Mannitol metabolism in the phytopathogenic fungus Alternaria alternata

Mannitol metabolism in fungi is thought to occur through a mannitol cycle first described in 1978. In this cycle, mannitol 1-phosphate 5-dehydrogenase (EC 1.1.1.17) was proposed to reduce fructose 6-phosphate into mannitol 1-phosphate, followed by dephosphorylation by a mannitol 1-phosphatase (EC 3.1.3.22) resulting in inorganic phosphate and mannitol. Mannitol would be converted back to fructose by the enzyme mannitol dehydrogenase (EC 1.1.1.138). Although mannitol 1-phosphate 5-dehydrogenase was proposed as the major biosynthetic enzyme and mannitol dehydrogenase as a degradative enzyme, both enzymes catalyze their respective reverse reactions. To date the cycle has not been confirmed through genetic analysis. We conducted enzyme assays that confirmed the presence of these enzymes in a tobacco isolate of Alternaria alternata. Using a degenerate primer strategy, we isolated the genes encoding the enzymes and used targeted gene disruption to create mutants deficient in mannitol 1-phosphate 5-dehydrogenase, mannitol dehydrogenase, or both. PCR analysis confirmed gene disruption in the mutants, and enzyme assays demonstrated a lack of enzymatic activity for each enzyme. GC-MS experiments showed that a mutant deficient in both enzymes did not produce mannitol. Mutants deficient in mannitol 1-phosphate 5-dehydrogenase or mannitol dehydrogenase alone produced 11.5 and 65.7 %, respectively, of wild type levels. All mutants grew on mannitol as a sole carbon source, however, the double mutant and mutant deficient in mannitol 1-phosphate 5-dehydrogenase grew poorly. Our data demonstrate that mannitol 1-phosphate 5-dehydrogenase and mannitol dehydrogenase are essential enzymes in mannitol metabolism in A. alternata, but do not support mannitol metabolism operating as a cycle.     

Conversion of glucose-1-phosphate to 3-keto-glucose-1-phosphate by cells of Agrobacterium tumefaciens

Incubation of resting cells of Agrobacterium tumefaciens with glucose-1-phosphate resulted in the accumulation of a new sugar phosphate in the suspending medium. Approximately 80% of the glucose-1-phosphate consumed was converted to the new compound, which was identified as alpha-d-ribo-hexopyranosyl-3-ulose-1-phosphate (3-ketoglucose-1-phosphate). Both utilization of glucose-1-phosphate and accumulation of 3-ketoglucose-1-phosphate were inhibited by 2,4-dinitrophenol, polymyxin, and d-glucose, which are inhibitors of the glucoside transport system of this bacterium but are not inhibitors of d-glucoside-3-dehydrogenase, which is the 3-ketoglucose-1-phosphate-forming enzyme. Consequently, it was concluded that glucose-1-phosphate penetrates into intracellular space by means of an active transport system. The glucose-1-phosphate is converted to 3-ketoglucose-1-phosphate by d-glucoside-3-dehydrogenase, and the 3-ketoglucose-1-phosphate formed reaches the extracellular space by passing through the surface layer of the bacterium.     

Did Archaeal and Bacterial Cells Arise Independently from Noncellular Precursors? A Hypothesis Stating That the Advent of Membrane Phospholipid with Enantiomeric Glycerophosphate Backbones Caused the Separation of the Two Lines of Descent

One of the most remarkable biochemical differences between the members of two domains Archaea and Bacteria is the stereochemistry of the glycerophosphate backbone of phospholipids, which are exclusively opposite. The enzyme responsible to the formation of Archaea-specific glycerophosphate was found to be NAD(P)-linked sn-glycerol-1-phosphate (G-1-P) dehydrogenase and it was first purified from Methanobacterium thermoautotrophicum cells and its gene was cloned. This structure gene named egsA (enantiomeric glycerophosphate synthase) consisted of 1,041 bp and coded the enzyme with 347 amino acid residues. The amino acid sequence deduced from the base sequence of the cloned gene (egsA) did not share any sequence similarity except for NAD-binding region with that of NAD(P)-linked sn-glycerol-3-phosphate (G-3-P) dehydrogenase of Escherichia coli which catalyzes the formation of G-3-P backbone of bacterial phospholipids, while the deduced protein sequence of the enzyme revealed some similarity with bacterial glycerol dehydrogenases. Because G-1-P dehydrogenase and G-3-P dehydrogenase would originate from different ancestor enzymes and it would be almost impossible to interchange stereospecificity of the enzymes, it seems likely that the stereostructure of membrane phospholipids of a cell must be maintained from the time of birth of the first cell. We propose here the hypothesis that Archaea and Bacteria were differentiated by the occurrence of cells enclosed by membranes of phospholipids with G-1-P and G-3-P as a backbone, respectively. Received: 24 March 1997 / Accepted: 21 May 1997     

Probing the mechanism of the Archaeoglobus fulgidus inositol-1-phosphate synthase

myo-Inositol-1-phosphate synthase (mIPS) catalyzes the conversion of glucose-6-phosphate (G-6-P) to inositol-1-phosphate. In the sulfate-reducing archaeon Archaeoglobus fulgidus it is a metal-dependent thermozyme that catalyzes the first step in the biosynthetic pathway of the unusual osmolyte di-myo-inositol-1,1'-phosphate. Several site-specific mutants of the archaeal mIPS were prepared and characterized to probe the details of the catalytic mechanism that was suggested by the recently solved crystal structure and by the comparison to the yeast mIPS. Six charged residues in the active site (Asp225, Lys274, Lys278, Lys306, Asp332, and Lys367) and two noncharged residues (Asn255 and Leu257) have been changed to alanine. The charged residues are located at the active site and were proposed to play binding and/or direct catalytic roles, whereas noncharged residues are likely to be involved in proper binding of the substrate. Kinetic studies showed that only N255A retains any measurable activity, whereas two other mutants, K306A and D332A, can carry out the initial oxidation of G-6-P and reduction of NAD+ to NADH. The rest of the mutant enzymes show major changes in binding of G-6-P (monitored by the 31P line width of inorganic phosphate when G-6-P is added in the presence of EDTA) or NAD+ (detected via changes in the protein intrinsic fluorescence). Characterization of these mutants provides new twists on the catalytic mechanism previously proposed for this enzyme.     

In vitro determined kinetic properties of mutant phosphoglucomutases and their effects on sugar catabolism in Escherichia coli

Based on primary amino acid sequence comparisons with other phosphoglucomutases, 12 conserved residues in the Acetobacter xylinum phosphoglucomutase (CelB) were substituted by site-directed mutagenesis, resulting in mutant enzymes with Kcat values [glucose-1-phosphate (G-1-P) to glucose-6-phosphate] ranging from 0 to 46% relative to that of the wild-type enzyme. In combination with a versatile set of plasmid expression vectors these proteins were used in a metabolic engineering study on sugar catabolism in Escherichia coli. Mutants of E. coli deficient in phosphoglucomutase synthesize intracellular amylose when grown on galactose, due to accumulation of G-1-P. Wild-type celB can complement this lesion, and we show here that the ability of the mutant enzymes to complement is sensitive to variations in their respective in vitro determined Kcat and Km G-1-P values. Reduced catalytic efficiencies could be compensated by increasing the CelB expression level, and in this way a mutant protein (substitution of Thr-45 to Ala) displaying a 7600-fold reduced catalytic efficiency could be used to eliminate the amylose accumulation. Complementation experiments with the homologous phosphoglucomutase indicated that a Km G-1-P value significantly below that of CelB is not critical for the in vivo conversion of the substrate.     

Enzyme kinetics in mammalian cells. 3. Regulation of activities of galactokinase, galactose-1-phosphate uridyl transferase and uridine diphosphogalactose-4-epimerase in human erythrocytes

The sequential enzyme assay as previously described has been used to study various effects on the three enzymes in human red cells involved in the phosphorylation of galactose: galactokinase, galactose-1-phosphate uridyl transferase and uridine diphospho-galactose-4-epimerase.

• 1 Enzyme activities in undiluted lysates appear to reflect the respective activities in whole cells.
• 2 Added extracellular Gal-1-P, G-1-P, UDPGal and UPDG do not affect enzyme activities in whole cells.
• 3 The kinase and transferase enzymes do not appear to be associated with the membrane fraction of the red cells.
• 4 Galactokinase activity is inhibited by G-6-P and Gal-1-P, but not by glucose, G-1-P, UDPG, UDPGal, UTP or NAD⁺. It is inhibited by ATP and ADP in high concentration.
• 5 Galactose-1-phosphate uridyl transferase activity is inhibited by G-1-P, G-6-P, UDPG, UDPGal, ATP, and ADP. It is not affected by UTP, NAD⁺, or galactose.
• 6 Uridine diphospho-galactose-4-epimerase activity is inhibited by UDPG, ATP, ADP, UTP and NADH. It is stimulated by NAD⁺ and possibly by Gal-1-P. It is unaffected by G-1-P, G-6-P.
• 7 The rates of the three reactions decrease with decreasing temperature. The activities of transferase and epimerase are inactivated at the same rate, the kinase activity is inactivated more slowly.
• 8 Dilution experiments indicate the presence in lysates of a pool of UDPG (or, possibly UDPGal) which regulates the activities transferase and the epimerase enzymes.
• 9 Results of dilution experiments suggest that the radioactive product of the transferase enzyme is different from commercially available UDPGal-u-¹⁴C.
• 10 ATP, UTP and UDPG interact with some substance(s) in the red cell lysate to cause a time dependent inactivation of the epimerase. These interactions are the result of glucose metabolism.

     

Receptor-mediated uptake of a mannose-6-phosphate bearing glycoprotein by isolated chicken osteoclasts

We have recently shown that degradation of bone collagen by osteoclasts occurs via proteolytic enzyme activity that depends on an acidic milieu. Since bone resorption occurs in an extracellular, acidic compartment located at the cell-matrix attachment site, the osteoclast must deliver the acid collagenolytic enzymes to the cell surface. These observations raise the possibility that the mannose-6-phosphate (M-6-P) receptor, known to sort acidic proteases in other cells, is involved in trafficking lysosomal enzymes to the plasmalemma of bone resorbing cells. To this end we studied receptor-mediated uptake, distribution and release, by isolated chicken osteoclasts, of 125I-hexosaminidase, a M-6-P bearing enzyme. We found that at 4 degrees C, the bone-resorbing polykaryons bind approximately 10,000 molecules of radioligand/cell with a Kd of 0.7 nM, which is endocytosed by osteoclasts at 37 degrees C by a calcium-independent process. Furthermore, 125I-hexosaminidase uptake is unaffected by mannosylated albumin, documenting specificity of the receptor-mediated event. Release of endocytosed enzyme from the cell is also much more rapid than its degradation, attesting to a pathway of uptake and secretion. By autoradiography, the M-6-P bearing ligand is concentrated at the site of osteoclast-bone attachment. Thus, osteoclasts also have the capacity to deliver M-6-P bearing degradative enzymes to their surface at the site of matrix degradation.     

The initial step of the glycerolipid pathway: identification of glycerol 3-phosphate/dihydroxyacetone phosphate dual substrate acyltransferases in Saccharomyces cerevisiae.

The initial step of phospholipid biosynthesis in yeast is carried out through the acylation of glycerol 3-phosphate (G-3-P) and dihydroxyacetone phosphate by stereospecific sn-1 acyltransferases. Here we report the identification of two key fatty acyltransferases of the glycerolipid biosynthesis pathway in Saccharomyces cerevisiae. Disruption of the open reading frame YBL011w, corresponding to a gene previously identified as a choline transporter suppressor (SCT1), resulted in a substantial decrease of total cellular G-3-P acyltransferase activity. A yeast strain disrupted at the open reading frame YKR067w, which encodes a protein closely related to Sct1p, also exhibited a dramatic reduction in G-3-P acyltransferase activity. Molecular characterizations of the genes revealed that a missense mutation in YKR067w accounted for a defect in the activities of the G-3-P acyltransferase in the yeast mutant strain TTA1. Heterologous expression of YKR067w in Escherichia coli further confirmed its enzyme activity. These results indicate that YKR067w and YBL011w, designated herein as GAT1 and GAT2(SCT1), respectively, are yeast G-3-P acyltransferase genes. Furthermore, biochemical results are presented to show that both Gat1p and Gat2p(Sct1p) are G-3-P/dihydroxyacetone phosphate dual substrate-specific sn-1 acyltransferases. The fatty acyl specificity of Gat1p is similar to that of the mammalian microsomal G-3-P acyltransferase, as it can effectively utilize a broad range of fatty acids as acyl donors. In contrast, Gat2p(Sct1p) displayed preference toward 16-carbon fatty acids. The most notable of the altered phospholipid compositions of the gat1Delta and gat2(sct1)Delta strains are a decreased phosphatidic acid pool and an increased phosphatidylserine/phosphatidylinositol ratio. This did not appear to affect the mutants as no growth defect was found. However, null mutations of both GAT1 and GAT2(SCT1) are synthetically lethal to yeast.     

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.     

Short-term hypothermia activates hepatic mitochondrial sn-glycerol-3-phosphate dehydrogenase and thermogenic systems

The contribution of the sn-glycerol-3-phosphate (G-3-P) shuttle in the control of energy metabolism is well established. It is also known that its activity may be modulated by hormones involved in thermogenesis, such as thyroid hormones or dehydroepiandrosterone and its metabolites, that act by inducing de novo synthesis of mitochondrial G-3-P dehydrogenase (mGPDH). However, little is known as to the factors that may influence the activity without enzyme induction. In the present study we investigated the possible role of the G-3-P shuttle in the thermogenic response to different hypothermic stresses. It was found that a decrease of body temperature causes the liver rapidly to enhance mGPDH activity and G-3-P-dependent respiration. The enhancement, which does not result from de novo synthesis of enzymes, has the potential of increasing heat production both by decreased ATP synthesis during the oxidation of G-3-P and by activation of the glycolytic pathway.     

Properties of a Tn5 insertion mutant defective in the structural gene (fruA) of the fructose-specific phosphotransferase system of Rhodobacter capsulatus and cloning of the fru regulon.

In photosynthetic bacteria such as members of the genera Rhodospirillum, Rhodopseudomonas, and Rhodobacter a single sugar, fructose, is transported by the phosphotransferase system-catalyzed group translocation mechanism. Previous studies indicated that syntheses of the three fructose catabolic enzymes, the integral membrane enzyme II, the peripheral membrane enzyme I, and the soluble fructose-1-phosphate kinase, are coordinately induced. To characterize the genetic apparatus encoding these enzymes, a Tn5 insertion mutation specifically resulting in a fructose-negative, glucose-positive phenotype was isolated in Rhodobacter capsulatus. The mutant was totally lacking in fructose fermentation, fructose uptake in vivo, phosphoenolpyruvate-dependent fructose phosphorylation in vitro, and fructose 1-phosphate-dependent fructose transphosphorylation in vitro. Extraction of the membrane fraction of wild-type cells with butanol and urea resulted in the preparation of active enzyme II free of contaminating enzyme I activity. This preparation was used to show that the activity of enzyme I was entirely membrane associated in the parent but largely soluble in the mutant, suggesting the presence of an enzyme I-enzyme II complex in the membranes of wild-type cells. The uninduced mutant exhibited measurable activities of both enzyme I and fructose-1-phosphate kinase, which were increased threefold when it was grown in the presence of fructose. Both activities were about 100-fold inducible in the parental strain. Although the Tn5 insertion mutation was polar on enzyme I expression, fructose-1-phosphate kinase activity was enhanced, relative to the parental strain. ATP-dependent fructokinase activity was low, but twofold inducible and comparable in the two strains. A second fru::Tn5 mutant and a chemically induced mutant selected on the basis of xylitol resistance showed pleiotropic loss of enzyme I, enzyme II, and fructose-1-phosphate kinase. These mutants were used to clone the fru regulon by complementing the negative phenotype with a wild-type cosmid bank.     

Regulatory Mutations of Inositol Biosynthesis in Yeast: Isolation of Inositol-Excreting Mutants

The enzyme inositol-1-phosphate synthase (I-1-P synthase), product of the INO1 locus, catalyzes the synthesis of inositol-1-phosphate from the substrate glucose-6-phosphate. The activity of this enzyme is dramatically repressed in the presence of inositol. By selecting for mutants which overproduce and excrete inositol, we have identified mutants constitutive for inositol-1-phosphate synthase as well as a mutation in phospholipid biosynthesis. Genetic analysis of the mutants indicates that at least three loci (designated OPI1, OPI2 and OPI4) direct inositol-mediated repression of I-1-P synthase. Mutants of these loci synthesize I-1-P synthase constitutively. Three loci are unlinked to each other and to INO1, the structural gene for the enzyme. A mutant of a fourth locus, OPI3, does not synthesize I-1-P synthase constitutively, despite its inositol excretion phenotype. This mutant is preliminarily identified as having a defect in phospholipid synthesis.     

Utilization of d-Ribitol by Lactobacillus casei BL23 Requires a Mannose-Type Phosphotransferase System and Three Catabolic Enzymes

Lactobacillus casei strains 64H and BL23, but not ATCC 334, are able to ferment d-ribitol (also called d-adonitol). However, a BL23-derived ptsI mutant lacking enzyme I of the phosphoenolpyruvate:carbohydrate phosphotransferase system (PTS) was not able to utilize this pentitol, suggesting that strain BL23 transports and phosphorylates d-ribitol via a PTS. We identified an 11-kb region in the genome sequence of L. casei strain BL23 (LCABL_29160 to LCABL_29270) which is absent from strain ATCC 334 and which contains the genes for a GlpR/IolR-like repressor, the four components of a mannose-type PTS, and six metabolic enzymes potentially involved in d-ribitol metabolism. Deletion of the gene encoding the EIIB component of the presumed ribitol PTS indeed prevented d-ribitol fermentation. In addition, we overexpressed the six catabolic genes, purified the encoded enzymes, and determined the activities of four of them. They encode a d-ribitol-5-phosphate (d-ribitol-5-P) 2-dehydrogenase, a d-ribulose-5-P 3-epimerase, a d-ribose-5-P isomerase, and a d-xylulose-5-P phosphoketolase. In the first catabolic step, the protein d-ribitol-5-P 2-dehydrogenase uses NAD⁺ to oxidize d-ribitol-5-P formed during PTS-catalyzed transport to d-ribulose-5-P, which, in turn, is converted to d-xylulose-5-P by the enzyme d-ribulose-5-P 3-epimerase. Finally, the resulting d-xylulose-5-P is split by d-xylulose-5-P phosphoketolase in an inorganic phosphate-requiring reaction into acetylphosphate and the glycolytic intermediate d-glyceraldehyde-3-P. The three remaining enzymes, one of which was identified as d-ribose-5-P-isomerase, probably catalyze an alternative ribitol degradation pathway, which might be functional in L. casei strain 64H but not in BL23, because one of the BL23 genes carries a frameshift mutation.     

Identification of a mitochondrial glycerol-3-phosphate dehydrogenase from Arabidopsis thaliana: evidence for a mitochondrial glycerol-3-phosphate shuttle in plants

We report molecular characterization of an Arabidopsis gene encoding a mitochondrial FAD-dependent glycerol-3-phosphate dehydrogenase (FAD-GPDH) that oxidizes glycerol-3-phosphate (G-3-P) to dihydroxyacetone phosphate. We demonstrate through in vitro targeting assays that the encoded gene product can be imported into mitochondrial membrane systems. Enzyme activity of the protein was confirmed through heterologous expression in Escherichia coli. The Arabidopsis gene is expressed throughout plant development, but at the highest level during seed germination. We also show that expression of the Arabidopsis FAD-GPDH gene is coupled to oxygen consumption and affected by ABA and stress conditions. Together with an NAD(+)-dependent GPDH, this enzyme could form a G-3-P shuttle, as previously established in other eukaryotic organisms, and links cytosolic G-3-P metabolism to carbon source utilization and energy metabolism in plants.     

Mutations of muscle glycogen synthase that disable activation by glucose 6-phosphate.

Glycogen synthase, an enzyme of historical importance in the field of reversible protein modification, is inactivated by phosphorylation and allosterically activated by glucose 6-phosphate (glucose-6-P). Previous analysis of yeast glycogen synthase had identified a conserved and highly basic 13-amino-acid segment in which mutation of Arg residues resulted in loss of activation by glucose-6-P. The equivalent mutations R578R579R581A (all three of the indicated Arg residues mutated to Ala) and R585R587R590A were introduced into rabbit muscle glycogen synthase. Whether expressed transiently in COS-1 cells or produced in and purified from Escherichia coli, both mutant enzymes were insensitive to activation by glucose-6-P. The effect of phosphorylation was studied in two ways. Purified, recombinant glycogen synthase was directly phosphorylated by casein kinase 2 and glycogen synthase kinase 3, under conditions that inactivate the wild-type enzyme. In addition, phosphorylation sites were converted to Ala by mutagenesis in wild-type and in the glucose-6-P desensitized mutants expressed in COS-1 cells. Phosphorylation inactivated the R578R579R581A mutant but had little effect on the R585R587R590A. This result was surprising since phosphorylation had the opposite effects on the corresponding yeast enzyme mutants. The results confirm that the region of glycogen synthase, Arg-578-Arg-590, is required for activation by glucose-6-P and suggest that it is part of a sensitive and critical switch involved in transitions between different conformational states. However, the role must differ subtly between the mammalian and the yeast enzymes.     

Substrate-Induced Stability of Glyceraldehyde 3-Phosphate Dehydrogenase from Mung Beans (Vigna radiata L.)

Time-dependent thermal inactivation of glyceraldehyde 3-phosphate dehydrogenase (GAPDH) present in the extract of mung beans at different periods of germination showed biphasic kinetics in the 12-h germinated seeds but single exponential decay at 24 h of germination. The glyceraldehyde 3-phosphate (G-3-P) concentration in the deproteinated extracts was found to increase with period of germination up to 36 h, parallel to that of GAPDH activity. G-3-P was found to offer protection of the enzyme against thermal inactivation and trypsin digestion. It is suggested that accumulation of G-3-P in germinating mung beans may be of physiological significance and it might offer protection to the enzyme in vivo against thermal inactivation and proteolysis.     

Differences in the metabolic responses of root tips of wheat and rye to aluminium stress

The effects of aluminium (Al) ions on the metabolism of root apical meristems were examined in 4-day-old seedlings of two cereals which differed in their tolerance to Al: wheat cv. Grana (Al-sensitive) and rye cv. Dakowskie Nowe (Al tolerant). During a 24 h incubation period in nutrient solutions containing 0.15 mM and 1.0 mM of Al for wheat and rye, respectively, the activity of first two enzymes in the pentose phosphate pathway (G-6-PDH and 6-PGDH) decreased in the sensitive cultivar. In the tolerant cultivar activities of these enzymes increased initially, then decreased slightly, and were at control levels after 24 h. In the Al-sensitive wheat cultivar a 50% reduction in the activity of 6-phosphogluconate dehydrogenase was observed in the presence of Al. Changes in enzyme activity were accompanied by changes in levels of G-6-P- the initial substrate in the pentose phosphate pathway. When wheat was exposed for 16 h to a nutrient solution containing aluminium, a 90% reduction in G-6-P concentration was observed. In the Al-tolerant rye cultivar, an increase and subsequently a slight decrease in G-6-P concentration was detected, and after 16 h of Al-stress the concentration of this substrate was still higher than in control plants. This dramatic Al-induced decrease in G-6-P concentration in the Al-sensitive wheat cultivar was associated with a decrease in both the concentration of glucose in the root tips as well as the activity of hexokinase, an enzyme which is responsible for phosphorylation of glucose to G-6-P. However, in the Al-tolerant rye cultivar, the activity of this enzyme remained at the level of control plants during Al-treatment, and the decrease in the concentration of glucose occurred at a much slower rate than in wheat. These results suggest that aluminium ions change cellular metabolism of both wheat and rye root tips. In the Al-sensitive wheat cultivar, irreversible disturbances induced by low doses of Al in the nutrient solution appear very quickly, whereas in the Al-tolerant rye cultivar, cellular metabolism, even under severe stress conditions, is maintained for a long time at a level which allows for root elongation to continue.Abbreviations G-6-PDH glucose-6-phosphate dehydrogenase - 6-PGDH 6-phosphogluconate dehydrogenase - G-6-P glucose-6-phosphate - TEA triethanolamine     

Regulation of glycolysis and level of the Crassulacean acid metabolism

Glycolysis shows different patterns of operation and different control steps, depending on whether the level of Crassulacean acid metabolism (CAM) is low or high in the leaves of Kalanchoe blossfeldiana v.Poelln., when subjected to appropriate photoperiodic treatments: at a low level of CAM operation all the enzymes of glycolysis and phosphoenol pyruvate (PEP) carboxylase present a 12 h rhythm of capacity, resulting from the superposition of two 24h rhythms out of phase; phosphofructokinase appears to be the main regulation step; attainment of high CAM level involves (1) an increase in the peak of capacity occurring during the night of all the glycolytic enzymes, thus achieving an over-all 24h rhythm, in strict allometric coherence with the increase in PEP carboxylase capacity, (2) the establishment of different phase relationships between the rhythms of enzyme capacity, and (3) the control of three enzymic steps (phosphofructokinase, the group 3-P-glyceraldehyde dehydrogenase — 3-P-glycerate kinase, and PEP carboxylase). Results show that the hypothesis of allosteric regulation of phosphofructokinase (by PEP) and PEP carboxylase (by malate and glucose-6-P) cannot provide a complete explanation for the temporal organization of glycolysis and that changes in the phase relationships between the rhythms of enzyme capacity along the pathway and a strict correlation between the level of PEP carboxylase capacity and the levels of capacity of the glycolytic enzymes are important components of the regulation of glycolysis in relation to CAM.Abbreviations CAM crassulacean acid metabolism - F-6-P fructose-6-phosphate - F-bi-P fructose-1,6 biphosphate - G-3-PDH 3-phosphoglyceraldehyde dehydrogenase (NAD), EC 1.2.1.12 - G-6-P glucose-6-phosphate - GSH reduced glutathion - GDH glycerolphosphate dehydrogenase, EC 1.1.1.8 - PEP phosphoenol pyruvate - PEPC PEP carboxylase, EC 4.1.1.31 - PFK phosphofructokinase, EC 2.7.1.11 - 2-PGA 2-phosphoglycerate - 3-PGA 3-phosphoglycerate - PGM phosphoglycerate phosphomutase, EC 5.4.2.1 - T.P. triose phosphates - TPI triose phosphate isomerase, EC 5.3.1.1     

Taurocyamine-utilizing Mutant of Pseudomonas aeruginosa with Altered Induction of 3-Guanidinopropionate Amidinohydrolase

A mutant, strain M-6, capable of utilizing taurocyamine (2-guanidinoethanesulfonate) as a nitrogen source was isolated from the parent strain, Pseudomonas aeruginosa GB-4, a derivative of wild-type P. aeruginosa PAO1 lacking the ability to produce guanidinobutyrase (EC 3.5.3.7). 3-Guanidinopropionate amidinohydrolase (EC class 3.5.3), which acts slowly on taurocyamine, was induced effectively by only 3-guanidinopropionate in the parent strain, while the enzyme of strain M-6 was induced by taurocyanime, guanidinoacetate, 3-guanidinopropionate, 4-guanidinobutyrate, and guanidinosuccinate. Strain M-6 synthesized a slight amount of the enzyme constitutively. The enzyme partially purified from strain M-6 exhibited substrate specificity similar to that of the wild-type strain. The mutant could grow also on 4-guanidinobutyrate, unlike the parent strain. These results indicate that strain M-6 acquired the ability to grow on taurocyamine by virtue of a mutation at the regulatory gene for 3-guanidinopropionate amidinohydrolase, which led to alteration of the specificity of the regulatory protein.     

Metabolism of glucose by unicellular blue-green algae

Summary A facultative photo- and chemoheterotroph, the unicellular bluegreen alga Aphanocapsa 6714, dissimilates glucose with formation of CO₂ as the only major product. A substantial fraction of the glucose consumed is assimilated and stored as polyglucose (probably glycogen). The oxidation of glucose proceeds through the pentose phosphate pathway. The first enzyme of this pathway, glucose-6-phosphate dehydrogenase, is partly inducible. In addition, the rate of glucose oxidation is controlled, at the level of glucose-6-phosphate dehydrogenase function, by the intracellular level of an intermediate of the Calvin cycle, ribulose-1,5-diphosphate, which is a specific allosteric inhibitor of this enzyme. As a consequence, the rate of glucose oxidation is greatly reduced by illumination, an effect reversed by the presence of DCMU, an inhibitor of photosystem II.Two obligate photoautotrophs, Synechococcus 6301 and Aphanocapsa 6308, produce CO₂ from glucose at extremely low rates, although their levels of pentose pathway enzymes and of hexokinase are similar to those in Aphanocapsa 6714. Failure to grow with glucose appears to reflect the absence of an effective glucose permease. A general hypothesis concerning the primary pathways of carbon metabolism in blue-green algae is presented.Abbreviations A (U)DPG ADP-glucose or UDP-glucose - G-1-P glucose-1-phosphate - G-6-P glucose-6-phosphate - G_(int.) intracellular glucose - F-6-P fructose-6-phosphate - 6-PG 6-phosphogluconate - Ru-5-P ribulose-5-phosphate - RUDP ribulose-1,5-diphosphate - PGA 3-phosphoglycerate - GAP glyceraldehyde-3-phosphate