SummaryH-NS is a small chromatin-associated protein found in enterobacteria. H-NS has affinity for all types of nucleic acids but binds preferentially to intrinsically curved DNA. The major role of H-NS is to modulate the expression of a large number of genes, mostly by negatively affecting transcription. Many of the H-NS-modulated genes are regulated by environmental signals, and expression of most of these genes is positively regulated by specific transcription factors. Therefore one of the purposes of H-NS could be to repress expression of some genes under conditions characteristic of a non-intestinal environment, but allow expression of specific genes in response to certain stimuli in the intestinal environment. The hns gene is autoregulated. In vivo the H-NS to DNA ratio is fairly constant except during cold shock, when it increases threeto fourfold. In this review we propose that only the preferential binding to intrinsically curved DNA plays a role under normal growth conditions, and we discuss the different mechanisms by which H-NS might affect gene expression and how H-NS could be involved in the response to different stress situations. Finally, we summarize the evolutionary and functional relationship between H-NS and the homologous StpA.
The parB region of plasmid R1 encodes two genes, hok and sok, which are required for the plasmid‐stabilizing activity exerted by parB. The hok gene encodes a potent cell‐killing factor, and it is regulated by the sok gene product such that cells losing a parB‐carrying plasmid during cell division are rapidly killed. Coinciding with death of the host cell, a characteristic change in morphology is observed. Here we show that the killing factor encoded by the hok gene is a membrane‐associated polypeptide of 52 amino acids. A gene located in the Escherichia coli relB operon, designated relF, is shown to be homologous to the hok gene. The relF gene codes for a polypeptide of 51 amino acids, which is 40% homologous to the hok gene product. Induced overexpression of the hok and relF gene products results in the same phenomena: loss of cell membrane potential, arrest of respiration, death of the host cell and change in cell morphology. The parB region and the relB genes were cloned into unstably inherited oriC minichromosomes. Whereas the parB region also conferred a high degree of genetic stability to an oriC minichromosome, the relB operon (with relF) did not; therefore the latter does not appear to ‘stabilize’ its replicon (the chromosome). The function of the relF gene is not known.
The DnaA protein concentration in Escherichia coli was increased above the wild-type level by inducing a lacP-controlled dnaA gene located on a plasmid. In these cells with different DnaA protein levels, we measured several parameters: dnaA gene expression; cell size, amount of DNA per cell, and number of origins per cell by flow cytometry; and origin-to-terminus ratio and the frequencies of five other markers on the chromosome by Southern hybridization. The response of the cells to higher levels of DnaA protein could be divided into three states. From the normal level to a level 1.5-fold higher, DnaA protein had little effect on dnaA gene expression and the rate of DNA replication but led to nearly proportional increases in DNA and origin concentrations. Between 1.5- and 3-fold, the normal DnaA protein concentration, dnaA gene expression was gradually decreased. In this interval, the origin concentration increased significantly; however, the replication rate was severely affected, becoming slower--especially near the origin--the higher the DnaA protein concentration, and as a result, the DNA concentration was constant. Further increases in the DnaA protein concentration did not lead to an increased origin concentration. Thus, the initiation mass was set by the DnaA protein from the normal level to an at least twofold-increased level, but the increased initiation did not lead to a large increase in the amount of DNA per unit of mass because of the inhibition of replication fork velocity.
Regulation of the dnaA gene, which codes for an essential factor for the initiation of replication from the chromosomal origin, was studied in vivo using transcriptional and translational gene fusions. We found that the dnaA gene was autoregulated over a 30-fold range by the activity of dnaA protein. Expression from the dnaA promoter region of a dnaA"lacZ fusion was inhibited up to sevenfold by surplus dnaA protein and was stimulated up to fivefold upon thermoinactivation of the mutant protein in five different dnaA(Ts) strains. The autoregulation was found to be exerted at transcription from the major dnaA promoter and was eliminated by deletion of sequences around position -65 of this promoter where a 9-bp sequence, which is also found four times in the chromosomal origin, is located.
The DnaA protein concentration was determined in five different Escherichia coli strains and in Salmonella typhimurium LT2 growing at different growth rates. The DnaA protein concentration was found to be invariant over a wide range of growth rates in the four E. coli K-12 strains and in S. typhimurium. In E. coli B/r the DnaA protein concentration was generally higher than in the K-12 strains, and it increased with decreasing growth rates. For all the strains, there appears to be a correlation between the DnaA protein concentration and the initiation mass. This supports the concept of the conentration of DnaA protein setting the initiation mass and, thus, that the DnaA protein is a key molecule in the regulation of initiation of chromosome replication in members of the family Enterobacteriaceae.
Using a transcriptional fusion to the lacZ gene, we have analyzed the anaerobic regulation of the hydrogenase 1 (hya) operon in response to different anaerobic growth conditions and to mutations in regulatory genes. We found that the transcription of the hya operon was induced when the growth condition was changed from aerobic to anaerobic and that this induction was independent of Fnr but dependent on regulators AppY and ArcA. Furthermore, we found that the transcription of the hya operon was not regulated by the cyclic AMP-cyclic AMP receptor protein complex. Investigation of the effects of different anaerobic growth conditions on the expression of the hya operon showed that expression was induced by formate and repressed by nitrate.Formate induction was not mediated by thejhL4 gene product, and nitrate repression was not mediated by the narL gene product. We found a high level of anaerobic expression of the hya operon in glucose medium supplemented with formate and in glycerol medium supplemented with fumarate, suggesting that hydrogenase isoenzyme 1 has a function during both fermentative growth and anaerobic respiration.
More than 50 years have passed since the presentation of the Replicon Model which states that a positively acting initiator interacts with a specific site on a circular chromosome molecule to initiate DNA replication. Since then, the origin of chromosome replication, oriC, has been determined as a specific region that carries sequences required for binding of positively acting initiator proteins, DnaA-boxes and DnaA proteins, respectively. In this review we will give a historical overview of significant findings which have led to the very detailed knowledge we now possess about the initiation process in bacteria using Escherichia coli as the model organism, but emphasizing that virtually all bacteria have DnaA proteins that interacts with DnaA boxes to initiate chromosome replication. We will discuss the dnaA gene regulation, the special features of the dnaA gene expression, promoter strength, and translation efficiency, as well as, the DnaA protein, its concentration, its binding to DnaA-boxes, and its binding of ATP or ADP. Furthermore, we will discuss the different models for regulation of initiation which have been proposed over the years, with particular emphasis on the Initiator Titration Model.
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