Positive and negative regulation of expression of the l-sorbose (sor) operon by SorC in Klebsiella pneumoniae

Summary In Klebsiella pneumoniae the gene products involved in the degradation of the ketose l-sorbose are encoded in the sor operon. It comprises, besides structural genes for uptake and catabolism, a promoter-proximal gene sorC, encoding a protein SorC of M_r 40 kDa, for which no enzymatic function has been detected. All sor genes are coordinately expressed and inducible by l-sorbose. Polar insertions and frameshift mutations in sorC cause a pleiotropic negative effect on the expression of all other sor genes. This defect is complemented in trans by the wild-type sorC ⁺ allele for frameshift mutations, but not for polar insertions. A single promoter for all sor genes, for which SorC is the activator, thus seems to be located in front of sorC. The repressor activity of SorC was demonstrated by complementation of constitutive sorC alleles with a sorC ⁺ allele leading to inducible expression of all sor genes, including sorC, which, as visualized by the use of a series of lacZ fusions, thus autoregulates its expression, both as an activator and a repressor.     

Regulation of amino sugar utilization in Bacillus subtilis by the GntR family regulators,NagR and GamR

In Bacillus subtilis separate sets of genes are implicated in the transport and metabolism of the amino sugars, glucosamine and N‐acetylglucosamine. The genes for use of N‐acetylglucosamine (nagAB and nagP) are found in most firmicutes and are controlled by a GntR family repressor NagR (YvoA). The genes for use of glucosamine (gamAP) are repressed by another GntR family repressor GamR (YbgA). The gamR‐gamAP synton is only found in B. subtilis and a few very close relatives. Although NagR and GamR are close phylogenetically, there is no cross regulation between their operons. GlcN6P prevents all binding of GamR to its targets. NagR binds specifically to targets containing the previously identified dre palindrome but its binding is not inhibited by GlcN6P or GlcNAc6P. GamR‐like binding sites were also found in some other Bacilli associated with genes for use of chitin, the polymer of N‐acetylglucosamine, and with a gene for another GamR homologue (yurK). We show that GamR can bind to two regions in the chi operon of B. licheniformis and that GamR and YurK are capable of heterologous regulation. GamR can repress the B. licheniformis licH‐yurK genes and YurK can repress B. subtilis gamA.     

Galactose Metabolism by Streptococcus mutans

The galK gene, encoding galactokinase of the Leloir pathway, was insertionally inactivated in Streptococcus mutans UA159. The galK knockout strain displayed only marginal growth on galactose, but growth on glucose or lactose was not affected. In strain UA159, the sugar phosphotransferase system (PTS) for lactose and the PTS for galactose were induced by growth in lactose and galactose, although galactose PTS activity was very low, suggesting that S. mutans does not have a galactose-specific PTS and that the lactose PTS may transport galactose, albeit poorly. To determine if the galactose growth defect of the galK mutant could be overcome by enhancing lactose PTS activity, the gene encoding a putative repressor of the operon for lactose PTS and phospho-β-galactosidase, lacR, was insertionally inactivated. A galK and lacR mutant still could not grow on galactose, although the strain had constitutively elevated lactose PTS activity. The glucose PTS activity of lacR mutants grown in glucose was lower than in the wild-type strain, revealing an influence of LacR or the lactose PTS on the regulation of the glucose PTS. Mutation of the lacA gene of the tagatose pathway caused impaired growth in lactose and galactose, suggesting that galactose can only be efficiently utilized when both the Leloir and tagatose pathways are functional. A mutation of the permease in the multiple sugar metabolism operon did not affect growth on galactose. Thus, the galactose permease of S. mutans is not present in the gal, lac, or msm operons.     

An Alternative Route for Recycling of N-Acetylglucosamine from Peptidoglycan Involves the N-Acetylglucosamine Phosphotransferase System in Escherichia coli

A set of enzymes dedicated to recycling of the amino sugar components of peptidoglycan has previously been identified in Escherichia coli. The complete pathway includes the nagA-encoded enzyme, N-acetylglucosamine-6-phosphate (GlcNAc6P) deacetylase, of the catabolic pathway for use of N-acetylglucosamine (GlcNAc). Mutations in nagA result in accumulation of millimolar concentrations of GlcNAc6P, presumably by preventing peptidoglycan recycling. Mutations in the genes encoding the key enzymes upstream of nagA in the dedicated recycling pathway (ampG, nagZ, nagK, murQ, and anmK), which were expected to interrupt the recycling process, reduced but did not eliminate accumulation of GlcNAc6P. A mutation in the nagE gene of the GlcNAc phosphotransferase system (PTS) was found to reduce by 50% the amount of GlcNAc6P which accumulated in a nagA strain and, together with mutations in the dedicated recycling pathway, eliminated all the GlcNAc6P accumulation. This shows that the nagE-encoded PTS transporter makes an important contribution to the recycling of peptidoglycan. The manXYZ-encoded PTS transporter makes a minor contribution to the formation of cytoplasmic GlcNAc6P but appears to have a more important role in secretion of GlcNAc and/or GlcNAc6P from the cytoplasm.Peptidoglycan (PG) or murein, the rigid shape-forming layer of the bacterial cell envelope, undergoes extensive degradation and resynthesis during normal bacterial growth. It is estimated that 40 to 50% of the PG is broken down and reused each generation (for a review, see reference 22). PG is a matrix of chains of alternating N-acetylglucosamine (GlcNAc) and N-acetylmuramic acid (MurNAc) sugars cross-linked by peptide bridges. Over the last 20 years the pathways for recycling both the peptide and amino sugar portions of the PG have been elucidated, and a number of genes involved in this process have been identified. Most of the genes involved encode dedicated enzymes whose only function seems to be to recover the material produced during PG turnover and to reuse it to synthesize more PG or as a source of energy. However, some of the enzymes shown to be involved have apparently been recruited from another metabolic pathway (e.g., murQ- and nagA-encoded enzymes [see below]), while other specialized PG-recycling enzymes have a subsidiary function (e.g., ampG- and ampD-encoded enzymes in β-lactamase induction [20]).The pathway for recycling the amino sugar part of PG in Escherichia coli is shown in Fig. ​Fig.11 (for a review, see reference 22). Periplasmic hydrolases (lytic transglycosylases, Slt) and endopeptidases break the PG backbone, liberating anhydro-muropeptides (principally GlcNAc-anhydro-MurNAc [anhMurNAc]-tetrapeptide), which are transported into the cytoplasm by the ampG-encoded transporter (10). The peptide portion is cleaved off either by the membrane-associated amiD-encoded amidase (28) or by the ampD-encoded cytoplasmic amidase (11), liberating the disaccharide. The tetrapeptide is converted to a tripeptide and free d-Ala, both of which are reused to produce UDP-MurNAc-pentapeptide (11). The GlcNAc-anhMurNAc disaccharide is cleaved by the nagZ-encoded β-N-acetylglucosaminidase (2, 32), and then both sugars are converted to their 6-phosphate forms by the specific kinases NagK (29) and AnmK (31). The latter produces MurNAc-6-phosphate (MurNAc6P), which is converted to GlcNAc6P by the murQ-encoded etherase (12, 30). MurNAc6P is also the product of transport of MurNAc by the MurNAc-specific phosphotransferase system (PTS) transporter MurP. The murP and murQ genes form an operon for use of MurNAc as a carbon source (4). Thus, the MurQ protein has both catabolic and recycling functions (12, 30). Similarly, further use of the GlcNAc6P involves an enzyme normally involved in the catabolism of GlcNAc, the nagA-encoded GlcNAc6P deacetylase of the GlcNAc degradation pathway (21). The deacetylase converts GlcNAc6P to glucosamine-6-phosphate (GlcN6P), which can be converted to UDP-GlcNAc, the first dedicated compound for the synthesis of the cell wall components, by the glmM- and glmU-encoded enzymes (16, 17).Open in a separate windowFIG. 1.Scheme for recycling of PG in E. coli. The enzymes and substrates are described in the text. Slt is the major soluble lytic transglycosylase. OM, outer membrane; PP, periplasm; IM, inner membrane. The enzymes involved in converting UDP-GlcNAc into the components of the PG and outer membrane are not shown. Arrows with a question mark indicate the pathways postulated to exist based on the results described in this work.It has been known for many years that mutations in nagA lead to very high levels of GlcNAc6P (33). Strains carrying nagA mutations are Nag^Sensitive (i.e., they do not grow in medium containing GlcNAc and another carbon source). The toxicity of the accumulated sugar phosphates means that secondary mutations that alleviate this toxicity arise spontaneously in vivo (33). GlcNAc6P is the inducing signal for the NagC repressor of the nag regulon, and the accumulation of GlcNAc6P in the nagA strain results in derepression (endogenous induction) of the nag regulon (25). One class of suppressor mutations result in noninducible versions of NagC that are not sensitive to GlcNAc6P, so that the nag genes stay repressed (23), implying that overexpression of the nag regulon genes is one cause of the toxicity. Amino sugars are essential constituents of the bacterial PG and lipopolysaccharide (LPS) in gram-negative bacteria. In the absence of an exogenous supply of amino sugars, glmS, encoding GlcN6P synthase, is an essential gene (for a review, see reference 7). As GlcNAc6P accumulates in nagA cells growing in medium devoid of amino sugars, it must ultimately be derived from the de novo synthesis of GlcN6P by GlmS, which is destined for synthesis of PG and the LPSs of the outer membrane. As no acetyltransferase for GlcN6P has been characterized, the most likely origin of the GlcNAc6P in nagA strains is recycling of the PG. The LPS of the outer membrane of gram-negative bacteria also contains GlcN, but it is not known to undergo any turnover and the work of Park (21) showed that radioactive GlcN was stably incorporated into the LPS fraction, whereas radioactivity was slowly lost from the PG of isolated sacculi.In this work the effect of mutations in the recycling pathway on the accumulation of GlcNAc6P in vivo was investigated. The results show that mutations in one or more genes of the recycling pathway reduce but do not eliminate GlcNAc6P accumulation in nagA strains. However, when these mutations are present in the same strain with a mutation in the nagE gene encoding the GlcNAc6P-specific transporter of the GlcNAc PTS, GlcNAc6P levels decrease to the background level. This shows that the GlcNAc PTS is another pathway that is involved in recycling the GlcNAc component of PG. The manXYZ-encoded PTS transporter is also capable of GlcNAc uptake, and its effect on the recycling process was also examined.     

Comparison of the sequences of the nagE operons from Klebsiella pneumoniae and Escherichia coli K12: enhanced variability of the enzyme IIN-acetylglucosamine in regions connecting functional domains.

Summary The nagE operon, encoding the enzyme II specific for N-acetylglucosamine (EII^Nag), and adjacent DNA from the chromosome of Klebsiella pneumoniae were sequenced and compared with the corresponding sequence from Escherichia colt K12. The deduced EII^Nag sequences differ in 72 out of 651 amino acids, the K. pneumoniae sequence being three residues longer. The amino acid differences were distributed unevenly, and were most frequent in regions connecting the three functional domains of the protein. In the nagE-nagB intergenic region, two promoter, two operator, and one CAP consensus sequence with regulatory functions were highly conserved. The nag structural genes from both species were very similar (83% DNA similarity; 89% amino acid similarity) except for frequent AT to GC exchanges in the wobble base of codons in K. pneumoniae DNA relative to the E. coli DNA.     

The Sulfur Oxidation Operon Repressor Function is Influenced by the Product of its Adjacent Upstream ORF in <Emphasis Type="Italic">Pseudaminobacter salicylatoxidans</Emphasis> KCT001

The repressor of sulfur-oxidizing (sox) operon regulates expression of genes encoding a multienzyme complex that governs the chemolithotrophic sulfur oxidation in Pseudaminobacter salycylatoxidans KCT001. The inducer of sox operon viz., thiosulfate and other sulfur anions had no impact on in vitro repressor–operator interaction which indicates an atypical derepression mechanism. The reduced repressor has higher affinity for its operator DNA. The sulfur oxidation repressor binds with operator regions and led to efficient repression in trans, however, increased repressor concentration resulted in higher gene expression. Using a reporter system in E. coli, the present study established that the thioredoxin-like protein, encoded in immediate upstream ORF, could nullify the observed reversal of the repression at higher repressor concentration. In this context, the involvement of the upstream gene product in the regulation of the sulfur oxidation gene expression has been reported.     

Sugar uptake and utilisation in Streptomyces coelicolor: a PTS view to the genome

Our research group is studying the phosphotransferase system (PTS) of Streptomyces coelicolor, which, in other bacteria, is centrally involved in carbon source uptake and regulation. We have surveyed the public available S. coelicolor genome sequence produced by the ongoing genome sequencing project for pts gene homologues (http://www.sanger.ac.uk/Projects/S_coelicolor/). Three genes encoding homologues of the general PTS components enzyme I (ptsI), HPr (ptsH), and enzyme IIA^Crr (crr; IIA^Glc-homologue) and six genes encoding homologues of sugar-specific PTS components were identified. The deduced primary sequences of the sugar-specific components shared significant similarities to PTS permeases of the mannitol/fructose family and of the glucose/sucrose family. A model is presented, in which possible functions of the novel described PTS homologues are discussed.     

Cloning and Characterization of the nagA Gene that Encodes β-N-Acetylglucosaminidase from Aspergillus nidulans and Its Expression in Aspergillus oryzae

We isolated a β-N-acetylglucosaminidase encoding gene and its cDNA from the filamentous fungus Aspergillus nidulans, and designated it nagA. The nagA gene contained no intron and encoded a polypeptide of 603 amino acids with a putative 19-amino acid signal sequence. The deduced amino acid sequence was very similar to the sequence of Candida albicans Hex1 and Trichoderma harzianum Nag1. Yeast cells containing the nagA cDNA under the control of the GAL1 promoter expressed β-N-acetylglucosaminidase activity. The chromosomal nagA gene of A. nidulans was disrupted by replacement with the argB marker gene. The disruptant strains expressed low levels of β-N-acetylglucosaminidase activity and showed poor growth on a medium containing chitobiose as a carbon source. Aspergillus oryzae strain carrying the nagA gene under the control of the improved glaA promoter produced large amounts of β-N-acetylglucosaminidase in a wheat bran solid culture.     

Molecular analysis of the phosphoenolpyruvate-dependent l-sorbose: phosphotransferase system from Klebsiella pneumoniae and of its multidomain structure

We have cloned a 3.4 kb DNA fragment from the chromosome of Klebsiella pneumoniae that codes for a phosphoenolpyruvate-dependent l-sorbose: phosphotransferase system (PTS). The cloned fragment was sequenced and four open reading frames coding for 135 (sorF), 164 (sorB), 266 (sorA) and 274 (sorM) amino acids, respectively, were found. The corresponding proteins could be detected in a T7 overexpression system, which yielded molecular masses of about 14000 for SorF, 19000 for SorB, 25000 for SorA and 27000 for SorM. SorF and SorB have all the characteristics of soluble and intracellular proteins in accordance with their functions as EIIA^Sor and EIIB^Sor domains of the l-sorbose PTS. SorA and SorM, by contrast, are strongly hydrophobic, membrane-bound proteins with two to five putative transmembrane helices that alternate with a series of hydrophilic loops. They correspond to domains EIIC^Sor and EIID^Sor. The four proteins of the l-sorbose PTS resemble closely (27%–60%) the four subunits of a d-fructose PTS (EIIA^Lev, EIIB^Lev, EIIC^Lev, and EIID^Lev) from Bacillus subtilis and the three subunits of the d-mannose PTS (EIIA,B^Man, EIIC^Man, and EIID^Man) from Escherichia coli K-12. The three systems constitute a new PTS family, and sequence comparisons revealed highly conserved structures for the membranebound proteins. A consensus sequence for the membrane proteins was used to postulate a model for their integration into the membrane.     

Control of the glycolytic gapA operon by the catabolite control protein A in Bacillus subtilis: a novel mechanism of CcpA-mediated regulation

Glycolysis is one of the main pathways of carbon catabolism in Bacillus subtilis. Expression of the gapA gene encoding glyceraldehyde-3-phosphate dehydrogenase, the key enzyme of glycolysis from an energetic point of view, is induced by glucose and other sugars. Two regulators are involved in induction of the gapA operon, the product of the first gene of the operon, the CggR repressor, and catabolite control protein A (CcpA). CcpA is required for induction of the gapA operon by glucose. Genetic evidence has demonstrated that CcpA does not control the expression of the gapA operon by binding directly to a target in the promoter region. Here, we demonstrate by physiological analysis of the inducer spectrum that CcpA is required only for induction by sugars transported by the phosphotransferase system (PTS). A functional CcpA is needed for efficient transport of these sugars. This interference of CcpA with PTS sugar transport results from an altered phosphorylation pattern of HPr, a phosphotransferase of the PTS. In a ccpA mutant strain, HPr is nearly completely phosphorylated on a regulatory site, Ser-46, and is trapped in this state, resulting in its inactivity in PTS phosphotransfer. A mutation in HPr affecting the regulatory phosphorylation site suppresses both the defect in PTS sugar transport and the induction of the gapA operon. We conclude that a low-molecular effector derived from glucose that acts as an inducer for the repressor CggR is limiting in the ccpA mutant.     

Nucleotide sequence and regulated expression of the Salmonella fljA gene encoding a repressor of the phase 1 flagellin gene

Summary The nucleotide sequence of Salmonella abortus-equi fljA, which together with the phase 2 flagellin gene constitutes the fljBA operon and encodes the repressor for the phase 1 flagellin gene fliC, was determined. The repressor was predicted to be a basic protein consisting of 179 amino acid residues (M_r = 20419 Da) encoded by ORFII. This was confirmed by the fact that host fliC is repressed by plasmid-encoded ORFII, which indeed expresses a 20 kDa product as determined by urea SDS-polyacrylamide gel electrophoresis. An amino acid sequence capable of forming a helix-turn-helix type of structure was predicted in the C-terminal region of FljA. A rho-independent intercistronic terminator was detected between fljB and ftjA. Chloramphenicol acetyltransferase (CAT) assays of fusions indicated that the terminator is capable of reducing expression of fljA to the level of a few percent, relative to fljB in broth cultures and to 1 % in M9 glycerol cultures.     

Simultaneous utilization of D-cellobiose, D-glucose, and D-xylose by recombinant Corynebacterium glutamicum under oxygen-deprived conditions

Corynebacterium glutamicum R was metabolically engineered to broaden its sugar utilization range to d-xylose and d-cellobiose contained in lignocellulose hydrolysates. The resultant recombinants expressed Escherichia coli xylA and xylB genes, encoding d-xylose isomerase and xylulokinase, respectively, for d-xylose utilization and expressed C. glutamicum R bglF ^317A and bglA genes, encoding phosphoenolpyruvate:carbohydrate phosphotransferase system (PTS) β-glucoside-specific enzyme IIBCA component and phospho-β-glucosidase, respectively, for d-cellobiose utilization. The genes were fused to the non-essential genomic regions distributed around the C. glutamicum R chromosome and were under the control of their respective constitutive promoter trc and tac that permitted their expression even in the presence of d-glucose. The enzyme activities of resulting recombinants increased with the increase in the number of respective integrated genes. Maximal sugar utilization was realized with strain X5C1 harboring five xylA–xylB clusters and one bglF ^317A –bglA cluster. In both d-cellobiose and d-xylose utilization, the sugar consumption rates by genomic DNA-integrated strain were faster than those by plasmid-bearing strain, respectively. In mineral medium containing 40 g l⁻¹ d-glucose, 20 g l⁻¹ d-xylose, and 10 g l⁻¹ d-cellobiose, strain X5C1 simultaneously and completely consumed these sugars within 12 h and produced predominantly lactic and succinic acids under growth-arrested conditions.     

Organization of genes required for gellan polysaccharide biosynthesis in<Emphasis Type="Italic"> Sphingomonas elodea</Emphasis> ATCC 31461

Sphingomonas elodea ATCC 31461 produces gellan, a capsular polysaccharide that is useful as a gelling agent for food and microbiological media. Complementation of nonmucoid S. elodea mutants with a gene library resulted in identification of genes essential for gellan biosynthesis. A cluster of 18 genes spanning 21 kb was isolated. These 18 genes are homologous to genes for synthesis of sphingan polysaccharide S-88 from Sphingomonas sp. ATCC 31554, with predicted amino acid identities varying from 61% to 98%. Both polysaccharides have the same tetrasaccharide repeat unit, comprised of [4)--l-rhamnose-(13)--d-glucose-(14)--d-glucuronic acid-(14)--d-glucose-(1]. Polysaccharide S-88, however, has mannose or rhamnose in the fourth position and has a rhamnosyl side chain, while gellan has no sugar side chain but is modified by glyceryl and acetyl substituents. Genes for synthesis of the precursor dTDP-l-rhamnose were highly conserved. The least conserved genes in this cluster encode putative glycosyl transferases III and IV and a gene of unknown function, gelF. Three genes (gelI, gelM, and gelN) affected the amount and rheology of gellan produced. Four additional genes present in the S-88 sphingan biosynthetic gene cluster did not have homologs in the gene cluster for gellan biosynthesis. Three of these gene homologs, gelR, gelS, and gelG, were found in an operon unlinked to the main gellan biosynthetic gene cluster. In a third region, a gene possibly involved in positive regulation of gellan biosynthesis was identified.