠杆菌质粒复制子以及氨苄抗性基因,构建了一个新的嗜盐古菌-大肠杆菌穿梭载体。利用定点突变和末端补平法依次将其中多余的酶切位点去除后,再添加hsp5启动子核心序列、人工合成的多克隆位点以及蛋白纯化标签His?Tag等重要元件成功构建了嗜盐古菌表达载体pSCM307。将报告基因bgaH插入到该载体的多克隆位点中并转化H. hispanica AS2049,通过X-gal平板筛选和β-半乳糖苷酶酶活实验检测pSCM307的表达能力。【结果】pSCM307具有独立的自主复制能力,其多克隆位点方便实用,报告基因bgaH在hsp5启动子控制下实现了高效表达。【结论】成功构建了嗜盐古菌领域中第一个方便使用的基因表达载体。     

杜氏盐藻GAPDH cDNA的克隆鉴定及其启动子功能表达载体的构建

根据藻类甘油醛3-磷酸脱氢酶(Glyceraldehyde-3-phosphate dehydrogenase,GAPDH)氨基酸高度保守序列设计简并引物,采用5',3'-RACE和巢式PCR的方法,得到了杜氏盐藻(Dunaliella salina)GAPDH cDNA全长序列.序列同源性比较和进化树等生物信息学分析结果表明,根据获得的盐藻GAPDH的核酸序列推导的氨基酸序列与其他已知物种的GAPDH有较高的同源性.定向克隆于原核表达载体的盐藻GAPDH cDNA在大肠杆菌中以融合蛋白的形式得到了高效表达,并成功构建了由盐藻GAPDH基因启动子驱动的cat(氯霉素乙酰转移酶)基因表达载体pUCGCat,为进一步研究杜氏盐藻GAPDH基因和启动子功能奠定了试验基础.     

核基质结合区提高报告基因在稳定转化的杜氏盐藻中的表达

前期的研究从杜氏盐藻（Dunaliella salina）中分离出一核基质结合区（matrix attachment region,MAR）片段——DSM1.实验证实,它在体外能与核基质结合且具有MAR的典型特征.为研究其在转基因盐藻中的作用,构建了RbcS启动子驱动、氯霉素乙酰转移酶（chloramp henicol acetyltransferase,CAT）基因为报告基因及表达盒两侧含DSM1 MAR的表达载体.电击法转化盐藻,随机挑选20株稳定转化的盐藻藻株,分析CAT酶活性.结果表明,在稳定转化的盐藻细胞中,MAR能使报告基因CAT的表达水平比对照藻株提高1-5倍,不同藻株之间个体表达的差异性也有所降低     

Identification and localization of 3-phenylcatechol dioxygenase and 2-hydroxy-6-oxo-6-phenylhexa-2,4-dienoate hydrolase genes of Pseudomonas putida and expression in Escherichia coli

The bphC and bphD genes of Pseudomonas putida involved in the catabolism of polychlorinated biphenyls or biphenyl were identified, localized, and studied for expression in Escherichia coli. This was achieved by cloning a 2.4-kilobase (kb) DNA fragment of recombinant cosmid pOH101 into HindIII site of pUC plasmids downstream of a lacZ promoter and measuring the enzyme activities of 3-phenylcatechol dioxygenase (3-PDase; a product of bphC) and the meta-cleavage product 2-hydroxy-6-oxo-6-phenylhexa-2,4-dienoate hydrolase (a product of bphD). The amount of 3-PDase produced in E. coli was about 20 times higher than that of the enzyme produced by the parent, P. putida. Determination of expression of the bphC and bphD genes through their own promoter sequences or by using the lacZ promoter of pUC plasmids was done by cloning the DNA that encodes bphC and bphD genes in a HindIII site of a promoter selection vector (pKK232-8) upstream of the gene for chloramphenicol acetyltransferase (CAT). The recombinant plasmid (pAW787) constructed by inserting the 2.4-kb DNA in pKK232-8 expressed both 3-PDase and CAT activities. Another hybrid construct (pAW786) in which the DNA insert was cloned in the opposite orientation lacked CAT activity but produced normal amounts of 3-PDase activity. On the basis of these results, we suggest that the bphC and bphD genes were expressed by using promoter sequences that are independent of the promoter that expresses CAT activity in E. coli. The locations of the bphC and bphD genes were determined by insertional inactivation of the open reading frames of structural genes bphC and bphD by Tn5 mutagenesis.(ABSTRACT TRUNCATED AT 250 WORDS)     

Identification and localization of 3-phenylcatechol dioxygenase and 2-hydroxy-6-oxo-6-phenylhexa-2,4-dienoate hydrolase genes of Pseudomonas putida and expression in Escherichia coli.

The bphC and bphD genes of Pseudomonas putida involved in the catabolism of polychlorinated biphenyls or biphenyl were identified, localized, and studied for expression in Escherichia coli. This was achieved by cloning a 2.4-kilobase (kb) DNA fragment of recombinant cosmid pOH101 into HindIII site of pUC plasmids downstream of a lacZ promoter and measuring the enzyme activities of 3-phenylcatechol dioxygenase (3-PDase; a product of bphC) and the meta-cleavage product 2-hydroxy-6-oxo-6-phenylhexa-2,4-dienoate hydrolase (a product of bphD). The amount of 3-PDase produced in E. coli was about 20 times higher than that of the enzyme produced by the parent, P. putida. Determination of expression of the bphC and bphD genes through their own promoter sequences or by using the lacZ promoter of pUC plasmids was done by cloning the DNA that encodes bphC and bphD genes in a HindIII site of a promoter selection vector (pKK232-8) upstream of the gene for chloramphenicol acetyltransferase (CAT). The recombinant plasmid (pAW787) constructed by inserting the 2.4-kb DNA in pKK232-8 expressed both 3-PDase and CAT activities. Another hybrid construct (pAW786) in which the DNA insert was cloned in the opposite orientation lacked CAT activity but produced normal amounts of 3-PDase activity. On the basis of these results, we suggest that the bphC and bphD genes were expressed by using promoter sequences that are independent of the promoter that expresses CAT activity in E. coli. The locations of the bphC and bphD genes were determined by insertional inactivation of the open reading frames of structural genes bphC and bphD by Tn5 mutagenesis.(ABSTRACT TRUNCATED AT 250 WORDS)     

Expression, localization, and functional analysis of polychlorinated biphenyl degradation genes cbpABCD of Pseudomonas putida.

Genes of Pseudomonas putida strains that are capable of degrading polychlorinated biphenyls were cloned in the plasmid vector pUC19. The resultant hybrid plasmid, pAW6194, contained cbpABCD genes on a 9.0-kb DNA fragment that was necessary for the catabolism of polychlorinated biphenyls. These genes were further subcloned on an 8.0-kb HindIII fragment of pAW540. Degradation of 3-chlorobiphenyl, 2,4-dichlorobiphenyl, and 2,4,5-trichlorobiphenyl into a chloro derivative of benzoic acid was found in Escherichia coli harboring chimeric plasmid pAW540. Expression of cbpA (biphenyl dioxygenase, 6.2 U/mg of protein) and cbpC (3-phenylcatechol dioxygenase, 611.00 U/mg of protein) genes was also found in E. coli containing the hybrid plasmid pAW540. These enzyme activities were up to 10-fold higher than those found in P. putida OU83. These results led us to conclude that cbpABCD genes of P. putida OU83 were encoded on cloned DNA and expressed in E. coli. Whether the expression of cbpABCD genes of P. putida OU83 was driven by its own promoters located on the cloned DNA or by the lacZ promoter of pUC19 was examined by subcloning a 8.0-kb DNA fragment encoding the cbpABCD genes, in both orientations, in the HindIII site of the promoter probe vector pKK232-8. The resulting recombinant plasmids, pAW560 and pAW561, expressed cbpABCD genes and conferred chloramphenicol resistance only in E. coli harboring pAW560, indicating that the expression of chloramphenicol acetyltransferase is independent of cbpABCD gene expression.(ABSTRACT TRUNCATED AT 250 WORDS)     

Expression, localization, and functional analysis of polychlorinated biphenyl degradation genes cbpABCD of Pseudomonas putida.

Genes of Pseudomonas putida strains that are capable of degrading polychlorinated biphenyls were cloned in the plasmid vector pUC19. The resultant hybrid plasmid, pAW6194, contained cbpABCD genes on a 9.0-kb DNA fragment that was necessary for the catabolism of polychlorinated biphenyls. These genes were further subcloned on an 8.0-kb HindIII fragment of pAW540. Degradation of 3-chlorobiphenyl, 2,4-dichlorobiphenyl, and 2,4,5-trichlorobiphenyl into a chloro derivative of benzoic acid was found in Escherichia coli harboring chimeric plasmid pAW540. Expression of cbpA (biphenyl dioxygenase, 6.2 U/mg of protein) and cbpC (3-phenylcatechol dioxygenase, 611.00 U/mg of protein) genes was also found in E. coli containing the hybrid plasmid pAW540. These enzyme activities were up to 10-fold higher than those found in P. putida OU83. These results led us to conclude that cbpABCD genes of P. putida OU83 were encoded on cloned DNA and expressed in E. coli. Whether the expression of cbpABCD genes of P. putida OU83 was driven by its own promoters located on the cloned DNA or by the lacZ promoter of pUC19 was examined by subcloning a 8.0-kb DNA fragment encoding the cbpABCD genes, in both orientations, in the HindIII site of the promoter probe vector pKK232-8. The resulting recombinant plasmids, pAW560 and pAW561, expressed cbpABCD genes and conferred chloramphenicol resistance only in E. coli harboring pAW560, indicating that the expression of chloramphenicol acetyltransferase is independent of cbpABCD gene expression.(ABSTRACT TRUNCATED AT 250 WORDS)     

Construction of an Escherichia coli-Clostridium perfringens shuttle vector and plasmid transformation of Clostridium perfringens

A stable shuttle vector which replicates in Escherichia coli and Clostridium perfringens was constructed by ligating a 3.6-kilobase (kb) fragment of plasmid pBR322 with C. perfringens plasmid pHB101 (3.1 kb). The marker for this shuttle plasmid originated from the 1.3-kb chloramphenicol resistance gene of plasmid pHR106. The resulting shuttle vector, designated pAK201, is 8 kb in size and codes for resistance to 20 micrograms of chloramphenicol per ml in both E. coli and C. perfringens. Following shuttle vector construction in E. coli, plasmid pAK201 was transformed into E. coli HB101 and C. perfringens ATCC 3624A, using intact cell electroporation. The transformation frequencies were 10(6) and 10(4) transformants per microgram of DNA in E. coli and C. perfringens, respectively. Restriction enzyme analysis of the chimera isolated from transformants of both microorganisms suggested that the plasmids were identical. Reciprocal transformation experiments in E. coli and C. perfringens indicated no difference in transformation frequency. Plasmid pAK201 was stable in C. perfringens following repeated transfer in the absence of chloramphenicol pressure. The restriction map of plasmid pAK201 shows six unique cut sites which should be useful for future genetic analysis and C. perfringens gene library construction.     

Construction of an Escherichia coli-Clostridium perfringens shuttle vector and plasmid transformation of Clostridium perfringens.

A stable shuttle vector which replicates in Escherichia coli and Clostridium perfringens was constructed by ligating a 3.6-kilobase (kb) fragment of plasmid pBR322 with C. perfringens plasmid pHB101 (3.1 kb). The marker for this shuttle plasmid originated from the 1.3-kb chloramphenicol resistance gene of plasmid pHR106. The resulting shuttle vector, designated pAK201, is 8 kb in size and codes for resistance to 20 micrograms of chloramphenicol per ml in both E. coli and C. perfringens. Following shuttle vector construction in E. coli, plasmid pAK201 was transformed into E. coli HB101 and C. perfringens ATCC 3624A, using intact cell electroporation. The transformation frequencies were 10(6) and 10(4) transformants per microgram of DNA in E. coli and C. perfringens, respectively. Restriction enzyme analysis of the chimera isolated from transformants of both microorganisms suggested that the plasmids were identical. Reciprocal transformation experiments in E. coli and C. perfringens indicated no difference in transformation frequency. Plasmid pAK201 was stable in C. perfringens following repeated transfer in the absence of chloramphenicol pressure. The restriction map of plasmid pAK201 shows six unique cut sites which should be useful for future genetic analysis and C. perfringens gene library construction.     

Mutational inactivation of the Saccharomyces cerevisiae RAD4 gene in Escherichia coli.

The RAD4 gene of Saccharomyces cerevisiae is required for the incision of damaged DNA during nucleotide excision repair. When plasmids containing the wild-type gene were transformed into various Escherichia coli strains, transformation frequencies were drastically reduced. Most plasmids recovered from transformants showed deletions or rearrangements. A minority of plasmids recovered from E. coli HB101 showed no evidence of deletion or rearrangement, but when they were transformed into S. cerevisiae on centromeric vectors, little or no complementation of the UV sensitivity of rad4 mutants was observed. Deliberate insertional mutagenesis of the wild-type RAD4 allele before transformation of E. coli restored transformation to normal levels. Plasmids recovered from these transformants contained an inactive rad4 allele; however, removal of the inserted DNA fragment restored normal RAD4 function. These experiments suggest that expression of the RAD4 gene is lethal to E. coli and show that lethality can be prevented by inactivation of the gene before transformation. Stationary-phase cultures of some strains of E. coli transformed with plasmids containing an inactivated RAD4 gene showed a pronounced delay in the resumption of exponential growth, suggesting that the mutant (and, by inference, possibly wild-type) Rad4 protein interferes with normal growth control in E. coli. The rad4-2, rad4-3, and rad4-4 chromosomal alleles were leaky relative to a rad4 disruption mutant. In addition, overexpression of plasmid-borne mutant rad4 alleles resulted in partial complementation of rad4 strains. These observations suggest that the Rad4 protein is relatively insensitive to mutational inactivation.