[The structure of the transposable genetic element ISBsu2 in the cryptic plasmid p1516 from a soil Bacillus subtilis strain and the presence of homologues of this element in the chromosomes of various Bacillus subtilis strains]. / Struktura mobil'nogo geneticheskogo élementa ISBsu2 iz kripticheskoi plazmidy P1516 pochvennogo shtamma Bacillus subtilis i nalichie gomologov étogo élementa v khromosomakh razlichnykh shtammov Bacillus subtilis.

A cryptic plasmid from a soil strain of Bacillus subtilis was found to contain a sequence having features of IS element. Homologous sequences were also found in the chromosome of this strain and in the chromosomes of some other B. subtilis strains.

[The ISBsu2 mobile element is present in a plasmid of a soil strain and in the chromosomes of several other strains of Bacillus subtilis]. / Prisutstvie mobil'nogo geneticheskogo élementa ISBsu2 v plazmide pochvennogo shtamma Bacillus subtilis i v khromosomakh riada shtammov étoi bakterii.

Chromosomes of several Bacillus subtilis strains were shown to contain homologs of the ISBsu2 mobile genetic element, which was earlier revealed in a cryptic plasmid of a soil strain of B. subtilis.

Protein secretion and possible roles for multiple signal peptidases for precursor processing in bacilli.

Bacillus subtilis is one of the best known Gram-positive bacteria at both the genetic and physiological level. The entire sequence of its chromosome is known and efficient tools for the genetic modification of this bacterium are available. Moreover, B. subtilis and related Bacillus species are widely used in biotechnology, in particular for the production of secreted enzymes. Although bacilli can secrete large amounts of several native enzymes, the use of these bacteria for the production of heterologous enzymes has frequently resulted in low yields. Here we describe the identification of several components of the Bacillus protein secretion machinery. These components can now be engineered for optimal protein secretion. Special emphasis is given on type I signal peptidases, which remove signal peptides from secretory precursor proteins. Five genes specifying such enzymes (sip, for signal peptidase) are present on the B. subtilis chromosome. Although none of the sip genes is essential by itself, a specific combination of mutations in these genes is lethal. The expression pattern of some of the sip genes coincides with that of many secretory proteins, which seems to reflect an adaptation to high demands on the secretion machinery. Although the various B. subtilis type I signal peptidases have at least partially overlapping substrate specificities, clear differences in substrate preferences are also evident. These observations have implications for the engineering of the processing apparatus for improved secretion of native and heterologous proteins by Bacillus.

Rolling-circle plasmids from Bacillus subtilis: complete nucleotide sequences and analyses of genes of pTA1015, pTA1040, pTA1050 and pTA1060, and comparisons with related plasmids from gram-positive bacteria.

Most small plasmids of Gram-positive bacteria use the rolling-circle mechanism of replication and several of these have been studied in considerable detail at the DNA level and for the function of their genes. Although most of the common laboratory Bacillus subtilis 168 strains do not contain plasmids, several industrial strains and natural soil isolates do contain rolling-circle replicating (RCR) plasmids. So far, knowledge about these plasmids was mainly limited to: (i) a classification into seven groups, based on size and restriction patterns; and (ii) DNA sequences of the replication region of a limited number of them. To increase the knowledge, also with respect to other functions specified by these plasmids, we have determined the complete DNA sequence of four plasmids, representing different groups, and performed computer-assisted and experimental analyses on the possible function of their genes. The plasmids analyzed are pTA1015 (5.8 kbp), pTA1040 (7.8 kbp), pTA1050 (8.4 kbp), and pTA1060 (8.7 kbp). These plasmids have a structural organization similar to most other known RCR plasmids. They contain highly related replication functions, both for leading and lagging strand synthesis. pTA1015 and pTA1060 contain a mobilization gene enabling their conjugative transfer. Strikingly, in addition to the conserved replication modules, these plasmids contain unique module(s) with genes which are not present on known RCR plasmids of other Gram-positive bacteria. Examples are genes encoding a type I signal peptidase and genes encoding proteins belonging to the family of response regulator aspartate phosphatases. The latter are likely to be involved in the regulation of post-exponential phase processes. The presence of these modules on plasmids may reflect an adaptation to the special conditions to which the host cells were exposed.

A 22 kb DNA sequence in the cspB-glpPFKD region at 75 degrees on the Bacillus subtilis chromosome.

A 21808 bp nucleotide sequence at 75 degrees on the genetic map of the Bacillus subtilis chromosome was determined. The sequence of this region is adjacent to the glpPFKD operon involved in glycerol utilization. Twenty-six ORFs were identified, one of which corresponds to the cspB gene, encoding a cold-shock protein. Seventeen of the deduced protein sequences of these ORFs displayed significant homology to known proteins in the data banks. One putative operon was identified, consisting of five ORFs, that is probably involved in the uptake and processing of copper. The location of cspB in this sequence does not confirm the genetic mapping data, indicating that the gene is closely linked to comK, which is located at 80 degrees on the B. subtilis chromosome.

Plasmid deletion formation between short direct repeats in Bacillus subtilis is stimulated by single-stranded rolling-circle replication intermediates.

The effects of the rolling-circle mode of replication and the generation of single-stranded DNA (ss DNA) on plasmid deletion formation between short direct repeats in Bacillus subtilis were studied. Deletion units consisting of direct repeats (9, 18, or 27 bp) that do or do not flank inverted repeats (300 bp) were introduced into various plasmid replicons that generate different amounts of ss DNA (from 0% to 40% of the total plasmid DNA). With ss DNA-generating rolling-circle-type plasmids, deletion frequencies between the direct repeats were 3- to 13-fold higher than in plasmids not generating ss DNA. When the direct repeats flanked inverted repeats the deletion frequencies in ss DNA-generating plasmids were increased by as much as 20- to 140-fold. These results support models for deletion formation based on template-switching errors during complementary strand synthesis of rolling-circle-type plasmids. The structural instability (deletion formation between short direct repeats) of the ss DNA-generating plasmid pTA1060 in B. subtilis was very low in the presence of a functional initiation site for complementary strand synthesis (minus origin). This observation suggests that it will be possible to develop stable host-vector cloning systems for B. subtilis.

Rapid detection of human parvovirus B19 DNA by dot-hybridization and the polymerase chain reaction.

The results of a comparison of three DNA-detection methods for human parvovirus B19 DNA are described. The sensitivity of detection of virus from hybridization assays using 32P-radiolabeled DNA and RNA probes was compared with a method for enzymatically amplifying specific target DNA sequences (polymerase chain reaction). B19 virus DNA was detected using a radiolabeled DNA probe at serum dilutions of 10(-3), equivalent to approximately 3 pg of viral DNA. Using radiolabeled RNA probes even 0.3 pg of viral DNA was detectable. The polymerase chain reaction was more sensitive than the hybridization assays: 100 fg of viral DNA was easily detectable by electrophoresis on agarose and after subsequent hybridization with a radiolabeled probe approximately 10 fg of B19 DNA was detected. The sensitivity of the PCR, combined with the simplicity and reduced time scale, demonstrates the potential of this technique as an additional method for routine diagnosis of B19 infections.

Secondary structure and expression in vivo and in vitro of messenger RNAs into which upstream AUG codons have been inserted.

We wanted to discover whether the conformation of the mRNA leader sequence is involved in translational fidelity. For this purpose we constructed several mutants of Semliki Forest virus 26S mRNA and inserted AUG codons into the leader sequence. We then analyzed the results of in vitro and in vivo translation of these mRNAs, probed enzymatically the secondary structure and performed minimal energy folding of the transcripts. Our results indicate that the position of a hairpin in the leader sequence determines at which AUG codon downstream from that hairpin translation is initiated.