Glucose and Gluconate Metabolism in an Escherichia coli Mutant Lacking Phosphoglucose Isomerase

A single gene mutant lacking phosphoglucose isomerase (pgi) was selected after ethyl methane sulfonate mutagenesis of Escherichia coli strain K-10. Enzyme assays revealed no pgi activity in the mutant, whereas levels of glucokinase, glucose-6-phosphate dehydrogenase, and gluconate-6-phosphate dehydrogenase were similar in parent and mutant. The amount of glucose released by acid hydrolysis of the mutant cells after growth on gluconate was less than 2% that released from parent cells; when grown in the presence of glucose, mutant and parent cells contained the same amount of glucose residues. The mutant grew on glucose one-third as fast as the parent; it also grew much slower than the parent on galactose, maltose, and lactose. On fructose, gluconate, and other carbon sources, growth was almost normal. In both parent and mutant, gluconokinase and gluconate-6-phosphate dehydrase were present during growth on gluconate but not during growth on glucose. Assay and degradation of alanine from protein hydrolysates after growth on glucose-1-(14)C and gluconate-1-(14)C showed that in the parent strain glucose was metabolized by the glycolytic path and the hexose monophosphate shunt. Gluconate was metabolized by the Entner-Doudoroff path and the hexose monophosphate shunt. The mutant used glucose chiefly by the shunt, but may also have used the Entner-Doudoroff path to a limited extent.     

Genetic definition of the substrate selectivity of outer membrane porin protein OprD of Pseudomonas aeruginosa.

Earlier studies proved that Pseudomonas aeruginosa OprD is a specific porin for basic amino acids and imipenem. It was also considered to function as a nonspecific porin that allowed the size-dependent uptake of monosaccharides and facilitation of the uptake of quinolone and other antibiotics. In the present study, we utilized P. aeruginosa strains with genetically defined levels of OprD to characterize the in vivo substrate selectivity of this porin. An oprD::omega interposon mutant was constructed by gene replacement utilizing an in vitro mutagenized cloned oprD gene. In addition, OprD was overexpressed from the lac promoter by cloning the oprD gene into the broad-host-range plasmid pUCP19. To test the substrate selectivity, strains were grown in minimal medium with limiting concentrations of the carbon sources glucose, gluconate, or pyruvate. In minimal medium with 0.5 mM gluconate, the growth rates of the parent strain H103 and its oprD::omega mutant H729 were only 60 and 20%, respectively, of that of the OprD-overexpressing strain H103(pXH2). In contrast, no significant differences were observed in the growth rates of these three strains on glucose or pyruvate, indicating that OprD selectively facilitated the transport of gluconate. To determine the role of OprD in antibiotic uptake, nine strains representing different levels of OprD and OprF were used to determine the MICs of different antibiotics. The results clearly demonstrated that OprD could be utilized by imipenem and meropenem but that, even when substantially overexpressed, it could not be significantly utilized by other beta-lactams, quinolones, or aminoglycosides. In addition, competition experiments confirmed that imipenem had common binding sites with basic amino acids in the OprD channel, but not with gluconate or glucose.     

Carbon allocation in wild-type and Glc+ Rhodobacter sphaeroides under photoheterotrophic conditions.

The photosynthetic bacterium Rhodobacter sphaeroides is capable of producing H2 via nitrogenase when grown photoheterotrophically in the absence of N2. By using 14C-labeled malate, it was found that greater than 95% of this substrate was catabolized completely to CO2 during H2 production. About 60% of this catabolism was associated with H2 biosynthesis, while almost 40% provided reductant for other cellular purposes. Thus, only a small fraction of malate provided carbon skeletons. The addition of ammonium, which inhibited nitrogenase activity, increased substrate conversion into carbon skeletons threefold. Catabolism of malate occurred primarily via the tricarboxylic acid cycle, but gluconeogenesis was also observed. The wild-type organism grew poorly on glucose, accumulated gluconate and 2-keto-3-deoxygluconate, and did not produce H2. More than 50% of metabolized glucose appeared in carbon skeletons or in storage compounds. A glucose-utilizing mutant was five times more effective in utilizing this substrate. This mutant produced H2 from glucose, using 74% of metabolized substrate for this purpose. Glucose converted to storage products or to other carbon skeletons was reduced to 8%. Fixation of CO2 competed directly with H2 production for reducing equivalents and ATP. Refixation of CO2 released from these substrates under H2-producing conditions was, at most, 10 to 12%. Addition of ammonium increased refixation of respired CO2 to 83%. Patterns of carbon flow of fixation products were associated with the particular strains and culture conditions.     

Carbon allocation in wild-type and Glc+ Rhodobacter sphaeroides under photoheterotrophic conditions

The photosynthetic bacterium Rhodobacter sphaeroides is capable of producing H2 via nitrogenase when grown photoheterotrophically in the absence of N2. By using 14C-labeled malate, it was found that greater than 95% of this substrate was catabolized completely to CO2 during H2 production. About 60% of this catabolism was associated with H2 biosynthesis, while almost 40% provided reductant for other cellular purposes. Thus, only a small fraction of malate provided carbon skeletons. The addition of ammonium, which inhibited nitrogenase activity, increased substrate conversion into carbon skeletons threefold. Catabolism of malate occurred primarily via the tricarboxylic acid cycle, but gluconeogenesis was also observed. The wild-type organism grew poorly on glucose, accumulated gluconate and 2-keto-3-deoxygluconate, and did not produce H2. More than 50% of metabolized glucose appeared in carbon skeletons or in storage compounds. A glucose-utilizing mutant was five times more effective in utilizing this substrate. This mutant produced H2 from glucose, using 74% of metabolized substrate for this purpose. Glucose converted to storage products or to other carbon skeletons was reduced to 8%. Fixation of CO2 competed directly with H2 production for reducing equivalents and ATP. Refixation of CO2 released from these substrates under H2-producing conditions was, at most, 10 to 12%. Addition of ammonium increased refixation of respired CO2 to 83%. Patterns of carbon flow of fixation products were associated with the particular strains and culture conditions.     

Pyruvate Carboxylase Deficiency in Pleiotropic Carbohydrate-Negative Mutant Strains of Pseudomonas aeruginosa

Cell extracts of Pseudomonas aeruginosa strain PAO were found to contain pyruvate carboxylase activity. Specific activities were minimal when cells were grown on Casamino Acids, acetate, or succinate, but were three- to fourfold higher when cells were grown in glucose, gluconate, glycerol, lactate, or pyruvate minimal media. The reaction in crude cell extracts and in partially purified preparations was dependent on pyruvate, adenosine 5'-triphosphate, and Mg(2+), but was not affected by either the presence or absence of acetyl coenzyme A. Activity was nearly totally inhibited by avidin and this inhibition was substantially blocked by free biotin in incubation mixtures. Cell extracts were shown to fix (14)CO(2) in a reaction that had these same characteristics. Eight pleiotropic, carbohydrate-negative mutant strains of the organism were isolated after nitrosoguanidine mutagenesis. Each mutant strain grew normally in acetate, succinate, and citrate minimal media but failed to utilize glucose, gluconate, 2-ketogluconate, mannitol, glycerol, lactate, and pyruvate as sole sources of carbon and energy. These strains were found by quantitative transductional analysis with phage F116 to form a single linkage group. Cell extracts of each mutant strain were either lacking or severely deficient in pyruvate carboxylase activity. Spontaneous revertants of five of the eight strains were isolated and found to recover simultaneously both pyruvate carboxylase activity and the ability to utilize each of the C(6) and C(3) compounds. A second linkage group of similar mutant strains that grew on the C(3) compounds was found to contain normal levels of pyruvate carboxylase activity, but each strain was deficient in an enzyme of the Entner-Doudoroff pathway.     

Transport of gluconate in Rhodotorula glutinis. Inactivation by glucose of the uptake system.

Transport of gluconate has been studied in a wild-type strain of Rhodotorula glutinis and in a mutant derived from it which has acquired the ability to grow on gluconate as the only carbon and energy source. The transport is energy dependent. It shows the same K_m for gluconate (0.1 mm) between pH 4.7 and 7, which suggests that the negatively charged gluconate is the true substrate for the transport system. The rate of gluconate uptake is much lower in the wild type than in the mutant. The mutant grown on gluconate transports gluconate much faster than if grown on other carbon sources. Glucose rapidly and irreversibly inactivates the transport system. This inactivation can also be effected by δ-gluconolactone and to a lesser extent by acetate; it is not prevented by gluconate and occurs also in the presence of cycloheximide.     

Gluconate metabolism in germinated spores of Bacillus megaterium QM B1551: primary roles of gluconokinase and the pentose cycle

The metabolic pathway of gluconate, a major product of glucose metabolism during spore germination, was investigated in Bacillus megaterium QM B1551. Compared to the parent, mutant spores lacking gluconokinase could not metabolize gluconate, whereas the revertant simultaneously restored the enzyme activity and the ability to metabolize it, indicating that gluconokinase was solely responsible for the onset of gluconate metabolism. To identify a further metabolic route for gluconate, we determined 14C yields in acetate and CO2 formed from [14C]gluconate, and found that experimental ratios of 14CO2/[14C]acetate obtained from [2-14C]gluconate and [3,4-14C]gluconate were not compatible with the ratios predicted from the Entner-Doudoroff pathway. In contrast, when CO2 release caused by recycling (approx. 30%) was corrected, the ratios almost agreed with those from the pentose cycle. Comparison of specific radioactivities in acetate also supported the conclusion that gluconate was metabolized via the pentose cycle, subsequently metabolized via the Embden-Meyerhof pathway, and finally degraded to acetate and CO2 without a contribution by the Krebs cycle.     

Transport of glucose, gluconate, and methyl alpha-D-glucoside by Pseudomonas aeruginosa

Glucose transport by Pseudomonas aeruginosa was studied. These studies were enhanced by the use of a mutant, strain PAO 57, which was unable to grow on glucose but which formed the inducible glucose transport system when grown in media containing glucose or other inducers such as 2-deoxy-d-glucose. Both PAO 57 and parental strain PAO transported glucose with an apparent K(m) of 7 muM. Free glucose was concentrated intracellularly by P. aeruginosa PAO 57 over 200-fold above the external level. These data constitute direct evidence that glucose is transported via active transport by P. aeruginosa. Various experimental data clearly indicated that P. aeruginosa PAO transported methyl alpha-d-glucose (alpha-MeGlc) via the glucose transport system. The apparent K(m) of alpha-MeGlc transport was 7 mM which indicated a 1,000-fold lower affinity of the glucose transport system for alpha-MeGlc than for glucose. While only unchanged alpha-MeGlc was detected intracellularly in P. aeruginosa, alpha-MeGlc was actually concentrated intracellularly less than 2-fold over the external level. Membrane vesicles of P. aeruginosa PAO retained transport activity for gluconate. This solute was concentrated intravesicularly several-fold over the external level. A component of the glucose transport system is believed to have been lost during vesicle preparation since glucose per se was not transported. Instead; glucose was converted to gluconate by membrane-associated glucose dehydrogenase and gluconate was then transported into the vesicles. Although this may constitute an alternate system for glucose transport, it is not a necessary prerequisite for glucose transport by intact cells since P. aeruginosa PAO 57, which lacks glucose dehydrogenase, was able to transport glucose at a rate equal to the parental strain.     

Reductive pentose phosphate-independent CO2 fixation in Rhodobacter sphaeroides and evidence that ribulose bisphosphate carboxylase/oxygenase activity serves to maintain the redox balance of the cell.

Whole-cell CO2 fixation and ribulose 1,5-bisphosphate carboxylase/oxygenase (RubisCO) activity were determined in Rhodobacter sphaeroides wild-type and mutant strains. There is no obvious difference in the levels of whole-cell CO2 fixation for the wild type, a form I RubisCO deletion mutant, and a form II RubisCO deletion mutant. No ribulose 1,5-bisphosphate-dependent CO2 fixation was detected in a form I-form II RubisCO double-deletion mutant (strain 16) or strain 16PHC, a derivative from strain 16 which was selected for the ability to grow photoheterotrophically with CO2 as an electron acceptor. However, significant levels of whole-cell CO2 fixation were detected in both strains 16 and 16PHC. Strain 16PHC exhibited CO2 fixation rates significantly higher than those of strain 16; the rates found for strain 16PHC were 30% of the level found in photoheterotrophically grown wild-type strain HR containing both form I and form II RubisCO and 10% of the level of the wild-type strain grown photolithoautotrophically. Strain 16PHC could not grow photolithoautotrophically in a CO2-H2 atmosphere; however, CO2 fixation catalyzed by photoheterotrophically grown strain 16PHC was repressed by addition of the alternate electron acceptor dimethyl sulfoxide. Dimethyl sulfoxide addition also influenced RubisCO activity under photolithoautotrophic conditions; 40 to 70% of the RubisCO activity was reduced without significantly influencing growth. Strain 16PHC and strain 16 contain nearly equivalent but low levels of pyruvate carboxylase, indicating that CO2 fixation enzymes other than pyruvate carboxylase contribute to the ability of strain 16PHC to grow with CO2 as an electron acceptor.     

生物氧化 CO2释放与氧化磷酸化生成 ATP 的相关性

通过解析葡萄糖有氧氧化过程中有机酸脱羧生成CO2的全部O原子来源,以及呼吸链一氧化磷酸化生成ATP的葡萄糖以外H原子的来源,明晰了葡萄糖有氧氧化过程中直接或者间接加H2O的特殊意义：H2O的H原子进入呼吸链一氧化磷酸化释放能量生成ATP;O原子结合到中间产物的C原子上形成羧基一COOH,以有机酸脱酸形式生成CO2释放出来。     

Monitoring flux through the oxidative pentose phosphate pathway using [1-14C]gluconate

The aim of this work was to examine the metabolism of exogenous gluconate by a 4-day-old cell suspension culture of Arabidopsis thaliana (L.) Heynh. Release of (14)CO(2) from [1-(14)C]gluconate was dependent on the concentration in the medium and could be resolved into a substrate-saturable component (apparent K(m) of approximately 0.4 mM) and an unsaturable component. At an external concentration of 0.3 mM, the rate of decarboxylation of applied gluconate was 0.2% of the rate of oxygen consumption by the cells. There was no effect of 0.3 mM gluconate on the rate of oxygen consumption, or on the rate of (14)CO(2) release from either [1-(14)C]glucose or [6-(14)C]glucose by the culture. The following observations argue that gluconate taken up by the cells is metabolised by direct phosphorylation to 6-phosphogluconate and subsequent decarboxylation through 6-phosphogluconate dehydrogenase. First, more than 95% of the label released from [1-(14)C]gluconate during metabolism by the cell culture was recovered as (14)CO(2). Secondly, inhibition of the oxidative pentose phosphate pathway (OPPP) by treatment with 6-aminonicotinamide preferentially inhibited release of (14)CO(2) from [1-(14)C]gluconate relative to that from [1-(14)C]glucose. Thirdly, perturbation of glucose metabolism by glucosamine did not affect (14)CO(2) from [1-(14)C]gluconate. Fourth, stimulation of the OPPP by phenazine methosulphate stimulated release of (14)CO(2) from [1-(14)C]gluconate to a far greater extent than that from [1-(14)C]glucose. It is proposed that measurement of (14)CO(2) from [1-(14)C]gluconate provides a simple and sensitive technique for monitoring flux through the OPPP pathway in plants.     

Loss of protein kinase-catalyzed phosphorylation of HPr, a phosphocarrier protein of the phosphotransferase system, by mutation of the ptsH gene confers catabolite repression resistance to several catabolic genes of Bacillus subtilis.

In gram-positive bacteria, HPr, a phosphocarrier protein of the phosphoenolpyruvate:sugar phosphotransferase system (PTS), is phosphorylated by an ATP-dependent, metabolite-activated protein kinase on seryl residue 46. In a Bacillus subtilis mutant strain in which Ser-46 of HPr was replaced with a nonphosphorylatable alanyl residue (ptsH1 mutation), synthesis of gluconate kinase, glucitol dehydrogenase, mannitol-1-P dehydrogenase and the mannitol-specific PTS permease was completely relieved from repression by glucose, fructose, or mannitol, whereas synthesis of inositol dehydrogenase was partially relieved from catabolite repression and synthesis of alpha-glucosidase and glycerol kinase was still subject to catabolite repression. When the S46A mutation in HPr was reverted to give S46 wild-type HPr, expression of gluconate kinase and glucitol dehydrogenase regained full sensitivity to repression by PTS sugars. These results suggest that phosphorylation of HPr at Ser-46 is directly or indirectly involved in catabolite repression. A strain deleted for the ptsGHI genes was transformed with plasmids expressing either the wild-type ptsH gene or various S46 mutant ptsH genes (S46A or S46D). Expression of the gene encoding S46D HPr, having a structure similar to that of P-ser-HPr according to nuclear magnetic resonance data, caused significant reduction of gluconate kinase activity, whereas expression of the genes encoding wild-type or S46A HPr had no effect on this enzyme activity. When the promoterless lacZ gene was put under the control of the gnt promoter and was subsequently incorporated into the amyE gene on the B. subtilis chromosome, expression of beta-galactosidase was inducible by gluconate and repressed by glucose. However, we observed no repression of beta-galactosidase activity in a strain carrying the ptsH1 mutation. Additionally, we investigated a ccpA mutant strain and observed that all of the enzymes which we found to be relieved from carbon catabolite repression in the ptsH1 mutant strain were also insensitive to catabolite repression in the ccpA mutant. Enzymes that were repressed in the ptsH1 mutant were also repressed in the ccpA mutant.     

Participation of the Entner-Doudoroff pathway in Escherichia coli strains with an inactive phosphotransferase system (PTS- Glc+) in gluconate and glucose batch cultures

The activity of the enzymes of the central metabolic pathways has been the subject of intensive analysis; however, the Entner-Doudoroff (ED) pathway has only recently begun to attract attention. The metabolic response to edd gene knockout in Escherichia coli JM101 and PTS- Glc+ was investigated in gluconate and glucose batch cultures and compared with other pyruvate kinase and PTS mutants previously constructed. Even though the specific growth rates between the strain carrying the edd gene knockout and its parent JM101 and PTS- Glc+ edd and its parent PTS- Glc+ were very similar, reproducible changes in the specific consumption rates and biomass yields were obtained when grown on glucose. These results support the participation of the ED pathway not only on gluconate metabolism but on other metabolic and biochemical processes in E. coli. Despite that gluconate is a non-PTS carbohydrate, the PTS- Glc+ and derived strains showed important reductions in the specific growth and gluconate consumption rates. Moreover, the overall activity of the ED pathway on gluconate resulted in important increments in PTS- Glc+ and PTS- Glc+ pykF mutants. Additional results obtained with the pykA pykF mutant indicate the important contribution of the pyruvate kinase enzymes to pyruvate synthesis and energy production in both carbon sources.     

Utilization of gluconate by Escherichia coli. Induction of gluconate kinase and 6-phosphogluconate dehydratase activities

1. A mutant of Escherichia coli, devoid of phosphopyruvate synthetase, glucosephosphate isomerase and 6-phosphogluconate dehydrogenase activities, grew readily on gluconate and inducibly formed an uptake system for gluconate, gluconate kinase and 6-phosphogluconate dehydratase while doing so. 2. This mutant also grew on glucose 6-phosphate and inducibly formed 6-phosphogluconate dehydratase; however, the formation of the gluconate uptake system and gluconate kinase was not induced under these conditions. 3. The use of the Entner–Doudoroff pathway for the dissimilation of 6-phosphogluconate, derived from either gluconate or glucose 6-phosphate, by this mutant was also demonstrated by the accumulation of 2-keto-3-deoxy-6-phosphogluconate (3-deoxy-6-phospho-l-glycero-2-hexulosonate) from both these substrates in a similar mutant that also lacked phospho-2-keto-3-deoxygluconate aldolase activity. 4. Glucose 6-phosphate inhibits the continued utilization of fructose by cultures of the mutants growing on fructose, as it does in wild-type E. coli. 5. The mutants do not use glucose for growth. This is shown to be due to insufficiency of phosphopyruvate, which is required for glucose uptake.     

Rhizobium japonicum mutant strains unable to grow chemoautotrophically with H2

Rhizobium japonicum strain SR grows chemoautotrophically on a mineral salts medium when incubated in an H2- and CO2-containing atmosphere. Mutant strains unable to grow or that grow very poorly chemoautotrophically with H2 have been isolated from strain SR. The mutant isolation procedure involved mutagenesis with ethyl methane sulfonate, penicillin selection under chemoautotrophic growth conditions, and plating of the survivors onto medium containing carbon. The resulting colonies were replica plated onto medium that did not contain carbon, and the plates were incubated in an H2- and CO2-containing atmosphere. Mutant strains unable to grow under these conditions were chosen. Over 100 mutant strains with defects in chemoautotrophic metabolism were obtained. The phenotypes of the mutants fall into various classes. These include strains unable to oxidize H2 and strains deficient in CO2 uptake. Some of the mutant strains were capable of oxidizing H2 only when artificial electron acceptors were provided. Two mutant strains specifically lack activity of the key CO2-fixing enzyme ribulose 1,5-bisphosphate carboxylase. Other mutant strains lack both H2-oxidizing ability and ribulose 1,5-bisphosphate carboxylase activity.     

Role of the pentose phosphate pathway and the Entner–Doudoroff pathway in glucose metabolism of Gluconobacter oxydans 621H

Glucose catabolism by the obligatory aerobic acetic acid bacterium Gluconobacter oxydans 621H proceeds in two phases comprising rapid periplasmic oxidation of glucose to gluconate (phase I) and oxidation of gluconate to 2-ketogluconate or 5-ketogluconate (phase II). Only a small amount of glucose and part of the gluconate is taken up into the cells. To determine the roles of the pentose phosphate pathway (PPP) and the Entner–Doudoroff pathway (EDP) for intracellular glucose and gluconate catabolism, mutants defective in either the PPP (Δgnd, Δgnd zwf*) or the EDP (Δedd–eda) were characterized under defined conditions of pH 6 and 15 % dissolved oxygen. In the presence of yeast extract, neither of the two pathways was essential for growth with glucose. However, the PPP mutants showed a reduced growth rate in phase I and completely lacked growth in phase II. In contrast, the EDP mutant showed the same growth behavior as the reference strain. These results demonstrate that the PPP is of major importance for cytoplasmic glucose and gluconate catabolism, whereas the EDP is dispensable. Reasons for this difference are discussed.     

Bacterial strains from human feces that reduce CO2 to acetic acid.

We used dilutions of fecal suspensions from a human volunteer to enrich cultures for bacteria that reduce CO2 to acetate in the colon. The soluble enrichment substrates used were glucose, methanol, formate, and vanillate, which were used with a gas phase that contained 80% N2 and 20% CO2. The gaseous enrichment substrates used were 80% H2-20% CO2 and 50% CO-50% CO2. We isolated three different strains that produced acetate from CO2. One strain produced acetate from methanol, vanillate, H2-CO2, glucose, and other sugars. The other two strains did not form acetate from methanol or vanillate. Both of the latter strains formed acetate from glucose and other sugars, but only one of these strains formed acetate from H2-CO2. Both of these strains cometabolized formate. However, none of the enrichment cultures or pure cultures used CO or formate as a substrate for growth. The two strains that produced acetate from H2 and CO2 grew slowly when the gases alone were used as substrates, but they rapidly cometabolized H2 and CO2 when they were grown with organic substrates. The ability of all of the strains to produce acetate from CO2 and/or other one-carbon precursors was verified by determining the radioactivity of the methyl and carboxyl groups of the acetate formed after growth with 14CO2 or other radioactively labeled one-carbon precursors.     

Utilization of gluconate by Escherichia coli. Uptake of d-gluconate by a mutant impaired in gluconate kinase activity and by membrane vesicles derived therefrom

1. From Escherichia coli strain K2.1.5(c).8.9, which is devoid of 6-phosphogluconate dehydrogenase (gnd) and 6-phosphogluconate dehydratase (edd) activities, a mutant R6 was isolated that was tolerant to gluconate though still edd(-), gnd(-). 2. Measurements of the fate of labelled gluconate, of the conversion of gluconate into 6-phosphogluconate, and of the induction of gluconate kinase by the two organisms show that, although both inducibly form a gluconate-transport system, strain R6 is impaired in its ability to convert the gluconate thus taken up into 6-phosphogluconate; it was therefore used for study of the kinetics and energetics of gluconate uptake. 3. Suspensions of strain R6 induced for gluconate uptake took up this substrate via a ;high affinity' transport process, with K(m) about 10mum and V(max.) about 25nmol/min per mg dry mass; a ;low affinity' system demonstrated to occur in certain E. coli mutants was not induced under the conditions used in this work. 4. The uptake of gluconate was inhibited by lack of oxygen and by inhibitors of electron transport; such inhibitors also promoted the efflux of gluconate taken up. 5. Membrane vesicles prepared from strain R6 also manifested these properties when incubated with suitable electron donors, at rates similar to those observed with whole cells. 6. The results indicate that the active transport of gluconate into the cells is the rate-limiting step in gluconate utilization by E. coli, and that the mechanism of this process can be validly studied with membrane vesicles.     

Regulation of hexose phosphate metabolism in Acetobacter xylinum

The metabolism of glucose and fructose was studied in resting succinate-grown cells of Acetobacter xylinum. From fructose only cellulose and CO(2) were formed by the cells, whereas from glucose, gluconate was formed much more rapidly than these two products. The molar ratio of sugar converted into cellulose to sugar converted into CO(2) was significantly greater than unity for both hexoses. The pattern of label retention in the cellulose formed by the cells from specifically (14)C-labelled glucose, fructose or gluconate corresponded to that of hexose phosphate in a pentose cycle. On the other hand, the isotopic configuration of cellulose arising from variously singly (14)C-labelled pyruvate did not agree with the operation of a pentose cycle on gluconeogenic hexose phosphate. Readily oxidizable tricarboxylic acid-cycle intermediates such as acetate, pyruvate or succinate promoted cellulose synthesis from fructose and gluconate although retarding their oxidation to CO(2). The incorporation into cellulose of C-1 of fructose was greatly increased in the presence of these non-sugar substrates, although its oxidation to CO(2) was greatly diminished. It is suggested that the flow of hexose phosphate carbon towards cellulose or through the pentose cycle in A. xylinum is regulated by an energy-linked control mechanism.     

Alginic acid synthesis in Pseudomonas aeruginosa mutants defective in carbohydrate metabolism.

Mutant cells of mucoid Pseudomonas aeruginosa isolated from cystic fibrosis patients were examined for their ability to synthesize alginic acid in resting cell suspensions. Unlike the wild-type strain which synthesizes alginic acid from glycerol, fructose, mannitol, glucose, gluconate, glutamate, or succinate, mutants lacking specific enzymes of carbohydrate metabolism are uniquely impaired. A phosphoglucose isomerase mutant did not synthesize the polysaccharide from mannitol, nor did a glucose 6-phosphate dehydrogenase mutant synthesize the polysaccharide from mannitol or glucose. Mutants lacking the Entner-Doudoroff pathway dehydrase or aldolase failed to produce alginate from mannitol, glucose, or gluconate, as a 3-phosphoglycerate kinase or glyceraldehyde 3-phosphate dehydrogenase mutant failed to produce from glutamate or succinate. These results demonstrate the primary role of the Entner-Doudoroff pathway enzymes in the synthesis of alginate from glucose, mannitol, or gluconate and the role of glyceraldehyde 3-phosphate dehydrogenase reaction for the synthesis from gluconeogenic precursors such as glutamate. The virtual absence of any activity of phosphomannose isomerase in cell extracts of several independent mucoid bacteria and the impairment of alginate synthesis from mannitol in mutants lacking phosphoglucose isomerase or glucose 6-phosphate dehydrogenase rule out free mannose 6-phosphate as an intermediate in alginate biosynthesis.