Vaccinia virus encodes an essential gene with strong homology to protein kinases

The B1 gene of vaccinia virus encodes a 34-kDa protein which is essential for viral replication. Temperature-sensitive mutants bearing lesions in this gene arrest at the stage of DNA replication during nonpermissive infections. In this report, the sequence of the 34-kDa open reading frame is presented, and the mutations in two ts alleles are identified. Analysis of the deduced protein sequence reveals strong homology with catalytic domains of numerous protein kinases. The lesion in one of the mutants alters an invariant glycine residue within one such domain.     

A nuclear yeast gene (GCY) encodes a polypeptide with high homology to a vertebrate eye lens protein

We describe here the nuclear gene for a yeast protein showing unexpectedly high homology with mammalian aldo/keto reductases as well as with p-crystallin, one of the prominent proteins of the frog eye lens. Although it could be proven that the gene occurs as a single copy in the haploid yeast genome, replacement of the intact by a disrupted, nonfunctional allele led to no obvious phenotype, indicating that the gene is dispensable. The gene was assigned to chromosome XV. It is transcribed in vivo into an mRNA of about 1300 bases with a coding capacity for a protein of 312 amino acids (estimated Mr 35,000).     

The yeast SSS1 gene is essential for secretory protein translocation and encodes a conserved protein of the endoplasmic reticulum.

The SEC61, SEC62 and SEC63 yeast gene products are membrane components of the apparatus that catalyses protein translocation into the endoplasmic reticulum (ER). In the hope of uncovering additional components of the translocation apparatus, we sought yeast genes whose overexpression would restore partial thermoresistance in a sec61 translocation-deficient mutant. The first extragenic Sec sixty-one suppressor, SSS1, is an essential single copy gene whose overexpression restores translocation in the sec61 mutant. Another extragenic suppressor was identified as TDH3, which encodes the major isozyme of the most abundant yeast protein, glyceraldehyde-3-phosphate dehydrogenase. TDH3 overexpression could exert an indirect effect by competitively inhibiting protein synthesis, thereby allowing the impaired translocation apparatus to cope with a reduced flow of newly synthesized secretory proteins. Depletion of the Sss1 protein rapidly results in accumulation of multiple secretory or membrane proteins devoid of post-translational modifications; the normally secreted alpha-factor accumulates on the cytosolic side of ER membranes. Thus, the SSS1 gene is required for continued translocation of secretory preproteins beyond their early association to ER membranes. Consistent with its essential role in protein translocation, the Sss1 protein localizes to the ER and homologues were detected in higher eukaryotes.     

Characterization of the XRN1 gene encoding a 5'-->3' exoribonuclease: sequence data and analysis of disparate protein and mRNA levels of gene-disrupted yeast cells.

Sequencing of the XRN1 gene of Saccharomyces cerevisiae, cloned in this laboratory as a gene encoding a 160-kDa 5'-->3' exoribonuclease (XRN1), shows that it is identical to a gene (DST2 or SEP1) encoding a DNA strand transferase and to genes involved in nuclear fusion, KEM1, and plasmid stability, RAR5. To better understand the various phenotypes associated with loss of XRN1 and the enzymatic activities associated with the protein, certain characteristics of our yeast cells lacking an active gene (xrn1) have been examined. Cells are larger (average volume is x 1.5-1.8) and have an increased doubling time (x1.9-2.1). The protein synthesis rate per cell is 80-90% that of wild-type (wt) cells, and the resultant cellular protein levels are higher. The rate of the 25S and 18S rRNA synthesis is approximately 45% that of wt cells and its cellular level is about 90% that of wt cells. Levels of protein bands resolved by one-dimensional PAGE show substantial differences. Synthesis rates observed for the same protein bands, as well as measurements of several specific mRNA levels by Northern analysis, suggest disparities in mRNA levels. Results show two to four times longer half-lives of specific short-lived mRNAs. The variations in levels of protein and RNA species found in the xrn1 cells may be the cause of some of the phenotypes found associated with gene loss.     

Yeast NOP2 encodes an essential nucleolar protein with homology to a human proliferation marker

We have isolated a gene (NOP2) encoding a nucleolar protein during a search for previously unidentified nuclear proteins in the yeast Saccharomyces cerevisiae. The protein encoded by NOP2 (Nop2p) has a predicted molecular mass of 70 kD, migrates at 90 kD by SDS-PAGE, and is essential for cell viability. Nop2p shows significant amino acid sequence homology to a human proliferation-associated nucleolar protein, p120. Approximately half of Nop2p exhibits 67% amino acid sequence identity to p120. Analysis of subcellular fractions indicates that Nop2p is located primarily in the nucleus, and nuclear fractionation studies suggest that Nop2p is associated with the nucleolus. Indirect immunofluorescence localization of Nop2p shows a nucleolar-staining pattern, which is heterogeneous in appearance, and a faint staining of the cytoplasm. The expression of NOP2 during the transition from stationary phase growth arrest to rapid growth was measured, and compared to the expression of TCM1, which encodes the ribosomal protein L3. Nop2p protein levels are markedly upregulated during the onset of growth, compared to the levels of ribosomal protein L3, which remain relatively constant. NOP2 mRNA levels also increase during the onset of growth, accompanied by a similar increase in the levels of TCM1 mRNA. The consequences of overexpressing NOP2 from the GAL10 promoter on a multicopy plasmid were investigated. Although NOP2 overexpression produced no discernible growth phenotype and had no effect on ribosome subunit synthesis, overexpression was found to influence the morphology of the nucleolus, as judged by electron microscopy. Overexpression caused the nucleolus to become detached from the nuclear envelope and to become more rounded and/or fragmented in appearance. These findings suggest roles for NOP2 in nucleolar function during the onset of growth, and in the maintenance of nucleolar structure.     

YRA1, an essential Saccharomyces cerevisiae gene, encodes a novel nuclear protein with RNA annealing activity.

The complexity of eukaryotic mRNA processing suggests a need for certain factors, called RNA chaperones, that can modulate RNA secondary structure as well as the interactions between pre-mRNA and trans-acting components. To identify factors that may fulfill this role in the yeast Saccharomyces cerevisiae, we fractionated whole-cell extracts and assayed for activity that could facilitate a specific RNA-RNA annealing reaction. We detected one strong RNA annealing activity and purified it to homogeneity. This previously undescribed factor, Yra1p, is localized to the nucleus; its sequence contains one RNP-motif RNA-binding domain. The YRA1 gene contains a 766-nt intron, the second-largest identified in this organism, and Yra1p serves an essential, nonredundant function. Taken together, our findings indicate that Yra1p is likely to have an important role in S. cerevisiae nuclear pre-mRNA metabolism.     

The Neurospora aab-1 gene encodes a CCAAT binding protein homologous to yeast HAP5.

The expression of the am (glutamate dehydrogenase) gene is dependent upon two upstream activating sequences, designated URSam(alpha) and URSam(beta). A heteromeric nuclear protein Am Alpha Binding protein (AAB) binds specifically to a CCAAT box within the URSam(alpha) element. AAB appears to be composed of three components. We used polyclonal antiserum raised against the highly purified AAB1 subunit to isolate a partial aab-1 cDNA clone, which was then used to isolate a full-length cDNA and a genomic clone. The full-length cDNA has the potential to encode a 272 amino acid protein with a calculated molecular weight of 30 kD. Amino acid sequence obtained by Edman analysis of the AAB1 protein confirmed that the aab-1 gene had been cloned. AAB-1 shows similarity to the HAP5 protein of yeast and the CBF-C protein of rat. Each of these proteins is an essential subunit of their respective heteromeric CCAAT binding proteins. The aab1 gene maps on linkage group III of Neurospora crassa near the trp-1 locus. Disruption of the aab-1 gene results in pleiotropic effects on growth and development as well as a 50% reduction in glutamate dehydrogenase levels. Transformation of the aab-1 disruption mutant strain with the cloned genomic copy of the aab-1 gene rescued all of the phenotypic alterations associated with the aab-1 mutation.     

The fission yeast dis3+ gene encodes a 110-kDa essential protein implicated in mitotic control.

The fission yeast mutant dis3-54 is defective in mitosis and fails in chromosome disjunction. Its phenotype is similar to that of dis2-11, a mutant with a mutation in the type 1 protein phosphatase gene. We cloned the dis3+ gene by transformation. Nucleotide sequencing predicts a coding region of 970 amino acids interrupted by a 164-bp intron at the 65th codon. The predicted dis3+ protein shares a weak but significant similarity with the budding yeast SSD1 or SRK1 gene product, the gene for which is a suppressor for the absence of a protein phosphatase SIT4 gene or the BCY1 regulatory subunit of cyclic AMP-dependent protein kinase. Anti-dis3 antibodies recognized the 110-kDa dis3+ gene product, which is part of a 250- to 350-kDa oligomer and is enriched in the nucleus. The cellular localization of the dis3+ protein is reminiscent of that of the dis2+ protein, but these two proteins do not form a complex. A type 1 protein phosphatase activity in the dis3-54 mutant extracts is apparently not affected. The dis3+ gene is essential for growth; gene disruptant cells do not germinate and fail in cell division. Increased dis3+ gene dosage reverses the Ts+ phenotype of a cdc25 wee1 strain, as does increased type 1 protein phosphatase gene dosage. Double mutant dis3 dis2 is lethal even at the permissive temperature, suggesting that the dis2+ and dis3+ genes may be functionally overlapped. The role of the dis3+ gene product in mitosis is unknown, but this gene product may be directly or indirectly involved in the regulation of mitosis.