蜡样芽孢杆菌ATCC14579核黄素操纵子的克隆及在枯草芽孢杆菌中的表达

利用BLAST从B．cereus ATCC14579的基因组中找到一段与枯草芽孢杆茵核黄素操纵子具有较高相似性的4．6kb大小的基因组DNA片段,该片段中含有完整的核黄素操纵子。该操纵子结构基因的编码产物的氨基酸序列与枯草芽孢杆菌核黄素操纵子相应结构基因的编码产物的氨基酸序列具有99％的同源性。该片段被克隆到大肠杆茵一枯草芽孢杆茵穿梭载体pHP13M中。表达分析的结果表明B．cereus ATCC14579核黄素操纵子可在大肠杆茵和枯草芽孢杆菌中表达。利用PCR方法用来自枯草杆菌的sac B基因的启动子替换B．cereus ATCC14579核黄素操纵子原有的启动子使其更好表达。替换启动子后的核黄素操纵子在本文使用的发酵条件下有较好的表达,核黄素产量从39．5mg／L增加到61．7mg/L.     

Riboflavin biosynthesis operon of Bacillus subtilis. XIII. Genetic and biochemical study of mutants with regard to intermediate stages of biosynthesis]

New riboflavin dependent mutants of Bacillus subtilis accumulating different pteridines were studied. The data obtained show that the formation of ribityl side chain proceeds in a few steps at least on a part of riboflavin precursors. The oxidation of connected ribosyl into ribulose with subsequent restoration of it into ribityl proceeds at first. The corresponding genes are located on terminal part of riboflavin operon, as show the results of two-factor transformational crosses with different donors and recipients.     

Amplification of the riboflavin operon genes of Bacillus subtilis in Escherichia coli cells]

Amplification of Bacillus subtilis DNA fragments was performed in Escherichia coli using plasmid RSF2124. The main principle of isolation and cloning hybrid plasmids was described using genes of riboflavin operon as a model. Bac. subtilis DNA was treated with restriction endonuclease EcoR; followed by the agarose gel electrophoretic separation of the resulting fragments. Gels were sliced, DNA was eluted from the corresponding slices and used to transform Bac. subtilis auxotrophs rib A72, rib S110 and rib D107. DNA fraction with the molecular weight 7 . 10(6) daltons restored prototrophy of these mutants. DNA of this fraction was ligated with EcoRI treated plasmid RSF2124 DNA and used for transformation of E. coli rk-mk+. Ampicillin resistant transformants which had lost the colicin production ability, were selected. The presence of riboflavin genes within the hybrid plasmids was detected by transformation of B. subtilis auxotrophs. Three hybrid plasmids (pPR1, pPR2 and pPR3), containing a fragment of Bac. subtilis DNA with the molecular weight 6.8 . 10(-6) daltons including riboflavin operon, were selected. The analysis of the transformation activity of Bac. subtilis DNA and plasmid pPR1 DNA revealed, that there was no restriction activity of Bac. subtilis cells against plasmid DNA amplified in E. coli. Heteroduplex analysis has shown that plasmids pPR1 and pPR2 differ in the orientation of Bac. subtilis DNA fragment. DNA of these plasmids restored prototrophy of the several studied E. coli riboflavin auxotrophs.     

Analgos of riboflavin, lumiflavin and alloxazine derivatives. II. Effect of roseoflavin on 6,7-dimethyl-8-ribityllumazine and riboflavin synthetase synthesis and growth of Bacillus subtilis]

The replacement of 8-CH3 group in the riboflavin molecule results in the formation of specific antimetabolites. They are rozeoflavin, 7-desmethylrozeoflavin, 8-amino (nor) riboflavin, 8-ribitylamino (nor) riboflavin. Effect of rozeoflavin and other riboflavin analogues on the growth and regulatory characteristics of Bacillus subtilis strains with different genetic state of riboflavin operon is studied. Roseoflavin at a concentration of 0.05 mkg/ml inhibits DRL synthesis in rib-b110 strain. An analogue inhibits the growth of auxotrophic and prototrophic strains at concentrations of 0.5 mkg/ml and 50 mkg/ml respectively. Riboflavin (1 mkg/ml) recovers the growth of bacteria. The curve of rozeoflavin regulation of DRL and riboflavin synthetase synthesis is shifted in 100 times in the direction of lesser concentrations as compared with riboflavin and 8 amino (nor) riboflavin. 180 mutants resistant to 100 mkg/ml of rozeoflavin were selected. 150 mutants over-synthetize riboflavin.     

Riboflavin operon in Bacillus subtilis contains additional promoters

Using the methods of molecular cloning permitted to show that riboflavin operon of Bacillus subtilis contains four promoters. Three of them are functionally active in the Bacillus subtilis system. The main promoter of the operon with regulatory region was cloned in plasmid pPL603. Cells containing the constructed plasmid pGM32 are resistant to chloramphenicol. The level of resistance is regulated by concentration of riboflavin (the effector of operon). The following model of rib-operon has been proposed: (Formula: see text).     

枯草芽孢杆菌核黄素操纵子rib operon的克隆与表达

目的:构建产核黄素的枯草芽孢杆菌基因工程菌.方法:以穿梭载体pEB03构建核黄素操纵子的表达质粒载体pGJB13和pGJB14,与质粒pMX45分别转化产核黄素的枯草芽孢杆菌GJ07,并通过发酵摇瓶实验检测核黄素的产量.结果:得到产核黄素的工程菌GJ13 、GJ14和GJ08,在以蔗糖为碳源的发酵条件下,GJ08可产核黄素820mg/L,提高了约55%.结论:得到了产核黄素的高产菌种G J08.     

核黄素发酵菌种改造研究进展

核黄素是一种水溶性维生素,与动植物的生长密切相关,人体不能合成核黄素,需从外部摄取,因此核黄素的生产具有重要意义。介绍了核黄素的生产发展历程和产核黄素的微生物种类。对枯草芽孢杆菌的核黄素代谢途径及其诱变育种进行了总结,重点介绍了菌种的基因重组改造方法,主要是提高核黄素操纵子表达以及提高Ru5P和GTP两种前体供应量合成途径通量,介绍了近些年新的改造方法,并对未来的发展方向进行了展望。     

The bounds of the riboflavin operon in Bacillus subtilis

All the structural genes of riboflavin biosynthesis are shown to be located on the 2.8 MD DNA fragment, using the collection of plasmids, carrying the Bacillus subtilis riboflavin operon fragments and Bacillus subtilis strains, containing various deletions of rib-operon for analysis. The proximal Bgl II site is shown to be located between promoter P1 and the first structural gene ribG. The distal Hind III site of fragment C is the left bound of the rib-operon.     

Characterization of Actinobacillus pleuropneumoniae riboflavin biosynthesis genes.

In this paper, we report the identification, cloning, and complete nucleotide sequence of four genes from Actinobacillus pleuropneumoniae that are involved in riboflavin biosynthesis. The cloned genes can specify production of large amounts of riboflavin in Escherichia coli, can complement several defined genetic mutations in riboflavin biosynthesis in E. coli, and are homologous to riboflavin biosynthetic genes from E. coli, Haemophilus influenzae, and Bacillus subtilis. The genes have been designated A. pleuropneumoniae ribGBAH because of their similarity in both sequence and arrangement to the B. subtilis ribGBAH operon.     

Riboflavin auxotrophs of Escherichia coli]

Escherichia coli riboflavin auxotrophs having a different level of riboflavin requirement were isolated. This auxotrophic mutations are located near cysB93 and trpA62 markers. The complementary effect of Bacillus subtilis riboflavin operon linked with pPR1 hybrid plasmid with rib8-1 and rib1-1 mutations was obtained.     

Cloning of genetic material in Bacillus

Plasmid vectors capable for propagation of Bacillus subtilis DNA fragments containing riboflavin genes were constructed. Cloning of rib operon using pUB110 derivatives was performed in recE4 strain by using sequentional rescue of plasmids containing subfragments of the operon. Also, rib operon was cloned on the vectors containing DNA repeats. It was shown that the presence of direct and inverted repeats within plasmids allows to transform B. subtilis cells by monomers of plasmid DNA. Vectors that contained repeated sequences of DNA and ensured efficient cloning of genetic material in B. subtilis recipient cells were constructed. The use of streptococcal plasmid pSM19035 allowed to obtain vectors which were suitable for cloning large DNA fragments (6 MD and even more) in B. subtilis. A model of B. subtilis transformation by various types of plasmid DNA is presented. The model is in agreement with the general conception of chromosomal DNA transformation.     

Operon of riboflavin biosynthesis in Bacillus subtilis. XV. A study of mutants related to the initial stages of biosynthesis. The origin of the ribityl chain of the riboflavin molecule]

The incorporation of 14C-labelled guanosine and xanthosine into riboflavin was studied. It is concluded that the ribose mojety of guanosine is converted to the ribityl side chain of riboflavin. Thus the immediate precursor of riboflavin biosynthesis is a guanosine compound. Two classes of the riboflavin-dependent mutants of Bacillus subtilis were studied. They are closely linked to the lysine markers and probably correspond to the initial steps of riboflavin biosynthesis pathway.     

Cloning of the Bacillus subtilis DNA fragment containing the genes for lysine and riboflavin biosynthesis

The SalI fragment of chromosomal DNA of Bacillus subtilis carrying the gene for lysine biosynthesis and the regulatory operator region (ribO) from the riboflavin gene was cloned into Escherichia coli cells. This fragment was shown to contain the gene coding for lysine synthesizing enzyme. Localization of this gene in Bac. subtili was determined. New plasmids pLRS33 and pLRB4 were constructed using pBR322; they carry a fragment homologous to pLP102 plasmid containing the operon for riboflavin biosynthesis.     

Operon of riboflavin biosynthesis in Bacillus subtilis. XVII. A study of the regulatory functions of the intermediate products and their derivatives

Repression of synthesis of GTP-cyclohydrolase and riboflavinsynthetase was studied in different regulatory mutants of Bacillus subtilis. The results of experiments with some riboflavin precursors and their derivatives revealed that 5-amino-2,6-dioxo-4-ribitylaminopyrimidine and 6-methyl-7-(1',2'-dioxyethyl)-8-ribityllumazine can serve as effectors in riboflavin biosynthesis.     

Transketolase mutation in riboflavin-synthesizing strains of Bacillus subtilis

Unlike its predecessors B. subtilis rosR and 41, riboflavin producing B. subtilis 24 strain does not utilize pentose and gluconate and poorly assimilates glucose. Simultaneous addition of glutamic and shikimic acid restored its capacity to grow and produce riboflavin in medium with pentose and gluconate. This strain lacks the activity of transketolase, the key enzyme of the pentose phosphate cycle, and possesses normal ribulose-5-phosphate-epimerase and glucose phosphate isomerase activities. Like enterobacteria, B. subtilis has two different transport systems for glucose and mannose. The data are discussed from the viewpoint of increasing riboflavin production by transketolase mutants. Probable consequences of cell wall and cytoplasmatic membrane damage in B. subtilis with this mutation are discussed.     

枯草芽孢杆菌核黄素操纵子与ribC基因的修饰与遗传效应

[目的]研究核黄素操纵子(rib)组成型高表达,以及ribC基因低水平表达对枯草芽孢杆菌过量合成核黄素的影响.[方法]在染色体原位修饰启动子,用mRNA稳定子替换mRNA前导区,使rib操纵子组成型高表达;修饰ribC基因的启动子,降低ribC基因的表达水平.采用qRT-PCR方法,表征基因的相对表达水平;通过摇瓶发酵,测定重组菌的生物量和核黄素产量,表征相关基因修饰所表现的遗传效应.[结果]用gsiB mRNA稳定子替换核黄素操纵子的mRNA前导区,使其相对表达水平提高了约1 500倍.ribC基因启动子-35区的首个碱基由“T”突变为“C”,使ribC基因的表达水平下降了97％以上.得到的重组菌株LX34在补加蔗糖20 g/L的LB培养基上摇瓶发酵36 h,可积累核黄素2.1 g/L,同时生物量没有明显下降.[结论]使用gsiB mRNA稳定子,能够有效地提高目标基因或操纵子的表达水平;启动子-35区首个碱基的点突变,能够有效降低ribC基因的表达水平;rib操纵子过量表达和ribC基因低水平表达,使细胞能够过量合成并积累核黄素.