Role of autolysins in the EDTA-induced lysis of Pseudomonas aeruginosa

Abstract A DNA fragment containing the genes secE, nusG and rplK of Staphylococcus carnosus was cloned using the Escherichia coli rplK gene as a probe. The S. carnosus secE homologue encodes a protein of 65 amino acid residues which is homologous to the carboxyl-terminal region of the E. coli SecE protein. The S. carnosus SecE polypeptide which, in contrast to the E. coli SecE protein, contains only one putative transmembrane segment, could fully replace the E. coli SecE protein in two different secE mutants. These results strongly suggest that the identified secE gene encodes an important component of the S. carnosus protein export apparatus.     

A chimeric disposition of the elongation factor genes in Rickettsia prowazekii.

An exceptional disposition of the elongation factor genes is observed in Rickettsia prowazekii, in which there is only one tuf gene, which is distant from the lone fus gene. In contrast, the closely related bacterium Agrobacterium tumefaciens has the normal bacterial arrangement of two tuf genes, of which one is tightly linked to the fus gene. Analysis of the flanking sequences of the single tuf gene in R. prowazekii shows that it is preceded by two of the four tRNA genes located in the 5' region of the Escherichia coli tufB gene and that it is followed by rpsJ as well as associated ribosomal protein genes, which in E. coli are located downstream of the tufA gene. The fus gene is located within the str operon and is followed by one tRNA gene as well as by the genes secE and nusG, which are located in the 3' region of tufB in E. coli. This atypical disposition of genes suggests that intrachromosomal recombination between duplicated tuf genes has contributed to the evolution of the unique genomic architecture of R. prowazekii.     

Identification of the gene encoding transcription factor NusG of Thermus thermophilus.

The nusG gene of Thermus thermophilus HB8 was cloned and sequenced. It is located 388 bp downstream from tufB, which is followed by the genes for ribosomal proteins L11 and L1. No equivalent to secE preceding nusG, as in Escherichia coli, could be detected. The nusG gene product was overproduced in E. coli. A rabbit antiserum raised against the purified recombinant NusG reacted exclusively with one protein band of T. thermophilus crude extracts in Western blot (immunoblot) analyses, and no cross-reaction of the antiserum with E. coli NusG was observed. Recombinant NusG and the reacting T. thermophilus wild-type protein had identical sizes on sodium dodecyl sulfate-polyacrylamide gels. T. thermophilus and E. coli NusG have 45% identical and 22.5% similar amino acids, and similarities between the two proteins are most pronounced in carboxy-terminal regions. The T. thermophilus nusG gene could not rescue a nusG-deficient E. coli mutant strain.     

A Mutation Affecting the Regulation of a Seca-Lacz Fusion Defines a New Sec Gene

It was shown previously that the secA gene of Escherichia coli is derepressed in cells that have a defect in protein export. Here it is demonstrated that the beta-galactosidase produced by a secA-lacZ gene fusion strain is regulated in the same way. Studies on the fusion strain reveal that the promoter or a site involved in regulation of the secA gene is located considerably upstream from the structural gene. The properties of the fusion strain provide a new selection for mutants that are defective in protein export. Selection for increased lac expression of a secA-lacZ fusion strain yields mutations in three of the known sec genes, secA, secD and prlA/secY. In addition, mutations in several genes not previously known to affect secA expression were obtained. A mutation in one of these genes causes a pleiotropic defect in protein export and a cold-sensitive growth defect; this gene, which maps at approximately 90 min on the bacterial chromosome, has been named secE.     

Characterization of trbC, a new F plasmid tra operon gene that is essential to conjugative transfer.

We have characterized a previously unidentified gene, trbC, which is contained in the transfer region of the Escherichia coli K-12 fertility factor, F. Our data show that the trbC gene is located between the F plasmid genes traU and traN. The product of trbC was identified as a polypeptide with an apparent molecular weight (Ma) of 23,500 that is processed to an Ma-21,500 mature protein. When ethanol was present, the Ma-23,500 polypeptide accumulated; the removal of ethanol resulted in the appearance of the processed mature protein. Subcellular fractionation experiments demonstrated that the processed, Ma-21,500 mature protein was located in the periplasm. DNA sequence analysis showed that trbC encodes a 212-amino-acid Mr-23,432 polypeptide that could be processed to a 191-amino-acid Mr-21,225 mature protein through the removal of a typical amino-terminal signal sequence. We also constructed two different Kmr gene insertion mutations in trbC and crossed these onto the transmissible F plasmid derivative pOX38. We found that cells carrying pOX38 trbC mutant plasmids were transfer deficient and resistant to infection by F-pilus-specific phages. Transfer proficiency and bacteriophage sensitivity were restored by complementation when a trbC+ plasmid clone was introduced into these cells. These results showed that trbC function is essential to the F plasmid conjugative transfer system and suggested that the TrbC protein participates in F-pilus assembly.     

Nucleotide sequence of traQ and adjacent loci in the Escherichia coli K-12 F-plasmid transfer operon.

The F tra operon region that includes genes trbA, traQ, and trbB was analyzed. Determination of the DNA sequence showed that on the tra operon strand, the trbA gene begins 19 nucleotides (nt) distal to traF and encodes a 115-amino-acid, Mr-12,946 protein. The traQ gene begins 399 nt distal to trbA and encodes a 94-amino-acid, Mr-10,867 protein. The trbB gene, which encodes a 179-amino-acid, Mr-19,507 protein, was found to overlap slightly with traQ; its start codon begins 11 nt before the traQ stop codon. Protein analysis and subcellular fractionation of the products expressed by these genes indicated that the trbB product was processed and that the mature form of this protein accumulated in the periplasm. In contrast, the protein products of trbA and traQ appeared to be unprocessed, membrane-associated proteins. The DNA sequence also revealed the presence of a previously unsuspected locus, artA, in the region between trbA and traQ. The artA open reading frame was found to lie on the DNA strand complementary to that of the F tra operon and could encode a 104-amino-acid, 12,132-dalton polypeptide. Since this sequence would not be expressed as part of the tra operon, the activity of a potential artA promoter region was assessed in a galK fusion vector system. In vivo utilization of the artA promoter and translational start sites was also examined by testing expression of an artA-beta-galactosidase fusion protein. These results indicated that the artA gene is expressed from its own promoter.     

The nusG gene of Streptomyces griseus: Cloning of the gene and analysis of the A-factor binding properties of the gene product

Abstract The nusG gene of Streptomyces griseus was cloned and the nucleotide sequence determined. It encodes a protein with an identify of 76% to the reported receptor (VbrA) for VB-C, an autoregulatory factor in Streptomyces virginae . NusG protein was expressed in Escherichia coli . However, no binding activity for A-factor, an butyrolactone autoregulator in S. griseus very similar to VB-C, could be detected. The nusG gene of S. griseus does not seem to encode the A-factor-binding protein.     

Export of the outer membrane lipoprotein is defective in secD, secE, and secF mutants of Escherichia coli.

The export of major outer membrane lipoprotein has been found to be affected in secD, secE, and secF mutants of Escherichia coli, which are defective in protein export in general. After a shift to the nonpermissive temperature, the kinetics of accumulation of prolipoprotein and pre-OmpA protein was indistinguishable from that of pre-OmpA protein accumulation in the secD and secF mutants but different in the secE mutant. The prolipoprotein accumulated in the secD, secE, and secF mutants at the nonpermissive temperature was not modified with glyceride. We conclude from these results and those of previous studies that the export of lipoprotein requires all common sec gene products except the SecB protein, i.e., the SecA, SecD, SecE, SecF, and SecY proteins.     

Partitioning of plasmid R1. Structural and functional analysis of the parA locus

The stability locus, parA+, of plasmid R1 is shown to be localized within a 1500 base-pair region of DNA on the largest EcoRI restriction fragment of plasmid R1. The nucleotide sequence of the region revealed the presence of two open reading frames, one of 320 codons, and another of 60 codons. The larger open reading frame encodes a polypeptide of 36,000 Mr. Deletions covering the promoter distal end of the 36,000 Mr reading frame give rise to synthesis of large amounts of truncated protein. Construction of promoter fusions between the parA+ promoter and the lacZ gene showed that the parA+ region encodes a factor that negatively regulates the expression of the 36,000 Mr protein. The locus exerting parA+-associated incompatibility, denoted incA+, was mapped to a 60 base-pair region covering the parA+ promoter. Most likely, this region is involved both in the negative regulation of the parA+ operon and in the parA+-associated incompatibility. Two explanations are suggested to explain this possible dual function of the parA+ promoter region. The parA+ region was cloned into an unstably inherited (par-) derivative of a mini-F derivative. The low copy number plasmid mini-F devoid of its own partition genes was stabilized more than 100-fold by carrying the parA+ genes. This observation is in accordance with the proposal that the parA+ locus specifies the true partition function of plasmid R1.