Molecular cloning and characterization of genes required for ribose transport and utilization in Escherichia coli K-12.

We isolated spontaneous and transposon insertion mutants of Escherichia coli K-12 that were specifically defective in utilization or in high-affinity transport of D-ribose (or in both). Cotransduction studies located all of the mutations near ilv, at the same position as previously identified mutations causing defects in ribokinase ( rbsK ) or ribose transport ( rbsP ). Plasmids that complemented the rbs mutations were isolated from the collection of ColE1 hybrid plasmids constructed by Clarke and Carbon. Analysis of those plasmids as well as of fragments cloned into pBR322 and pACYC184 allowed definition of the rbs region. Products of rbs genes were identified by examination of the proteins produced in minicells containing various rbs plasmids. We identified four rbs genes: rbsB , which codes for the 29-kilodalton ribose-binding protein; rbsK , which codes for the 34-kilodalton ribokinase ; rbsA , which codes for a 50-kilodalton protein required for high-affinity transport; and rbsC , which codes for a 27-kilodalton protein likely to be a transport system component. Our studies showed that these genes are transcribed from a common promoter in the order rbsA rbsC rbsB rbsK . It appears that the high-affinity transport system for ribose consists of the three components, ribose-binding protein, the 50-kilodalton RbsA protein, and the 27-kilodalton RbsC protein, although a fourth, unidentified component could exist. Mutants defective in this transport system, but normal for ribokinase , are able to grow normally on high concentrations of the sugar, indicating that there is at least a second, low-affinity transport system for ribose in E. coli K-12.     

A mutated PtsG, the glucose transporter, allows uptake of D-ribose.

Mutations arose from an Escherichia coli strain defective in the high (Rbs/ribose) and low (Als/allose and Xyl/xylose) affinity D-ribose transporters, which allow cells to grow on D-ribose. Genetic tagging and mapping of the mutations revealed that two loci in the E. coli linkage map are involved in creating a novel ribose transport mechanism. One mutation was found in ptsG, the glucose-specific transporter of phosphoenolpyruvate:carbohydrate phosphotransferase system and the other in mlc, recently reported to be involved in the regulation of ptsG. Five different mutations in ptsG were characterized, whose growth on D-ribose medium was about 80% that of the high affinity system (Rbs+). Two of them were found in the predicted periplasmic loops, whereas three others are in the transmembrane region. Ribose uptakes in the mutants, competitively inhibited by D-glucose, D-xylose, or D-allose, were much lower than that of the high affinity transporter but higher than those of the Als and Xyl systems. Further analyses of the mutants revealed that the rbsK (ribokinase) and rbsD (function unknown) genes are involved in the ribose transport through PtsG, indicating that the phosphorylation of ribose is not mediated by PtsG and that some unknown metabolic function mediated by RbsD is required. It was also found that D-xylose, another sugar not involved in phosphorylation, was efficiently transported through the wild-type or mutant PtsG in mlc-negative background. The efficiencies of xylose and glucose transports are variable in the PtsG mutants, depending on their locations, either in the periplasm or in the membrane. In an extreme case of the transmembrane change (I283T), xylose transport is virtually abolished, indicating that the residue is directly involved in determining sugar specificity. We propose that there are at least two domains for substrate specificity in PtsG with slightly altered recognition properties.     

Ribokinase from Escherichia coli K12. Nucleotide sequence and overexpression of the rbsK gene and purification of ribokinase

The nucleotide sequence of a 1455-base pair TaqI-HinfI fragment of the rbs operon of Escherichia coli K12 has been determined. It includes the 3' terminus of rbsB (the gene for ribose-binding protein) and the entire rbsK gene, encoding ribokinase. Potential consensus promoter sequences and a stable stem-loop structure are present in the rbsB-rbsK intercistronic region. The regulatory significance of these sequence features is discussed with respect to the rbs operon. rbsK has been cloned downstream from the Serratia marcescens trp promoter on a multicopy plasmid. Cells harboring this plasmid, when grown on minimal ribose plus ampicillin, express ribokinase at the level of 2% of the soluble protein, and induction with indoleacrylic acid raises ribokinase levels another 8-fold. Ribokinase has been purified to homogeneity (216 mumol/min/mg) from a strain harboring this plasmid. Protein sequence analyses of peptides generated by cyanogen bromide cleavage and o-iodosobenzoic acid cleavage confirmed the translation initiation site and the reading frame of the DNA sequence. Amino acid compositions of native ribokinase and the C-terminal dodecapeptide agree with the predicted amino acid compositions, confirming the accuracy of the DNA sequence and the translation termination site.     

Regulation of competence development and sugar utilization in Haemophilus influenzae Rd by a phosphoenolpyruvate:fructose phosphotransferase system

Changes in intracellular cAMP concentration play important roles in Haemophilus influenzae , regulating both sugar utilization and competence for natural transformation. In enteric bacteria, cAMP levels are controlled by the phosphoenolpyruvate:glycose phosphotransferase system (PTS) in response to changes in availability of the preferred sugars it transports. We have demonstrated the existence of a simple PTS in H. influenzae by several methods. We have cloned the H. influenzae ptsI gene, encoding PTS Enzyme I; genome analysis locates it in a pts operon structurally homologous to those of enteric bacteria. In vitro phosphorylation assays confirmed the presence of functional PTS components. A ptsI null mutation reduced fructose uptake to 1% of the wild-type rate, and abolished fructose fermentation even when exogenous cAMP was provided. The ptsI mutation also prevented fermentation of ribose and galactose, but utilization of these cAMP-dependent sugars was restored by addition of cAMP. In wild-type cells the non-metabolizable fructose analogue xylitol prevented fermentation of these sugars, confirming that the fructose PTS regulates cAMP levels. Development of competence under standard inducing conditions was reduced 250-fold by the ptsI mutation, unless cells were provided with exogenous cAMP. Competence is thus shown to be under direct nutritional control by a fructose-specific PTS.     

Mechanisms causing rapid and parallel losses of ribose catabolism in evolving populations of Escherichia coli B

Twelve populations of Escherichia coli B all lost D-ribose catabolic function during 2,000 generations of evolution in glucose minimal medium. We sought to identify the population genetic processes and molecular genetic events that caused these rapid and parallel losses. Seven independent Rbs(-) mutants were isolated, and their competitive fitnesses were measured relative to that of their Rbs(+) progenitor. These Rbs(-) mutants were all about 1 to 2% more fit than the progenitor. A fluctuation test revealed an unusually high rate, about 5 x 10(-5) per cell generation, of mutation from Rbs(+) to Rbs(-), which contributed to rapid fixation. At the molecular level, the loss of ribose catabolic function involved the deletion of part or all of the ribose operon (rbs genes). The physical extent of the deletion varied between mutants, but each deletion was associated with an IS150 element located immediately upstream of the rbs operon. The deletions apparently involved transposition into various locations within the rbs operon; recombination between the new IS150 copy and the one upstream of the rbs operon then led to the deletion of the intervening sequence. To confirm that the beneficial fitness effect was caused by deletion of the rbs operon (and not some undetected mutation elsewhere), we used P1 transduction to restore the functional rbs operon to two Rbs(-) mutants, and we constructed another Rbs(-) strain by gene replacement with a deletion not involving IS150. All three of these new constructs confirmed that Rbs(-) mutants have a competitive advantage relative to their Rbs(+) counterparts in glucose minimal medium. The rapid and parallel evolutionary losses of ribose catabolic function thus involved both (i) an unusually high mutation rate, such that Rbs(-) mutants appeared repeatedly in all populations, and (ii) a selective advantage in glucose minimal medium that drove these mutants to fixation.     

Isolation and genetic study of Erwinia mutants devoid of common components of the phosphoenolpyruvate-dependent phosphotransferase system

Mutants of bacteria belonging the genus Erwinia (Erwinia chrysanthemi and Erwinia carotovora) with pleiotropic disturbances in the utilization of many substrates were obtained through chemical and transposon mutagenesis. Genetic studies revealed that these mutants had defective ptsI or ptsH genes responsible for the synthesis of common components of the phosphoenolpyruvate-dependent phosphotransferase system, enzyme I and the HPr protein, respectively. The ptsI+ allele in both Erwinia species was cloned in vivo. Mapping of obtained mutations indicated that the ptsI and ptsH genes of E. chrysanthemi do not constitute a linkage group. The ptsI gene is located at 100 min of the chromosomal map, whereas the ptsH gene is located at 175 min. Sequencing of a portion of the E. chrysanthemi ptsI gene showed that a product of the cloned DNA region had up to 68% homology with the N terminus of Escherichia coli enzyme I.     

Corynebacterium diphtheriae: a PTS view to the genome

We have surveyed the publicly available genome sequence of Corynebacterium diphtheriae (www.sanger.ac.uk) to identify components of the phosphotransferase system (PTS), which plays a central role in carbon metabolism in many bacteria. Three gene loci were found to contain putative pts genes. These comprise: (i) the genes of the general phosphotransferases enzyme I (ptsI) and HPr (ptsH), a fructose-specific enzyme IIABC permease (fruA), and a fructose 1-phosphate kinase (fruK); (ii) a gene that encodes an enzyme IIAB of the fructose/mannitol family, and a novel HPr-like gene, ptsF, that encodes an HPr domain fused to a domain of unknown function; (iii) and a gene for a glucose-specific enzyme IIBCA (ptsG). A search for genes that may be putative PTS-targets or that may operate in general carbon regulation revealed a possible regulatory gene encoding an antiterminator protein downstream from ptsG. Furthermore, genes were detected encoding glycerol kinase, glucose kinase, and a homologue of the global activator of carbon catabolite repression in Escherichia coli, CAP. The possible significance of these observations in carbon metabolism and the novel features of the detected genes are discussed.     

Isolation and characterization from pathogenic fungi of genes encoding ammonium permeases and their roles in dimorphism

Nutrient sensing plays important roles in fungal development in general, and specifically in critical aspects of pathogenicity and virulence, for both animal and plant pathogens. Dimorphic pathogens such as the phytopathogenic smut fungi, Ustilago maydis and Microbotryum violaceum, must switch from a yeast-like to a filamentous form in order to cause disease. Two genes encoding methylammonium permeases (MEPs) were identified from each of these latter fungi and all the encoded proteins were most similar to Mep2p, the high-affinity permease from Saccharomyces cerevisiae that plays a direct role in pseudohyphal or filamentous growth for that organism. This is the first report of MEPs from pathogenic fungi. The two genes from U. maydis and one of the genes from M. violaceum were expressed in diploid S. cerevisiae mutants deleted for all three mep genes (mep1mep2mep3). Each of the heterologous genes could complement the severe growth defect of the S. cerevisiae mutant on low ammonium. Moreover, the U. maydis ump2 gene, initially detected as an upregulated gene in budding cells, was also able to complement the pseudohyphal defect characteristic of the mutant yeast. This gene is thus one of few heterologous MEP genes capable of efficiently restoring pseudohyphal growth in yeast. For U. maydis, disruption of ump2 eliminated the filamentous phenotype of haploid cells on low ammonium, while ump1 disruption only slightly reduced methylamine uptake. The most significant drop in methylamine uptake was seen for the ump2 and the ump1ump2 double mutants. Moreover, when grown in liquid medium, the ump1ump2 double mutant aggregated and sedimented. Also, the importance of a putative site for phosphorylation by protein kinase A was investigated in both Mep2p and Ump2p via site-directed mutagenesis of the respective genes. A mutation predicted to prevent phosphorylation of either protein, still allowed each to provide growth on low ammonium, but eliminated their abilities to provide pseudohyphal growth for the S. cerevisiae triple mutant. These findings allow us to present a model of how ammonium transporters play a role in regulating dimorphic growth in fungi.     

Identification of yacE (coaE) as the structural gene for dephosphocoenzyme A kinase in Escherichia coli K-12

Dephosphocoenzyme A (dephospho-CoA) kinase catalyzes the final step in coenzyme A biosynthesis, the phosphorylation of the 3'-hydroxy group of the ribose sugar moiety. Wild-type dephospho-CoA kinase from Corynebacterium ammoniagenes was purified to homogeneity and subjected to N-terminal sequence analysis. A BLAST search identified a gene from Escherichia coli previously designated yacE encoding a highly homologous protein. Amplification of the gene and overexpression yielded recombinant dephospho-CoA kinase as a 22.6-kDa monomer. Enzyme assay and nuclear magnetic resonance analyses of the product demonstrated that the recombinant enzyme is indeed dephospho-CoA kinase. The activities with adenosine, AMP, and adenosine phosphosulfate were 4 to 8% of the activity with dephospho-CoA. Homologues of the E. coli dephospho-CoA kinase were identified in a diverse range of organisms.     

Physiological studies on regulation of glycerol utilization by the phosphoenolpyruvate:sugar phosphotransferase system in Enterococcus faecalis.

In vitro studies with purified glycerol kinase from Enterococcus faecalis have established that this enzyme is activated by phosphorylation of a histidyl residue in the protein, catalyzed by the phosphoenolpyruvate-dependent phosphotransferase system (PTS), but the physiological significance of this observation is not known. In the present study, the regulation of glycerol uptake was examined in a wild-type strain of E. faecalis as well as in tight and leaky ptsI mutants, altered with respect to their levels of enzyme I of the PTS. Glycerol kinase was shown to be weakly repressible by lactose and strongly repressible by glucose in the wild-type strain. Greatly reduced levels of glycerol kinase activity were also observed in the ptsI mutants. Uptake of glycerol into intact wild-type and mutant cells paralleled the glycerol kinase activities in extracts. Glycerol uptake in the leaky ptsI mutant was hypersensitive to inhibition by low concentrations of 2-deoxyglucose or glucose even though the rates and extent of 2-deoxyglucose uptake were greatly reduced. These observations provide strong support for the involvement of reversible PTS-mediated phosphorylation of glycerol kinase in the regulation of glycerol uptake in response to the presence or absence of a sugar substrate of the PTS in the medium. Glucose and 2-deoxyglucose were shown to elicit rapid efflux of cytoplasmic [14C]lactate derived from [14C]glycerol. This phenomenon was distinct from the inhibition of glycerol uptake and was due to phosphorylation of the incoming sugar by cytoplasmic phosphoenolpyruvate. Lactate appeared to be generated by sequential dephosphorylation and reduction of cytoplasmic phosphoenolpyruvate present in high concentrations in resting cells. The relevance of these findings to regulatory phenomena in other bacteria is discussed.     

Effects of homologous phosphoenolpyruvate-carbohydrate phosphotransferase system proteins on carbohydrate uptake and poly(3-Hydroxybutyrate) accumulation in Ralstonia eutropha H16

Seven gene loci encoding putative proteins of the phosphoenolpyruvate-carbohydrate phosphotransferase system (PEP-PTS) were identified in the genome of Ralstonia eutropha H16 by in silico analysis. Except the N-acetylglucosamine-specific PEP-PTS, an additional complete PEP-PTS is lacking in strain H16. Based on these findings, we generated single and multiple deletion mutants defective mainly in the PEP-PTS genes to investigate their influence on carbon source utilization, growth behavior, and poly(3-hydroxybutyrate) (PHB) accumulation. As supposed, the H16 ΔfrcACB and H16 ΔnagFEC mutants exhibited no growth when cultivated on fructose and N-acetylglucosamine, respectively. Furthermore, a transposon mutant with a ptsM-ptsH insertion site did not grow on both carbon sources. The observed phenotype was not complemented, suggesting that it results from an interaction of genes or a polar effect caused by the Tn5::mob insertion. ptsM, ptsH, and ptsI single, double, and triple mutants stored much less PHB than the wild type (about 10 to 39% [wt/wt] of cell dry weight) and caused reduced PHB production in mutants lacking the H16_A2203, H16_A0384, frcACB, or nagFEC genes. In contrast, mutant H16 ΔH16_A0384 accumulated 11.5% (wt/wt) more PHB than the wild type when grown on gluconate and suppressed partially the negative effect of the ptsMHI deletion on PHB synthesis. Based on our experimental data, we discussed whether the PEP-PTS homologous proteins in R. eutropha H16 are exclusively involved in the complex sugar transport system or whether they are also involved in cellular regulatory functions of carbon and PHB metabolism.     

Alternative lactose catabolic pathway in Lactococcus lactis IL1403

In this study, we present a glimpse of the diversity of Lactococcus lactis subsp. lactis IL1403 beta-galactosidase phenotype-negative mutants isolated by negative selection on solid media containing cellobiose or lactose and X-Gal (5-bromo-4-chloro-3-indolyl-beta-d-galactopyranoside), and we identify several genes essential for lactose assimilation. Among these are ccpA (encoding catabolite control protein A), bglS (encoding phospho-beta-glucosidase), and several genes from the Leloir pathway gene cluster encoding proteins presumably essential for lactose metabolism. The functions of these genes were demonstrated by their disruption and testing of the growth of resultant mutants in lactose-containing media. By examining the ccpA and bglS mutants for phospho-beta-galactosidase activity, we showed that expression of bglS is not under strong control of CcpA. Moreover, this analysis revealed that although BglS is homologous to a putative phospho-beta-glucosidase, it also exhibits phospho-beta-galactosidase activity and is the major enzyme in L. lactis IL1403 involved in lactose hydrolysis.     

CcpA-mediated repression of Clostridium difficile toxin gene expression

The presence of glucose or other rapidly metabolizable carbon sources in the bacterial growth medium strongly represses Clostridium difficile toxin synthesis independently of strain origin. In Gram-positive bacteria, carbon catabolite repression (CCR) is generally regarded as a regulatory mechanism that responds to carbohydrate availability. In the C. difficile genome all elements involved in CCR are present. To elucidate in vivo the role of CCR in C. difficile toxin synthesis, we used the ClosTron gene knockout system to construct mutants of strain JIR8094 that were unable to produce the major components of the CCR signal transduction pathway: the phosphotransferase system (PTS) proteins (Enzyme I and HPr), the HPr kinase/phosphorylase (HprK/P) and the catabolite control protein A, CcpA. Inactivation of the ptsI, ptsH and ccpA genes resulted in derepression of toxin gene expression in the presence of glucose, whereas repression of toxin production was still observed in the hprK mutant, indicating that uptake of glucose is required for repression but that phosphorylation of HPr by HprK is not. C. difficile CcpA was found to bind to the regulatory regions of the tcdA and tcdB genes but not through a consensus cre site motif. Moreover in vivo and in vitro results confirmed that HPr-Ser45-P does not stimulate CcpA-dependent binding to DNA targets. However, fructose-1,6-biphosphate (FBP) alone did increase CcpA binding affinity in the absence of HPr-Ser45-P. These results showed that CcpA represses toxin expression in response to PTS sugar availability, thus linking carbon source utilization to virulence gene expression in C. difficile.     

Fructose transport in Bacillus subtilis.

The transport of fructose in Bacillus subtilis was studied in various mutant strains lacking the following activities: ATP-dependent fructokinase (fruC), the fructose 1-phosphate kinase (fruB) the phosphofructokinase (pfk), the enzyme I of the phosphoenolpyruvate phosphotransferase system (the thermosensitive mutation ptsI1), and a transport activity (fruA). Combinations of these mutations indicated that the transport of fructose in Bacillus subtilis is tightly coupled to its phosphorylation either in fructose 1-phosphate, identified in vivo and in vitro or in fructose 6-phosphate identified by indirect lines of evidence. These steps of fructose metabolism were shown to depend on the activity of the enzyme I of the phosphoenolpyruvate phosphotransferase systems. The fruA mutations affect the transport of fructose when the bacteria are submitted to catabolite repression. The mutations were localized on the chromosome of Bacillus subtilis in a cluster including the fruB gene. When grown in a medium supplemented by a mixture of potassium glutamate and succinate the fruA mutants are able to carry on the two vectorial metabolisms generating fructose 6-phosphate as well as fructose 1-phosphate. A negative search of strictly negative transport mutants in fruA strains indicated that more than two structural genes are involved in the transport of fructose.