On the multiple functional roles of the active site histidine in catalysis and allosteric regulation of Escherichia coli glucosamine 6-phosphate deaminase.

The active site of glucosamine-6-phosphate deaminase (EC 3.5.99.6, formerly 5.3.1.10) from Escherichia coli was first characterized on the basis of the crystallographic structure of the enzyme bound to the competitive inhibitor 2-amino-2-deoxy-glucitol 6-phosphate. The structure corresponds to the R allosteric state of the enzyme; it shows the side-chain of His143 in close proximity to the O5 atom of the inhibitor. This arrangement suggests that His143 could have a role in the catalysis of the ring-opening step of glucosamine 6-phosphate whose alpha-anomer is the true substrate. The imidazole group of this active-site histidine contacts the carboxy groups from Glu148 and Asp141, via its Ndelta1 atom [Oliva et al. (1995) Structure 3, 1323-1332]. These interactions change in the T state because the side chain of Glu148 moves toward the allosteric site, leaving at the active site the dyad Asp141-His143 [Horjales et al. (1999) Structure 7, 527-536]. In this research, a dual approach using site-directed mutagenesis and controlled chemical modification of histidine residues has been used to investigate the role of the active-site histidine. Our results support a multifunctional role of His143; in the forward reaction, it is involved in the catalysis of the ring-opening step of the substrate, glucosamine 6-P. In the reverse reaction, the substrate fructose 6-P binds in its open chain, carbonylic form. The role of His143 in the binding of both glucosamine 6-P and reaction intermediates in their extended-chain forms was demonstrated by binding experiments using the reaction intermediate analogue, 2-amino-2-deoxy-D-glucitol 6-phosphate. His143 was also shown to be a critical residue for the conformational coupling between active and allosteric sites. From the pH dependence of the reactivity of the active site histidine to diethyl dicarbonate, we observed a pK(a) change of 1.2 units to the acid side when the enzyme undergoes the allosteric T to R transition during which the side chain of Glu148 moves toward the active site. The kinetic study of the Glu148-Gln mutant deaminase shows that the loss of the carboxy group and its replacement with the corresponding amide modifies the k(cat) versus pH profile of the enzyme, suggesting that the catalytic step requiring the participation of His143 has become rate-limiting. This, in turn, indicates that the interaction Glu148-His143 in the wild-type enzyme in the R state contributes to make the enzyme functional over a wide pH range.

N-acetylglucosamine-6-phosphate deacetylase from Escherichia coli: purification and molecular and kinetic characterization.

N-Acetylglucosamine-6-phosphate deacetylase (E.C. 3.5.1.25), an enzyme of the amino sugar utilization pathway, has been purified from an overproducing strain of Escherichia coli. The enzyme is a tetramer of identical 41-kDa subunits. The sedimentation coefficient of the oligomer is 6.5 s(20),w and it has a pI of 4.9. The circular dichroism spectrum of the enzyme in the far uv range suggests that it is a protein belonging to the alpha/beta structural family. In the native enzyme, two thiols per chain are titrated with 5-5'-dithio-bis(2-nitrobenzoate) (NbS2); one reacts rapidly, the other more slowly. The reaction of the more reactive sulfhydryl completely inhibits the activity of the enzyme. Three thiols, of the total of eight per subunit of the native enzyme, are modified by methyl iodide without significantly changing the kinetic parameters; the methylated enzyme becomes insensitive to NbS2 inhibition. One of the enzyme reaction products, glucosamine 6-phosphate, completely protects this thiol from NbS2 reaction. The kinetics of the deacetylase reaction have been studied both in the forward direction and in the backward direction. The reverse reaction is strongly unfavored and is probably physiologically insignificant, but it was useful for obtaining a better kinetic description of the enzyme. A sequential mechanism, with ordered release of products and a slow isomerization of the enzyme-acetate complex, is proposed. This model is supported by data from substrate and product inhibition patterns in both directions of the reaction.

Asymmetric allosteric activation of Escherichia coli glucosamine-6-phosphate deaminase produced by replacements of Tyr 121.

Tyrosine 121, a residue located in a alpha-helical polypeptide segment of glucosamine 6-phosphate deaminase from Escherichia coli, has recently been proposed to have a role in the binding of the allosteric activator N-acetyl-D-glucosamine 6-phosphate. Accordingly, the site-directed mutants Tyr 121-Thr and Tyr 121-Trp were constructed, to assess experimentally the role of Tyr 121 in the allosteric function of the enzyme. The kinetic study of both mutant forms revealed that the replacements caused striking changes in allosteric activator binding and allosteric properties, when compared to the wild-type enzyme. While the wild-type deaminase behaves as a classical allosteric K-system which can be described by the allosteric concerted model, both mutant forms present an asymmetric behavior toward the allosteric activator, which can be described as two distinct half-of-the-sites allosteric activation steps occurring with different affinities for the N-acetyl-D-glucosamine 6-phosphate. During the first (high affinity) activation phase, the mutant forms of deaminase behave as mixed K/V allosteric enzyme. The biphasic activation curve was also demonstrated by direct binding measurements of the 14C-labeled activator to Tyr 121-Trp and Tyr 121-Thr deaminases. The kinetic analysis of these mutant forms also showed that the threonine replacement produced an important distortion of the enzyme structure reflected in a considerable decrease of its catalytic efficiency.(ABSTRACT TRUNCATED AT 250 WORDS)

Ribosomal protein methylation in Escherichia coli: the gene prmA, encoding the ribosomal protein L11 methyltransferase, is dispensable.

The prmA gene, located at 72 min on the Escherichia coli chromosome, is the genetic determinant of ribosomal protein L11-methyltransferase activity. Mutations at this locus, prmA1 and prmA3, result in a severely undermethylated form of L11. No effect, other than the lack of methyl groups on L11, has been ascribed to these mutations. DNA sequence analysis of the mutant alleles prmA1 and prmA3 detected point mutations near the C-terminus of the protein and plasmids overproducing the wild-type and the two mutant proteins have been constructed. The wild-type PrmA protein could be crosslinked to its radiolabelled substrate, S-adenosyl-L-methionine (SAM), by u.v. irradiation indicating that it is the gene for the methyltransferase rather than a regulatory protein. One of the mutant proteins, PrmA3, was also weakly crosslinked to SAM. Both mutant enzymes when expressed from the overproducing plasmids were capable of catalysing the incorporation of 3H-labelled methyl groups from SAM to L11 in vitro. This confirmed the observation that the mutant proteins possess significant residual activity which could account for their lack of growth phenotype. However, a strain carrying an in vitro-constructed null mutation of the prmA gene, transferred to the E. coli chromosome by homologous recombination, was perfectly viable.

Glucosamine-6-phosphate deaminase from Escherichia coli has a trimer of dimers structure with three intersubunit disulphides.

Glucosamine-6-phosphate deaminase is an oligomeric protein composed of six identical 29.7 kDa subunits. Each subunit has four cysteine residues located at positions 118, 219, 228 and 239. We have previously shown that Cys-118 and Cys-239 form a pair of vicinal thiols, the reactivity of which changes with the allosteric transition. The site-directed mutations Cys-->Ser corresponding to the other two cysteine residues have been constructed, as well as some selected multiple mutations involving the four cysteines. Thiol and disulphide measurements on the wild-type and mutant enzymes indicate that thiols from Cys-219 are oxidized and form interchain disulphide bonds. The disulphide-linked dimer was demonstrated by SDS/PAGE. This result is consistent with preliminary crystallographic data and thermal denaturation studies, and strongly suggests that glucosamine-6-phosphate deaminase is a trimer of disulphide-linked dimers. The mutant forms of the deaminase lacking the interchain disulphide bond or the thiol at Cys-228 are both stable hexamers showing the same sensitivity to urea denaturation as the wild-type protein. Furthermore, these Cys-->Ser mutants display the same kinetics and allosteric properties as those already described for the wild-type enzyme.

Cotranscription of two genes necessary for ribosomal protein L11 methylation (prmA) and pantothenate transport (panF) in Escherichia coli K-12.

Genetic complementation and enzyme assays have shown that the DNA region between panF, which encodes pantothenate permease, and orf1, the first gene of the fis operon, encodes prmA, the genetic determinant for the ribosomal protein L11 methyltransferase. Sequencing of this region identified one long open reading frame that encodes a protein of 31,830 Da and corresponds to the prmA gene. We found, both in vivo and in vitro, that prmA is expressed from promoters located upstream of panF and thus that the panF and prmA genes constitute a bifunctional operon. We located the major 3' end of prmA transcripts 90 nucleotides downstream of the stop codon of prmA in the DNA region upstream of the fis operon, a region implicated in the control of the expression of the fis operon. Although no promoter activity was detected immediately upstream of prmA, S1 mapping detected 5' ends of mRNA in this region, implying that some mRNA processing occurs within the bicistronic panF-prmA mRNA.

Coordinated regulation of amino sugar-synthesizing and -degrading enzymes in Escherichia coli K-12.

The intracellular concentration of the enzyme glucosamine-6-phosphate synthase, encoded by the gene glmS in Escherichia coli, is repressed about threefold by growth on the amino sugars glucosamine and N-acetylglucosamine. This regulation occurs at the level of glmS transcription. It is not due just to the presence of intracellular amino sugar phosphates, because mutations which derepress the genes of the nag regulon (coding for proteins involved in the uptake and metabolism of N-acetylglucosamine) also repress the expression of glmS in the absence of exogenous amino sugars.

A dominant mutation in the gene for the Nag repressor of Escherichia coli that renders the nag regulon uninducible.

The gene nagC encodes the repressor for the nag regulon. A point mutation within the gene, which confers a super-repressor phenotype and makes the repressor insensitive to the inducer, N-acetylglucosamine 6-phosphate, has been characterized. The mutation is semi-dominant since heterozygous diploids have reduced growth rates on glucosamine and N-acetylglucosamine compared to the wild-type strain.

Identification of two cysteine residues forming a pair of vicinal thiols in glucosamine-6-phosphate deaminase from Escherichia coli and a study of their functional role by site-directed mutagenesis.

The nucleotide sequence of the nagB gene in Escherichia coli, encoding glucosamine-6-phosphate deaminase, located four cysteinyl residues at positions 118, 219, 228, and 239. Chemical modification studies performed with the purified enzyme had shown that the sulfhydryl groups of two of these residues form a vicinal pair in the enzyme and are easily modified by thiol reagents. The allosteric transition to the more active conformer (R), produced by the binding of homotropic (D-glucosamine 6-phosphate or 2-deoxy-2-amino-D-glucitol 6-phosphate) or heterotropic (N-acetyl-D-glucosamine 6-phosphate) ligands, completely protected these thiols against chemical modification. Selective cyanylation of the vicinal thiols with 2-nitro-5-(thiocyanato)benzoate, followed by alkaline hydrolysis to produce chain cleavage at the modified cysteines, gave a pattern of polypeptides which allowed us to identify Cys118 and Cys239 as the residues forming the thiol pair. Subsequently, three mutated forms of the gene were constructed by oligonucleotide-directed mutagenesis, in which one or both of the cysteine codons were changed to serine. The mutant proteins were overexpressed and purified, and their kinetics were studied. The dithiol formed by Cys118 and Cys239 was necessary for maximum catalytic activity. The single replacements and the double mutation affected catalytic efficiency in a similar way, which was also identical to the effect of the chemical block of the thiol pair. However, only one of these cysteinyl residues, Cys239, had a significant role in the allosteric transition, and its substitution for serine reduced the allosteric interaction energy, due to a lower value of KT.

Repression and induction of the nag regulon of Escherichia coli K-12: the roles of nagC and nagA in maintenance of the uninduced state.

The nag regulon located at 15.5 min on the Escherichia coli chromosome consists of two divergent operons, nagE and nagBACD, encoding genes involved in the uptake and metabolism of N-acetylglucosamine. Null mutations have been created in each of the genes by insertion of antibiotic resistance cartridges. The phenotypes of the strains carrying the insertions in nagE, B and A were consistent with the previous identification of gene products: nagE, EII(Nag), the N-acetylglucosamine specific transporter of the phosphotransferase system and nagB and nagA, the two enzymes necessary for the degradation of N-acetylglucosamine. Insertions in the nagC result in derepression of the nag genes, which is consistent with earlier observations that the nagC gene encodes the repressor of the regulon. Insertions in nagA also provoke a derepression, implying that nagA has a role in the regulation of the expression of the nag regulon as well as in the degradation of the amino-sugars. N-acetylglucosamine-6-phosphate, the intracellular product of N-acetylglucosamine transport and the substrate of the nagA gene product, is shown to be an inducer of the regulon and this suggests how nagA mutations result in derepression: the absence of N-acetylglucosamine-6-phosphate deacetylase allows N-acetylglucosamine-6-phosphate to accumulate and induce the regulon.

A severely truncated form of translational initiation factor 2 supports growth of Escherichia coli.

We have constructed strains carrying null mutations in the chromosomal copy of the gene for translational initiation factor (IF) 2 (infB). A functional copy of the infB gene is supplied in trans by a thermosensitive lysogenic lambda phage integrated at att lambda. These strains enabled us to test in vivo the importance of different structural elements of IF2 expressed from genetically engineered plasmid constructs. We found that, as expected, the gene for IF2 is essential. However, a protein consisting of the C-terminal 55,000 Mr fragment of the wild-type IF2 protein is sufficient to allow growth when supplied in excess. This result suggests that the catalytic properties are localized in the C-terminal half of the protein, which includes the G-domain, and that this fragment is sufficient to complement the IF2 deficiency in the infB deletion strain.

Secondary structure of Escherichia coli glucosamine-6-phosphate deaminase from amino acid sequence and circular dichroism spectroscopy.

The secondary structure of the purified glucosamine-6-phosphate deaminase from Escherichia coli K12 was investigated by both circular dichroism (CD) spectroscopy and empirical prediction methods. The enzyme was obtained by allosteric-site affinity chromatography from an overproducing strain bearing a pUC18 plasmid carrying the structural gene for the enzyme. From CD analysis, 34% of alpha-helix, 9% of parallel beta-sheet, 11% of antiparallel beta-sheet, 15% turns and 35% of non-repetitive structures, were estimated. A joint prediction scheme, combining six prediction methods with defined rules using several physicochemical indices, gave the following values: alpha-helix, 37%; beta-sheet, 22%; turns, 18% and coil, 23%. The structure predicted showed also a considerable degree of alternacy of alpha and beta structures; 64% of helices are amphipathic and 90% of beta-sheets are hydrophobic. Overall, the data suggest that deaminase has as dominant motif, an alpha/beta structure.

Induction of the nag regulon of Escherichia coli by N-acetylglucosamine and glucosamine: role of the cyclic AMP-catabolite activator protein complex in expression of the regulon.

The divergent nag regulon located at 15.5 min on the Escherichia coli map encodes genes necessary for growth on N-acetylglucosamine and glucosamine. Full induction of the regulon requires both the presence of N-acetylglucosamine and a functional cyclic AMP (cAMP)-catabolite activator protein (CAP) complex. Glucosamine produces a lower level of induction of the regulon. A nearly symmetric consensus CAP-binding site is located in the intergenic region between nagE (encoding EIINag) and nagB (encoding glucosamine-6-phosphate deaminase). Expression of both nagE and nagB genes is stimulated by cAMP-CAP, but the effect is more pronounced for nagE. In fact, very little expression of nagE is observed in the absence of cAMP-CAP, whereas 50% maximum expression of nagB is observed with N-acetylglucosamine in the absence of cAMP-CAP. Two mRNA 5' ends separated by about 100 nucleotides were located before nagB, and both seem to be similarly subject to N-acetylglucosamine induction and cAMP-CAP stimulation. To induce the regulon, N-acetylglucosamine or glucosamine must enter the cell, but the particular transport mechanism used is not important.

Sequence of the nagBACD operon in Escherichia coli K12 and pattern of transcription within the nag regulon.

The DNA sequence of a 3.6kb region downstream of the nagB gene (encoding glucosamine-6-PO4-deaminase) in Escherichia coli has been determined. Three open reading frames, which are subsequently referred to as nagA, nagC and nagD, were detected in this sequence. Genetic complementation and enzyme assays have shown that the first of these, nagA, encodes N-acetyl glucosamine-6-phosphate deacetylase. Growth on N-acetyl glucosamine induces the synthesis of a 1900 nucleotide long transcript which covers just nagE, encoding EIINag which is transcribed divergently from nagB, and of a 4200 nucleotide long transcript which covers all four ORFs of the nagB,A,C, D operon. More mRNA corresponding to nagB and nagA is detected than that corresponding to the distal genes, nagC and nagD. Considerable amounts of the induced mRNA are truncated molecules having their 3' ends after nagB and after nagA. Multiple 3' RNA ends have been mapped after nagD and seem to correspond to the ends of transcripts stabilized by mRNA secondary structure (REP sequences) rather than transcription termination sites. A second promoter producing nagD-specific transcripts has been mapped just in front of the nagD gene.

Autogenous control of Escherichia coli threonyl-tRNA synthetase expression in vivo.

The regulation of the expression of thrS, the structural gene for threonyl-tRNA synthetase, was studied using several thrS-lac fusions cloned in lambda and integrated as single copies at att lambda. It is first shown that the level of beta-galactosidase synthesized from a thrS-lac protein fusion is increased when the chromosomal copy of thrS is mutated. It is also shown that the level of beta-galactosidase synthesized from the same protein fusion is decreased if wild-type threonyl-tRNA synthetase is overproduced from a thrS-carrying plasmid. These results strongly indicate that threonyl-tRNA synthetase controls the expression of its own gene. Consistent with this hypothesis it is shown that some thrS mutants overproduce a modified form of threonyl-tRNA synthetase. When the thrS-lac protein fusion is replaced by several types of thrS-lac operon fusions no effect of the chromosomal thrS allele on beta-galactosidase synthesis is observed. It is also shown that beta-galactosidase synthesis from a promoter-proximal thrS-lac operon fusion is not repressed by threonyl-tRNA synthetase overproduction. The fact that regulation is seen with a thrS-lac protein fusion and not with operon fusions indicates that thrS expression is autoregulated at the translational level. This is confirmed by hybridization experiments which show that under conditions where beta-galactosidase synthesis from a thrS-lac protein fusion is derepressed three- to fivefold, lac messenger RNA is only slightly increased.

Overproduction and purification of initiation factor IF2 and pNUSA proteins from a recombinant plasmid bearing strain.

The genes for translational initiation factor, IF2 and pNusA have been cloned into a plasmid vector where they are placed under the control of the inducible lambdapL promoter and the c1857 thermosensitive repressor. When a strain carrying this plasmid is heat induced, IF2 alpha, IF2 beta and pNusA are overproduced 15 to 20 fold. This has allowed us to purify the IF2 and NusA proteins in large amounts.

Effect of NusA protein on expression of the nusA,infB operon in E. coli.

Protein and operon fusions between lacZ and various genes of the nusA,infB operon have been constructed on lambda bacteriophages and used to show that the operon is negatively regulated by the level of NusA protein. Overproducing NusA (but not IF2) from a multicopy plasmid reduces the level of beta-galactosidase from the fusions indicating repression of the operon. Introducing the lambda carrying the fusions into nusA mutant strains produces a higher level of beta-galactosidase-indicative of derepression of the operon. In particular, a larger form of the NusA protein which does not affect bacterial growth per se causes a derepression of the operon. As both protein and operon fusions respond equivalently, we conclude that the nusA protein is acting at the transcriptional level to regulate expression of the nusA, infB operon.

Evidence that pheV, a gene for tRNAPhe of E. coli is transcribed from tandem promoters.

A DNA fragment of 487 bp containing a gene for tRNAPhe has been sequenced. Although the tRNAPhe sequence is identical to that of pheU (which maps at 94.5 min) the surrounding sequences are quite different. This sequence is thus that of a second gene for tRNAPhe (which we shall call pheV). In vitro transcription experiments and S1 mapping in vivo show the existence of two promoters separated by about 60 nucleotides. The second transcript starts only 3 nucleotides 5' from the tRNAPhe structural sequence. A DNA sequence characteristic of a rho-independent terminator is located 30 nucleotides 3' of the end of the structural gene and is shown to function efficiently in vitro.

Attenuation control of the Escherichia coli phenylalanyl-tRNA synthetase operon.

The pheST operon codes for the two subunits of the essential enzyme phenylalanyl-tRNA synthetase. The nucleotide sequence of the regulatory regions of the operon, in vitro transcription data and in vivo experiments indicate that the operon is controlled by attenuation in a way similar to many amino acid biosynthetic operons. In this work the control of the pheST operon was studied in vivo by measuring the effect of deletions in the regulatory regions on downstream expression. The presence of a strong promoter followed by an approximately 90% efficient terminator in front of the structural parts of the operon is demonstrated. An open reading frame coding for a 14 amino acid long leader peptide containing five phenylalanine residues is located between the promoter and the terminator. The presence of the transcription terminator is shown to be essential to the operon's regulation. The localization of the promoter and the terminator agrees with the results of previous in vitro experiments. It is also shown that about 30% of the transcripts covering the pheST operon come from the upstream gene, rplT, which codes for the ribosomal protein L20. Although cotranscription exists between rplT and pheST, these genes are not systematically coregulated since reducing the translation of rplT about tenfold, does not change pheST expression. The pheST operon is also shown to be derepressed by a cellular excess of phenylalanyl-tRNA synthetase. This derepression is shown to be due to the pheST attenuator.

Two translational initiation sites in the infB gene are used to express initiation factor IF2 alpha and IF2 beta in Escherichia coli.

The gene infB codes for the two forms of translational initiation factor IF2: IF2 alpha (97 300 daltons) and IF2 beta (79 700 daltons). To determine whether the two forms differ at their N terminus, purified IF2 alpha and IF2 beta were subjected to 11 or more steps of Edman degradation. The N-terminal amino acid sequences are completely different, but match perfectly the DNA sequences at the beginning of the infB open reading frame and an in-phase region 471 bp downstream. A fusion was constructed between the proximal half of the infB gene and the lacZ gene lacking the region coding for the first eight amino acids. The fused gene expresses two products of 170 000 and 150 000 daltons, corresponding to the fused proteins IF2 alpha-beta-galactosidase and IF2 beta-beta-galactosidase, which confirms in vivo that the IF2 forms differ at their N terminus. A deletion of the 5'-non-translated region of the fused gene, including the Shine/Dalgarno ribosomal binding site, results in the expression of IF2 beta-beta-galactosidase but not IF2 alpha-beta-galactosidase. This strongly suggests that IF2 beta results from independent translation rather than from a precise proteolytic cleavage of IF2 alpha. Further evidence for initiation of protein synthesis at the putative IF2 alpha and IF2 beta start sites was sought by using an in vitro dipeptide synthesis assay. A DNA fragment containing the entire infB gene was cloned into three plasmid vectors and the resulting recombinant DNAs were used as templates in assays containing fMet-tRNA and various labelled aminoacyl-tRNAs.(ABSTRACT TRUNCATED AT 250 WORDS)