Mitochondrial protein synthesis is required for maintenance of intact mitochondrial genomes in Saccharomyces cerevisiae.

The genes of Saccharomyces cerevisiae coding for the mitochondrial threonine and tryptophan tRNA synthetases and for a putative mitochondrial ribosomal protein have been cloned. These, and the previously cloned gene for a mitochondrial elongation factor, were used to disrupt or partially delete the wild-type chromosomal copies of the genes in the respiratory-competent strain W303. In each case, inactivation of a gene whose product is required for mitochondrial protein synthesis causes an instability in mitochondrial DNA. Although intact mitochondrial genomes are rapidly and quantitatively eliminated in the protein synthesis defective strains, specific rho- genomes can be maintained stably over many generations. These results indicate that mitochondrial protein synthesis is required for the propagation of wild-type mitochondrial DNA in yeast.     

ESF1 is required for 18S rRNA synthesis in Saccharomyces cerevisiae

We report that Esf1p (Ydr365cp), an essential, evolutionarily conserved nucleolar protein, is required for the biogenesis of 18S rRNA in Saccharomyces cerevisiae. Depletion of Esf1p resulted in delayed processing of 35S precursor and a striking loss of 18S rRNA. Esf1p physically associated with ribosomal proteins and proteins involved in 18S rRNA biogenesis. Consistent with its role in 18S rRNA biogenesis, Esf1p also physically associated with U3 and U14 snoRNAs, but did not appear to be a core component of the SSU processome. These data indicate that Esf1p plays a direct role in early pre-rRNA processing.     

Replication protein A is required for meiotic recombination in Saccharomyces cerevisiae

In Saccharomyces cerevisiae, meiotic recombination is initiated by transient DNA double-stranded breaks (DSBs). These DSBs undergo a 5' --> 3' resection to produce 3' single-stranded DNA ends that serve to channel DSBs into the RAD52 recombinational repair pathway. In vitro studies strongly suggest that several proteins of this pathway--Rad51, Rad52, Rad54, Rad55, Rad57, and replication protein A (RPA)--play a role in the strand exchange reaction. Here, we report a study of the meiotic phenotypes conferred by two missense mutations affecting the largest subunit of RPA, which are localized in the protein interaction domain (rfa1-t11) and in the DNA-binding domain (rfa1-t48). We find that both mutant diploids exhibit reduced sporulation efficiency, very poor spore viability, and a 10- to 100-fold decrease in meiotic recombination. Physical analyses indicate that both mutants form normal levels of meiosis-specific DSBs and that the broken ends are processed into 3'-OH single-stranded tails, indicating that the RPA complex present in these rfa1 mutants is functional in the initial steps of meiotic recombination. However, the 5' ends of the broken fragments undergo extensive resection, similar to what is observed in rad51, rad52, rad55, and rad57 mutants, indicating that these RPA mutants are defective in the repair of the Spo11-dependent DSBs that initiate homologous recombination during meiosis.     

Thioredoxin is required for vacuole inheritance in Saccharomyces cerevisiae

The vacuole of Saccharomyces cerevisiae projects a stream of tubules a and vesicles (a segregation structure) into the bud in early S phase. We have described an in vitro reaction, requiring physiological temperature, ATP, and cytosol, in which isolated vacuoles form segregation structures and fuse. This in vitro reaction is defective when reaction components are prepared from vac mutants that are defective in this process in vivo, Fractionation of the cytosol reveals at least three components, each of which can support the vacuole fusion reaction, and two stimulatory fractions. Purification of one low molecular weight activity (LMA1) yields a heterodimeric protein with a thioredoxin subunit. Most of the thioredoxin of yeast is in this complex rather than the well-studied monomer. A deletion of both S. cerevisiae thioredoxin genes causes a striking vacuole inheritance defect in vivo, establishing a role for thioredoxin as a novel factor in this trafficking reaction.     

Three additional genes required for deoxyribonucleic acid synthesis in Saccharomyces cerevisiae

Deoxyribonucleic acid (DNA) synthesis was examined in asynchronous and synchronous cultures of a number of cdc (cell division cycle) temperature-sensitive mutant strains. The kinetics of DNA synthesis after a shift to the restrictive temperature was compared with that obtained after inhibition of protein synthesis at the permissive temperature, a condition that specifically blocks the initiation of new rounds of DNA replication, but does not block those in progress. Mutations in three genes (cdc 4, 7, and 28) appear to block a precondition for DNA synthesis since cells carrying these lesions cannot start new rounds of DNA replication after a shift from permissive to restrictive temperature, but can finish rounds that were in progress. These three genes are classified as having roles in the "initiation" of DNA synthesis. Mutations in two genes (cdc 8 and 21) block DNA synthesis, itself, since cells harboring these lesions that had started DNA synthesis at the permissive temperature arrest synthesis abruptly upon a shift to the restrictive temperature. Mutations in 13 other cdc genes do not impair DNA synthesis in the first cell cycle at the restrictive temperature.     

Histone H2A is required for normal centromere function in Saccharomyces cerevisiae

Histones are structural and functional components of the eukaryotic chromosome, and their function is essential for normal cell cycle progression. In this work, we describe the characterization of two Saccharomyces cerevisiae cold-sensitive histone H2A mutants. Both mutants contain single amino acid replacements of residues predicted to be on the surface of the nucleosome and in close contact with DNA. We show that these H2A mutations cause an increase-in-ploidy phenotype, an increased rate of chromosome loss, and a defect in traversing the G(2)-M phase of the cell cycle. Moreover, these H2A mutations show genetic interactions with mutations in genes encoding kinetochore components. Finally, chromatin analysis of these H2A mutants has revealed an altered centromeric chromatin structure. Taken together, these results strongly suggest that histone H2A is required for proper centromere-kinetochore function during chromosome segregation.     

Mitochondrial NADH kinase, Pos5p, is required for efficient iron-sulfur cluster biogenesis in Saccharomyces cerevisiae

In Saccharomyces cerevisiae, the mitochondrial inner membrane readily allows transport of cytosolic NAD(+), but not NADPH, to the matrix. Pos5p is the only known NADH kinase in the mitochondrial matrix. The enzyme phosphorylates NADH to NADPH and is the major source of NADPH in the matrix. The importance of mitochondrial NADPH for cellular physiology is underscored by the phenotypes of the Δpos5 mutant, characterized by oxidative stress sensitivity and iron-sulfur (Fe-S) cluster deficiency. Fe-S clusters are essential cofactors of proteins such as aconitase [4Fe-4S] and ferredoxin [2Fe-2S] in mitochondria. Intact mitochondria isolated from wild-type yeast can synthesize these clusters and insert them into the corresponding apoproteins. Here, we show that this process of Fe-S cluster biogenesis in wild-type mitochondria is greatly stimulated and kinetically favored by the addition of NAD(+) or NADH in a dose-dependent manner, probably via transport into mitochondria and subsequent conversion into NADPH. Unlike wild-type mitochondria, Δpos5 mitochondria cannot efficiently synthesize Fe-S clusters on endogenous aconitase or imported ferredoxin, although cluster biogenesis in isolated Δpos5 mitochondria is restored to a significant extent by a small amount of imported Pos5p. Interestingly, Fe-S cluster biogenesis in wild-type mitochondria is further enhanced by overexpression of Pos5p. The effects of Pos5p on Fe-S cluster generation in mitochondria indicate that one or more steps in the biosynthetic process require NADPH. The role of mitochondrial NADPH in Fe-S cluster biogenesis appears to be distinct from its function in anti-oxidant defense.     

The Exocyst is a multiprotein complex required for exocytosis in Saccharomyces cerevisiae.

In the yeast Saccharomyces cerevisiae, the products of at least 15 genes are involved specifically in vesicular transport from the Golgi apparatus to the plasma membrane. Previously, we have shown that three of these genes, SEC6, SEC8 and SEC15, encode components of a multisubunit complex which localizes to the tip of the bud, the predominant site of exocytosis in S. cerevisiae. Mutations in three more of these genes, SEC3, SEC5 and SEC10, were found to disrupt the subunit integrity of the Sec6-Sec8-Sec15 complex, indicating that these genes may encode some of the remaining components of this complex. To examine this possibility, we cloned and sequenced the SEC5 and SEC10 genes, disrupted them, and either epitope tagged them (Sec5p) or prepared polyclonal antisera (Sec10p) to them for co-immunoprecipitation studies. Concurrently, we biochemically purified the remaining unidentified polypeptides of the Sec6-Sec8-Sec15 complex for peptide microsequencing. The genes encoding these components were identified by comparison of predicted amino acid sequences with those obtained from peptide microsequencing of the purified complex components. In addition to Sec6p, Sec8p and Sec15p, the complex contains the proteins encoded by SEC3, SEC5, SEC10 and a novel gene, EXO70. Since these seven proteins function together in a complex required for exocytosis, and not other intracellular trafficking steps, we have named it the Exocyst.     

Phosphatidylinositol 4-phosphate is required for translation initiation in Saccharomyces cerevisiae

The small natural product wortmannin inhibits protein synthesis by modulating several phosphatidylinositol (PI) metabolic pathways. A primary target of wortmannin in yeast is the plasma membrane-associated PI 4-kinase (PI4K) Stt4p, which is required for actin cytoskeleton organization. Here we show that wortmannin treatment or inactivation of Stt4p, but not disorganization of the actin cytoskeleton per se, leads to a rapid attenuation of translation initiation. Interestingly, inactivation of Pik1p, a wortmannin-insensitive, functionally distinct PI4K, implicated in the regulation of Golgi functions and secretion, also results in severe translation initiation defects with a marked increase of the phosphorylation of the translation initiation factor eIF2alpha. Because wortmannin largely phenocopies the effects of rapamycin (e.g. it triggers nuclear accumulation of Gln3p), it likely also inhibits the PI kinase-related, target of rapamycin (TOR) kinases. Importantly, however, neither inactivation of Stt4p nor Pik1p significantly affects TOR-controlled readouts other than translation initiation, indicating that these PI4Ks do not simply function upstream of TOR. Together, our results reveal the existence of a novel translation initiation control mechanism in yeast that is tightly coupled to the synthesis of distinct PI4P pools.     

Golgi manganese transport is required for rapamycin signaling in Saccharomyces cerevisiae

The Pmr1 Golgi Ca2+/Mn2+ ATPase negatively regulates target of rapamycin complex (TORC1) signaling, the rapamycin-sensitive TOR complex in Saccharomyces cerevisiae. Since pmr1 causes resistance to rapamycin and tor1 causes hypersensitivity, we looked for genetic interactions of pmr1 with tor1. Deletion of TOR1 restored two wild-type phenotypes. Loss of TOR1 restored the ability of the pmr1 strain to grow on media containing 2 mm MnCl2 and conferred wild type as well as the wild-type sensitivity to rapamycin. Mn2+ additions to media partially suppressed rapamycin resistance of wild type and pmr1 tor1, suggesting that Tor1 and Tor2 are regulated by manganese. We parsed the roles of Ca2+ and Mn2+ transport and the compartments in rapamycin response using separation-of-function mutants available for Pmr1. A strain containing the D53A mutant (Mn2+ transporting) of Pmr1 is rapamycin sensitive, but the Q783A mutant (Ca2+ transporting) strain is rapamycin resistant. Mn2+ transport into the Golgi lumen appears to be required for rapamycin sensitivity. Overexpression of Ca2+ pump SERCA1, Ca2+/H+ antiporter Vcx1, or a Mn2+ transporting mutant of Vcx1 (Vcx1-M1) failed to restore rapamycin sensitivity, and loss of Pmr1 but not other transporters of Ca2+ or Mn2+ results in rapamycin resistance. Overexpression of Ccc1, a Fe2+ and Mn2+ transporter that has been localized to Golgi and the vacuole, does restore rapamycin sensitivity to pmr1Delta. We conclude that Mn2+ in the Golgi inhibits TORC1 signaling.     

The SNF3 gene is required for high-affinity glucose transport in Saccharomyces cerevisiae.

Glucose uptake mutants have not been previously obtained in Saccharomyces cerevisiae, possibly because there seem to be at least two transport systems, of low and high affinities. We showed that snf3 (sucrose nonfermenting) mutants did not express high-affinity glucose uptake. Furthermore, their growth was completely impaired on low concentrations of glucose in the presence of antimycin A (which blocks respiration). Several genes which complemented the original snf3 gene were obtained on multicopy plasmids. Some of them, as well as plasmid-carried SNF3 itself, conferred a substantial increase in high-affinity glucose uptake in both snf3 and wild-type hosts. The effects of glucose on the expression of such a plasmid-determined high-affinity uptake resembled those in the wild type. Other genes complementing snf3 seemed to cause an increase in low-affinity glucose uptake. We suggest that SNF3 may function specifically in high-affinity glucose uptake, which is needed under some conditions of growth on low glucose concentrations. SNF3 itself or the other complementing genes may specify components of the glucose uptake system.     

Sister chromatid cohesion is required for postreplicative double-strand break repair in Saccharomyces cerevisiae.

The repair of DNA double-strand breaks by recombination requires the presence of an undamaged copy that is used as a template during the repair process. Because cells acquire resistance to gamma irradiation during DNA replication and because sister chromatids are the preferred partner for double-strand break repair in mitotic diploid yeast cells, it has long been suspected that cohesion between sister chromatids might be crucial for efficient repair. This hypothesis is consistent with the sensitivity to gamma irradiation of mutants defective in the cohesin complex that holds sister chromatids together from DNA replication until the onset of anaphase (reviewed in) . It is also in accordance with the finding that surveillance mechanisms (checkpoints) that sense DNA damage arrest cell cycle progression in yeast by causing stabilization of the securin Pds1, thereby blocking sister chromatid separation. The hypersensitivity to irradiation of cohesin mutants could, however, be due to a more direct involvement of the cohesin complex in the process of DNA repair. We show here that passage through S phase in the presence of cohesin, and not cohesin per se, is essential for efficient double-strand break repair during G2 in yeast. Proteins needed to load cohesin onto chromosomes (Scc2) and to generate cohesion during S phase (Eco1) are also shown to be required for repair. Our results confirm what has long been suspected but never proven, that cohesion between sister chromatids is essential for efficient double-strand break repair in mitotic cells.     

Phosphatidylserine synthesis required for the maximal tryptophan transport activity in Saccharomyces cerevisiae

Saccharomyces cerevisiae cho1/pss mutants, which are severely impaired in phosphatidylserine (PS) synthesis, do not have detectable amounts of PS in their lipid fractions. Their derivatives with mutations that cause defects in tryptophan synthesis grew poorly in a medium containing 5 micrograms/ml of L-tryptophan, a concentration that met the requirements of tryptophanauxotrophic CHO1/PSS strains. The rates of tryptophan uptake of trp1 cho1/pss mutants were low at low tryptophan concentrations. This defect in the use of tryptophan was restored either by expression of CHO1/PSS or by introduction of a gene encoding tryptophan transporter, TAT1 or TAT2. These results indicate that PS synthesis is required for the maximal tryptophan-transporting activity of S. cerevisiae at low tryptophan concentrations.     

The ARS consensus sequence is required for chromosomal origin function in Saccharomyces cerevisiae.

Replication origins have been mapped to positions that coincide, within experimental error (several hundred base pairs), with ARS elements. To determine whether the DNA sequences required for ARS function on plasmids are required for chromosomal origin function, the chromosomal copy of ARS306 was deleted and the chromosomal copy of ARS307 was replaced with mutant derivatives of ARS307 containing single point mutations in domain A within the ARS core consensus sequence. The chromosomal origin function of these derivatives was assayed by two-dimensional agarose gel electrophoresis. Deletion of ARS306 deleted the associated replication origin. The effects on chromosomal origin function of mutations in domain A paralleled their effects on ARS function, as measured by plasmid stability. These results demonstrate that chromosomal origin function is a property of the ARS element itself.     

A positive regulatory gene, THI3, is required for thiamine metabolism in Saccharomyces cerevisiae.

We have isolated a thiamine auxotrophic mutant carrying a recessive mutation which lacks the positive regulatory gene, THI3, which differs in the regulation of thiamine transport from the THI2 (PHO6) gene described previously (Y. Kawasaki, K. Nosaka, Y. Kaneko, H. Nishimura, and A. Iwashima, J. Bacteriol. 172:6145-6147, 1990) for expression of thiamine metabolism in Saccharomyces cerevisiae. The mutant (thi3) had a markedly reduced thiamine transport system as well as reduced activity of thiamine-repressible acid phosphatase and of several enzymes for thiamine synthesis from 2-methyl-4-amino-5-hydroxymethylpyrimidine and 4-methyl-5-beta-hydroxyethylthiazole. These results suggest that thiamine metabolism in S. cerevisiae is subject to two positive regulatory genes, THI2 (PHO6) and THI3. We have also isolated a hybrid plasmid, pTTR1, containing a 6.2-kb DNA fragment from an S. cerevisiae genomic library which complements thiamine auxotrophy in the thi3 mutant. This gene was localized on a 3.0-kb ClaI-BglII fragment in the subclone pTTR5. Complementation of the activities for thiamine metabolism in the thi3 mutant transformed by some plasmids with the THI3 gene was also examined.