Accumulation of guanosine tetraphosphate induced by polymixin and gramicidin in Escherichia coli.

The effects of two polypeptide antibiotics, polymixin B and gramicidin S, on the intracellular pool size and turnover of guanosine tetraphosphate (ppGpp) were analyzed in stringent (relA+) and relaxed (relA) strains of Escherichia coli. When either one of these two drugs was added to stringent bacteria cultures at a final concentration that blocked protein and RNA synthesis, ppGpp was found to accumulate. Under similar conditions of inhibition of macromolecular synthesis, ppGpp also appeared to accumulate in relaxed bacteria. Moreover, in either type of strain, no significant accumulation of guanosine pentaphosphate (pppGpp) could be detected upon drug treatment. It was, therefore, concluded that polymixin and gramicidin elicit ppGpp accumulation through a mechanism independent of the relA gene product and, consequently, quite distinct from the stringent control system triggered by amino acid starvation. Further experiments performed by using tetracycline as an inhibitor of ppGpp synthesis, showed that the increase in the level of this nucleotide induced by drug action was due, in fact, to a strong restriction of its degradation rate.

Functional aspects of bacterial polysomes during limited protein synthesis.

The effects of amino acid starvation on the metabolic behavior of polysomes and the size distribution of proteins have been studied in an otherwise isogenic pair of stringent (relA+) and relaxed (relA) strains of Escherichia coli. The stability of polysomes has been analyzed by using two different approaches. First, the process of their degradation has been followed after treating the cells with rifampicin, an inhibitor of the synthesis of all classes of RNA including messenger RNA. Secondly, the process of their assembly has been studied after their previous conversion to monosomes, as induced by glucose deprivation of cells. It is shown that, in either type of bacterial strain, polysomes are continually broken down and re-synthesized during amino acid starvation. However, such polysome turnover is then less rapid than in normally growing bacteria and, moreover, it seems amino acid specific since it occurs at a lower rate during arginine starvation than during histidine starvation, namely, in the relaxed strain. The molecular weight distribution of proteins has been determined after labeling of cells with radioactive methionine and separation of polypeptides by one-dimensional polyacrylamide gel electrophoresis. The average size of polypeptides synthesized in the stringent strain during starvation is quite similar to that measured during normal growth. By contrast, a significant shift towards smaller molecules is observed in the relaxed strain deprived of an essential amino acid. Here again, this reduction of the size of polypeptides seems amino acid specific since it is especially marked during arginine starvation. These results are discussed in terms of ribosomes translocation and premature peptide chain termination in connection with the accuracy of the translational process.

Isolation, cloning, and expression of a new murine zinc finger encoding gene.

With the aim of identifying genes involved in cartilage differentiation, we have used a subtractive hybridization strategy with cDNAs from a chondrocytic cell line (MC615) and mRNAs from a mesenchymal precursor cell line (10T1/2). We have isolated a cDNA clone representing a novel mouse gene. The predicted 368-amino acid protein, designated ZF-12, contains four C(2)H(2)-type zinc finger motifs and one region homologous to the LeR domain, a finger-associated structural domain. ZF-12 mRNAs are expressed during embryonic development and in different organs in adult, including rib cartilage. These data suggest that ZF-12 might play an important role not only in cartilage differentiation, but also in basic cellular processes.

Phosphorylation of an Escherichia coli protein at tyrosine.

The analysis of protein phosphorylation in the bacterium Escherichia coli showed that, while most phosphoproteins are modified at serine and/or threonine residues, one of them is modified exclusively at tyrosine. This particular protein which has a molecular weight of 54,500 and a pHi value of 5.6 is found associated with the membrane/ribosome fraction of the cell.

Differential pattern of misreading induced by streptomycin in vitro.

A simplified, plasmid-directed coupled system was used to study the effect of streptomycin on the accuracy of natural messenger translation in vitro. The interaction of six different codons with their cognate tRNAs and 18 non-cognate tRNAs was analysed in the presence and absence of the antibiotic. Streptomycin appeared to modify, to a varying extent, the frequency of errors in codon-anticodon recognition. From this observation, some rules for mistranslation were inferred.

Autophosphorylation of a bacterial protein at tyrosine.

Autophosphorylation at tyrosine is a common process in eukaryotic kinases, which is generally modulated by regulatory ligands and affects the properties of these enzymes. We report that this type of modification occurs also in bacteria, namely in an 81 kDa protein from Acinetobacter johnsonii. This protein is phosphorylated at the expense of ATP exclusively at tyrosine residues. It is located in the inner-membrane fraction of cells and can be totally solubilized by detergents. It has been purified to homogeneity by antiphosphotyrosine immunochromatography. Analysis of the peptides released under trypsin proteolysis of the protein has shown that it autophosphorylates at several tyrosine residues. The discovery of protein autophosphorylation in bacteria seems of special interest for studying the regulatory aspects of this modification when considering the relative simplicity of the bacterial systems, as compared with most eukaryotic systems, namely in terms of physiology and genetics.

Specific interactions between the IclR repressor of the acetate operon of Escherichia coli and its operator.

The positions of interference points between the IclR repressor of the acetate operon of Escherichia coli and its specific operator were examined. The number and nature of nucleotides essential to repressor binding were determined by scanning populations of DNA previously methylated at guanine residues by dimethyl sulfate, or depurinated by treatment with formic acid, or depyrimidated by treatment with hydrazine. A total of 46 nucleotides, distributed almost equally between the two strands of the operator region, were found to be functionally important, although to a varying extent. These are clustered in two successive domains which expand from nucleotide -54 to nucleotide -27 and can organize in a palindrome-like structure containing a large proportion of A and T residues.

Relationship between exopolysaccharide production and protein-tyrosine phosphorylation in gram-negative bacteria.

The phosphorylation of proteins at tyrosine residues is known to play a key role in the control of numerous fundamental processes in animal systems. In contrast, the biological significance of protein-tyrosine phosphorylation in bacteria, which has only been recognised recently, is still unclear. Here, we have analysed the role in Escherichia coli cells of an autophosphorylating protein-tyrosine kinase, Wzc, and a phosphotyrosine-protein phosphatase, Wzb, by performing knock-out experiments on the corresponding genes, wzc and wzb, and looking at the metabolic consequences induced. The results demonstrate that the phosphorylation of Wzc, as regulated by Wzb, is directly connected with the production of a particular capsular polysaccharide, colanic acid. Thus, when Wzc is phosphorylated on tyrosine, no colanic acid is synthesised by bacteria, but when dephosphorylated by Wzb, colanic acid is produced. This process is rather specific to the pair of proteins Wzc/Wzb. Indeed, a much lesser effect, if any, on colanic acid synthesis is observed when knock-out experiments are performed on another pair of genes, etk and etp, which also encode respectively a protein-tyrosine kinase, Etk, and a phosphotyrosine-protein phosphatase, Etp, in E. coli. In addition, the analysis of the phosphorylation reaction at the molecular level reveals differences between Gram-negative and Gram-positive bacteria, namely in the number of protein components required for this reaction to occur.

FruR-mediated transcriptional activation at the ppsA promoter of Escherichia coli.

The start site of transcription of the ppsA gene, whose expression is controlled by the regulatory protein FruR in Escherichia coli, was determined by primer extension of in vivo transcripts. The interactions of the ppsA promoter with either RNA polymerase or FruR factor were analysed by the base removal method. Our results indicate that: (i) the RNA polymerase binding site has a -10 extended module but lacks its -35 hexamer; (ii) FruR binds to a target DNA region centered around position -45.5 upstream of the ppsA gene. In addition, circular permutation analysis showed that, upon binding to its site, FruR induces a sharp bend of 120 degrees in the DNA helix, which suggests a crucial involvement of FruR-induced bending in ppsA promoter activation. Direct contacts between the upstream activating DNA and RNA polymerase were studied in an in vitro transcription assay by using reconstituted RNA polymerase mutants containing Ala substitutions in C-terminal domain of their alpha subunit. The alpha[L262A], alpha[R265A] and alpha[N268A] substitutions, which caused the most drastic reduction in the FruR-mediated activation of the ppsA promoter, had previously been shown to inhibit the upstream element-mediated activation at the rrnBP1 promoter.

Functional characterization of the low-molecular-mass phosphotyrosine-protein phosphatase of Acinetobacter johnsonii.

The ptp gene of Acinetobacter johnsonii was previously reported to encode a low-molecular-mass protein, Ptp, whose amino acid sequence, predicted from the theoretical analysis of the nucleotide sequence of the gene, exhibits a high degree of similarity with those of different eukaryotic and prokaryotic phosphotyrosine-protein phophatases. We have now overexpressed the ptp gene in Escherichia coli cells, purified the Ptp protein to homogeneity by a single-step chromatographic procedure, and analysed its functional properties. We have shown that Ptp can catalyse the dephosphorylation of p-nitrophenyl phosphate and phosphotyrosine, but has no effect on phosphoserine or phosphothreonine. Its activity is blocked by ammonium molybdate and sodium orthovanadate, which are strong inhibitors of phosphotyrosine-protein phosphatases, as well as by N-ethylmaleimide and iodoacetic acid. Such specificity of Ptp for phosphotyrosine has been confirmed by the observation that it can dephosphorylate endogenous proteins phosphorylated on tyrosine, but not proteins modified on either serine or threonine. In addition, Ptp has been shown to quantitatively dephosphorylate two exogenous peptides, derived respectively from leech hirudin and human gastrin, previously phosphorylated on tyrosine. Moreover, site-directed mutagenesis experiments performed on Cys11 and Arg16, which are both present in the sequence motif (H/V)C(X5)R(S/T) typical of eukaryotic phosphotyrosine-protein phosphatases, have demonstrated that each amino acid residue is essential for the catalytic activity of Ptp. Taken together, these data provide evidence that Ptp is a member of the phosphotyrosine-protein phosphatase family. Furthermore, in search for the biological function of Ptp, we have found that it can specifically dephosphorylate an endogenous protein kinase, termed Ptk, which is known to autophosphorylate at multiple tyrosine residues in the inner membrane of Acinetobacter johnsonii cells. This represents the first identification of a protein substrate for a bacterial phosphotyrosine-protein phosphatase, and therefore constitutes a possible model for analysing the role of reversible phosphorylation on tyrosine in the regulation of microbial physiology.

In vitro binding of the pleiotropic transcriptional regulatory protein, FruR, to the fru, pps, ace, pts and icd operons of Escherichia coli and Salmonella typhimurium.

Evidence has been presented suggesting that the fructose repressor, FruR, is a pleiotropic transcriptional regulatory protein controlling the expression of numerous operons concerned with carbon metabolism in Escherichia coli and Salmonella typhimurium. We have conducted in vitro DNA binding studies to ascertain the nature of the DNA sequences to which FruR binds. Employing both DNA band migration retardation and DNase I footprint analyses, FruR was found to bind to two operators within the regulatory region preceding the structural genes of the fructose operon, fruB(MH)KA. These two operators, O1 and O2, comprise nearly identical palindromes of 12 bp with a half-site of TGAAAC. The binding of FruR to these inverted repeats was found to be reversed by inclusion of micromolar concentrations of fructose-1-phosphate. The two operators are located between the single putative promoter of the fructose operon and the translational initiation site of the fruB gene. Other regulated operons were shown to bind FruR to a single site upstream of the first structural gene as follows: (1) ppsA (positive regulation); (2) icd (positive regulation); (3) aceB (positive regulation); and (4) pts (negative regulation). In all cases, low concentrations of fructose-1-phosphate displaced the protein from the DNA. The binding sites were determined, and a FruR consensus sequence was established. Computer searches revealed the presence of this sequence in numerous functionally diverse operons, implying that FruR is a global transcriptional regulatory protein in enteric bacteria.

Three-dimensional structure of the DNA-binding domain of the fructose repressor from Escherichia coli by 1H and 15N NMR.

FruR is an Escherichia coli transcriptional regulator that belongs to the LacI DNA-binding protein family. By using 1H and 15N NMR spectroscopy, we have determined the three-dimensional solution structure of the FruR N-terminal DNA-binding domain consisting of 57 amino acid residues. A total of 809 NMR-derived distances and 54 dihedral angle constraints have been used for molecular modelling with the X-PLOR program. The resulting set of calculated structures presents an average root-mean-square deviation of 0.37 A at the main-chain level for the first 47 residues. This highly defined N-terminal part of the structure reveals a similar topology for the three alpha-helices when compared to the 3D structures of LacI and PurR counterparts. The most striking difference lies in the connection between helix II and helix III, in which three additional residues are present in FruR. This connecting segment is well structured and contains a type III turn. Apart from hydrophobic interactions of non-polar residues with the core of the domain, this connecting segment is stabilised by several hydrogen bonds and by the aromatic ring stacking between Tyr19 of helix II and Tyr28 of the turn. The region containing the putative "hinge helix" (helix IV), that has been described in PurR-DNA complex to make specific base contacts in the minor groove of DNA, is unfolded. Examination of hydrogen bonds highlights the importance of homologous residues that seem to be conserved for their ability to fulfill helix N and C-capping roles in the LacI repressor family.

Promoter vectors with restriction-site banks.

New vectors harboring the promoter for the chloramphenicol acetyl transferase gene (cat promoter) have been constructed. These vectors are all derived from pJRD184 [Heusterspreute et al., Gene 39 (1985) 299-304], which contains a restriction-site bank. The cat promoter has been inserted at various positions and in reverse orientations so that almost all the restriction sites originally present on JRD184 can be used in cloning experiments. The expression of the aceK gene of Escherichia coli cloned under the control of the cat promoter has been tested. A large increase in the synthesis of the isocitrate dehydrogenase kinase, the aceK gene product, has demonstrated the efficiency of the newly constructed vectors.

Overproduction, purification and structural characterization of the functional N-terminal DNA-binding domain of the fru repressor from Escherichia coli K-12.

A DNA fragment encoding the DNA-binding domain (amino acids 1-60) of the Escherichia coli fru transcriptional regulator was cloned into the pGEX-KT vector and expressed in frame with the fused gene encoding glutathione S-transferase. The fusion protein was purified to homogeneity by affinity chromatography on immobilized glutathione, and then cleaved with thrombin. After separation by a cation-exchange chromatography step, the DNA-binding domain exhibited proper folding, as shown by proton NMR analysis. Furthermore, it showed specific interaction with the operator region of the ace operon, as checked by gel retardation and DNA methylation-protection experiments.

Characterization of a bacterial gene encoding an autophosphorylating protein tyrosine kinase.

Acinetobacter johnsonii harbors a protein tyrosine kinase activity that is able to catalyze autophosphorylation, like a number of eukaryotic tyrosine kinases. A biochemical and genetic analysis of this enzyme was performed. Maximum phosphorylation in vitro was obtained by incubating the kinase for 2 min at pH 7.0 in the presence of 5 mM magnesium chloride. In contrast to eukaryotic enzymes, no inhibitory effect of genistein and no phosphorylation of synthetic substrates such as poly (Glu80 Tyr20) or angiotensin II were observed. The analysis of the bacterial kinase by two-dimensional gel electrophoresis revealed the presence of at least five isoforms, all phosphorylated exclusively at tyrosine, which supports the concept that autophosphorylation occurs at multiple sites within the protein. The cloning and nucleotide sequencing of the gene encoding this kinase were achieved, which represents the first molecular characterization of a gene of this type in bacteria. An open reading frame of 2199 nucleotides encoding a protein of 82,373 Da was detected. The analysis of the deduced amino acid sequence suggested a possible involvement of the enzyme in cell recognition and bacterial pathogenicity. In addition, the cloning and sequencing of the region immediately upstream of the gene encoding the kinase revealed a novel open reading frame of 426 nucleotides encoding a phosphotyrosine protein phosphatase of 16,217 Da, which indicates that autophosphorylation on tyrosine is a physiologically reversible reaction.

Overproduction and characterization of the iclR gene product of Escherichia coli K-12 and comparison with that of Salmonella typhimurium LT2.

The iclR gene of Escherichia coli K-12, which encodes a regulatory protein (repressor) for the aceBAK operon, is located between that operon and metH in the 91-min region of the chromosome. The iclR gene was cloned and expressed in a coupled T7 RNA polymerase/promoter system and the gene product was identified by specific binding to a fragment containing the aceBAK operator region. The iclR gene product is a polypeptide of 274 amino acids (aa) with a calculated Mr of 29,741. Comparison of the deduced IclR aa sequence to that of Salmonella typhimurium revealed that the two IclR repressors exhibit 89% identity. A possible helix-turn-helix motif characteristic of DNA-binding proteins was found within the IclR sequence. A search in protein data banks revealed that IclR has a score of similarity of 43.7% with GylR, a transcriptional regulator of the glycerol operon of Streptomyces coelicolor.

Cyclic AMP independence of Escherichia coli protein phosphorylation.

The effect of cyclic AMP on protein phosphorylation was analyzed comparatively in two strains of E.coli differing in their capacity to synthesize this nucleotide, one of them lacking the adenylate cyclase activity. The results obtained from both in vivo and in vitro experiments concurred in showing that the bacterial protein kinase activity is cAMP-independent.

A study of bacterial response to polypeptide antibiotics.

When Escherichia coli cells are treated with either polymixin or gramicidin at concentrations that block protein and RNA synthesis, they accumulate a significant amount of guanosine tetraphosphate ppGpp. Such accumulation occurs in stringent (relA+) as well as in relaxed (relA) strains and no guanosine pentaphosphate pppGpp is then detected within the cells. These observations suggest that polypeptide antibiotics elicit ppGpp formation through a mechanism different from the stringent control system triggered by amino acid starvation of bacteria. Experiments based on tetracycline action indicate, moreover, that the accumulation of ppGpp under polymixin or gramicidin treatment is connected with a strong restriction of the degradation rate of this nucleotide.

Two-dimensional analysis of proteins phosphorylated in E. coli cells.

Proteins phosphorylated in Escherichia coli cells were analyzed by the O'Farrell two-dimensional gel technique. Cytoplasmic and ribosomal fractions were studied separately. Double labeling with [32P]orthophosphate and [35S]sulfate followed by selective autoradiographic detection of each radioisotope allowed precise location of 12 major phosphoproteins on the total protein pattern of bacteria. Both the molecular mass and isoelectric point of these phosphoproteins were determined.

Inaccurate protein synthesis in a mutant of Salmonella typhimurium defective in transfer RNA pseudouridylation.

Protein synthesis was studied comparatively in a wild-type strain of Salmonella typhimurium and in hisT mutant cells defective in the pseudouridylation of transfer RNA. From a quantitative point of view, no significant differences between the two types of strain was observed when measuring the rate of protein synthesis during either exponential growth or starvation for histidine. In contrast, the qualitative analysis of proteins by two-dimensional gel electrophoresis showed that histidine-starved hisT cells mistranslate the genetic program at a higher frequency than exponentially growing hisT cells or either starved or unstarved hisT+ cells.