Interplay between DnaA and SeqA proteins during regulation of bacteriophage lambda pR promoter activity.

DnaA and SeqA proteins are main regulators (positive and negative, respectively) of the chromosome replication in Escherichia coli. Nevertheless, both these replication regulators were found recently to be also transcription factors. Interestingly, both DnaA and SeqA control activity of the bacteriophage lambdap(R) promoter by binding downstream of the transcription start site, which is unusual among prokaryotic systems. Here we asked what are functional relationships between these two transcription regulators at one promoter region. Both in vivo and in vitro studies revealed that DnaA and SeqA can activate the p(R) promoter independently and separately rather than in co-operation, however, increased concentrations of one of these proteins negatively influenced the transcription stimulation mediated by the second regulator. This may suggest a competition between DnaA and SeqA for binding to the p(R) regulatory region. The physiological significance of this DnaA and SeqA-mediated regulation of p(R) is demonstrated by studies on lambda plasmid DNA replication in vivo.

SeqA-mediated stimulation of a promoter activity by facilitating functions of a transcription activator.

It was demonstrated recently that the SeqA protein, a main negative regulator of Escherichia coli chromosome replication initiation, is also a specific transcription factor. SeqA specifically activates the bacteriophage lambda pR promoter while revealing no significant effect on the activity of another lambda promoter, pL. Here, we demonstrate that lysogenization by bacteriophage lambda is impaired in E. coli seqA mutants. Genetic analysis demonstrated that CII-mediated activation of the phage pI and paQ promoters, which are required for efficient lysogenization, is less efficient in the absence of seqA function. This was confirmed in in vitro transcription assays. Interestingly, SeqA stimulated CII-dependent transcription from pI and paQ when it was added to the reaction mixture before CII, although having little effect if added after a preincubation of CII with the DNA template. This SeqA-mediated stimulation was absolutely dependent on DNA methylation, as no effects of this protein were observed when using unmethylated DNA templates. Also, no effects of SeqA on transcription from pI and paQ were observed in the absence of CII. Binding of SeqA to templates containing the tested promoters occurs at GATC sequences located downstream of promoters, as revealed by electron microscopic studies. In contrast to pI and paQ, the activity of the third CII-dependent promoter, pE, devoid of neighbouring downstream GATC sequences, was not affected by SeqA both in vivo and in vitro. We conclude that SeqA stimulates transcription from pI and paQ promoters in co-operation with CII by facilitating functions of this transcription activator, most probably by allowing more efficient binding of CII to the promoter region.

Degradation of mutant initiator protein DnaA204 by proteases ClpP, ClpQ and Lon is prevented when DNA is SeqA-free.

A mutant form of the Escherichia coli replication initiator protein, DnaA204, is unstable. At low growth rates, the dnaA204 mutant cells experience a limitation of initiator protein and grow with reduced initiation frequency and DNA concentration. The mutant DnaA protein is stabilized by the lack of SeqA protein. This stabilization was also observed in a dam mutant where the chromosome remains unmethylated. Since unmethylated DNA is not bound by SeqA, this indicates that DnaA204 is not stabilized by the lack of SeqA protein by itself, but rather by lack of SeqA complexed with DNA. Thus the destabilization of DnaA204 may be due either to interaction with SeqA-DNA complexes or changes in nucleoid organization and superhelicity caused by SeqA. The DnaA204 protein was processed through several chaperone/protease pathways. The protein was stabilized by the presence of the chaperones ClpA and ClpX and degraded by their cognate protease ClpP. The dnaA204 mutant was not viable in the absence of ClpY, indicating that this chaperone is essential for DnaA204 stability or function. Its cognate protease ClpQ, as well as Lon protease, degraded DnaA204 to the same degree as ClpP. The chaperones GroES, GroEL and DnaK contributed to stabilization of DnaA204 protein.

Overexpression of the cgtA (yhbZ, obgE) gene, coding for an essential GTP-binding protein, impairs the regulation of chromosomal functions in Escherichia coli.

GTPases belonging to the Obg/Gtp1 subfamily are essential proteins in most bacterial species and are evolutionarily conservative from bacteria to humans. However, their specific functions in the regulation of cellular processes are largely unknown. Here we demonstrate that overproduction of a member of the Obg/Gtp1 subfamily, cgtA ( yhbZ, obgE) gene product, in Escherichia coli is deleterious for bacterial growth. However, syntheses of DNA, RNA, and proteins were not significantly affected under these conditions as measured by efficiency of incorporation of radioactive precursors. On the other hand, flow cytometry studies revealed that cgtA-overexpressing bacteria form enlarged cells with significantly changed distribution of chromosomal DNA. These results strongly suggest that overproduction of a GTP-binding protein from the Obg/Gtp1 subfamily impairs regulation of some chromosomal functions in E. coli, especially synchronization of DNA replication initiation and possibly also partitioning of daughter chromosomes after a replication round.

Impaired chromosome partitioning and synchronization of DNA replication initiation in an insertional mutant in the Vibrio harveyi cgtA gene coding for a common GTP-binding protein.

The Vibrio harveyi cgtA gene product belongs to a subfamily of small GTP-binding proteins, called Obg-like proteins. Members of this subfamily are present in diverse organisms ranging from bacteria to humans. On the other hand, the functions of these proteins in the regulation of cellular processes are largely unknown. Genes coding for these proteins are essential in almost all bacteria investigated thus far. However, a viable V. harveyi insertional mutant in the cgtA gene was described recently. Therefore, this mutant gives a unique opportunity to study functions of a member of the subfamily of Obg-like proteins. Here we demonstrate that the mutant cells often form long filaments with expanded, non-partitioned or rarely partitioned chromosomes. Such a phenotype suggests impairment of the mechanism of chromosome partition. Flow cytometric studies revealed that synchronization of chromosome replication initiation is also significantly disturbed in the cgtA mutant. Moreover, in contrast to wild-type V. harveyi, inhibition of chromosome replication and/or of cell division in the mutant bacteria caused significant increase in the number of large cells, suggesting that the cgtA gene product may be involved in the coupling of cell growth to chromosome replication and cell division. These results indicate that CgtA, an Obg-like GTP-binding protein, plays an important role in the regulation of chromosomal functions.

A role for the common GTP-binding protein in coupling of chromosome replication to cell growth and cell division.

Homologues of CgtA, the common GTP-binding protein of Vibrio harveyi, are present in diverse organisms ranging from bacteria to humans. In bacteria, proteins homologous to CgtA form a subfamily of small GTP-binding proteins, called Obg/Gtp1. Similarity between bacterial members of this subfamily and their eukaryotic homologues is as high as about 50%. Nevertheless, specific functions of these proteins remain largely unknown. Genes coding for CgtA-like proteins are essential in almost all species of bacteria. The only known exception is V. harveyi, whose cells survive disruption of the cgtA gene. Therefore, the V. harveyi cgtA insertional mutant is a very useful tool for studies on functions of CgtA. Here we demonstrate that under normal growth conditions, cells of the cgtA mutant are slightly larger than wild-type cells, whereas indirect inhibition of DNA replication initiation by addition of rifampicin results in significantly higher differences in average cell size between these two strains as measured by flow cytometry. These differences decreased when cell division was inhibited by cephalexin. DNA synthesis per cell mass was found to be increased in the cgtA mutant relative to wild-type V. harveyi strain, whereas the mutant cells grew slower than bacteria with functional cgtA gene. Kinetics of DNA replication after inhibition of cell division was also considerably different in wild-type and cgtA mutant strains. These results suggest that the cgtA gene product plays a role in coupling of DNA replication to cell growth and cell division.