Temperature-sensitive forms of large and small invertase in a mutant derived from a SUC1 strain of Saccharomyces cerevisiae.

Mutagenesis of the sucrose-fermenting (SUC1) Saccharomyces cerevisiae strain 4059-358D yielded an invertase-negative mutant (D10). Subsequent mutagenic treatment of D10 gave a sucrose-fermenting revertant (D10-ER1) that contained the same amount of large (mannoprotein) invertase as strain 4059-358D but only trace amounts of the smaller intracellular nonglycosylated enzyme. Limited genetic evidence indicated that the mutations in D10 and D10-ER1 are allelic to the SUC1 gene. The large invertases from D10-ER1 and 4059-358D were purified and compared. The two enzymes have similar specific activity and Km for sucrose, cross-react immunologically, and show the same subunit molecular weight after removal of the carbohydrate with endo-beta-N-acetylglucosaminidae H. They differ in that the large enzyme from the revertant is rapidly inactivated at 55 degrees C, whereas that from the parent is relatively stable at 65 degrees C. The small invertase in extracts of D10-ER1 is also heat sensitive as compared to the small enzyme from the original parent strain. The low level of small invertase in mutant D10-ER1 may reflect increased intracellular degradation of this heat-labile form. In several crosses of D10-ER1 with strains carrying the SUC1 or SUC3 genes, the temperature sensitivity of the large and small invertases and the low cellular level of small invertase appeared to cosegregate. These findings are evidence that SUC1 is a structural gene for invertase and that both large and small forms are encoded by a single gene. A detailed genetic analysis is presented in a companion paper.     

Isopentenyladenosine deficient tRNA from an antisuppressor mutant of Saccharomyces cerevisiae.

We have isolated a mutant of Saccharomyces cerevisiae that contains 1.5% of the normal tRNA complement of isopentenyladenosine (i6A). The mutant was characterized by the reduction in efficiency of a tyrosine inserting UAA nonsense suppressor. The chromatographic profiles of tRNATyr and tRNASer on benzoylated DEAE-cellulose are consistent with the loss of i6A by these species. Transfer RNA from the mutant exhibits 6.5% of the cytokinin biological activity expected for yeast tRNA. Transfer RNAs from the mutant that normally contain i6A accept the same levels of amino acids in vitro as the fully modified species. With the exception of i6A, the level of modified bases in unfractionated tRNA from the mutant appears to be normal. The loss of i6A apparently affects tRNA's role in protein synthesis at a step subsequent to aminoacylation.     

Isolation and characterization of a Saccharomyces cerevisiae mutant deficient in pyruvate kinase activity.

A mutant of the yeast Saccharomyces cerevisiae that is deficient in pyruvate kinase activity has been isolated. The mutant strain is capable of growth when supplied with lactate as the carbon source but not capable of growth when supplied with dextrose or other fermentable sugars or glycerol as the carbon source. Genetic analysis demonstrated that the phenotype of the pyruvate kinase-deficient strain was due to a single nuclear mutation, which was designated pyk1, and preliminary genetic mapping experiments located the pyk1 locus on chromosome I, 30 centimorgans from the ade1 locus. Adenine nucleotide levels in the mutant and parental strains were compared when the cells were subjected to various growth and starvation conditions. When carbon supply and energy production were dissociated by supplying the mutant strain with dextrose, adenine nucleotide levels fell dramatically. This result suggests that the initial reactions of glycolysis are not rate limiting, nor are they readily inhibited by feedback controls.     

The structural genes of internal invertases in Saccharomyces cerevisiae.

Summary Polyacrylamide gel electrophoresis (without SDS) of invertases from strains each carrying only one of the five known SUC-genes revealed differences in mobility of the internal enzymes. SUC1 invertase moved distinctly slower than the invertases formed in the presence of genes SUC2 to SUC5. Three bands of internal invertase activity were found in diploids carrying both SUC1 (slow invertase) and one of the other SUC-genes (fast invertases). Tetrad analysis of such diploids yielded haploids which showed the same three bands if they carried SUC1 in combination with another SUC gene. A gene dosage effect was observed in relation to invertase activity in haploid strains with only gene SUC1 or only SUC4 on one hand, and both genes on the other hand. A sucrose non-fermenting and invertase negative strain with mutant allele suc3-3 of gene SUC3 (fast invertase) was crossed with SUC1. The heterozygous diploid and the recombinant haploids (SUC1 suc3-3) showed two bands in the region of the internal invertase: a slow SUC1 band and a second band corresponding to the intermediate band of SUC1-SUC3 strains. The intermediate band in SUC1 suc3-3 strains is considered as a hybrid consisting of an active SUC1-monomer and an inactive suc3-mutant monomer. Formation of such hybrid bands was taken as evidence for the structural nature of SUC-genes.     

SUC1 gene of Saccharomyces: a structural gene for the large (glycoprotein) and small (carbohydrate-free) forms of invertase.

Saccharomyces cerevisiae revertant strain D10-ER1 has been shown to contain thermosensitive forms of the large (glycoprotein) and small (carbohydrate-free) invertases and a very low level of the small enzyme, along with a wild-type level of the large form (T. Mizunaga et al., Mol. Cell. Biol. 1:460-468, 1981). These characteristics cosegregated in crosses of the revertant strain with wild-type sucrose-fermenting (SUC1) or nonfermenting (suc0) strains. In addition, there is tight linkage between sucrose and maltose fermentation in revertant D10-ER1 (characteristic of the SUC1 and MAL1 genes). From this we infer that a single reversion event is responsible for the several changes observed in D10-ER1, and that this mutation maps within or very close to the SUC1 gene present in the ancestor strain 4059-358D. The revertant SUC1 allele in D10-ER1 (termed SUC1-R1) was expressed independently of the wild-type SUC1 gene when both were present in diploid cells. Diploids carrying only the wild-type or the mutant genes synthesized invertases with the characteristics of the parental Suc+ haploids. The possibility that a modifier gene was responsible for the alterations in the invertases of revertant D10-ER1 was ruled out by appropriate crosses. We conclude that SUC1 is a structural gene that codes for both the large and the small forms of invertase and suggest that SUC2 through SUC5 are structural genes as well.     

A nuclear mutant of Saccharomyces cerevisiae deficient in mitochondrial DNA replication and polymerase activity

We have isolated a thermosensitive mutant which is transformed into a population of cells devoid of mitochondrial DNA (rho 0 cells) at 35 degrees C and is deficient in mitochondrial (mt) DNA polymerase activity. A single recessive nuclear mutation (mip1) is responsible for rho 0 phenotype and mtDNA polymerase deficiency in vitro. At 25 degrees C (or 30 degrees C) a dominant suppressor mutation (SUP) masks the deficiency in vivo. The meiotic segregants (mip1 sup) which do not harbor the suppressor have a rho 0 phenotype both at 25 and 35 degrees C. They have no mtDNA polymerase activity, in contrast with MIP rho 0 mutants of mitochondrial inheritance which do exhibit mtDNA polymerase activity. In the thermosensitive mutant (mip1 SUP), the replication of mtDNA observed in vivo at 30 degrees C is completely abolished at 35 degrees C. In the meiotic segregants (mip1 sup), no mtDNA replication takes place at 30 and 35 degrees C. The synthesis of nuclear DNA is not affected. DNA polymerases may have replicative and/or repair activity. There is no evidence that mip mutants are deficient in mtDNA repair. In contrast the MIP gene product is strictly required for the replication of mtDNA and for the expression of the mtDNA polymerase activity. This enzyme might be the replicase of mtDNA.     

Regulation of invertase synthesis by glucose in Saccharomyces cerevisiae.

Saccharomyces cerevisiae growing under repressible conditions (1% of glucose or more) produces a burst of external invertase when shifted to higher temperatures. The secretion of this invertase requires protein synthesis, but was found to be independent of RNA formation. The level of mRNA accumulated and translated was inversely proportional to the glucose present in the growth medium. These results are consistent with the hypothesis that invertase is continuously synthesized both in the presence and absence of glucose, but under repressible conditions is degraded before secretion takes place.     

Subunit structure of external invertase from Saccharomyces cerevisiae.

Because 50% of the mass of the external invertase of Saccharomyces cerevisiae consists of carbohydrate, it has been extremely difficult to obtain an accurate molecular weight of this enzyme by centrifugal or electrophoretic techniques. However, on removing almost all of the oligosaccharide chains of this enzyme with the endo-beta-N-acetyl-glucosaminidase H from Streptomyces plicatus, it has been possible to show that carbohydrate-free invertase is composed of two 60,000-dalton subunits. Terminal sequence analysis with carboxypeptidases A, B, and Y provided strong evidence that the subunits are identical.     

Isolation of a Saccharomyces cerevisiae mutant strain deficient in deoxycytidylate deaminase activity and partial characterization of the enzyme.

Deoxycytidylate deaminase activity in Saccharomyces cerevisiae has been partially characterized. The yeast enzyme was found to exhibit properties similar to those of dCMP deaminases isolated from higher eucaryotes. A mutant strain completely deficient in dCMP deaminase activity was isolated by selection for resistance to 5-fluoro-2'-deoxycytidylate followed by screening for cross sensitivity to 5-fluoro-2'-deoxyuridylate, a potent inhibitor of the yeast thymidylate synthetase. We have designated this new allele dcd1 . A strain exhibiting an auxotrophic requirement for dUMP was isolated after mutagenesis of a dcd1 tup7 haploid. Genetic analysis revealed that this auxotrophic phenotype resulted from a combination of the dcd1 allele and a second, unlinked, nuclear mutation that we designated dmp1 . This allele, which by itself conveys no readily discernible phenotype, presumably impairs efficient synthesis of dUMP from UDP. The auxotrophic requirement of dcd1 dmp1 tup7 strains also can be satisfied by exogenous dTMP but not deoxyuridine.     

Immortalization of rat embryo fibroblasts by mutant polyomavirus large T antigens deficient in DNA binding.

We have identified a putative DNA-binding domain in polyomavirus large T antigen. Mutations introduced into the gene between amino acids 290 and 310 resulted in proteins that no longer bound to the high-affinity binding sites on the polyomavirus genome, showed no detectable nonspecific DNA binding, and were not able to initiate DNA replication from the viral origin. These mutant T antigen genes were introduced into rat embryo fibroblasts together with the neomycin resistance gene to allow selection for growth in the presence of G418. All the mutations tested facilitated the establishment of these cells in long-term culture at an efficiency indistinguishable from that of the wild-type protein.     

Change in invertase activity of sweet potato in response to wounding and purification and properties of its invertases

When root tissue of sweet potato (Ipomoea batatas Lam.) was sliced, acid invertase activity, initially absent in freshly sliced tissue, appeared after a 3- to 6-hour lag phase, rapidly reached a maximum in 18 hours, and thereafter decreased. The increase in invertase activity was accompanied by a decrease in sucrose content of the root tissue. Alkaline invertase activity was present in fresh root tissue, but changed little after wounding. Acid invertase in wounded tissue and alkaline invertase in fresh tissue were purified and their properties were investigated. The acid invertase was a ß-fructofuranosidase and was unaffected by substrate or by any of the cations and several metabolites. The alkaline invertase was more specific for sucrose, was inhibited by glucose and glucose 6-phosphate, and displayed non-Michaelis-Menten kinetics.     

Isolation of Saccharomyces cerevisiae mutants constitutive for invertase synthesis.

A new method for detecting invertase activity in Saccharomyces cerevisiae colonies was used to screen for mutants resistant to catabolite repression of invertase. Mutations causing the highest level of derepression were located in two previously identified genes, cyc8 and tup1. Several of the cyc8 mutations, notably cyc8-10 and cyc8-11, were temperature dependent, repressed at 23 degrees C, and derepressed at 37 degrees C. The kinetics of derepression of invertase mRNA in cyc8-10 cells shifted from 23 to 37 degrees C was determined by Northern blots. Invertase mRNA was detectable at 5 min after the shift, with kinetics of accumulation very similar to that of wild-type cells shifted from high-glucose to low-glucose medium. Assays of representative enzymes showed that many but not all glucose-repressible enzymes are derepressed in both cyc8 and tup1 mutants. cyc8 and tup1 appear to be the major negative regulatory genes controlling catabolite repression in yeasts.     

Secretion-defective mutations in the signal sequence for Saccharomyces cerevisiae invertase.

Nine mutations in the signal sequence region of the gene specifying the secreted Saccharomyces cerevisiae enzyme invertase were constructed in vitro. The consequences of these mutations were studied after returning the mutated genes to yeast cells. Short deletions and two extensive substitution mutations allowed normal expression and secretion of invertase. Other substitution mutations and longer deletions blocked the formation of extracellular invertase. Yeast cells carrying this second class of mutant gene expressed novel active internal forms of invertase that exhibited the following properties. The new internal proteins had the mobilities in denaturing gels expected of invertase polypeptides that had retained a defective signal sequence and were otherwise unmodified. The large increase in molecular weight characteristic of glycosylation was not seen. On nondenaturing gels the mutant enzymes were found as heterodimers with a normal form of invertase that is known to be cytoplasmic, showing that the mutant forms of the enzyme are assembled in the same compartment as the cytoplasmic enzyme. All of the mutant enzymes were soluble and not associated with the membrane components after fractionation of crude cell extracts on sucrose gradients. Therefore, these signal sequence mutations result in the production of active internal invertase that has lost the ability to enter the secretory pathway. This demonstrates that the signal sequence is required for the earliest steps in membrane translocation.