A mannose-sensing AraC-type transcriptional activator regulates cell-cell aggregation of Vibrio cholerae.

In addition to catalyzing coupled transport and phosphorylation of carbohydrates, the phosphoenolpyruvate:carbohydrate phosphotransferase system (PTS) regulates various physiological processes in most bacteria. Therefore, the transcription of genes encoding the PTS is precisely regulated by transcriptional regulators depending on substrate availability. As the distribution of the mannose-specific PTS (PTSMan) is limited to animal-associated bacteria, it has been suggested to play an important role in host-bacteria interactions. In Vibrio cholerae, mannose is known to inhibit biofilm formation. During host infection, the transcription level of the V. cholerae gene encoding the putative PTSMan (hereafter referred to as manP) significantly increases, and mutations in this gene increase host survival rate. Herein, we show that an AraC-type transcriptional regulator (hereafter referred to as ManR) acts as a transcriptional activator of the mannose operon and is responsible for V. cholerae growth and biofilm inhibition on a mannose or fructose-supplemented medium. ManR activates mannose operon transcription by facilitating RNA polymerase binding to the promoter in response to mannose 6-phosphate and, to a lesser extent, to fructose 1-phosphate. When manP or manR is impaired, the mannose-induced inhibition of biofilm formation was reversed and intestinal colonization was significantly reduced in a Drosophila melanogaster infection model. Our results show that ManR recognizes mannose and fructose in the environment and facilitates V. cholerae survival in the host.

A Membrane-Targeted Peptide Inhibiting PtxA of Phosphotransferase System Blocks Streptococcus mutans.

Streptococcus mutans, the primary cause of dental caries, takes up carbohydrates through the phosphoenolpyruvate sugar phosphotransferase system (PTS). This study aimed to identify a novel membrane-targeted antimicrobial peptide (AMP) that could also target the L-ascorbate-specific PtxA component of the S. mutans PTS system. C10-KKWW was identified and selected using virtual screening of a lipopeptide library, a minimum inhibiting concentration (MIC) assay, cytotoxicity assays and a hemolysis assay. Surface plasmon resonance confirmed that C10-KKWW had a high binding affinity for PtxA. Combining with scanning electron microscopy and cell permeability assay, it was shown that the effects of C10-KKWW could be attributed to both membrane and PtxA. Wild type (WT) S. mutans, a ptxA deletion mutant (ΔptxA), and a mutant-complemented strain (CptxA), were cultured consistently in brain heart infusion (BHI) medium, tryptone-vitamin medium supplemented with 15 mM L-ascorbate (TVL), or for 5 h in BHI supplemented with 7.4 mM sodium L-ascorbate. Compared to ∆ptxA, in WT S. mutans and CptxA, C10-KKWW had a stronger MIC (3.9 µg/mL), and distinctively decreased biofilm viability. The extracellular concentrations of L-ascorbate/sodium L-ascorbate were not changed before and after WT treated with C10-KKWW. L-ascorbate-induced operon genes, or other PTS genes, were significantly suppressed by C10-KKWW. In conclusion, C10-KKWW has been developed; it acts through interaction with the bacterial membrane and interferes with L-ascorbate translocation to inhibit S. mutans growth and eradicate its biofilm. C10-KKWW may be especially effective at optimal oral ascorbate levels. A combination of C10-KKWW with sodium L-ascorbate might also be a novel strategy for dental caries treatment.

In silico search of inhibitors of Streptococcus mutans for the control of dental plaque.

Biofilm is an extremely complex microbial community arranged in a matrix of polysaccharides and attached to a substrate. Its development is crucial in the pathophysiology of oral infections like dental caries, as well as in periodontal, pulp, and periapical diseases. Streptococcus mutans is one of the most effective microorganisms in lactic acid production of the dental biofilm. Identifying essential Streptococcus mutans proteins using bioinformatics methods helps to search for alternative therapies. To this end, the bacterial genomes of several Streptococcus mutans strains and representative strains of other cariogenic and non-cariogenic bacteria were analysed by identifying pathogenicity islands and alignments with other bacteria, and by detecting the exclusive genes of cariogenic species in comparison to the non-pathogenic ones. This study used tools for orthology prediction such as BLAST and OrthoMCL, as well as the server IslandViewer for the detection of pathogenicity islands. In addition, the potential interactome of Streptococcus mutans was rebuilt by comparing it to interologues of other species phylogenetically close to or associated with cariogenicity. This protocol yielded a final list of 20 proteins related to potentially virulent factors that can be used as therapeutic targets in future analyses. The EIIA and EIIC enzymatic subunits of the phosphotransferase system (PTS) were prioritized, as well as the pyruvate kinase enzyme, which are directly involved in the metabolism of carbohydrates and in obtaining the necessary energy for the microorganism's survival. These results will guide a subsequent experimental trial to develop new, safe, and effective molecules in the treatment of dental caries.

Partial depolymerization of genetically modified potato tuber periderm reveals intermolecular linkages in suberin polyester.

Suberin is a biopolyester found in specialized plant tissues, both internal and external, with key frontier physiological functions. The information gathered so far from its monomer and oligomer composition, and in situ studies made by solid state techniques, haven't solved the enigma of how the suberin polyester is assembled as a macromolecule. To investigate how monomers are linked in suberin, we analyzed oligomer fragments solubilized by the partial depolymerization of suberin from potato (Solanum tuberosum) tuber periderms. The structure of the suberin oligomers, namely which monomers they included, and the type and frequency of the inter-monomer ester linkages, was assessed by ESI-MS/MS and high resolution NMR analysis. The analyzed potato periderms included the one from wild type (cv. Desirée) and from plants where suberin-biosynthesis genes were downregulated in chain elongation (StKCS6), ω-hydroxylation (CYP86A33) and feruloylation (FHT). Two building blocks were identified as possible key structures in the macromolecular development of the potato periderm suberin: glycerol - α,ω-diacid - glycerol, as the core of a continuous suberin aliphatic polyester; and glycerol - ω-hydroxyacid - ferulic acid, anchoring this polyaliphatic matrix at its periphery to the vicinal polyaromatics, through linking to ferulic acid. The silencing of the StKCS6 gene led to non-significant alterations in suberin structure, showing the relatively minor role of the very-long chain (>C28) fatty acids in potato suberin composition. The silencing of CYP86A33 gene impaired significantly suberin production and disrupted the biosynthesis of acylglycerol structures, proving the relevance of the latter and thus of the glycerol - α,ω-diacid - glycerol unit for the typical suberin lamellar organization. The silencing of the FHT gene led to a lower frequency of ferulate linkages in suberin polyester but to more polyphenolic guaiacyl units as seen by FTIR analyses in the intact polymer.

Modification of glucose import capacity in Escherichia coli: physiologic consequences and utility for improving DNA vaccine production.

BACKGROUND: The bacterium Escherichia coli can be grown employing various carbohydrates as sole carbon and energy source. Among them, glucose affords the highest growth rate. This sugar is nowadays widely employed as raw material in industrial fermentations. When E. coli grows in a medium containing non-limiting concentrations of glucose, a metabolic imbalance occurs whose main consequence is acetate secretion. The production of this toxic organic acid reduces strain productivity and viability. Solutions to this problem include reducing glucose concentration by substrate feeding strategies or the generation of mutant strains with impaired glucose import capacity. In this work, a collection of E. coli strains with inactive genes encoding proteins involved in glucose transport where generated to determine the effects of reduced glucose import capacity on growth rate, biomass yield, acetate and production of an experimental plasmid DNA vaccine (pHN). RESULTS: A group of 15 isogenic derivatives of E. coli W3110 were generated with single and multiple deletions of genes encoding glucose, mannose, beta-glucoside, maltose and N-acetylglucosamine components of the phosphoenolpyruvate:sugar phosphotransferase system (PTS), as well as the galactose symporter and the Mgl galactose/glucose ABC transporter. These strains were characterized by growing them in mineral salts medium supplemented with 2.5 g/L glucose. Maximum specific rates of glucose consumption (qs) spanning from 1.33 to 0.32 g/g h were displayed by the group of mutants and W3110, which resulted in specific growth rates ranging from 0.65-0.18 h(-1). Acetate accumulation was reduced or abolished in cultures with all mutant strains. W3110 and five selected mutant derivatives were transformed with pHN. A 3.2-fold increase in pHN yield on biomass was observed in cultures of a mutant strain with deletion of genes encoding the glucose and mannose PTS components, as well as Mgl. CONCLUSIONS: The group of E. coli mutants generated in this study displayed a reduction or elimination of overflow metabolism and a linear correlation between qs and the maximum specific growth rate as well as the acetate production rate. By comparing DNA vaccine production parameters among some of these mutants, it was possible to identify a near-optimal glucose import rate value for this particular application. The strains employed in this study should be a useful resource for studying the effects of different predefined qs values on production capacity for various biotechnological products.

Addition of genes for cellobiase and pectinolytic activity in Escherichia coli for fuel ethanol production from pectin-rich lignocellulosic biomass.

Ethanologenic Escherichia coli strain KO11 was sequentially engineered to contain the Klebsiella oxytoca cellobiose phosphotransferase genes (casAB) as well as a pectate lyase (pelE) from Erwinia chrysanthemi, yielding strains LY40A (casAB) and JP07 (casAB pelE), respectively. To obtain an effective secretion of PelE, the Sec-dependent pathway out genes from E. chrysanthemi were provided on a cosmid to strain JP07 to construct strain JP07C. Finally, oligogalacturonide lyase (ogl) from E. chrysanthemi was added to produce strain JP08C. E. coli strains LY40A, JP07, JP07C, and JP08C possessed significant cellobiase activity in cell lysates, while only strains JP07C and JP08C demonstrated extracellular pectate lyase activity. Fermentations conducted by using a mixture of pure sugars representative of the composition of sugar beet pulp (SBP) showed that strains LY40A, JP07, JP07C, and JP08C were able to ferment cellobiose, resulting in increased ethanol production from 15 to 45% in comparison to that of KO11. Fermentations with SBP at very low fungal enzyme loads during saccharification revealed significantly higher levels of ethanol production for LY40A, JP07C, and JP08C than for KO11. JP07C ethanol yields were not considerably higher than those of LY40A; however, oligogalacturonide polymerization studies showed an increased breakdown of biomass to small-chain (degree of polymerization, ≤6) oligogalacturonides. JP08C achieved a further breakdown of polygalacturonate to monomeric sugars, resulting in a 164% increase in ethanol yields compared to those of KO11. The addition of commercial pectin methylesterase (PME) further increased JP08C ethanol production compared to that of LY40A by demethylating the pectin for enzymatic attack by pectin-degrading enzymes.

Identification and application of a different glucose uptake system that functions as an alternative to the phosphotransferase system in Corynebacterium glutamicum.

Corynebacterium glutamicum uses the phosphoenolpyruvate-dependent sugar phosphotransferase system (PTS) to uptake and phosphorylate glucose; no other route has yet been identified. Disruption of the ptsH gene in wild-type C. glutamicum resulted, as expected, in a phenotype exhibiting little growth on any of the PTS sugars: glucose, fructose, and sucrose. However, a suppressor mutant that grew on glucose but not on the other two sugars was spontaneously isolated from the PTS-negative strain WTΔptsH. The suppressor strain SPH2, unlike the wild-type strain, exhibited a phenotype of resistance to 2-deoxyglucose which is known to be a toxic substrate for the glucose-PTS of this microbe, suggesting that strain SPH2 utilizes glucose via a different system involving a permease and native glucokinases. Analysis of the C. glutamicum genome sequence using Escherichia coli galactose permease, which can transport glucose, led to the identification of two candidate genes, iolT1 and iolT2, both of which have been reported as myo-inositol transporters. When cultured on glucose medium supplemented with myo-inositol, strain WTΔptsH was able to consume glucose, suggesting that glucose uptake was mediated by one or more myo-inositol-induced transporters. Overexpression of iolT1 alone and that of iolT2 alone under the gapA promoter in strain WTΔptsH rendered the strain capable of growing on glucose, proving that each transporter played a role in glucose uptake. Disruption of iolT1 in strain SPH2 abolished growth on glucose, whereas disruption of iolT2 did not, revealing that iolT1 was responsible for glucose uptake in strain SPH2. Sequence analysis of the iol gene cluster and its surrounding region identified a single-base deletion in the putative transcriptional regulator gene Cgl0157 of strain SPH2. Introduction of the frameshift mutation allowed strain WTΔptsH to grow on glucose, and further deletion of iolT1 abolished the growth again, indicating that inactivation of Cgl0157 under a PTS-negative background can be a means by which to express the iolT1-specified glucose uptake bypass instead of the native PTS. When this strategy was applied to a defined lysine producer, the engineered strain displayed increased lysine production from glucose.

Antimicrobial actions of α-mangostin against oral streptococci.

The increasing prevalence of dental caries is making it more of a major world health problem. Caries is the direct result of acid production by cariogenic oral bacteria, especially Streptococcus mutans. New and better antimicrobial agents active against cariogenic bacteria are badly needed, especially natural agents derived directly from plants. We have evaluated the inhibitory actions of α-mangostin, a xanthone purified from ethanolic extracts of the tropical plant Garcinia mangostana L., by repeated silica gel chromatography. α-Mangostin was found to be a potent inhibitor of acid production by S. mutans UA159, active against membrane enzymes, including the F(H+)-ATPase and the phosphoenolpyruvate - sugar phosphotransferase system. α-Mangostin also inhibited the glycolytic enzymes aldolase, glyceraldehyde-3-phosphate dehydrogenase, and lactic dehydrogenase. Glycolysis by intact cells in suspensions or biofilms was inhibited by α-mangostin at concentrations of 12 and 120 µmol·L⁻¹, respectively, in a pH-dependent manner, with greater potency at lower pH values. Other targets for inhibition by α-mangostin included (i) malolactic fermentation, involved in alkali production from malate, and (ii) NADH oxidase, the major respiratory enzyme for S. mutans. The overall conclusion is that α-mangostin is a multitarget inhibitor of mutans streptococci and may be useful as an anticaries agent.

Solution structure of the IIAChitobiose-IIBChitobiose complex of the N,N'-diacetylchitobiose branch of the Escherichia coli phosphotransferase system.

The solution structure of the IIA-IIB complex of the N,N'-diacetylchitobiose (Chb) transporter of the Escherichia coli phosphotransferase system has been solved by NMR. The active site His-89 of IIA(Chb) was mutated to Glu to mimic the phosphorylated state and the active site Cys-10 of IIB(Chb) was substituted by serine to prevent intermolecular disulfide bond formation. Binding is weak with a K(D) of approximately 1.3 mm. The two complementary interaction surfaces are largely hydrophobic, with the protruding active site loop (residues 9-16) of IIB(Chb) buried deep within the active site cleft formed at the interface of two adjacent subunits of the IIA(Chb) trimer. The central hydrophobic portion of the interface is surrounded by a ring of polar and charged residues that provide a relatively small number of electrostatic intermolecular interactions that serve to correctly align the two proteins. The conformation of the active site loop in unphosphorylated IIB(Chb) is inconsistent with the formation of a phosphoryl transition state intermediate because of steric hindrance, especially from the methyl group of Ala-12 of IIB(Chb). Phosphorylation of IIB(Chb) is accompanied by a conformational change within the active site loop such that its path from residues 11-13 follows a mirror-like image relative to that in the unphosphorylated state. This involves a transition of the phi/psi angles of Gly-13 from the right to left alpha-helical region, as well as smaller changes in the backbone torsion angles of Ala-12 and Met-14. The resulting active site conformation is fully compatible with the formation of the His-89-P-Cys-10 phosphoryl transition state without necessitating any change in relative translation or orientation of the two proteins within the complex.

Solution structure of a post-transition state analog of the phosphotransfer reaction between the A and B cytoplasmic domains of the mannitol transporter IIMannitol of the Escherichia coli phosphotransferase system.

The solution structure of the post-transition state complex between the isolated cytoplasmic A (IIAMtl) and phosphorylated B (phospho-IIBMtl) domains of the mannitol transporter of the Escherichia coli phosphotransferase system has been solved by NMR. The active site His-554 of IIAMtl was mutated to glutamine to block phosphoryl transfer activity, and the active site Cys-384 of IIBMtl (residues of IIBMtl are denoted in italic type) was substituted by serine to permit the formation of a stable phosphorylated form of IIBMtl. The two complementary interaction surfaces are predominantly hydrophobic, and two methionines on IIBMtl, Met-388 and Met-393, serve as anchors by interacting with two deep pockets on the surface of IIAMtl. With the exception of a salt bridge between the conserved Arg-538 of IIAMtl and the phosphoryl group of phospho-IIBMtl, electrostatic interactions between the two proteins are limited to the outer edges of the interface, are few in number, and appear to be weak. This accounts for the low affinity of the complex (Kd approximately 3.7 mm), which is optimally tuned to the intact biological system in which the A and B domains are expressed as a single polypeptide connected by a flexible 21-residue linker. The phosphoryl transition state can readily be modeled with no change in protein-protein orientation and minimal perturbations in both the backbone immediately adjacent to His-554 and Cys-384 and the side chains in close proximity to the phosphoryl group. Comparison with the previously solved structure of the IIAMtl-HPr complex reveals how IIAMtl uses the same interaction surface to recognize two structurally unrelated proteins and explains the much higher affinity of IIAMtl for HPr than IIBMtl.

Substrate-induced conformational changes in the membrane-embedded IIC(mtl)-domain of the mannitol permease from Escherichia coli, EnzymeII(mtl), probed by tryptophan phosphorescence spectroscopy.

Membrane-bound transport proteins are expected to proceed via different conformational states during the translocation of a solute across the membrane. Tryptophan phosphorescence spectroscopy is one of the most sensitive methods used for detecting conformational changes in proteins. We employed this technique to study substrate-induced conformational changes in the mannitol permease, EnzymeII(mtl), of the phosphoenolpyruvate-dependent phosphotransferase system from Escherichia coli. Ten mutants containing a single tryptophan were engineered in the membrane-embedded IIC(mtl)-domain, harboring the mannitol translocation pathway. The mutants were characterized with respect to steady-state and time-resolved phosphorescence, yielding detailed, site-specific information of the Trp microenvironment and protein conformational homogeneity. The study revealed that the Trp environments vary from apolar, unstructured, and flexible sites to buried, highly homogeneous, rigid peptide cores. The most remarkable example of the latter was observed for position 97, because its long sub-second phosphorescence lifetime and highly structured spectra in both glassy and fluid media imply a well defined and rigid core around the probe that is typical of beta-sheet-rich structural motifs. The addition of mannitol had a large impact on most of the Trp positions studied. In the case of position 97, mannitol binding induced partial unfolding of the rigid protein core. On the contrary, for residue positions 126, 133, and 147, both steady-state and time-resolved data showed that mannitol binding induces a more ordered and homogeneous structure around these residues. The observations are discussed in context of the current mechanistic and structural model of EII(mtl).

Sugar import and phytopathogenicity of Spiroplasma citri: glucose and fructose play distinct roles.

We have shown previously that the glucose PTS (phosphotransferase system) permease enzyme II of Spiroplasma citri is split into two distinct polypeptides, which are encoded by two separate genes, crr and ptsG. A S. citri mutant was obtained by disruption of ptsG through homologous recombination and was proved unable to import glucose. The ptsG mutant (GII3-glc1) was transmitted to periwinkle (Catharanthus roseus) plants through injection to the leaf-hopper vector. In contrast to the previously characterized fructose operon mutant GMT 553, which was found virtually nonpathogenic, the ptsG mutant GII3-glc1 induced severe symptoms similar to those induced by the wild-type strain GII-3. These results, indicating that fructose and glucose utilization were not equally involved in pathogenicity, were consistent with biochemical data showing that, in the presence of both sugars, S. citri used fructose preferentially. Proton nuclear magnetic resonance analyses of carbohydrates in plant extracts revealed the accumulation of soluble sugars, particularly glucose, in plants infected by S. citri GII-3 or GII3-glc1 but not in those infected by GMT 553. From these data, a hypothetical model was proposed to establish the relationship between fructose utilization by the spiroplasmas present in the phloem sieve tubes and glucose accumulation in the leaves of S. citri infected plants.

The glucose-specific carrier of the Escherichia coli phosphotransferase system.

Thirteen glucose analogues bearing electrophilic groups were synthesized (five of them for the first time) and screened as inhibitors of the glucose transporter (EIIGlc) of the Escherichia coli phosphoenolpyruvate-sugar phosphotransferase system (PTS). 2',3'-Epoxypropyl beta-d-glucopyranoside (3a) is an inhibitor and also a pseudosubstrate. Five analogues are inhibitors of nonvectorial Glc phosphorylation by EIIGlc but not pseudosubstrates. They are selective for EIIGlc as demonstrated by comparison with EIIMan, another Glc-specific but structurally different transporter. 3a is the only analogue that inhibits EIIGlc by binding to the high-affinity cytoplasmic binding site and also strongly inhibits sugar uptake mediated by this transporter. The most potent inhibitor in vitro, methyl 6,7-anhydro-d,l-glycero-alpha-d-gluco-heptopyranoside (1d), preferentially interacts with the low-affinity cytoplasmic site but only weakly inhibits Glc uptake. Binding and/or phosphorylation from the cytoplasmic side of EIIGlc is more permissive than sugar binding and/or translocation of substrates via the periplasmic site. EIIGlc is rapidly inactivated by the 6-O-bromoacetyl esters of methyl alpha-d-glucopyranoside (1a) and methyl alpha-d-mannopyranoside (1c), methyl 6-deoxy-6-isothiocyanato-alpha-d-glucopyranoside (1e), beta-d-glucopyranosyl isothiocyanate (3c) and beta-d-glucopyranosyl phenyl isothiocyanate (3d). Phosphorylation of EIIGlc protects, indicating that inactivation occurs by alkylation of Cys421. Glc does not protect, but sensitizes EIIGlc for inactivation by 1e and 3d, which is interpreted as the effect of glucose-induced conformational changes in the dimeric transporter. Glc also sensitizes EIIGlc for inactivation by 1a and 1c of uptake by starved cells. This indicates that Cys421 which is located on the cytoplasmic domain of EIIGlc becomes transiently accessible to substrate analogues on the periplasmic side of the transporter.

Synthesis of phosphoenol pyruvate (PEP) analogues and evaluation as inhibitors of PEP-utilizing enzymes.

The synthesis of 10 new phosphoenolpyruvate (PEP) analogues with modifications in the phosphate and the carboxylate function is described. Included are two potential irreversible inhibitors of PEP-utilizing enzymes. One incorporates a reactive chloromethylphosphonate function replacing the phosphate group of PEP. The second contains a chloromethyl group substituting for the carboxylate function of PEP. An improved procedure for the preparation of the known (Z)- and (E)-3-chloro-PEP is also given. The isomers were obtained as a 4 : 1 mixture, resolved by anion-exchange chromatography after the last reaction step. The stereochemistry of the two isomers was unequivocally assigned from the (3)J(H-C) coupling constants between the carboxylate carbons and the vinyl protons. All of these and other known PEP-analogues were tested as reversible and irreversible inhibitors of Mg2+- and Mn2+- activated PEP-utilizing enzymes: enzyme I of the phosphoenolpyruvate:sugar phosphotransferase system (PTS), pyruvate kinase, PEP carboxylase and enolase. Without exception, the most potent inhibitors were those with substitution of a vinyl proton. Modification of the phosphate and the carboxylate groups resulted in less effective compounds. Enzyme I was the least tolerant to such modifications. Among the carboxylate-modified analogues, only those replaced by a negatively charged group inhibited pyruvate kinase and enolase. Remarkably, the activity of PEP carboxylase was stimulated by derivatives with neutral groups at this position in the presence of Mg2+, but not with Mn2+. For the irreversible inhibition of these enzymes, (Z)-3-Cl-PEP was found to be a very fast-acting and efficient suicide inhibitor of enzyme I (t(1/2) = 0.7 min).

31P-NMR and 13C-NMR studies of mannose metabolism in Plesiomonas shigelloides. Toxic effect of mannose on growth.

The metabolism of mannose was examined in resting cells in vivo using 13C-NMR and 31P-NMR spectroscopy, in cell-free extracts in vitro using 31P-NMR spectroscopy, and by enzyme assays. Plesiomonas shigelloides was shown to transport mannose by a phosphoenolpyruvate-dependent phosphotransferase system producing mannose 6-phosphate. However, a toxic effect was observed when P. shigelloides was grown in the presence of mannose. Investigation of mannose metabolism using in vivo 13C NMR showed mannose 6-phosphate accumulation without further metabolism. In contrast, glucose was quickly metabolized under the same conditions to lactate, ethanol, acetate and succinate. Extracts of P. shigelloides exhibited no mannose-6-phosphate isomerase activity whereas the key enzyme of the Embden-Meyerhof pathway (6-phosphofructokinase) was found. This result explains the mannose 6-phosphate accumulation observed in cells grown on mannose. The levels of phosphoenolpyruvate and Pi were estimated by in vivo 31P-NMR spectroscopy. The intracellular concentrations of phosphoenolpyruvate and Pi were relatively constant in both starved cells and mannose-metabolizing cells. In glucose-metabolizing cells, the phosphoenolpyruvate concentration was lower, and about 80% of the Pi was used during the first 10 min. It thus appears that the toxic effect of mannose on growth is not due to energy depletion but probably to a toxic effect of mannose 6-phosphate.

Structure of the IIA domain of the mannose transporter from Escherichia coli at 1.7 angstroms resolution.

The mannose transporter from Escherichia coli is a member of the phosphoenolpyruvate-dependent phosphotransferase system. The multi-subunit complex couples translocation across the bacterial inner membrane with phosphorylation of the solute. A functional fragment (IIA(Man), residues 2 to 133) of the membrane-associated IIAB(Man) subunit of the mannose transporter was expressed as a selenomethionine protein, and the unphosphorylated molecule was crystallized and its structure solved by X-ray crystallography. The protein consists of a central five-stranded beta-sheet covered by helices on either face. The order of the secondary structure elements is (beta alpha)4, alpha beta. Four beta-strands are arranged in a parallel manner with strand order 2134 and are linked by helices forming right-handed cross-over connections. The fifth strand that forms one edge of the sheet and runs antiparallel to the others is swapped between the subunits of the dimeric structure. Helices D and E form a helical hairpin. Histidine 10, which is transiently phosphorylated during catalysis, is located at the topological switch-point of the structure, close to the subunit interface. Its imidazole ring is hydrogen bonded to the buried side-chain of Asp67. It is likely that Asp67 acts as a general base and thus increases the nucleophilicity of the histidine. Modeling suggests that the covalently bound phosphoryl group would be stabilized by the macrodipole of helix C. Putative interactions between IIA(Man) and the histidine-containing phosphocarrier protein are discussed.

Confronting the problem of interconnected structural changes in the comparative modeling of proteins.

Comparative models of three proteins have been built using a variety of computational methods, heavily supplemented by visual inspection. We consider the accuracy obtained to be worse than expected. A careful analysis of the models shows that a major reason for the poor results is the interconnectedness of the structural differences between the target proteins and the template structures they were modeled from. Side chain conformations are often determined by details of the structure remote in the sequence, and can be influenced by relatively small main chain changes. Almost all of the regions of substantial main chain conformational change interact with at least one other such region, so that they often cannot be modeled independently. Visual inspection is sometimes effective in correcting errors in sequence alignment and in spotting when an alternative template structure is more appropriate. We expect some improvements in the near future through the development of structure-based sequence alignment tools, side chain interconnectedness rotamer choice algorithms, and a better understanding of the context sensitivity of conformational features.

Mutagenesis by 9-aminoacridine in Salmonella typhimurium: inhibition by glucose and other PTS class A carbon sources.

Reversion of the hisC3076 frameshift marker of Salmonella typhimurium has been measured following treatment of cells in growth and non-growth media with 9-aminoacridine (9AA). By varying the carbon source present in a defined medium, it has been shown that mutagenesis is reduced close to the spontaneous level in the presence of glucose whilst significant reductions are also observed with glucosamine, mannose, mannitol, fructose or glucose 6-phosphate. Intermediate mutant yields are observed when lactic acid or glycerol are present, whereas any one of a further group of carbon sources (gluconate, arabinose, ribose, succinate or casein hydrolysate) permit relatively large numbers of mutants to be recovered. Interestingly, when any one of these "high yield" carbon sources is supplemented with glucose the strong inhibitory effect characteristic of glucose is again observed. On the basis of these results, it can be concluded that inhibition of 9AA-induced reversion by a carbon source is not an exclusive property of glucose, although when more than one carbon source is present the inhibitory effect of glucose predominates. Possible explanations for these findings include the active exclusion of 9AA from cells as a direct consequence of glucose transport across the cell membrane. To address this possibility, cells were pre-grown in verapamil, a calcium channel antagonist which is known to increase the mutagenicity of various 9-anilinoacridine derivatives in S. typhimurium. We found that glucose inhibition of 9AA-induced mutagenesis was not relaxed to any significant extent following treatment with verapamil. In a further experiment, two glucose analogues (2'-deoxyglucose and methyl-D-glucoside) known to be actively transported into the cell but not metabolised past the first phosphorylation step were used. These analogues inhibit the transport into the cell of several types of molecules, but since they do not significantly depress 9AA mutagenesis it seems unlikely that blockage of 9AA transport across the cell membrane can be invoked to explain the inhibitory effect of glucose on 9AA mutagenesis. An alternative explanation based on glucose-mediated repression of an error-prone, mutation-generating, DNA-repair process is presented.

31phospho-NMR demonstration of phosphocysteine as a catalytic intermediate on the Escherichia coli phosphotransferase system EIIMtl.

The mannitol-specific phosphotransferase system transport protein, Enzyme IIMtl, contains two catalytically important phosphorylated amino acid residues, both present on the cytoplasmic part of the enzyme. Recently, this portion has been subcloned, purified, and shown to be an enzymatically active domain. The N-terminal half has also been subcloned and shown to be the mannitol-binding domain. When combined the two domains catalyze mannitol phosphorylation at the expense of phospho-HPr (van Weeghel, R. P., Meyer, G. H., Pas, H. H., Keck, W. H., and Robillard, G. T., Biochemistry in press). The phospho-NMR spectrum of the purified phosphorylated cytoplasmic domain, taken at pH 8.0, shows two signals, one at -6.9 ppm compared with inorganic phosphate resulting from phosphohistidine and one at +11.9 ppm originating from phosphocysteine. Addition of mannitol plus membranes containing the N-terminal mannitol-binding domain results in the formation of mannitol 1-phosphate and the disappearance of the two signals at -6.9 and +11.9 ppm.

Reconstitution of regulatory properties of adenylate cyclase in Escherichia coli extracts.

The inhibition of adenylate cyclase activity of Escherichia coli by methyl alpha-glucoside has been demonstrated in intact or in permeable cells but not in cell-free extracts. In intact or permeable cells, this inhibition is demonstrable only in strains expressing the genes for proteins of the phosphoenolpyruvate:glycose phosphotransferase system (PTS); in permeable cells, the inhibition also requires potassium phosphate. Using homogeneous proteins of the PTS, we have reconstituted in cell-free extracts many of the features of the regulated form of adenylate cyclase: (i) In the absence of K2HPO4, permeable cells have lower adenylate cyclase activity than extracts; addition of homogeneous PTS proteins to the extracts brings adenylate cyclase activity close to the level observed in permeable cells. (ii) The low activity observed in permeable cells is stimulated by potassium phosphate; this stimulation is also observed in extracts supplemented with PTS proteins and phosphoenolpyruvate. (iii) In permeable cells, potassium phosphate-stimulated adenylate cyclase activity is inhibited by methyl alpha-glucoside or pyruvate; extracts behaved similarly when supplemented with PTS proteins, K2HPO4, and phosphoenolpyruvate. Thus, the regulated form of adenylate cyclase has been reconstituted in cell-free extracts by addition of homogeneous PTS proteins.