The relA locus specifies a positive effector in branched-chain amino acid transport regulation

Transcriptome analysis of hopanoid deficient mutant of Rhodopseuodomonas palustris TIE-1

All three domains of life have an ordered plasma membrane which is pivotal in the selective fitness of primitive life. Like cholesterol in eukaryotes, hopanoids are important in bacteria to modulate membrane order. Hopanoids are pentacyclic triterpenoid lipids biosynthesised in many eubacteria, few ferns and lichens. Hopanoid modulates outer membrane order and hopanoid deficiency results in the weakened structural integrity of the membrane which may in turn affect the other structures within or spanning the cell envelope and contributing to various membrane functions. Hence, to decipher the role of hopanoid, genome-wide transcriptome of wild-type and Δshc mutant of Rhodopseudomonas palustris TIE-1 was studied which indicated 299 genes were upregulated and 306 genes were downregulated in hopanoid deficient mutant, representing ∼11.5% of the genome. Thirty-eight genes involved in chemotaxis, response to stimuli and signal transduction were differentially regulated and impaired motility in hopanoid deficient mutant showed that hopanoid plays a crucial role in chemotaxis. The docking study demonstrated that diguanylate cyclase which catalyses the synthesis of secondary messenger exhibited the capability to interact with hopanoids and might be confederating in chemotaxis and signal transduction. Seventy-four genes involved in membrane transport were differentially expressed and cell assays also explicit that the multidrug transport is compromised in Δshc mutant. Membrane transport is reliant on hopanoids which may explain the basis for previous observations linking hopanoids to antibiotic resistance. Disturbing the membrane order by targeting lipid synthesis can be a possible novel approach in developing new antimicrobials and hopanoid biosynthesis could be a potential target.

DksA potentiates direct activation of amino acid promoters by ppGpp

Amino acid starvation in Escherichia coli results in a spectrum of changes in gene expression, including inhibition of rRNA and tRNA promoters and activation of certain promoters for amino acid biosynthesis and transport. The unusual nucleotide ppGpp plays an important role in both negative and positive regulation. Previously, we and others suggested that positive effects of ppGpp might be indirect, resulting from the inhibition of rRNA transcription and, thus, liberation of RNA polymerase for binding to other promoters. Recently, we showed that DksA binds to RNA polymerase and greatly enhances direct effects of ppGpp on the negative control of rRNA promoters. This conclusion prompted us to reevaluate whether ppGpp might also have a direct role in positive control. We show here that ppGpp greatly increases the rate of transcription initiation from amino acid promoters in a purified system but only when DksA is present. Activation occurs by stimulation of the rate of an isomerization step on the pathway to open complex formation. Consistent with the model that ppGpp/DksA stimulates amino acid promoters both directly and indirectly in vivo, cells lacking dksA fail to activate transcription from the hisG promoter after amino acid starvation. Our results illustrate how transcription factors can positively regulate transcription initiation without binding DNA, demonstrate that dksA directly affects promoters in addition to those for rRNA, and suggest that some of the pleiotropic effects previously associated with dksA might be ascribable to direct effects of dksA on promoters involved in a wide variety of cellular functions.

Combined, functional genomic-biochemical approach to intermediary metabolism: interaction of acivicin, a glutamine amidotransferase inhibitor, with Escherichia coli K-12

Acivicin, a modified amino acid natural product, is a glutamine analog. Thus, it might interfere with metabolism by hindering glutamine transport, formation, or usage in processes such as transamidation and translation. This molecule prevented the growth of Escherichia coli in minimal medium unless the medium was supplemented with a purine or histidine, suggesting that the HisHF enzyme, a glutamine amidotransferase, was the target of acivicin action. This enzyme, purified from E. coli, was inhibited by low concentrations of acivicin. Acivicin inhibition was overcome by the presence of three distinct genetic regions when harbored on multicopy plasmids. Comprehensive transcript profiling using DNA microarrays indicated that histidine biosynthesis was the predominant process blocked by acivicin. The response to acivicin, however, was quite complex, suggesting that acivicin inhibition resonated through more than a single cellular process.

Mechanism of regulation of transcription initiation by ppGpp. I. Effects of ppGpp on transcription initiation in vivo and in vitro

To determine the role of ppGpp in both negative and positive regulation of transcription initiation during exponential growth in Escherichia coli, we examined transcription in vivo and in vitro from the growth-rate-dependent rRNA promoter rrnB P1 and from the inversely growth-rate-dependent amino acid biosynthesis/transport promoters PargI, PhisG, PlysC, PpheA, PthrABC, and PlivJ. rrnB P1 promoter activity was slightly higher at all growth-rates in strains unable to synthesize ppGpp (deltarelAdeltaspoT) than in wild-type strains. Consistent with this observation and with the large decrease in rRNA transcription during the stringent response (when ppGpp levels are much higher), ppGpp inhibited transcription from rrnB P1 in vitro. In contrast, amino acid promoter activity was considerably lower in deltarelAdeltaspoT strains than in wild-type strains, but ppGpp had no effect on amino acid promoter activity in vitro. Detailed kinetic analysis in vitro indicated that open complexes at amino acid promoters formed much more slowly and were much longer-lived than rrnB P1 open complexes. ppGpp did not increase the rates of association with, or escape from, amino acid promoters in vitro, consistent with its failure to stimulate transcription directly. In contrast, ppGpp decreased the half-lives of open complexes at all promoters, whether the half-life was seconds (rrnB P1) or hours (amino acid promoters). The results described here and in the accompanying paper indicate that ppGpp directly inhibits transcription, but only from promoters like rrnB P1 that make short-lived open complexes. The results indicate that stimulation of amino acid promoters occurs indirectly. The accompanying paper evaluates potential models for positive control of amino acid promoters by ppGpp that might explain the requirement of ppGpp for amino acid prototrophy.

Starvation as an inducer of error-free DNA repair in Escherichia coli

Previous work in this laboratory has shown that heat shock or vitamin B1 deprivation induces an error-free DNA-repair process in Escherichia coli. The system is absolutely dependent on excision repair, while its induction is delayed in lon- or recA- cells. We have now shown that starvation of E. coli for amino acids, glucose or phosphate, conditions known to induce the stringent response or the glu and pho regulons, respectively, leads to a similar uvrA-dependent increase in UV resistance and decrease in UV-induced mutation frequency. These results support the hypothesis that the effect is a general response to non-mutagenic stress that may play an important role in the survival of cells exposed to harsh environments.

[Nucleoside polyphosphates: occurrence, metabolism and function]

Procaryotes have regulatory systems allowing to vary the metabolism in response to nutritional variations, to reduce the growth, and to start development. Nucleoside polyphosphates are mediators of coordinated alterations of metabolism. In this review, after a brief recall of the characteristics of the stringent response, the occurrence, determinations, and the metabolism of the nucleoside polyphosphates are presented. The representation of the pleiotropic effects includes the regulation of the protein synthesis and of the protein synthesis apparatus, of the protein turnover, of the N- and carbohydrate metabolism, of the formation of cell membranes and cell walls as well as the possible function of the development.

Stringent control and protein synthesis in bacteria

Most bacteria have evolved a number of regulatory mechanisms which allow them to maintain a balanced and rather constant cellular composition in response to nutritional variations. In particular, when the availability of any aminoacyl-tRNA species becomes limiting (namely through amino acid starvation or inactivation of an aminoacyl-tRNA synthetase), several biochemically distinct physiological processes are significantly modified. This coordinate adjustment of cellular activity is termed the "stringent response". Under such conditions of aminoacyl-tRNA limitation, protein synthesis still proceeds, but various quantitative as well as qualitative changes in polypeptide metabolism can be observed. In this review, after a brief recall of the main characteristics of the stringent response, several aspects concerning protein synthesis in deprived bacteria have been presented. First, the rates of residual protein formation, peptide chain growth and protein degradation, and the molecular weight distribution of proteins newly synthesized have been analyzed. Then, the data relative to the biosynthetic regulation of non-ribosomal and ribosomal proteins have been summarized and compared to the results obtained from in vitro experiments using transcription-translation coupled systems. Finally, the problem of translational fidelity during deprivation has been discussed in connection with the metabolic behavior of polysomal structures which are still maintained in cells. The stringent dependence of cellular activity on aminoacyl-tRNA supply is known to be abolished by single-site mutations which confer to bacteria a phenotype referred to as "relaxed". These mutant strains provide an useful analytical tool in the scope of understanding the stringency phenomenon. Therefore, their proteosynthetic activity under aminoacyl-tRNA deprivation has also been studied here, in comparison to that of normal wild-type strains.

The relA locus and the regulation of lysine biosynthesis in Escherichia coli

The allelic state of relA influences the phenotype of Escherichia coli strains carrying the lysA22 mutation:lysA22 relA strains are Lys- where lysA22 relA+ strains grow (slowly) in the absence of lysine. This physiological effect has been related to an effect of the expression of the relA locus on the regulation of lysine biosynthesis. The fully derepressed levels of some lysine enzymes (aspartokinase III, aspartic semialdehyde dehydrogenase, didhydrodipicolinate reductase) are observed under lysine limitation only in rel+ strains. And the induction of DAP-decarboxylase by DAP is much higher in rel+ than in rel- strains when an amino acid limitation of growth is also realised. These results are in agreement with the hypothesis of Stephens et al. (1975) on a possible role of the stringent regulation as a general signal for amino acid deficiency.

Biochemistry and regulation of a second L-proline transport system in Salmonella typhimurium

This paper reports some biochemical characteristics of a second L-proline transport system in Salmonella typhimurium. In the accompanying paper, R. Menzel and J. Roth (J. Bacteriol. 141:1064--1070, 1980) have identified this system by showing that it is inactivated by mutations at the locus proP. We have found that it is an active transport system with an apparent Km for L-proline of 3 x 10(-4) M and a strict specificity for L-proline and some of its analogs. Unlike the L-proline transport system encoded in putP, this second system is induced by amino acid limitation.

Regulation of high-affinity leucine transport in Escherichia coli

Leucine is transported into E coli by two osmotic shock-sensitive, high-affinity systems (LIV-I and leucine-specific systems) and one membrane bound, low-affinity system (LIV-II). Expression of the high-affinity transport systems is altered by mutations in livR and 1stR, genes for negatively acting regulatory elements, and by mutations in rho, the gene for transcription termination. All four genes for high-affinity leucine transport (livJ, livK, livH, and livG) are closely linked and have been cloned on a plasmid vector, pOX1. Several subcloned fragments of this plasmid have been prepared and used in complementation and regulation studies. The results of these studies suggest that livJ and livK are separated by approximately one kilobase and give a gene order of livJ-livK-livH. livJ and livK appear to be regulated in an interdependent fashion; livK is expressed maximally when the livJ gene is activated by mutation or deletion. The results support the existence of separate promotors for the livJ and livK genes. The effects of mutations in the rho and livR genes are additive on one another and therefore appear to be involved in independent regulatory mechanisms. Mutations in the rho gene affect both the LIV-I and leucine-specific transport systems by increasing the expression of livJ and livK, genes for the LIV-specific and leucine-specific binding proteins, respectively.