The C-terminal domain of Saccharomyces cerevisiae DNA topoisomerase II.

A set of carboxy-terminal deletion mutants of Saccharomyces cerevisiae DNA topoisomerase II were constructed for studying the functions of the carboxyl domain in vitro and in vivo. The wild-type yeast enzyme is a homodimer with 1,429 amino acid residues in each of the two polypeptides; truncation of the C terminus to Ile-1220 has little effect on the function of the enzyme in vitro or in vivo, whereas truncations extending beyond Gln-1138 yield completely inactive proteins. Several mutant enzymes with C termini in between these two residues were found to be catalytically active but unable to complement a top2-4 temperature-sensitive mutation. Immunomicroscopy results suggest that the removal of a nuclear localization signal in the C-terminal domain is likely to contribute to the physiological dysfunction of these proteins; the ability of these mutant proteins to relax supercoiled DNA in vivo shows, however, that at least some of the mutant proteins are present in the nuclei in a catalytically active form. In contrast to the ability of the catalytically active mutant proteins to relax supercoiled intracellular DNA, all mutants that do not complement the temperature-dependent lethality and high frequency of chromosomal nondisjunction of top2-4 were found to lack decatenation activity in vivo. The plausible roles of the DNA topoisomerase II C-terminal domain, in addition to providing a signal for nuclear localization, are discussed in the light of these results.     

The proteinase yscA-inhibitor, IA3, gene. Studies of cytoplasmic proteinase inhibitor deficiency on yeast physiology

The gene of the proteinase yscA inhibitor IA3, PAI3, of the yeast Saccharomyces cerevisiae was isolated by oligonucleotide screening of a genomic DNA library and sequenced. The gene codes for a single protein of 68 amino acids. The structural PAI3 gene was deleted in vitro by oligonucleotide-site-directed mutagenesis. The mutated allele was introduced via homologous recombination into the genome of wild-type yeast and into the genome of a yeast mutant, which lacks the second cytoplasmic proteinase-inhibitor, IB2. The deficiency of either or of both inhibitors has no effect on the cell viability under various physiological conditions. The inhibitor mutants, however, show an increase in the general in vivo protein degradation rate. The IA3 mutant has a 2-3-fold increased protein degradation rate in the first 6 h after a shift from rich medium onto starvation-medium, whereas the IB2 mutant shows a constantly increased degradation rate of 20-50% under the same conditions. The inhibitor double null mutant has the same protein degradation rate as the IA3 null mutant. These results suggest an in vivo interaction between the vacuolor endopeptidases and their cytoplasmic inhibitors.     

Dominant negative mutator mutations in the mutL gene of Escherichia coli.

The mutL gene product is part of the dam-directed mismatch repair system of Escherichia coli but has no known enzymatic function. It forms a complex on heteroduplex DNA with the mismatch recognition MutS protein and with MutH, which has latent endonuclease activity. An N-terminal hexahistidine-tagged MutL was constructed which was active in vivo. As a first stop to determine the functional domains of MutL, we have isolated 72 hydroxylamine-induced plasmid-borne mutations which impart a dominant-negative phenotype to the wild-type strain for increased spontaneous mutagenesis. None of the mutations complement a mutL deletion mutant, indicating that the mutant proteins by themselves are inactive. All the dominant mutations but one could be complemented by the wild-type mutL at about the same gene dosage. DNA sequencing indicated that the mutations affected 22 amino acid residues located between positions 16 and 549 of the 615 amino acid protein. In the N-terminal half of the protein, 12 out of 15 amino acid replacements occur at positions conserved in various eukaryotic MutL homologs. All but one of the sequence changes affecting the C-terminal end of the protein are nonsense mutations.     

Disruption of the gene encoding subunit VI of yeast cytochrome bc1 complex causes respiratory deficiency of cells with reduced cytochrome c levels

A double mutant of Saccharomyces cerevisiae, in which CYCL gene is deleted and the chromosomal copy of the 17 kDa protein gene is disrupted, has been constructed. This mutant cannot grow on nonfermentable carbon sources, but normal growth can be restored by complementation of either mutation with a yeast vector containing either the wild-type 17 kDa protein gene or the CYCl gene. These results show that although the 17 kDa protein, subunit VI of yeast cytochrome bc1 complex is dispensable for yeast mitochondrial respiration in cells with the wild-type levels of cytochrome c, the 17 kDa protein is essential for respiration when the level of cytochrome c is limited, indicating that is plays a role in electron transport. This glycerol- phenotype of the double mutant can serve as the basis for further genetic studies on the function of the 17 kDa protein in yeast mitochondria and may provide insight into the physiological function of the hinge protein, the counterpart of the yeast 17 kDa protein, in beef heart mitochondria.     

hsk1+, a Schizosaccharomyces pombe gene related to Saccharomyces cerevisiae CDC7, is required for chromosomal replication.

Degenerate oligonucleotide-directed polymerase chain reaction was conducted to clone a possible Schizosaccharomyces pombe homologue [hsk1 for a putative homologue of CDC7 (seven) kinase 1] of Saccharomyces cerevisiae Cdc7 kinase. The cloned cDNA for hsk1+ contains an open reading frame consisting of 507 amino acids with predicted mol. wt of 58,370 that possesses overall amino acid identity of 46% (65% including similar residues) to CDC7. In addition to conserved domains for serine-threonine kinases, the predicted primary structure of Hsk1 contains three 'kinase insert' sequences characteristic to Cdc7 at the positions identical to those of Cdc7. Whereas the length and sequences of the kinase inserts are diverged between the two yeast species, 58% identity (76% including similar residues) is detected within the kinase conserved domains. The hsk1+ gene, which is present as a single copy on the S.pombe chromosome, contains two introns within the coding frame. Disruption of the hsk1+ gene by insertion of the ura4+ gene is lethal to growth. Analysis of the DNA content of germinating spores that contain hsk1 null alleles indicates that DNA replication is inhibited in the mutant. The morphology of these mutant spores after germination indicates abnormal nuclear division in some population of germinating spores, suggesting either that Hsk1 may be required for inhibition of mitosis until completion of S phase or that it may also be involved in proper execution of mitosis. Our results suggest that hsk1+ is a strong candidate for the functional fission yeast homologue of budding yeast CDC7 and that a mechanism through which initiation of chromosomal replication is regulated may be conserved between the two yeast species.     

Nucleotide sequence of the wild-type RAD4 gene of Saccharomyces cerevisiae and characterization of mutant rad4 alleles.

Shuttle plasmids carrying the wild-type RAD4 gene of Saccharomyces cerevisiae cannot be propagated in Escherichia coli (R. Fleer, W. Siede, and E. C. Friedberg, J. Bacteriol. 169:4884-4892, 1987). In order to determine the nucleotide sequence of the cloned gene, we used a plasmid carrying a mutant allele that allows plasmid propagation in E. coli. The wild-type sequence in the region of this mutation was determined from a second plasmid carrying a different mutant rad4 allele. We established the locations and characteristics of a number of spontaneously generated plasmid-borne RAD4 mutations that alleviate the toxicity of the wild-type gene in E. coli and of several mutagen-induced chromosomal mutations that inactivate the excision repair function of RAD4. These mutations are situated in very close proximity to each other, and all are expected to result in the expression of truncated polypeptides missing the carboxy-terminal one-third of the Rad4 polypeptide. This region of the gene may be important both for the toxic effect of the Rad4 protein in E. coli and for its role in DNA repair in S. cerevisiae.     

Isolation and expression of the gene encoding yeast mitochondrial malate dehydrogenase.

The mitochondrial tricarboxylic acid cycle enzyme malate dehydrogenase was purified from Saccharomyces cerevisiae, and an antibody to the purified enzyme was obtained in rabbits. Immunoscreening of a yeast genomic DNA library cloned into a lambda gt11 expression vector with anti-malate dehydrogenase immunoglobulin G resulted in identification of a lambda recombinant encoding an immunoreactive beta-galactosidase fusion protein. The yeast DNA portion of the coding region for the fusion protein translates into an amino acid sequence which is very similar to carboxy-terminal sequences of malate dehydrogenases from other organisms. In s. cerevisiae transformed with a multicopy plasmid carrying the complete malate dehydrogenase gene, the specific activity and immunoreactivity of the mitochondrial isozyme are increased by eightfold. Expression of both the chromosomal and plasmid-borne genes is repressed by growth on glucose. Disruption of the chromosomal malate dehydrogenase gene in haploid S. cerevisiae produces mutants unable to grow on acetate and impaired in growth on glycerol plus lactate as carbon sources.     

Cell division regulation by BIR1, a member of the inhibitor of apoptosis family in yeast

The inhibitor of apoptosis (IAP) gene family comprises molecules that block the activity of pro-apoptotic caspase proteases. Paradoxically, yeasts contain IAP proteins but no caspases and no apoptotic program. To determine the function of these proteins in vivo, we disrupted the BIR1 gene, encoding the only known IAP in yeast Saccharomyces cerevisiae. Sporulation of heterozygous diploids yielded no viable mutant haploids, indicating that BIR1 is an essential gene. By flow cytometry, some heterozygous mutants were polyploid accumulating >4 N DNA content. These cells exhibited a 20-40% reduction in growth rate, which was rescued by plasmid-borne over-expression of BIR1 but not by its human counterpart, survivin. Deletion analysis revealed that the N-terminal domain of Bir1, containing the conserved baculovirus IAP repeat, was able to partially complement the cell growth defect caused by BIR1 deletion. Moreover, the full-length and truncated forms of Bir1 accelerated cell division in wild-type cells. Finally, BIR1 heterozygous mutants exhibited grossly altered cell morphology with misshapen or abnormally long buds connected to an unusually large mother cell. These findings identify a novel function of IAP proteins in the pleiotropic control of cell division, in addition to their role in the suppression of apoptosis.     

Molecular dissection of the hydrophobic segments H3 and H4 of the yeast Ca2+ channel component Mid1

The Saccharomyces cerevisiae MID1 gene product, Mid1, is composed of 548 amino acid residues, has four relatively hydrophobic segments named H1-H4, and functions as a Ca(2+)-permeable, stretch-activated channel when expressed in mammalian cells. In some conditions Mid1 cooperates with Cch1, a yeast homolog of the alpha1 subunit of mammalian voltage-gated channels. To identify the important regions or amino acid residues necessary for Mid1 function, we employed in vitro site-directed mutagenesis on H3 and H4 of Mid1 and expressed the resulting mutant genes in a mid1 null mutant to examine whether the mutant gene products are functional or not in vivo. Mutant Mid1 proteins lacking the whole H3 or H4 segment, H3De or H4De, did not complement the lethality and low Ca(2+) accumulation activity of the mid1 mutant, although their localization and contents appeared to be normal, indicating that H3 and H4 are required for Mid1 function itself. Single amino acid exchange experiments on individual amino acid residues of H3 and H4 showed that 10 of 20 residues in H3 and 14 of 23 residues in H4 were important for the normal function of Mid1. In particular, we found four severe loss-of-function mutations, D341E, F356S, C373D, and C373R, and two interesting mutations leading to a high level of Ca(2+) accumulation with a slightly low complementing activity, G342A and Y355A. The importance of these amino acid residues will be discussed.