A promoter for Bacillus subtilis expression vector

A 117-bp EcoRI-PstI fragment with strong promoter activity (P1 promoter) was cloned from Bacillus subtilis chromosomal DNA and sequenced. The P1 promoter was shown to contain a putative -35 region (TTTACT) and -10 region (TAGATT), and promotes expression of cloned human interleukin-2 (IL-2) and human interferon-gamma (IFN-gamma) genes in B. subtilis.     

Cloning in Bacillus subtilis of temperature-dependent promoter fragments from Bacillus stearothermophilus and Bacillus subtilis

Abstract Using promoter-probe plasmids, more than 200 promoter-containing fragments from Bacillus stearothermophilus and Bacillus subtilis were cloned in B. subtilis . Among these, 15 promoter fragments were highly temperature-dependent in activity compared to the promoter sequence (TTGAAA for the −35 region, TATAAT for the −10 region) of the amylase gene, amyT , from B. stearothermophilus . Some fragments exhibited higher promoter activities at elevated temperature (48°C), others showed higher activities at lower temperature (30°C). Active promoter fragments at higher and lower temperatures were obtained mainly from the thermophile ( B. stearothermophilus ) and the mesophile ( B. subtilis ), respectively. A promoter fragment active at high temperature was sequenced, and the feature of the putative promoter region was discussed.     

A pleitropic mutation affecting purine metabolism in Bacillus subtilis

A pleiotropic mutation (cpm) which is localized in the vicinity of the spoOA gene is described in Bacillus subtilis. The mutation inhibits spore formation, rendering bacteria auxotrophic for adenine and tyrosine, enhances sensitivity to antibiotics, decreases cell motility, inhibits the ability to grow on pentoses and to maintain bacteriophage multiplication, induces severalfold the activities of alkaline proteinase and alpha-amylase. At the same time, the cpm mutant starts to excrete inosine into the growth medium. This excretion most probably is explained by a 50-fold increase in the activity of inosine monophosphate: 5'-nucleotidase and a 10-fold decrease in the activity of purine nucleoside phosphorylase. The inosine production and Ade- phenotype of the cpm mutant is not accompanied by the change in the activity of succinyl adenosine monophosphate synthetase. The nature of the mutation is discussed.     

Restriction fragments that exert promoter activity during postexponential growth of Bacillus subtilis.

Two restriction fragments of Bacillus subtilis DNA were identified which caused the cat-86 gene present on the promoter cloning plasmid pPL703 to be activated predominantly during postexponential growth of host cells. The postexponential increase was observed in both sporulation-positive strains and in a spoOA mutant of B. subtilis. However, the postexponential increase in the cat-86 gene product, chloramphenicol acetyltransferase, was diminished or not observed when the plasmid-containing cells were grown in the presence of excess glucose. The promoter-containing fragment, designated as 33, was mapped to a site on the B. subtilis chromosome adjacent to hisA. The other fragment, 14, mapped to a site adjacent to ctrA. When present on a high-copy vector, both fragments caused a reduction in the sporulation frequency of host cells. Fragment 33 in high copy number conferred on B. subtilis cells three additional phenotypic changes: brown colony color, intracellular inclusions, and, in a protease-deficient mutant, the production of extracellular protease activity. These activities were observed only in postexponential-phase cultures.     

Mapping of a genetic locus that affects glycerol 3-phosphate transport in Bacillus subtilis.

Two types of fosfomycin-resistant mutants of Bacillus subtilis were isolated. Mutants of the first type (GlpT mutants) were resistant to at least 200 microgram of fosfomycin per ml and failed to take up exogenous glycerol 3-phosphate. Mutants of the second type were resistant to lower concentrations of fosfomycin and transported glycerol-3-phosphate as efficiently as wild-type bacteria. The glpT mutations, but not the mutations in the second type of fosfomycin-resistant mutants, map in the cysA-aroI region of the B. subtilis chromosome.     

Genetic mapping of katB, a locus that affects catalase 2 levels in Bacillus subtilis

A locus affecting the synthesis of spore-specific catalase 2 in Bacillus subtilis was mapped using two- and three-factor transductional crosses at 342 degrees between hsrE and iol. It was named katB. Strains lacking catalase 2 remained sporulation proficient, but blockage of sporulation at stage IV or earlier affected the electrophoretic mobility of the native enzyme.     

The spoIIN279(ts) mutation affects the FtsA protein of Bacillus subtilis.

The spo-279(ts) mutation, originally thought to be located in the spoIIG operon of Bacillus subtilis, has been mapped in close proximity but outside of the spoIIG locus. This mutation defines a new gene, spoIIN, located midway between the spoIIG and the spoVE loci, and whose product is required for successful completion of the asymmetric septation step. The spoIIN locus was cloned using a combination of 'walking steps' upstream from the spoIIG region and hybridization screening of a bacteriophage lambda library. Sequencing of DNA fragments able to rescue the spoIIN279(ts) mutation revealed that the spoIIN locus is identical with the B subtilis counterpart of the Escherichia coli ftsA gene. After cloning the ftsA region from a strain containing the spoIIN279(ts) mutation we found that this mutation converts the ninth residue of the FtsA protein from serine to asparagine. The spoIIN279(ts) mutation, which is recessive, leads to filamentation during growth at 42 degrees C and causes defective formation of the sporulation septum at this non-permissive temperature. The FtsA protein is therefore required for proper cell septation, both during vegetative growth and sporulation. Possible additional roles of FtsA during sporulation are discussed.     

A new mutation delivery system for genome-scale approaches in Bacillus subtilis

In Bacillus subtilis, although many genetic tools have been developed, gene replacement remains labour-intensive and not compatible with large-scale approaches. We have developed a new one-step gene replacement procedure that allows rapid alteration of any gene sequence or multiple gene sequences in B. subtilis without altering the chromosome in any other way. This novel approach relies on the use of upp, which encodes uracil phosphoribosyl-transferase, as a counter-selectable marker. We fused the upp gene to an antibiotic-resistance gene to create an 'upp-cassette'. A polymerase chain reaction (PCR)-generated fragment, consisting of the target gene with the desired mutation joined to the upp-cassette, was integrated into the chromosome by homologous recombination, using positive selection for antibiotic resistance. Then, the eviction of the upp-cassette from the chromosome by recombination between short repeated chromosomal sequences, included in the design of the transforming DNA molecule, was achieved by counter-selection of upp. This procedure was successfully used to deliver a point mutation, to generate in-frame deletions with reduced polar effects, and to combine deletions in three paralogous genes encoding two-component sensor kinases. Also, two chromosome regions carrying previously unrecognized essential functions were identified, and large deletions in two dispensable regions were combined. This work outlines a strategy for identifying essential functions that could be used at genome scale.