d-Glucose Transport System of Zymomonas mobilis

The properties of the d-glucose transport system of Zymomonas mobilis were determined by measuring the uptake of nonmetabolizable analogs (2-deoxy-d-glucose and d-xylose) by wild-type cells and the uptake of d-glucose itself by a mutant lacking glucokinase. d-Glucose was transported by a constitutive, stereospecific, carrier-mediated facilitated diffusion system, whereby its intracellular concentration quickly reached a plateau close to but not above the external concentration. d-Xylose was transported by the d-glucose system, as evidenced by inhibition of its uptake by d-glucose. d-Fructose was not an efficient competitive inhibitor of d-glucose uptake, indicating that it has a low affinity for the d-glucose transport system. The apparent K(m) of d-glucose transport was in the range of 5 to 15 mM, with a V(max) of 200 to 300 nmol min mg of protein. The K(m) of Z. mobilis glucokinase (0.25 to 0.4 mM) was 1 order of magnitude lower than the K(m) for d-glucose transport, although the V(max) values for transport and phosphorylation were similar. Thus, glucose transport cannot be expected to be rate limiting at concentrations of extracellular glucose normally used in fermentation processes, which greatly exceed the K(m) for the transport system. The low-affinity, high-velocity, nonconcentrative system for d-glucose transport described here is consistent with the natural occurrence of Z. mobilis in high-sugar environments and with the capacity of Z. mobilis for rapid conversion of glucose to metabolic products with low energetic yield.     

The use of deoxyfluoro-d-glucopyranoses and related compounds in a study of yeast hexokinase specificity

1. 2-Deoxy-2-fluoro-d-glucose, 2-deoxy-2-fluoro-d-mannose and 2-deoxy-2,2-difluoro-d-arabino-hexose are good substrates for yeast hexokinase. 2. 3-Deoxy-3-fluoro-d-glucose and 4-deoxy-4-fluoro-d-glucose are poor substrates and have very similar K(m) values (8x10(-2)m). 3. Neither alpha- nor beta-d-glucopyranosyl fluoride is a substrate or inhibitor. 4. Studies with 2-chloro-2-deoxy- and 2-O-methyl derivatives of d-glucose and d-mannose have revealed that little chemical modification is possible at position 2 without substantial loss in substrate binding. 5. The variation in the value of K(m) for the d-hexose derivatives was associated with a corresponding change in the value of K(m) for MgATP(2-) showing that the binding of MgATP(2-) is modified by the binding of the sugar.     

Substrate specificity of a chimera made from Xenopus SGLT1-like protein and rabbit SGLT1

To characterize the sugar translocation pathway of Na(+)/glucose cotransporter type 1 (SGLT1), a chimera was made by substituting the extracellular loop between transmembrane domain (TM) 12 and TM13 of Xenopus SGLT1-like protein (xSGLT1L) with the homologous region of rabbit SGLT1. The chimera was expressed in Xenopus oocytes and its transport activity was measured by the two-microelectrode voltage-clamp method. The substrate specificity of the chimera was different from those of xSGLT1L and SGLT1. In addition the chimera's apparent Michaelis-Menten constant (K(m)) for myo-inositol, 0.06 mM, was about one fourth of that of xSGLT1L, 0.25 mM, while the chimera's apparent K(m) for d-glucose, 0.8 mM, was about one eighth of that of xSGLT1L, 6.3 mM. Our results suggest that the extracellular loop between TM12 and TM13 participates in the sugar transport of SGLT1.     

Mlc of Thermus thermophilus: a glucose-specific regulator for a glucose/mannose ABC transporter in the absence of the phosphotransferase system

We report the presence of Mlc in a thermophilic bacterium. Mlc is known as a global regulator of sugar metabolism in gram-negative enteric bacteria that is controlled by sequestration to a glucose-transporting EII(Glc) of the phosphotransferase system (PTS). Since thermophilic bacteria do not possess PTS, Mlc in Thermus thermophilus must be differently controlled. DNA sequence alignments between Mlc from T. thermophilus (Mlc(Tth)) and Mlc from E. coli (Mlc(Eco)) revealed that Mlc(Tth) conserved five residues of the glucose-binding motif of glucokinases. Here we show that Mlc(Tth) is not a glucokinase but is indeed able to bind glucose (K(D) = 20 microM), unlike Mlc(Eco). We found that mlc of T. thermophilus is the first gene within an operon encoding an ABC transporter for glucose and mannose, including a glucose/mannose-binding protein and two permeases. malK1, encoding the cognate ATP-hydrolyzing subunit, is located elsewhere on the chromosome. The system transports glucose at 70 degrees C with a K(m) of 0.15 microM and a V(max) of 4.22 nmol per min per ml at an optical density (OD) of 1. Mlc(Tth) negatively regulates itself and the entire glucose/mannose ABC transport system operon but not malK1, with glucose acting as an inducer. MalK1 is shared with the ABC transporter for trehalose, maltose, sucrose, and palatinose (TMSP). Mutants lacking malK1 do not transport either glucose or maltose. The TMSP transporter is also able to transport glucose with a K(m) of 1.4 microM and a V(max) of 7.6 nmol per min per ml at an OD of 1, but it does not transport mannose.     

A colorimetric determination of inositol monophosphates as an assay for d-glucose 6-phosphate–1l-myoinositol 1-phosphate cyclase

A rapid and convenient chemical assay for the enzyme d-glucose 6-phosphate-1l-myoinositol 1-phosphate cyclase is described. The 1l-myoinositol 1-phosphate formed enzymically was oxidized with periodic acid liberating inorganic phosphate, which was assayed. myoInositol 2-phosphate can be assayed in the same way. Glucose 6-phosphate and other primary phosphate esters gave only very small quantities of inorganic phosphate under the conditions described. The K(m) of the enzyme for d-glucose 6-phosphate, 7.5+/-2.5x10(-4)m, was identical with that measured by the radiochemical method. 2-Deoxy-d-glucose 6-phosphate was a powerful competitive inhibitor, K(i) 2.0+/-0.5x10(-5)m, but was not a substrate for the enzyme.     

The chitin disaccharide, N,N'-diacetylchitobiose, is catabolized by Escherichia coli and is transported/phosphorylated by the phosphoenolpyruvate:glycose phosphotransferase system

We have previously reported that wild type strains of Escherichia coli grow on the chitin disaccharide N,N'-diacetylchitobiose, (GlcNAc)(2), as the sole source of carbon (Keyhani, N. O., and Roseman, S. (1997) Proc. Natl. Acad. Sci., U. S. A. 94, 14367-14371). A nonhydrolyzable analogue of (GlcNAc)(2,) methyl beta-N, N'-[(3)H]diacetylthiochitobioside ([(3)H]Me-TCB), was used to characterize the disaccharide transport process, which was found to be mediated by the phosphoenolpyruvate:glycose phosphotransferase system (PTS). Here and in the accompanying papers (Keyhani, N. O., Boudker, O., and Roseman, S. (2000) J. Biol. Chem. 275, 33091-33101; Keyhani, N. O., Bacia, K., and Roseman, S. (2000) J. Biol. Chem. 275, 33102-33109; Keyhani, N. O., Rodgers, M., Demeler, B., Hansen, J., and Roseman, S. (2000) J. Biol. Chem. 275, 33110-33115), we report that transport of [(3)H]Me-TCB and (GlcNAc)(2) involves a specific PTS Enzyme II complex, requires Enzyme I and HPr of the PTS, and results in the accumulation of the sugar derivative as a phosphate ester. The phosphoryl group is linked to the C-6 position of the GlcNAc residue at the nonreducing end of the disaccharide. The [(3)H]Me-TCB uptake system was induced only by (GlcNAc)(n), n = 2 or 3. The apparent K(m) of transport was 50-100 micrometer, and effective inhibitors of uptake included (GlcNAc)(n), n = 2 or 3, cellobiose, and other PTS sugars, i.e. glucose and GlcNAc. Presumably the PTS sugars inhibit by competing for PTS components. Kinetic properties of the transport system are described.     

Magnesium Transport in Bacillus subtilis W23 During Growth and Sporulation

The active transport of magnesium by cells of Bacillus subtilis strain W23 occurs by a highly specific transport system (Mg(2+) is favored over Mn(2+), Co(2+), or Ca(2+)) that is energy dependent (i.e., glucose is required in minimal medium and the system is inhibited by cyanide and m-chlorophenyl carbonylcyanidehydrazone). The rate of magnesium uptake by log-phase B. subtilis cells follows saturation kinetics with a K(m) of 2.5 x 10(-4) M and a V(max) of 4.4 mumol per min per g (dry weight) at 30 C. Manganese is a competitive inhibitor showing a K(i) of 5 x 10(-4) M. During sporulation the rate of magnesium transport declines. This decline in rate is specific for the magnesium system as the manganese and calcium transport rates increase. The residual magnesium transport function in sporulating cells shows both an altered K(m) and an altered V(max). The magnesium content of late sporulating cells is also lower than that for log-phase cells.     

Reconstitution of a defunct glycolytic pathway via recruitment of ambiguous sugar kinases

During a recent investigation of the persistence of substrate ambiguity in contemporary enzymes, we identified three distinct ambiguous sugar kinases embedded within the modern Escherichia coli genome [Miller, B. G., and Raines, R. T. (2004) Biochemistry 43, 6387-6392]. These catalysts are the YajF, YcfX, and NanK polypeptides, all of which possess rudimentary glucokinase activities. Here, we report on the discovery of a fourth bacterial kinase with ambiguous substrate specificity. AlsK phosphorylates the glucose epimer, d-allose, with a k(cat)/K(m) value of 6.5 x 10(4) M(-)(1) s(-)(1). AlsK also phosphorylates d-glucose, with a k(cat)/K(m) value that is 10(5)-fold lower than the k(cat)/K(m) value displayed by native E. coli glucokinase. Overexpression of the alsK gene relieves the auxotrophy of a glucokinase-deficient bacterium, demonstrating that weak enzymatic activities derived from ambiguous catalysts can provide organisms with elaborated metabolic capacities. To explore how ambiguous catalysts are recruited to provide new functions, we placed the glucokinase-deficient bacterium under selection for growth at the expense of glucose. Under these conditions, the bacterium acquires a spontaneous mutation in the putative promoter region of the yajF gene, a locus previously shown to encode a sugar kinase with relaxed substrate specificity. The point mutation regenerates a consensus sigma(70) promoter sequence that leads to a 94-fold increase in the level of yajF expression. This increase provides sufficient glucokinase activity for reconstitution of the defunct glycolytic pathway of the bacterial auxotroph. Our current findings indicate that ambiguous enzymatic activities continue to play an important role in the evolution of new metabolic pathways, and provide insight into the molecular mechanisms that facilitate the recruitment of such catalysts during periods of natural selection.     

Specificity of natural and artificial substrates for human Cdc25A

Cdc25A is a dual-specific protein phosphatase involved in the regulation of the kinase activity of Cdk-cyclin complexes in the eukaryotic cell cycle. To understand the mechanism of this important regulator, we have generated highly purified biochemical reagents to determine the kinetic constants for human Cdc25A with respect to a set of peptidic, artificial, and natural substrates. Cdc25A and its catalytic domain (dN25A) demonstrate very similar kinetics toward the artificial substrates p-nitrophenyl phosphate (k(cat)/K(m) = 15-25 M(-1) s(-1)) and 3-O-methylfluorescein phosphate (k(cat)/K(m) = 1.1-1.3 x 10(4) M(-1) s(-1)). Phospho-peptide substrates exhibit extremely low second-order rate constants and a flat specificity profile toward Cdc25A and dN25A (k(cat)/K(m) = 1 to 10 M(-1) s(-1)). In contrast to peptidic substrates, Cdc25A and dN25A are highly active phosphatases toward the natural substrate, T14- and Y15-bis-phosphorylated Cdk2/CycA complex (Cdk2-pTpY/CycA) with k(cat)/K(m) values of 1.0-1.1 x 10(6) M(-1) s(-1). In the context of the Cdk2-pTpY/CycA complex, phospho-threonine is preferred over phospho-tyrosine by more than 10-fold. The highly homologous catalytic domain of Cdc25c is essentially inactive toward Cdk2-pTpY/CycA. Taken together these data indicate that a significant degree of the specificity of Cdc25 toward its Cdk substrate resides within the catalytic domain itself and yet is in a region(s) that is outside the phosphate binding site of the enzyme.     

Relationship between sugar structure and competition for the sugar transport system in Bakers' yeast

Twenty-five sugars have been compared as inhibitors of l-sorbose or d-xylose transport by the constitutive, monosaccharide transport system in bakers' yeast. d-Glucose showed the highest activity (i.e., apparent K(i) = 5 mm). Since all sugars except 2-deoxyglucose showed a decrease in activity relative to glucose (i.e., apparent K(i) = 25 - >2,000 mm), an attempt was made to relate the activity of each sugar with the way its structure differs from that of d-glucose. Assuming that the inhibition was the result of sugar-carrier complex formation, the analysis showed that the transport system has a rather broad specificity for pyranoses. Single changes at each of the five carbons of d-glucose (except for the 2-deoxy derivative) result in variable decreases in activity depending upon the carbon number and the alteration. The largest decrease in activity effected by a single change is the methylation or glucosylation of the anomeric hydroxyl. The combination of two or more changes leads to a decrease which is greater than the decrease in activity resulting from the individual changes occurring alone.     

Purification and characterization of a protein tyrosine acid phosphatase from boar seminal vesicle glands

A protein tyrosine phosphatase (PTPase) with acid phosphatase activity was purified (500-fold) from the fluid of boar seminal vesicles. Preparative purification was performed with a 3-step procedure, employing FPLC S-Sepharose Fast Flow, Mono Q and Superdex 75 column. Protein tyrosine acid phosphatase (PTAPase) was homogeneous by polyacrylamide gel electrophoresis (PAGE, SDS-PAGE). PTAPase is a glycoprotein which has a molecular weight of about 41-42 kDa. This enzyme was maximally active at pH 5.5, and its thermostability was less than 80 degrees C. The K(m) value for p-nitrophenylphosphate, a specific synthetic substrate, was 0.87 x 10(-3)M, however, higher substrate specificity was shown when phosphotyrosine (K(m)=0.37 x 10(-3)M) and protein fragments, such as gastrin (K(m)=0.0032 x 10(-3)M) and hirudin (K(m)=0.0075 x 10(-3)M), were used as substrates. Activity of PTAPase was inhibited by dephostatin, molybdate and orthovanadate by 100, 95 and 70%, respectively, when phosphotyrosine was used as the substrate. Immunofluorescence study has shown that the seminal vesicles are the only source of PTAPase in boar seminal plasma.     

Interactions in vivo between IIIGlc of the phosphoenolpyruvate:sugar phosphotransferase system and the glycerol and maltose uptake systems of Salmonella typhimurium

Our previous studies indicated that the ability of phosphoenolpyruvate:sugar phosphotransferase system (PTS) substrates to inhibit the uptake of glycerol or maltose in Salmonella typhimurium is dependent on the relative cellular content of the PTS-sensitive uptake system and of the PTS protein IIIGlc. Our present study confirms and extends those observations. The maltose and glycerol uptake systems are rendered (wholly or partially) insensitive to PTS inhibition by the presence of a second PTS-sensitive uptake system (respectively that for glycerol or maltose) and its substrate. Both the second PTS-sensitive uptake system and its substrate were needed for this protective effect. Galactose and the galactose permease (a PTS-insensitive transport system) did not have any effect on PTS-mediated inhibition of the maltose uptake system. The protective effect of the second PTS-sensitive uptake system and its substrate is counteracted by increasing the cellular levels of IIIGlc. Overproduction of IIIGlc in crr-plasmid-containing strains renders the glycerol and maltose uptake systems hypersensitive to inhibition by PTS substrates. We interpret our results on the basis of a stoichiometric interaction between IIIGlc and a PTS-sensitive uptake system, in which the IIIGlc--transport-system complex is inactive. Competition between two PTS-sensitive transport systems for formation of inactive complex with IIIGlc lowers the free intracellular concentration of IIIGlc resulting in a mutual protective effect against inhibition by IIIGlc.     

Hexose uptake in the plant symbiotic ascomycete Tuber borchii Vittadini: biochemical features and expression pattern of the transporter TBHXT1

Here, we report the first evidence of a hexose transporter gene, Tbhxt1, in the ectomycorrhizal ascomycete Tuber borchii Vittadini. The protein encoded by Tbhxt1 functionally complements the hxt-null mutant Saccharomyces cerevisiae EBYVW.4000. TBHXT1 has a strong preference for d-glucose (K(m)=38+/-10 microM) over d-fructose (K(m)=16+/-5mM) and uncoupling experiments indicate that TBHXT1 catalyzes the transport via a proton-symport mechanism. The investigations on the substrate specificity reveal that TBHXT1 also imports d-mannose, and the use of deoxyglucose analogues shows that the hydroxyl groups at C1, C3 and C4 are important for substrate recognition. Tbhxt1 is not regulated by fructose, but it reaches its highest level of expression at 3mM glucose and is repressed by very high glucose concentration. Prolonged carbon starvation condition upregulates Tbhxt1, while its expression remains at basal level in the ectomycorrhizal tissue. The mode of regulation of Tbhxt1 is consistent with its role as a high-affinity d-glucose transporter.     

Multiplicity of Isoleucine, Leucine, and Valine Transport Systems in Escherichia coli K-12

The kinetics of isoleucine, leucine, and valine transport in Escherichia coli K-12 has been analyzed as a function of substrate concentration. Such analysis permits an operational definition of several transport systems having different affinities for their substrates. The identification of these transport systems was made possible by experiments on specific mutants whose isolation and characterization is described elsewhere. The transport process with highest affinity was called the "very-high-affinity"process. Isoleucine, leucine, and valine are substrates of this transport process and their apparent K(m) values are either 10(-8), 2 x 10(-8), or 10(-7) M, respectively. Methionine, threonine, and alanine inhibit this transport process, probably because they are also substrates. The very-high-affinity transport process is absent when bacteria are grown in the presence of methionine, and this is due to a specific repression. Methionine and alanine were also found to affect the pool size of isoleucine and valine. Another transport process is the "high-affinity" process. Isoleucine, leucine, and valine are substrates of this transport process, and their apparent K(m) value is 2 x 10(-6) M for all three. Methionine and alanine cause very little or no inhibition, whereas threonine appears to be a weak inhibitor. Several structural analogues of the branched-chain amino acids inhibit the very-high-affinity or the high-affinity transport process in a specific way, and this confirms their existence as two separate entities. Three different "low-affinity" transport processes, each specific for either isoleucine or leucine or valine, show apparent K(m) values of 0.5 x 10(-4) M. These transport processes show a very high substrate specificity since no inhibitor was found among other amino acids or among many branched-chain amino acid precursors or analogues tried. The evolutionary significance of the observed redundancy of transport systems is discussed.     

Sugar recognition by the glucose and mannose permeases of Escherichia coli. Steady-state kinetics and inhibition studies

The glucose (EII(Glc)) and mannose (EII(Man)) permeases of the phosphoenolpyruvate:sugar phosphotransferase system (PTS) of Escherichia coli belong to structurally different families of PTS transporters. The sugar recognition mechanism of the two transporters is compared using as inhibitors and pseudosubstrates all possible monodeoxy analogues, monodeoxyfluoro analogues, and epimers of D-glucose. The analogues were tested as phosphoryl acceptors in vitro and as uptake inhibitors with intact cells. Both EII have a high K(m) of phosphorylation for glucose modified at C-4 and C-6, and these analogues also are weak inhibitors of uptake. Conversely, modifications at C-1 (and also at C-2 with EII(Man)) were well tolerated. OH-3 is proposed to interact with hydrogen bond donors on EII(Glc) and EII(Man), since only substitution by fluorine was tolerated. Glucose-6-aldehydes, which exist as gem-diols in aqueous solution, are potent and highly selective inhibitors of "nonvectorial" phosphorylation by EII(Glc) (K(I) 3-250 microM). These aldehydes are comparatively weak inhibitors of transport by EII(Glc) and of phosphorylation and transport by EII(Man). Both transporters display biphasic kinetics (with glucose and some analogues) but simple Michaelis-Menten kinetics with 3-fluoroglucose (and other analogues). Kinetic simulations of the phosphorylation activities measured with different substrates and inhibitors indicate that two independent activities are present at the cytoplasmic side of the transporter. A working model that accounts for the kinetic data is presented.     

Transport of d-glucose by brush border membranes isolated from the renal cortex

The transport of d-glucose by brush border membranes isolated from the rabbit renal cortex was studied. At concentrations less than 2 mM, the rate of d-glucose uptake increased linearly with the concentration of the sugar. No evidence was found for a “high-affinity” (μM) saturable site. Saturation was indicated at concentrations of d-glucose greater than 5 mM. The uptake of d-glucose was stereospecific and selectively inhibited by d-galactose and other sugars. Phlorizin inhibited the uptake of d-glucose in the presence and absence of Na⁺. The glycoside was a potent inhibitor of the efflux of d-glucose. Preloading the brush border membrane vesicles with d-glucose, but not with l-glucose, accelerated exchange diffusion of d-glucose. These results demonstrate that the uptake of d-glucose by renal brush borders represents transport into an intravesicular space rather than solely binding. The rate of d-glucose uptake was increased when the Na⁺ in the extravesicular medium was high and the membranes were preloaded with a Na⁺-free medium. The rate of d-glucose uptake was inhibited by preloading the brush border membranes with Na⁺. These results are consistent with the Na⁺ gradient hypothesis for d-glucose transport in the kidney. Thus, the presence of a Na⁺-dependent facilitated transport of d-glucose in isolated renal brush border membranes is indicated. This finding is consistent with what is known of the transport of the sugar in more physiologically intact preparations and suggests that the membranes serve as an effective model system in examining the mechanism of d-glucose transport in the kidney.     

Direct effect of temperature on the catalytic activity of nitric oxide synthases types I, II, and III.

The effect of temperature (between 5.0 and 45.0 degrees C) on the catalytic activity of nitric oxide synthases types I, II, and III (NOS-I, NOS-II, and NOS-III, respectively) has been investigated, at pH 7.5. The value of V(max) for NOS-I activity increases from 1.8 x 10(1) pmol min(-1) mg(-1), at 5.0 degrees C, to 1.8 x 10(2) pmol min(-1) mg(-1), at 45.0 degrees C; on the other hand, the value of K(m) (=4.0 x 10(-6) M) is temperature independent. Again, the value of V(max) for NOS-II activity increases from 8.0 pmol min(-1) mg(-1), at 7.0 degrees C, to 5.4 x 10(1) pmol min(-1) mg(-1), at 40.0 degrees C, the value of K(m) (=1.8 x 10(-5) M) being unaffected by temperature. Temperature exerts the same effect on NOS-I and NOS-II activity, as shown by the same values of DeltaH(V(max)) (=4.2 x 10(1) kJ mol(-1)), DeltaH(K(m)) (=0 kJ mol(-1)), and DeltaH((V(max))(/K(m))()) (=4.2 x 10(1) kJ mol(-1)). On the contrary, the value of K(m) for NOS-III activity decreases from 3.8 x 10(-5) M, at 10.0 degrees C, to 1.6 x 10(-5) M, at 40.0 degrees C, the value of V(max) (=6.8 x 10(1) pmol min(-1) mg(-1)) being temperature independent. Present results indicate that temperature influences directly NOS-I and NOS-II activity independently of the substrate concentration, the values of K(m) being temperature independent. However, when l-arginine level is higher than 2 x 10(-4) M, as observed under in vivo conditions, NOS-III activity is essentially unaffected by temperature, the substrate concentration exceeding the value of K(m). As a whole, although further studies in vivo are needed, these observations seem to have potential physiopathologic implications.     

Glucose transport by a mutant of Streptococcus mutans unable to accumulate sugars via the phosphoenolpyruvate phosphotransferase system.

Streptococcus mutans transports glucose via the phosphoenolpyruvate (PEP)-dependent sugar phosphotransferase system (PTS). Earlier studies indicated that an alternate glucose transport system functions in this organism under conditions of high growth rates, low pH, or excess glucose. To identify this system, S. mutans BM71 was transformed with integration vector pDC-5 to generate a mutant, DC10, defective in the general PTS protein enzyme I (EI). This mutant expressed a defective EI that had been truncated by approximately 150 amino acids at the carboxyl terminus as revealed by Western blot (immunoblot) analysis with anti-EI antibody and Southern hybridizations with a fragment of the wild-type EI gene as a probe. Phosphotransfer assays utilizing 32P-PEP indicated that DC10 was incapable of phosphorylating HPr and EIIAMan, indicating a nonfunctional PTS. This was confirmed by the fact that DC10 was able to ferment glucose but not a variety of other PTS substrates and phosphorylated glucose with ATP and not PEP. Kinetic assays indicated that the non-PTS system exhibited an apparent Ks of 125 microM for glucose and a Vmax of 0.87 nmol mg (dry weight) of cells-1 min-1. Sugar competition experiments with DC10 indicated that the non-PTS transport system had high specificity for glucose since glucose transport was not significantly by a 100-fold molar excess of several competing sugar substrates, including 2-deoxyglucose and alpha-methylglucoside. These results demonstrate that S. mutans possesses a glucose transport system that can function independently of the PEP PTS.     

Binding of Cu2+ to S-adenosyl-L-homocysteine hydrolase

S-Adenosylhomocysteine (AdoHcy) hydrolase regulates biomethylation and homocysteine metabolism. It has been proposed to be a copper binding protein playing an important role in copper transport and distribution. In the present work, the kinetics of binding and releasing of copper ions was studied using fluorescence method. The dissociation constant for copper ions with AdoHcy hydrolase was determined by fluorescence quenching titration and activity titration methods using ethylenediaminetetraacetic acid (EDTA), nitrilotriacetic acid (NTA), and glycine as competitive chelators. The experimental results showed that copper ions bind to AdoHcy hydrolase with a K(d) of approximately 10(-11) M. The association rate constant was determined to be 7 x 10(6) M(-1)s(-1). The releasing of copper ions from the enzyme was found to be biphasic with a k(1) of 2.8 x 10(-3) s(-1) and k(2) of 1.7x10(-5) s(-1). It is suggested that copper ions do not bind to the substrate binding sites because the addition of adenine substrate did not compete with the binding of copper to AdoHcy hydrolase. Interestingly, it was observed that EDTA could bind to AdoHcy hydrolase with a dissociation constant of K(1) = 8.0 x 10(-5) M and result in an increased affinity (K(d) = approximately 10(-17) M) of binding of copper ions to the enzyme.     

Characterization of SafC, a catechol 4-O-methyltransferase involved in saframycin biosynthesis

Members of the saframycin/safracin/ecteinascidin family of peptide natural products are potent antitumor agents currently under clinical development. Saframycin MX1, from Myxococcus xanthus, is synthesized by a nonribosomal peptide synthetase, SafAB, and an O-methyltransferase, SafC, although other proteins are likely involved in the pathway. SafC was overexpressed in Escherichia coli, purified to homogeneity, and assayed for its ability to methylate a variety of substrates. SafC was able to catalyze the O-methylation of catechol derivatives but not phenols. Among the substrates tested, the best substrate for SafC was L-dihydroxyphenylalanine (L-dopa), which was methylated specifically in the 4'-O position (k(cat)/K(m) = 5.5 x 10(3) M(-1) s(-1)). SafC displayed less activity on other catechol derivatives, including catechol, dopamine, and caffeic acid. The more labile l-5'-methyldopa was an extremely poor substrate for SafC (k(cat)/K(m) = approximately 2.8 x 10(-5) M(-1) s(-1)). L-dopa thioester derivatives were also much less reactive than L-dopa. These results indicate that SafC-catalyzed 4'-O-methylation of L-dopa occurs prior to 5'-C-methylation, suggesting that 4'-O-methylation is likely the first committed step in the biosynthesis of saframycin MX1. SafC has biotechnological potential as a methyltransferase with unique regioselectivity.