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.     

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.     

Expression of the genes for lysine biosynthesis of Bacillus subtilis in Escherichia coli cells

Hybrid plasmids pLRS33 and pLRB4 containing Bac. subtilis genes coding lysin biosynthesis were subjected to genetical analysis. It is shown that after pLRS33- and pLRB4- transformation of E. coli strains, auxotrophic relative to lysin and diaminopimelic acid, there occurs complementation of dapA, dapB, dapC, dapD, dapE, lysA mutations by plasmid pLRS33 and of dapC, dapB, lysA mutations by plasmid pLRB4. The plasmids are studied for their influence on the level of lysin and its precurror synthesis in E. coli strains.     

Genetic mapping of regulatory mutations of Bacillus subtilis riboflavin operon

Summary Seven mutations leading to riboflavin overproduction inBacillus subtilis were found to be linked to the markerdnaF133 (145° on theB. subtilis genetic map) by transformation. Cotransfer indexes (42.5%–61.7%) suggest that theribC mutations are alleles of the same locus. Results of transduction and transformation crosses suggest the following order of markers:pyrD26 –ts-6 –dnaF133 –ribC –recA1.     

The Bacillus subtilis addAB genes are fully functional in Escherichia coli

An Escherichia coli recBCD deletion mutant was transformed with plasmids containing the Bacillus subtilis add genes. The transformants had relatively high ATP-dependent exonuclease- and ATP-dependent helicase activities, and their viability, the ability to repair u.v.-damaged DNA and the recombination in conjugation were nearly completely restored. The B. subtilis Add enzyme did not show Chi-activity in phage lambda recombination. The individual B. subtilis Add proteins were not able to form an enzymatically active complex with the E. coli RecB,C,D proteins, and they could not complement the recB,C,D deficiency. Evidence is presented that only two subunits are involved in the B. subtilis ATP-dependent exonuclease. This is in contrast to E. coli in which the RecBCD enzyme consists of three subunits.     

Unusual structure of the regulatory region of the riboflavin biosynthesis operon in Bacillus subtilis

In vitro mutagenesis with methylhydroxylamine and nitrosomethylurea was used to obtain a number of Bacillus subtilis mutants impaired in flavin-dependent response. Mutants displayed varying degree of flavin-dependent repression of riboflavin synthase and of 6,7-dimethyl-8-ribityl-lumasine accumulation. Single nucleotide substitutions were detected by DNA sequencing in all of the mutants, affecting the 48 b.p. target area between the mRNA start and the AUG of the first gene.     

In vivo transfer of genes from Escherichia coli to Bacillus subtilis

Summary Escherichia coli cells, carrying plasmid pRD1 with (a) drug resistance markers from Pseudomonas (km^r, carb^r, tc^r) and (b) the nif-gene group from Klebsiella, were incubated together with Bacillus subtilis cells (str^r), whose cell wall had been disintegrated with lysozyme. Upon plating the cell mixtures onto appropriately supplemented selective medium, multiple drug resistant Bacillus subtilis cells were obtained. Their nature was verified by suitable biochemical tests and checking for the presence of additional genetic markers. The majority of the isolates was unstable. Some however retained multiple drug resistance for longer periods of time, and several produced nitrogenase activity. The data are interpreted as evidence not only for the transfer of the respective genes but also for their expression in the gram-positive recipient cells.Abbreviations pRD1 a hybrid plasmid, renamed by Ray Dixon - pRP4 plasmid from Pseudomonas, originally described by Datta et al., J. Bacteriol 108, 1244 (1971) - km ^r, carb ^r, tc ^r, str ^r resistance against kanamycin, carbenicillin, tetracyclin and streptomycin, respectively - r restriction negative. For other bacterial markers refer to Bachmann, B.J. et al., Bacteriological Reviews 40, 116 (1976)     

Functional expression of two Bacillus subtilis chromosomal genes in Escherichia coli.

EcoRI-cleaved deoxyribonucleic acid segments carrying two genes from Bacillus subtilis, pyr and leu, have been cloned in Escherichia coli by insertion into a derivative of the E. coli bacteriophage lambda. Lysogenization of pyrimidine- and leucine-requiring auxotrophs of E. coli by the hybrid phages exhibited prototrophic phenotypes, suggesting the expression of B. subtilis genes in E. coli. Upon induction, these lysogens produced lysates capable of transducing E. coli pyr and leu auxotrophs to prototrophy with high frequency. Isolated DNAs of these bacteriophages have the ability to transform B. subtilis auxotrophs to pyr and leu independence and contain EcoRI-cleaved segments which hybridize to corresponding segments of B. subtilis.     

Biosynthesis of riboflavin: characterization of the bifunctional deaminase-reductase of Escherichia coli and Bacillus subtilis.

The ribG gene at the 5' end of the riboflavin operon of Bacillus subtilis and a reading frame at 442 kb on the Escherichia coli chromosome (subsequently designated ribD) show similarity with deoxycytidylate deaminase and with the RIB7 gene of Saccharomyces cerevisiae. The ribG gene of B. subtilis and the ribD gene of E. coli were expressed in recombinant E. coli strains and were shown to code for bifunctional proteins catalyzing the second and third steps in the biosynthesis of riboflavin, i.e., the deamination of 2,5-diamino-6-ribosylamino-4(3H)-pyrimidinone 5'-phosphate (deaminase) and the subsequent reduction of the ribosyl side chain (reductase). The recombinant proteins specified by the ribD gene of E. coli and the ribG gene of B. subtilis were purified to homogeneity. NADH as well as NADPH can be used as a cosubstrate for the reductase of both microorganisms under study. Expression of the N-terminal or C-terminal part of the RibG protein yielded proteins with deaminase or reductase activity, respectively; however, the truncated proteins were rather unstable.     

Creating new genes by plasmid recombination in Escherichia coli and Bacillus subtilis

Gene shuffling is a way of creating proteins with interesting new characteristics, starting from diverged sequences. We tested an alternative to gene shuffling based on plasmid recombination and found that Bacillus subtilis efficiently recombines sequences with 4% divergence, and Escherichia coli mutS is more appropriate for sequences with 22% divergence.     

Autolysis of Escherichia coli and Bacillus subtilis cells in low gravity

The role of gravity in the autolysis of Bacillus subtilis and Escherichia coli was studied by growing cells on Earth and in microgravity on Space Station Mir. Autolysis analysis was completed by examining the death phase or exponential decay of cells for approximately 4 months following the stationary phase. Consistent with published findings, the stationary-phase cell population was 170% and 90% higher in flight B. subtilis and E. coli cultures, respectively, than in ground cultures. Although both flight autolysis curves began at higher cell densities than control curves, the rate of autolysis in flight cultures was identical to that of their respective ground control rates. Received: 3 December 1998 / Received revision: 23 February 1999 / Accepted: 14 March 1999     

Heterospecific expression of the Bacillus subtilis cell shape determination genes mreBCD in Escherichia coli

The divIVB operon of Bacillus subtilis includes the cell shape-associated mre genes, including the membrane-associated proteins MreC and MreD. TnphoA mutagenesis was utilized to analyze a topological model for MreC. MreC has a short cytoplasmic amino terminus, a single membrane-spanning domain, and a large carboxy terminal domain which lies externally to the outer leaflet of the cell membrane. Expression of the B. subtilis MreB protein, or the Mre C and D proteins, results in a morphological conversion of the Escherichia coli host cells from a rod to a roughly spherical cell, morphologically similar to mre-negative mutants of E. coli. Immunolocalization of the MreC protein in B. subtilis revealed that this protein is found at the midcell division site of the bacterial cells, consistent with the postulated role of the Mre proteins in the regulation of septum-specific peptidoglycan synthesis.     

Duplication-translocations of tryptophan operon genes in Escherichia coli

Mutants of Escherichia coli were selected in which a single mutational event had both relieved the polar effect of an early trpE mutation on trpB and simultaneously released the expression of trpB from tryptophan repression. The frequency at which these mutations appeared was roughly equal to the frequency of point mutations. In each of these mutants, the mutation increased the function of trpB and also increased the activity of some, but not all, of the other four tryptophan operon genes. Genetic analysis showed that the mutations were not located within the trp operon since in each case the parental trp operon could be recovered from the mutants. Each mutant was shown to carry a duplication of a trp operon segment translocated to a new position near the trp operon. Polarity is relieved since the trpB duplication-translocation is not in the same operon as the trpE polar mutation. The duplicated and translocated segments are fused to operons not regulated by tryptophan, so trpB function is no longer subject to tryptophan repression. The properties of the mutants indicate that the length of the duplicated segment and the position to which it is translocated differ in each of the seven mutants studied. The duplications are unstable, but the segregation pattern observed is not consistent with a single crossover model for segregation. That such duplication-translocation events generate a variety of new genetic arrangements at a frequency comparable with point mutations suggests they may play an important role in evolution.