A carbon catabolite repression mutant of Saccharomyces cerevisiae with elevated hexokinase activity: Evidence for regulatory control of hexokinase PII synthesis

Summary Mutants were investigated that had elevated hexokinase activity and had been isolated previously as resistant to carbon catabolite repression (Zimmermann and Scheel 1977). They were allele tested with mutant strains of Lobo and Maitra (1977), which had defects in one or more of the genes coding for glucokinase and unspecific hexokinases. It was shown, that the mutation abolishing carbon catabolite repression had occured in a gene that was not allelic to any of the structural genes coding for hexokinases. This indicated that a regulatory defect was responsible for elevated hexokinase activity. This agreed with observations that hexokinase activities were like wild-type during growth on non-fermentable carbon sources in hex2 mutants. Recombination between the mutant allele hex2 and mutant alleles hxk1 and hxk2, coding for hexokinase PI and PII respectively, clearly demonstrated that only hexokinase PII was elevated in hex2 mutants. When hex2 mutant cells grown on YEP ethanol were shifted to YEP glucose media, hexokinase activity increased after 30min. This increase depended on de novo protein synthesis. hex2 mutants provide evidence, that carbon catabolite repression and synthesis of hexokinase PII are under common regulatory control.     

Constitutive appearance of peroxisomes in a regulatory mutant of the methylotrophic yeast Hansenula polymorpha

Summary A selection by glucosamine for mutants of Hansenula polymorpha insensitive to glucose repression of methanol assimilation is described. Constitutive synthesis of enzymes is established in standard batch cultures of glucosegrown cells. Upon prolonged glucose metabolism the phenotype is masked by catabolite inactivation and degradation of enzymes. Addition of the substrate methanol remarkably improves constitutive synthesis by preventing catabolite inactivation and delaying degradation. Regular peroxisomes of reduced number are formed in mutant cells under repressed conditions. No constitutive synthesis is detectable using ethanol as a carbon source. In addition, this alcohol is detrimental to growth of the mutants, indicating that H. polymorpha is constrained to repress synthesis of enzymes involved in the C₁-metabolism when ethanol is present as a substrate.     

Mechanism of inactivation of hexokinase PII of Saccharomyces cerevisiae by D-xylose

The mechanism of inactivation of hexokinase PII of Saccharomyces cerevisiae by D-xylose was characterized. Inactivation was dependent on the presence of MgATP and was irreversible. Inactivation involved phosphorylation of the protein. Observation of the carbon catabolite repression of selected enzymes showed that invertase and maltase synthesis were not repressed when hexokinase PII was phosphorylated.     

Catabolite inactivation of isocitrate lyase from Saccharomyces cerevisiae

A reversible carbon catabolite inactivation step is described for isocitrate lyase from Saccharomyces cerevisiae. This reversible inactivation step of isocitrate lyase is similar to that described for fructose 1,6-bisphosphatase. Addition of 2,4-dinitrophenol, nystatin or glucose to cultures, grown in ethanol as carbon source, caused a rapid loss of the isocitrate lyase and fructose 1,6-bisphosphatase activities at pH 5.5 but not at pH 7.5. These results suggest that intracellular acidification and thus a cAMP increase is involved in the catabolite inactivation mechanism of both enzymes. From results obtained by addition of glucose to yeast cultures at pH 7.5 it was concluded that others factors than cAMP can play a role in the catabolite inactivation mechanism of both enzymes.     

Genetic and biochemical evidence for hexokinase PII as a key enzyme involved in carbon catabolite repression in yeast

Summary Mutants with reduced hexokinase activity previously isolated as resistant to carbon catabolite repression of invertase and maltase (Zimmermann and Scheel, 1977) were allele tested with mutant strains of Lobo and Maitra (1977) which had defects in one or several of the genes coding for glucokinase and the two unspecific hexokinases. It could be demonstrated, that the mutation abolishing carbon catabolite repression had occurred in a gene allelic to the structural gene of hexokinase PII. Moreover, the defective mutant allele for hexokinase PII isolated by Lobo and Maitra (1977) was also defective in carbon catabolite repression. Neither glucokinase nor hexokinase PI showed any effect on this regulatory system. Biochemical analysis in crude extracts also showed altered kinetic properties of hexokinases in the hex1 mutants. The results directly support the hypothesis previously put forward, that one of the hexokinases is not only active as a catalytic, but also as a regulatory protein.     

Regulation of protein synthesis in methylotrophic yeasts: Repression of methanol dissimilating enzymes by nitrogen limitation

The influence of nitrogen limitation on the regulation of the methanol oxidizing enzymes alcohol oxidase, catalase, formaldehyde dehydrogenase and formate dehydrogenase in the two methylotrophic yeastsHansenula polymorpha andKloeckera sp. 2201 was studied in continuous culture. When shifted from carbon-limited growth conditions (with a mixture of glucose and methanol as carbon sources) to a nitrogen-limited environment both cultures were found to go through a transition phase where neither enhanced residual concentrations of the nitrogen source nor of one of the two carbon sources could be detected in the supernatant. As soon as nitrogen became a limiting substrate an immediate reorganisation of the cell composition was initiated: protein content of the cells dropped to approximately 40% of its initial value, glycogen was synthesized and the enzyme composition of the cells was changed. The peroxisomal enzymes alcohol oxidase and catalase in both organisms and the two dehydrogenases for formaldehyde and formate in cells ofKloeckera sp. 2201 were subject to degradation (catabolite inactivation). The measured rates of inactivation indicated that in cells ofH. polymorpha this process might be limited to peroxisomes, whereas inKloeckera sp. 2201 the degradation was found to affect peroxisomal as well as cytoplasmic enzymes. In contrast to methanol dissimilating enzymes the net rate of synthesis of hexokinase, glucose-6-phosphate dehydrogenase and 6-phosphogluconate dehydrogenase was not affected by this process but those enzymes were synthesized with increased rates.     

Proteolysis of hexokinase PII is not the triggering signal of carbon catabolite derepression in Saccharomyces cerevisiae

The role of hexokinase PII in mediating carbon catabolite derepression in yeast has been examined. Hexokinase isoenzyme PII (EC 2.7.1.1) was partially degraded when protease inhibitors were omitted from the buffer used for preparation of cell-free extracts. The hexokinase PII inactivation induced by D-xylose was correlated with derepression of maltase (EC 3.2.1.20) in the wild-type strain Saccharomyces cerevisiae G-517 and in D.308.3, a strain that contains the cloned hexokinase PII gene on a multicopy plasmid. This inactivation was not correlated with the loss of hexokinase PII protein as assayed by immunoblotting. We conclude that during the derepression process there is no release of proteolytic peptides from hexokinase PII.     

Characterization of a mutant of the yeast Candida maltosa defective in catabolite inactivation of gluconeogenetic enzymes

A spontaneous mutant of the yeast Candida maltosa SBUG 700 was isolated showing pseudohyphal marphology under all growth conditions tested. The C. maltosa PHM mutant takes up glucose with the kinetics of C. maltosa SBUG 700 and starved cells contain the same cyclic AMP concentration. Addition of glucose to the PHM mutant does not result in an increase of the intracellular cyclic AMP level and in catabolite inactivation of fructose-1,6-bisphosphatase, malate dehydrogenase and phosphoenolpyruvate carboxykinase. However, addition of 2,4-dinitrophenol is followed by a rapid, transient increase of the cyclic AMP level in the mutant cells, but not by catabolite inactivation. These results show that a common mechanism might be responsible for catabolite inactivation and glucose-induced cAMP signaling or that glucose-induced cAMP signaling is required for catabolite inactivation in C. maltosa.     

Cloning and restriction analysis of the hexokinase PII gene of the yeast Saccharomyces cerevisiae

Summary Carbon catabolite repression in yeast depends on catalytic active hexokinase isoenzyme PII (Entian 1980a). A yeast strain lacking hexokinase isoenzymes PI and PII was transformed, using a recombinant pool with inserts of yeast nuclear DNA up to 10 kbp in length. One hundred transformants for hexokinase were obtained. All selected plasmids coded for hexokinase isoenzyme PII, none for hexokinase isoenzyme PI, and carbon catabolite repression was restored in the transformants. Thirty-five independently isolated stable plasmids were investigated further. Analysis with the restriction enzyme EcoRI showed that these plasmids fell into two classes with different restriction behaviour. One representative of each class was amplified in Escherichia coli and transferred back into the yeast hexokinase-deficient strain with concomitant complementation of the nuclear mutation. The two types of insert were analysed in detail with 16 restriction enzymes, having 0–3 cleavage sites on transformant vector YRp7. The plasmids differed from each other by the orientation of the yeast insert in the vector. After yeast transformation with fragments of one plasmid the hexokinase PII gene was localised within a region of 1.65 kbp.     

A partial defect in carbon catabolite repression in mutants of Saccharomyces cerevisiae with reduced hexose phosphyorylation

Summary Mutants of Saccharomyces cerevisiae with reduced glucose phosphorylation were investigated. They were all recessive and belonged to one gene HEX1, mutant designation hex1. Carbon catabolite repression of alpha-glucosidases, invertase and part of the total malate dehydrogenase was reduced. Repression of the glyoxylate cycle enzymes, isocitrate lyase and malate synthetase, as well as that of gluconeogenetic fructose-1, 6-bisphosphatase was normal. A slight effect on repression of succinate: cytochrome c oxidoreductase and respiration was to be detected. The effect on repression by fructose was much less pronounced but still clear. However, there was a paradoxical effect of hexose concentration with higher concentrations repressing less. Maltose was also less repressing in the mutant. Growth on all sugars degraded via the hexose phosphorylation reaction was reduced and more strongly so at higher concentrations. Intracellular concentrations of glucose-6-phosphate, fructose-6-phosphate and fructose-1,6-bisphosphate were largely the same in mutant and wild type. The only striking difference between mutant and wild type was a fourfold higher intracellular glucose concentration in maltose grown mutants cells. The data obtained do not support the contention that carbon catabolite repression of the enzymes studied is triggered by intracellular hexoses or their metabolites alone. They rather suggest that it is some component of the hexose phosphorylating system that contributes to carbon catabolite repression.     

Involvement of Hexokinase Hxk1 in Glucose Catabolite Repression of LIP2 Encoding Extracellular Lipase in the Yeast Yarrowia lipolytica

The yeast Yarrowia lipolytica produces an extracellular lipase encoded by the LIP2 gene. However, very little is known about the mechanisms controlling its expression, especially on glucose media. In this work, the involvement of hexokinase Hxk1 in the glucose catabolite repression of LIP2 was investigated in a lipase overproducing mutant less sensitive to glucose repression. This mutant has a reduced capacity to phosphorylate hexose compared with the wild-type strain, but no differences could be observed between the HXK1 sequences in the two isolates. This suggested that the reduced phosphorylating activity of the mutant strain probably resulted from a modification in the level of HXK1 expression. However, overexpression of the HXK1 gene in this mutant led to a decrease of both LIP2 induction and extracellular lipase activity, suggesting that the hexokinase is involved in the glucose catabolite repression of LIP2 in Y lipolytica.     

Inhibition and inactivation of glucose-phosphorylating enzymes from Saccharomyces cerevisiae by D-xylose

Three glucose-phosphorylating enzymes were separated from cell-free extracts of Saccharomyces cerevisiae by hydroxylapatite chromatography. Variations in the amounts of these enzymes in cells growing on glucose and on ethanol showed that hexokinase PI was a constitutive enzyme, whereas synthesis of hexokinase PII and glucokinase were regulated by the carbon source used. Glucokinase proved to be a glucomannokinase with Km values of 0.04 mM for both glucose and mannose. D-Xylose produced an irreversible inactivation of the three glucose-phosphorylating enzymes depending on the presence or absence of ATP. Hexokinase PI inactivation required ATP, while hexokinase PII was inactivated by D-xylose without ATP in the reaction mixture. Glucokinase was protected by ATP from this inactivation. D-Xylose acted as a competitive inhibitor of hexokinase PI and glucokinase and as a non-competitive inhibitor of hexokinase PII.     

The hexokinase isoenzyme PII of Saccharomyces cerevisiae ia a protein kinase

The HXK2 gene product has an important role in controlling carbon catabolite repression in Saccharomyces cerevisiae. We have raised specific antibodies against the hexokinase PII protein and have demonstrated that it is a 58 kDa phosphoprotein with protein kinase activity. The predicted amino acid sequence of the HXK2 gene product has significant homology to the conserved catalytic domain of mammalian and yeast protein kinases. Protein kinase activity was located in a different domain of the protein from the hexose-phosphorylating activity. The hexokinase PII protein level remained unchanged in P2T22D mutant cells (hxk1 HXK2 glk1) growing in a complex medium with glucose. The protein kinase activity of hexokinase PII is regulated by the glucose concentration of the culture medium. Exit from the carbon catabolite repression phase and entry into derepression phase may be controlled, in part, by modulation of the 58 kDa protein kinase activity by changes in cyclic AMP concentration.     

Saccharomyces cerevisiae mutants provide evidence of hexokinase PII as a bifunctional enzyme with catalytic and regulatory domains for triggering carbon catabolite repression

A selection system has been devised for isolating hexokinase PII structural gene mutants that cause defects in carbon catabolite repression, but retain normal catalytic activity. We used diploid parental strains with homozygotic defects in the hexokinase PI structural gene and with only one functional hexokinase PII allele. Of 3,000 colonies tested, 35 mutants (hex1r) did not repress the synthesis of invertase, maltase, malate dehydrogenase, and respiratory enzymes. These mutants had additional hexokinase PII activity. In contrast to hex1 mutants (Entian et al., Mol. Gen. Genet. 156:99-105, 1977; F.K. Zimmermann and I. Scheel, Mol. Gen. Genet. 154:75-82, 1977), which were allelic to structural gene mutants of hexokinase PII and had no catalytic activity (K.-D. Entian, Mol. Gen. Gent. 178:633-637, 1980), the hex1r mutants sporulated hardly at all or formed aberrant cells. Those ascospores obtained were mostly inviable. As the few viable hex1r segregants were sterile, triploid cells were constructed to demonstrate allelism between hex1r mutants and hexokinase PII structural gene mutants. Metabolite concentrations, growth rate, and ethanol production were the same in hex1r mutants and their corresponding wild-type strains. Recombination of hexokinase and glucokinase alleles gave strains with different specific activities. The defect in carbon catabolite repression was strongly associated with the defect in hexokinase PII and was independent of the glucose phosphorylating capacity. Hence, a secondary effect caused by reduced hexose phosphorylation was not responsible for the repression defect in hex1 mutants. These results, and those with the hex1r mutants isolated, strongly supported our earlier hypothesis that hexokinase PII is a bifunctional enzyme with (i) catalytic activity and (ii) a regulatory component triggering carbon catabolite repression (Entian, Mol. Gen. Genet. 178:633-637, 1980; K.-D. Entian and D. Mecke, J. Biol. Chem. 257:870-874, 1982).     

Effects of null mutations in the hexokinase genes of Saccharomyces cerevisiae on catabolite repression.

Saccharomyces cerevisiae has two homologous hexokinases, I and II; they are 78% identical at the amino acid level. Either enzyme allows yeast cells to ferment fructose. Mutant strains without any hexokinase can still grow on glucose by using a third enzyme, glucokinase. Hexokinase II has been implicated in the control of catabolite repression in yeasts. We constructed null mutations in both hexokinase genes, HXK1 and HXK2, and studied their effect on the fermentation of fructose and on catabolite repression of three different genes in yeasts: SUC2, CYC1, and GAL10. The results indicate that hxk1 or hxk2 single null mutants can ferment fructose but that hxk1 hxk2 double mutants cannot. The hxk2 single mutant, as well as the double mutant, failed to show catabolite repression in all three systems, while the hxk1 null mutation had little or no effect on catabolite repression.     

Isolation of the facA (acetyl-coenzyme A synthetase) and acuE (malate synthase) genes of Aspergillus nidulans

Summary Acetate inducible genes of Aspergillus nidulans were cloned via differential hybridization to cDNA probes. Using transformation of mutant strains the genes were identified as facA (acetyl-Coenzyme A synthetase) and acuE (malate synthase). The levels of RNA encoded by these genes were shown to be acetate inducible and subject to carbon catabolite repression. Induction is abolished in a facB mutant and carbon catabolite repression is relieved in a creA mutant.     

Relaxation of catabolite repression in streptomycin-dependent Escherichia coli

Acetohydroxy acid synthetase, which is sensitive to catabolite repression in wild-type Escherichia coli B, was relatively resistant to this control in a streptomycin-dependent mutant. The streptomycin-dependent mutant was found to be inducible for beta-galactosidase in the presence of glucose, although repression of beta-galactosidase by glucose occurred under experimental conditions where growth of the streptomycin-dependent mutant was limited. Additional glucose-sensitive enzymes of wild-type E. coli B (citrate synthase, fumarase, aconitase and isocitrate dehydrogenase) were found to be insensitive to the carbon source in streptomycin-dependent mutants: these enzymes were formed by streptomycin-dependent E. coli B in equivalent quantities when either glucose or glycerol was the carbon source. Two enzymes, glucokinase and glucose 6-phosphate dehydrogenase, that are glucose-insensitive in wild-type E. coli B were formed in equivalent quantity on glucose or glycerol in both streptomycin-sensitive and streptomycin-dependent E. coli B. The results indicate a general decrease or relaxation of catabolite repression in the streptomycin-dependent mutant. The yield of streptomycin-dependent cells from glucose was one-third less than that of the streptomycin-sensitive strain. We conclude that the decreased efficiency of glucose utilization in streptomycin-dependent E. coli B is responsible for the relaxation of catabolite repression in this mutant.     

Inactivation of gluconeogenic enzymes in glycolytic mutants of Saccharomyces cerevisiae.

Yeast mutants blocked at different steps of the glycolytic pathways have been used to study the inactivation of several gluconeogenic enzymes upon addition of sugars. While phosphorylation of the sugars appears a requisite for the inactivation of fructose 1,6-bisphosphatase and phosphoenol-pyruvate carboxykinase, malate dehydrogenase is inactivated by fructose in mutants lacking hexokinase. The normal inactivation elicited by glucose in a mutant lacking phosphofructokinase indicates that the process does not require metabolism of the sugar beyond hexose monophosphates. A possible role for ATP in the inactivation process is suggested.     

Histidine utilization by Alcaligenes eutrophus: Regulation of histidase formation under heterotrophic conditions of growth

Histidine supported good growth of Alcaligenes eutrophus strain H 16 as a nitrogen source, but only poor growth as a carbon and energy source. The facultative chemolithoautotrophic bacterium was also able to utilize urocanic acid, the first intermediate of histidine catabolism. The products of histidine degradation were ammonium, formate and glutamate. Three enzymes of the pathway, histidase, urocanase and formiminoglutamate hydrolase, were present in histidine-grown cells. Two types of spontaneous mutants, derived from the wild type, were characterized by an increased growth rate on histidine. One of these types was found to produce histidase constitutively and at a higher activity compared with the parental strain. The second type of mutant had apparently gained an improved histidine uptake system, which is supposed to be growth rate-limiting in the wild type. From the physiological studies the conclusion was drawn that the control of histidine-degrading enzymes is based on induction by urocanate and catabolite repression by carbon sources supporting fast growth, such as succinate or pyruvate. Ammonium was found not to affect catabolite repression, however, we obtained evidence that histidine uptake is subject to a nitrogen control.Abbreviation CTAB hexadecyltrimethylammonium bromide