Translation initiation factor 4A from Saccharomyces cerevisiae: analysis of residues conserved in the D-E-A-D family of RNA helicases.

The eukaryotic translation initiation factor 4A (eIF-4A) possesses an in vitro helicase activity that allows the unwinding of double-stranded RNA. This activity is dependent on ATP hydrolysis and the presence of another translation initiation factor, eIF-4B. These two initiation factors are thought to unwind mRNA secondary structures in preparation for ribosome binding and initiation of translation. To further characterize the function of eIF-4A in cellular translation and its interaction with other elements of the translation machinery, we have isolated mutations in the TIF1 and TIF2 genes encoding eIF-4A in Saccharomyces cerevisiae. We show that three highly conserved domains of the D-E-A-D protein family, encoding eIF-4A and other RNA helicases, are essential for protein function. Only in rare cases could we make a conservative substitution without affecting cell growth. The mutants show a clear correlation between their growth and in vivo translation rates. One mutation that results in a temperature-sensitive phenotype reveals an immediate decrease in translation activity following a shift to the nonpermissive temperature. These in vivo results confirm previous in vitro data demonstrating an absolute dependence of translation on the TIF1 and TIF2 gene products.     

The human U5 snRNP-specific 100-kD protein is an RS domain-containing, putative RNA helicase with significant homology to the yeast splicing factor Prp28p.

Through UV-crosslinking experiments, we previously provided evidence suggesting that a U5 snRNP protein with a molecular weight in the 100-kDa range is an ATP-binding protein (Laggerbauer B, Lauber J, Lührmann R, 1996, Nucleic Acid Res 24:868-875). Separation of HeLa U5 snRNP proteins on 2D gels revealed multiple variants with apparent molecular masses of 100 kDa. Subsequent microsequencing of these variants led to the isolation of a cDNA encoding a protein with an N-terminal RS domain and a C-terminal domain that contains all of the conserved motifs characteristic of members of the DEAD-box family of RNA-stimulated ATPases and RNA helicases. Antibodies raised against cDNA-encoded 100-kDa protein specifically recognized native U5-100kD both on immunoblots and in purified HeLa U5 snRNPs or [U4/U6.U5] tri-snRNP complexes, confirming that the bona fide 100-kDa cDNA had been isolated. In vitro phosphorylation studies demonstrated that U5-100kD can serve as a substrate for both Clk/Sty and the U1 snRNP-associated kinase, and further suggested that the multiple U5-100kD variants observed on 2D gels represent differentially phosphorylated forms of the protein. A database homology search revealed a significant degree of homology (60% similarity, 37% identity) between the Saccharomyces cerevisiae splicing factor, Prp28p, which lacks an N-terminal RS domain, and the C-terminal domain of U5-100kD. Consistent with their designation as structural homologues, anti-Prp28 antibodies recognized specifically the human U5-100kD protein on immunoblots. Together with the DEXH-box U5-200kD protein (Lauber J et al., 1996, EMBO J 15:4001-4015), U5-100kD is the second example of a putative RNA helicase that is tightly associated with the U5 snRNP. Given the recent identification of the U5-116kD protein as a homologue of the ribosomal translocase EF-2 (Fabrizio P, Laggerbauer B, Lauber J, Lane WS, Lührmann R, 1997, EMBO J 16:4092-4106), at least three integral U5 snRNP proteins thus potentially facilitate conformational changes in the spliceosome during nuclear pre-mRNA splicing.     

The 5-S RNA binding protein from yeast (Saccharomyces cerevisiae) ribosomes. Evolution of the eukaryotic 5-S RNA binding protein.

The ribonucleoprotein complex between 5-S RNA and its binding protein (5-S RNA . protein complex) of yeast ribosomes was released from 60-S subunits with 25 mM EDTA and the protein component was purified by chromatography on DEAE-cellulose. This protein, designated YL3 (Mr = 36000 on dodecylsulfate gels), was relatively insoluble in neutral solutions (pH 4--9) and migrated as one of four acidic 60-S subunit proteins when analyzed by the Kaltschmidt and Wittman two-dimensional gel system. Amino acid analyses indicated lower amounts of lysine and arginine than most ribosomal proteins. Sequence homology was observed in the N terminus of YL3, and two prokaryotic 5-S RNA binding proteins, EL18 from Escherichia coli and HL13 from Halobacterium cutirubrum: Ala1-Phe2-Gln3-Lys4-Asp5-Ala6-Lys7-Ser8-Ser9-Ala10-Tyr11-Ser12-Ser13-Arg14-Phe15-Gln16-Tyr17-Pro18-Phe19-Arg20-Arg21-Arg22-Arg23-Glu24-Gly25-Lys26-Thr27-Asp28-Tyr29-Tyr35; of particular interest was homology in the cluster of basic residues (18--23). Since the protein contained one methionine residue it could be split into two fragments, CN1 (Mr = 24700) and CN2 (Mr = 11300) by CNBr treatment; the larger fragment originated from the N terminus. The N-terminal amino acid sequence of CN2 shared a limited sequence homology with an internal portion of a second 5-S RNA binding protein from E. coli, EL5, and, based also on the molecular weights of the proteins and studies on the protein binding sites in 5-S RNAs, a model for the evolution of the eukaryotic 5-S RNA binding protein is suggested in which a fusion of the prokaryotic sequences may have occurred. Unlike the native 5-S RNA . protein complex, a variety of RNAs interacted with the smaller CN2 fragment to form homogeneous ribonucleoprotein complexes; the results suggest that the CN1 fragment may confer specificity on the natural 5-S RNA-protein interaction.     

Protein-RNA interactions in the U5 snRNP of Saccharomyces cerevisiae.

We present here the first insights into the organization of proteins on the RNA in the U5 snRNP of Saccharomyces cerevisiae. Photo-crosslinking with uniformly labeled U5 RNA in snRNPs reconstituted in vitro revealed five contacting proteins, Prp8p, Snu114p, p30, p16, and p10, contact by the three smaller proteins requiring an intact Sm site. Site-specific crosslinking showed that Snu114p contacts the 5' side of internal loop 1, whereas Prp8p interacts with five different regions of the 5' stem-loop, but not with the Sm site or 3' stem-loop. Both internal loops in the 5' domain are essential for Prp8p to associate with the snRNP, but the conserved loop 1 is not, although this is the region to which Prp8p crosslinks most strongly. The extensive contacts between Prp8p and the 5' stem-loop of U5 RNA support the hypothesis that, in spliceosomes, Prp8p stabilizes loop 1-exon interactions. Moreover, data showing that Prp8p contacts the exons even in the absence of loop 1 indicate that Prp8p may be the principal anchoring factor for exons in the spliceosome. This and the close proximity of the spliceosomal translocase, Snu114p, to U5 loop 1 and Prp8p support and extend the proposal that Snu114p mimics U5 loop 1 during a translocation event in the spliceosome.     

The PRP4 (RNA4) protein of Saccharomyces cerevisiae is associated with the 5'' portion of the U4 small nuclear RNA.

We have combined oligonucleotide-directed RNase H degradation and immunoprecipitation in a study of the association of the Saccharomyces cerevisiae PRP4 protein with the U4-U6 complex. We have found that three oligonucleotides were able to direct nearly to completion the RNase H-specific cleavage of the target RNA molecules as they exist in splicing extracts. Immunoprecipitation of the degradation products with PRP4 antibody showed that the 5' portion of U4 small nuclear RNA (snRNA) and the 3' portion of U6 snRNA coimmunoprecipitated with the PRP4 protein. Micrococcal nuclease protection experiments confirmed further that the 5' portion and 3' end of U4 snRNA were very resistant to nuclease digestion, whereas the 3' portion of U6 snRNA was protected to only a very small extent. We conclude that the PRP4 protein of S. cerevisiae is associated primarily with the 5' portion of U4 snRNA in the U4-U6 small nuclear ribonucleoprotein (snRNP).     

Protein-RNA interactions in the U5 snRNP of Saccharomyces cerevisiae.

We present here the first insights into the organization of proteins on the RNA in the U5 snRNP of Saccharomyces cerevisiae. Photo-crosslinking with uniformly labeled U5 RNA in snRNPs reconstituted in vitro revealed five contacting proteins, Prp8p, Snu114p, p30, p16, and p10, contact by the three smaller proteins requiring an intact Sm site. Site-specific crosslinking showed that Snu114p contacts the 5' side of internal loop 1, whereas Prp8p interacts with five different regions of the 5' stem-loop, but not with the Sm site or 3' stem-loop. Both internal loops in the 5' domain are essential for Prp8p to associate with the snRNP, but the conserved loop 1 is not, although this is the region to which Prp8p crosslinks most strongly. The extensive contacts between Prp8p and the 5' stem-loop of U5 RNA support the hypothesis that, in spliceosomes, Prp8p stabilizes loop 1-exon interactions. Moreover, data showing that Prp8p contacts the exons even in the absence of loop 1 indicate that Prp8p may be the principal anchoring factor for exons in the spliceosome. This and the close proximity of the spliceosomal translocase, Snu114p, to U5 loop 1 and Prp8p support and extend the proposal that Snu114p mimics U5 loop 1 during a translocation event in the spliceosome.     

Multiple functions of Saccharomyces cerevisiae splicing protein Prp24 in U6 RNA structural rearrangements.

U6 spliceosomal RNA has a complex secondary structure that includes a highly conserved stemloop near the 3' end. The 3' stem is unwound when U6 RNA base-pairs with U4 RNA during spliceosome assembly, but likely reforms when U4 RNA leaves the spliceosome prior to the catalysis of splicing. A mutation in yeast U6 RNA that hyperstabilizes the 3' stem confers cold sensitivity and inhibits U4/U6 assembly as well as a later step in splicing. Here we show that extragenic suppressors of the 3' stem mutation map to the gene coding for splicing factor Prp24. The suppressor mutations are located in the second and third of three RNA-recognition motifs (RRMs) in Prp24 and are predicted to disrupt RNA binding. Mutations in U6 RNA predicted to destabilize a novel helix adjacent to the 3' stem also suppress the 3' stem mutation and enhance the growth defect of a suppressor mutation in RRM2 of Prp24. Both phenotypes are reverted by a compensatory mutation that restores pairing in the novel helix. These results are best explained by a model in which RRMs 2 and 3 of Prp24 stabilize an extended intramolecular structure in U6 RNA that competes with the U4/U6 RNA interaction, and thus influence both association and dissociation of U4 and U6 RNAs during the splicing cycle.     

RNA and protein elongation rates in Saccharomyces cerevisiae

Summary The RNA elongation rate has been measured in yeast by the kinetics of appearance of radioactivity in the different molecular weight classes by the method first developed by Bremer and Yuan (1968). Despite the limitations caused by the breakdown of the 35s rRNA precursor, an estimate of 29 to 38 nucleotides/second at 30° has been obtained for the RNA elongation rate. The protein elongation rate has been calculated by the method of Maaløe and Kjeldgaard (1966) which consists of dividing the number of amino acids polymerized into protein per unit of time by the number of active ribosomes. This has given values of 7 to 9 amino acids/second at 30°.These numbers are of the same order as those found in Escherichia coli when corrected to 37°. Eucaryotic cells could thus have preserved part of the coupling found in bacteria between RNA and protein elongation rates.     

Identification of essential elements in U14 RNA of Saccharomyces cerevisiae.

The U14 RNA of Saccharomyces cerevisiae is a small nucleolar RNA (snoRNA) required for normal production of 18S rRNA. Depletion of U14 results in impaired processing of pre-rRNA, deficiency in 18S-containing intermediates and marked under-accumulation of mature 18S RNA. The present report describes results of functional mapping of U14, by a variety of mutagenic approaches. Special attention was directed at assessing the importance of sequence elements conserved between yeast and mouse U14 as well as other snoRNA species. Functionality was assessed in a test strain containing a galactose dependent U14 gene. The results show portions of three U14 conserved regions to be required for U14 accumulation or function. These regions include bases in: (i) the 5'-proximal box C region, (ii) the 3'-distal box D region, and (iii) a 13 base domain complementary to 18S rRNA. Point and multi-base substitution mutations in the snoRNA conserved box C and box D regions prevent U14 accumulation. Mutations in the essential 18S related domain do not effect U14 levels, but do disrupt synthesis of 18S RNA, indicating that this region is required for function. Taken together, the results suggest that the box C and box D regions influence U14 expression or stability and that U14 function might involve direct interaction with 18S RNA.     

Expression of the 18kDa protein of Mycobacterium leprae in Saccharomyces cerevisiae

Summary Mycobacterium leprae, the etiologic agent of leprosy, until now has not been grown in vitro, resulting in exceedingly obstacles for the production of purified antigens. It is therefore of interest to clone the relevant M.leprae antigens in other easy to handle microbial hosts. Here, we describe two different systems for expressing the 18kDa antigen of M.leprae in S. cerevisiae. Each system was shown to be effective in antigen expression, but the secretion system provided easier purification. Working with different host strains under different growth conditions, large quantities of biologically active proteins were obtained.     

The DNA-binding protein Hdf1p (a putative Ku homologue) is required for maintaining normal telomere length in Saccharomyces cerevisiae.

In mammalian cells, the Ku autoantigen is an end- binding DNA protein required for the repair of DNA breaks [Troelstra, C. and Jaspers, N.G.J. (1994) Curr. Biol., 4, 1149- 1151]. A yeast gene (HDF1) encoding a putative homologue of the 70 kDa subunit of Ku has recently been identified [Feldmann, H. and Winnacker, E. L. (1993) J. Biol. Chem., 268, 12895- 12900]. We find that hdf1 mutant strains have substantially shorter telomeres than wild-type strains. We speculate that Hdf1p may bind the natural ends of the chromosome, in addition to binding to the ends of broken DNA molecules. Strains with both an hdf1 mutation and a mutation in TEL 1 (a gene related to the human ataxia telangiectasia gene) have extremely short telomeres and grow slowly.     

Fourteen residues of the U1 snRNP-specific U1A protein are required for homodimerization, cooperative RNA binding, and inhibition of polyadenylation

It was previously shown that the human U1A protein, one of three U1 small nuclear ribonucleoprotein-specific proteins, autoregulates its own production by binding to and inhibiting the polyadenylation of its own pre-mRNA. The U1A autoregulatory complex requires two molecules of U1A protein to cooperatively bind a 50-nucleotide polyadenylation-inhibitory element (PIE) RNA located in the U1A 3' untranslated region. Based on both biochemical and nuclear magnetic resonance structural data, it was predicted that protein-protein interactions between the N-terminal regions (amino acids [aa] 1 to 115) of the two U1A proteins would form the basis for cooperative binding to PIE RNA and for inhibition of polyadenylation. In this study, we not only experimentally confirmed these predictions but discovered some unexpected features of how the U1A autoregulatory complex functions. We found that the U1A protein homodimerizes in the yeast two-hybrid system even when its ability to bind RNA is incapacitated. U1A dimerization requires two separate regions, both located in the N-terminal 115 residues. Using both coselection and gel mobility shift assays, U1A dimerization was also observed in vitro and found to depend on the same two regions that were found in vivo. Mutation of the second homodimerization region (aa 103 to 115) also resulted in loss of inhibition of polyadenylation and loss of cooperative binding of two U1A protein molecules to PIE RNA. This same mutation had no effect on the binding of one U1A protein molecule to PIE RNA. A peptide containing two copies of aa 103 to 115 is a potent inhibitor of polyadenylation. Based on these data, a model of the U1A autoregulatory complex is presented.     

The KNS1 gene of Saccharomyces cerevisiae encodes a nonessential protein kinase homologue that is distantly related to members of the CDC28/cdc2 gene family

Summary A novel protein kinase homologue (KNS1) has been identified in Saccharomyces cerevisiae. KNS1 contains an open reading frame of 720 codons. The carboxy-terminal portion of the predicted protein sequence is similar to that of many other protein kinases, exhibiting 36% identity to the cdc2 gene product of Schizosaccharomyces pombe and 34% identity to the CDC28 gene product of S. cerevisiae. Deletion mutations were constructed in the KNS1 gene. kns1 mutants grow at the same rate as wild-type cells using several different carbon sources. They mate at normal efficiencies, and they sporulate successfully. No defects were found in entry into or exit from stationary phase. Thus, the KNS1 gene is not essential for cell growth and a variety of other cellular processes in yeast.     

Prion protein prevents Bax-mediated cell death in the absence of other Bcl-2 family members in Saccharomyces cerevisiae

Although there is no consensus regarding the normal function of the prion protein, increasing evidence points towards a role in cellular protection against cell death. We have previously shown that prion protein is a potent inhibitor of Bax-induced apoptosis in human primary neurons and in the breast carcinoma MCF-7 cells. Here, we used the yeast Saccharomyces cerevisiae to investigate if the neuroprotective function of prion protein requires other members of the Bcl-2 family given that S. cerevisiae lacks Bcl-2 genes but undergoes a mitochondrial-dependent apoptotic cell death upon exogenous expression of Bax protein. We show that Bax induces cell death and growth inhibition in S. cerevisiae. Prion protein prevents Bax-mediated cell death. Prion protein overcomes Bax-mediated growth arrest in S phase but cannot overcome population growth inhibition because the cells then accumulate in G(2)/M phase. We conclude that prion protein does not require other Bcl-2 family proteins to protect against Bax-mediated cell death.     

The human DDX and DHX gene families of putative RNA helicases

Nucleic acid helicases are characterized by the presence of the helicase domain containing eight motifs. The sequence of the helicase domain is used to classify helicases into families. To identify members of the DEAD and DEAH families of human RNA helicases, we used the helicase domain sequences to search the nonredundant peptide sequence database. We report the identification of 36 and 14 members of the DEAD and DEAH families of putative RNA helicases, including several novel genes. The gene symbol DDX had been used previously for both DEAD- and DEAH-box families. We have now adopted DDX and DHX symbols to denote DEAD- and DEAH-box families, respectively. Members of human DDX and DHX families of putative RNA helicases play roles in differentiation and carcinogenesis.