A general upstream binding factor for genes of the yeast translational apparatus

A multi-component upstream activation sequence of the Saccharomyces cerevisiae glyceraldehyde-3-phosphate dehydrogenase gene promoter

The majority of the activation potential of the Saccharomyces cerevisiae TDH3 gene promoter is contained within nucleotides -676 to -381 (relative to the translation initiation codon). An upstream activation sequence (UAS) in this region has been characterized by in vitro and in vivo assays and demonstrated to be composed of two small, adjacent DNA sequence elements. The essential determinant of this upstream UAS is a general regulatory factor 1 (GRF1) binding site at nucleotides -513 to -501. A synthetic DNA element comprising this sequence, or an analogue in which two of the degenerate nucleotides of the GRF1 site consensus sequence were altered, activated 5' deleted TDH3 and CYC1 promoters. The second DNA element of the UAS is a 7 bp sequence which is conserved in the promoters of several yeast genes encoding glycolytic enzymes and occurs at positions -486 to -480 of the TDH3 promoter. This DNA sequence represents a novel promoter element: it contains no UAS activity itself, yet potentiates the activity of a GRF1 UAS. The potentiation of the GRF1 UAS by this element occurs when placed upstream from the TATA box of either the TDH3 or CYC1 promoters. The characteristics of this element (termed GPE for GRF1 site potentiator element) indicate that it represents a binding site for a different yeast protein which increases the promoter activation mediated by the GRF1 protein. Site-specific deletion and promoter reconstruction experiments suggest that the entire activation potential of the -676 to -381 region of the TDH3 gene promoter may be accounted for by a combination of the GRF1 site and the GPE.

The promoter of Saccharomyces cerevisiae FBA1 gene contains a single positive upstream regulatory element

The glycolytic enzyme fructose 1,6-bisphosphate aldolase is encoded by the FBA1 gene of Saccharomyces cerevisiae. Transcription of aldolase gene is not regulated by glucose and high levels of expression have been observed also during growth on nonfermentable carbon source. A FBA1::lacZ gene fusion was constructed and a deletion analysis demonstrated the presence of a unique cis-acting positive upstream element (UAS) required for high levels of FBA1 expression. This element is located between positions -550 and -440 upstream of the aldolase open reading frame and it contains sequences known to constitute the binding sites for the multifunctional proteins RAP1 and ABFI and two TTCC motifs.

Functional analysis of the promoter of the gene encoding the acidic ribosomal protein L45 in yeast

The gene encoding the acidic ribosomal protein L45 in yeast is expressed coordinately with other rp-genes. The promoter region of this gene harbours binding sites for CP1 and ABF1. We demonstrate that the CP1-site is not involved in the transcription activation of the L45-gene. Rather, the ABF1-site, through deviating from the consensus sequence (RTARY3N3ACG), appears to be essential for efficient transcription. Replacement of this site by a consensus RAP1-binding site (an RPG box) did not alter the transcriptional yield of the L45-gene. An additional transcription activating region is present downstream of the ABF1-site. The relevant nucleotide sequence, which is repeated in the L45-gene promoter, gives rise to complex formation with a yeast protein extract in a bandshift assay. The results indicate that the L45-gene promoter has a complex architecture.

Participation of ABF-1 protein in expression of the Saccharomyces cerevisiae CAR1 gene

DNA fragments previously shown to be required for expression of the CAR1 (arginase) gene in Saccharomyces cerevisiae and to support transcriptional activation of a reporter gene in a heterologous expression vector were shown to bind purified regulatory protein ABF-1. Two ABF-1 sites were identified in the CAR1 upstream region, one to which ABF-1 protein bound with high affinity and a second to which it bound much less avidly. The higher-affinity ABF-1 binding site upstream of CAR1 was an effective competitor of the HMRE, ARS1 B domain, and COR2-GFI binding sequences for protein binding. Point mutations in the CAR1 high-affinity ABF-1 binding site resulted in a 12-fold loss of transcriptional activation of a reporter gene compared with the wild-type CAR1 DNA fragment. These data are consistent with the suggestion that ABF-1 protein is one of the transcription factors involved in expression of the CAR1 gene.

Association of ribosomal subunits. A new functional role for yeast EF-1 alpha in protein biosynthesis

A yeast ribosomal subunit association factor (AF) has been purified from a high-salt ribosomal wash. The purified enzyme is a thermostable protein that associates ribosomal subunits at low Mg2+ concentration without requiring energy. It appears to be an aggregate of trimers or dimers (molecular mass 125 or 79 kDa) which on sodium dodecyl sulfate gels shows the presence of a major protein band whose estimated molecular mass is 43 kDa. Evidence also indicates the existence of a 50-kDa polypeptide which seems to be unstable since with freezing and thawing it gives rise to the 43-kDa polypeptide. It was shown that the labelled factor interacts with 80S ribosomes and with 40S ribosomal subunits. The purified polypeptide reacts with antibodies directed against EF-1 alpha, this last protein recognizing the antibodies raised against AF. Likewise, both EF-1 alpha and AF associate ribosomal subunits in the same way. When EF-1 is heated, it not only maintains its association activity, but also behaves like a 43-kDa polypeptide in an SDS electrophoresis run. These observations strongly suggest that AF originates from EF-1 alpha, which implies that the well-known elongation factor may also play a role in the initiation step of protein synthesis.

The organization and expression of the Saccharomyces cerevisiae L4 ribosomal protein genes and their identification as the homologues of the mammalian ribosomal protein gene L7a

A cDNA for the mouse ribosomal protein (rp) L7a, formerly called Surf-3, was used as a probe to isolate two homologous genes from Saccharomyces cerevisiae. The two yeast genes (L4-1 and L4-2) were identified as encoding S. cerevisiae L4 by 2D gel analysis of the product of the in vitro translation of hybrid-selected mRNA and additionally by direct amino acid sequencing. The DNA sequences of the two yeast genes were highly homologous (95%) over the 771 bp that encode the 256 amino acids of the coding regions but showed little homology outside the coding region. L4-1 differed from L4-2 by 7 out of the 256 amino acids in the coding region, which is the greatest divergence between the products of any two duplicated yeast ribosomal protein genes so far reported. There is strong homology between the mouse rpL7a/Surf-3 and the yeast L4 genes -57% at the nucleic acid level and also 57% at the amino acid level (though some regions reach as much as 80-90% homology). While most yeast ribosomal protein genes contain an intron in their 5' region both L4-1 and L4-2 are intronless. The mRNAs derived from each yeast gene contained heterogenous 5' and 3' ends but in each case the untranslated leaders were short. The L4-1 mRNA was found to be much more abundant than the L4-2 mRNA as assessed by cDNA and transcription analyses. Yeast cells containing a disruption of the L4-1 gene formed much smaller colonies than either wild-type or disrupted L4-2 strains. Disruption of both L4 genes is a lethal event, probably due to an inability to produce functional ribosomes.

Optimization of Bacillus alpha-amylase production by Saccharomyces cerevisiae

Production of Bacillus amyloliquefaciens alpha-amylase by Saccharomyces cerevisiae using the multicopy plasmid pAAH5 and ways of improving the yields of secreted enzyme were studied. In standard non-buffered medium, alpha-amylase was rapidly inactivated but stabilization of the pH at 6 led to stable accumulation of alpha-amylase in the culture medium. Removal of 1100 bp of the upstream sequence of the ADH1 promoter present on pAAH5 resulted in delayed but increased alpha-amylase production: 29-fold in selective medium, two-fold in non-selective medium. With the original ADH1 promoter, accumulation of alpha-amylase in the medium started to level off before the cultures reached stationary phase and was very low when exponentially growing cells were transferred from glucose to ethanol. This coincided with the appearance of a mRNA larger than the alpha-amylase messenger. With the shortened promoter, the normal-size alpha-amylase mRNA was detected under all growth conditions and alpha-amylase was efficiently secreted into the medium also late in stationary phase and after transfer to ethanol. Highest total yields of alpha-amylase were obtained with the short promoter in non-selective glucose-containing medium; this may be explained by the greater final cell density obtained. However, the production of alpha-amylase per cell mass was higher in ethanol-containing selective medium. Seventy to eighty per cent of the alpha-amylase activity was secreted into the medium independent of the total amount produced.

RAP1 protein activates and silences transcription of mating-type genes in yeast

RAP1 is a sequence-specific DNA-binding protein essential for cell growth. The occurrence of RAP1-binding sites in many promoter regions, the mating-type gene silencer elements, and telomeres suggests that RAP1 has multiple functions in the cell. To assess its role in transcription, temperature-sensitive mutations in RAP1 were generated. Analysis of rap1ts strains provides evidence that RAP1 functions in both transcriptional activation and silencing of mating-type genes. Several observations indicate that rap1ts strains are defective in the expression of MAT alpha, whose upstream activation sequence (UAS) contains a RAP1-binding site. At nonpermissive temperatures, decreases in MAT alpha steady-state transcript levels can be detected in MAT alpha rap1ts strains. Furthermore, these strains are deficient in alpha-pheromone production and simultaneously express at least two alpha-specific genes. These phenotypes can be reversed by replacing the RAP1-binding site at MAT alpha with a binding site for the GAL4 transcriptional activator. Certain rap1ts alleles have an opposite effect on the silent mating-type locus HMR, which becomes partially derepressed at nonpermissive temperatures.

Involvement of the silencer and UAS binding protein RAP1 in regulation of telomere length

The yeast protein RAP1, initially described as a transcriptional regulator, binds in vitro to sequences found in a number of seemingly unrelated genomic loci. These include the silencers at the transcriptionally repressed mating-type genes, the promoters of many genes important for cell growth, and the poly[(cytosine)1-3 adenine] [poly(C1-3A)] repeats of telomeres. Because RAP1 binds in vitro to the poly(C1-3A) repeats of telomeres, it has been suggested that RAP1 may be involved in telomere function in vivo. In order to test this hypothesis, the telomere tract lengths of yeast strains that contained conditionally lethal (ts) rap1 mutations were analyzed. Several rap1ts alleles reduced telomere length in a temperature-dependent manner. In addition, plasmids that contain small, synthetic telomeres with intact or mutant RAP1 binding sites were tested for their ability to function as substrates for poly(C1-3A) addition in vivo. Mutations in the RAP1 binding sites reduced the efficiency of the addition reaction.

TUF factor binds to the upstream region of the pyruvate decarboxylase structural gene (PDC1) of Saccharomyces cerevisiae

The upstream activation site of the pyruvate decarboxylase gene, PDC1, of Saccharomyces cerevisiae contains an RPG box, and mediates the increase in expression of a PDC1-lacZ fusion gene during growth on glucose. Oligonucleotide replacement experiments indicate that the RPG box functions as an absolute activator of expression, but other elements (possibly CTTCC repeats) are required for carbon source regulation, and maximal expression. Gel retardation and oligonucleotide competition experiments suggest that the DNA binding factor TUF interacts with the RPG box in the upstream region of PDC1. Binding of TUF factor is not carbon source dependent in in vitro experiments, and is probably not responsible for glucose induction of PDC1 expression.

Expression of translation initiation factor 4A from yeast and mouse in Saccharomyces cerevisiae

The eukaryotic translation initiation factor 4A (eIF-4A) plays an important role in regulating initiation. To analyze its function in yeast, we carried out a mutational analysis of the TIF1 and TIF2 genes, which encode eIF-4A. Expression of these two yeast genes has also been investigated at the transcriptional level and it has been found that both are expressed in wild-type yeast cells. Analysis of the expression of eIF-4A-beta-galactosidase fusion proteins reveals that the TIF2 gene is more highly expressed than the TIF1 gene. Interestingly, the yeast eIF-4A protein shows a high degree of amino acid sequence similarity to the mouse homologue. However, we find that the mammalian factor does not support protein synthesis in yeast either in vivo or in vitro.

Multifunctional DNA-binding proteins mediate concerted transcription activation of yeast ribosomal protein genes

Transcription activation of ribosomal protein genes (rp genes) in yeast is mediated through two different abundant transacting proteins, RAP1 and ABF1. These factors are multifunctional proteins playing a part in diverse cellular processes, all related to cellular growth.

An essential gene in Saccharomyces cerevisiae shares an upstream regulatory element with PRP4

ORF2 is an essential gene immediately upstream of PRP4 (formerly RNA4), a gene involved in nuclear mRNA processing in Saccharomyces cerevisiae. The two genes are arranged head-to-head. An 8 base-pair conserved sequence element is found upstream of both genes, as well as upstream of certain other genes that are known to be involved in pre-mRNA processing. Through deletion analysis we have found that both of the conserved sequence elements are important for transcription of both genes. We have cloned ORF2 and have isolated temperature-sensitive orf2 mutants. The phenotype of these mutants does not suggest a role for ORF2 in mRNA processing. The deduced amino acid sequence of ORF2 indicates significant similarity to DPR1, a gene encoding a protein that is involved in the carboxy-terminal processing of G-protein.

Efficient expression of the Saccharomyces cerevisiae glycolytic gene ADH1 is dependent upon a cis-acting regulatory element (UASRPG) found initially in genes encoding ribosomal proteins

The glycolytic form of alcohol dehydrogenase (ADHI) is encoded by the ADH1 gene of Saccharomyces cerevisiae. We found that efficient expression of the ADH1 gene requires a sequence between bp -635 and -615 with respect to the +1 mRNA start point; removal of this sequence reduced ADH1 mRNA levels 25-fold but did not affect carbon-source regulation. DNaseI footprinting analysis of the ADH1 promoter revealed the specific protection of a perfect match to UASRPG at -630 to -615. UASRPG is thought to be responsible for activation of transcription, via binding of the translation upstream factor (TUF), of genes encoding components of the translational apparatus. In band retardation assays, the promoters for the elongation factor 1 alpha-encoding genes (TEF1 and TEF2) competed for binding of the protein to the copy of UASRPG in the ADH1 promoter. We conclude that TUF is probably involved in activation of the bulk of ADH1 transcription. Further, we propose that TUF has a role in the activation of many or most glycolytic genes. If so, it is essential for efficient expression of a wide variety of functionally disparate products that are required by yeast cells for rapid growth.

Mutations in ADE3 reduce the efficiency of the omnipotent suppressor sup45-2

Mutations in a known yeast gene, ADE3, were shown to act as an antisuppressor, reducing the efficiency of the omnipotent suppressor, sup45-2. The ADE3 locus encodes the trifunctional enzyme C1-tetrahydrofolate synthase, which is required for the biosynthesis of purines, thymidylate, methionine, histidine, pantothenic acid and formylmethionyl-tRNA(fMet. The role of this enzyme in translational fidelity had not previously been suspected.

A yeast telomere binding activity binds to two related telomere sequence motifs and is indistinguishable from RAP1

Telomere Binding Activity (TBA), an abundant protein from Saccharomyces cerevisiae, was identified by its ability to bind to telomeric poly(C1-3A) sequence motifs. The substrate specificity of TBA has been analyzed in order to determine whether the activity binds to a unique structure assumed by the irregularly repeating telomeric sequences or whether the activity recognizes and binds to subset of specific sequences found within the telomere repeat tracts. Deletion analysis and DNase I protection assays demonstrate that TBA binds specifically to two poly-(C1-3A) sequences that differ by one nucleotide. The methylation of four guanine residues, located at identical relative positions within these two binding sequences, interferes with TBA binding to the substrates. A synthetic olignucleotide containing a single TBA binding site can function as a TBA binding substrate. The TBA binding site shares homology with the binding sites reported for the Repressor/Activator Protein 1 (RAP1), Translation Upshift Factor (TUF) and General Regulatory Factor (GRFI) transcription factors, and TBA binds directly to RAP1/TUF/GRFI substrate sequences. Yeast TBA preparations and the RAP1 gene product expressed in E. coli cells are both similarly sensitive to in vitro protease digestion. Affinity-purified TBA extracts include a protein indistinguishable from RAP1 in binding specificity, size, and antigenicity. The binding affinity of TBA for the two telomeric poly(C1-3A) binding sites is higher than its affinity for any of the other binding substrates used for its identification. In extracts of yeast spheroplasts prepared by incubation of yeast cells with Zymolyase, an altered, proteolyzed form, of TBA (TBA-S) is present. TBA-S has a faster mobility in gel retardation assays and SDS-PAGE gels, yet it retains the DNA binding properties of standard TBA preparations: it binds to RAP1/TUF/GRFI substrates with the same relative binding affinity and protects poly(C1-3A) tracts from DNase I digestion with a "footprint" identical to that of standard TBA preparations.

The gene family encoding the Arabidopsis thaliana translation elongation factor EF-1 alpha: molecular cloning, characterization and expression

The gene family encoding the Arabidopsis thaliana translation elongation factor (EF-1 alpha) was analysed. This family contains four genes (A1-A4) organized in a similar manner in different varieties of Arabidopsis. Based upon both their physical separation and a comparison of their sequences, it is suggested that the A4 gene and the A1, A2, and A3 genes constitute two distinct subfamilies within the genome. By introducing chimaeric gene constructs into Arabidopsis cells, we showed that the A1 gene promoter mediates a transient expression about twofold higher than that obtained using the CaMV 35 S promoter. This expression depends on a 348 bp DNA fragment extending from -982 to -634 bp upstream of the initiation codon. This element contains a characteristic telomeric sequence (AACCCTAA) which is also found in the promoters of the A2 and A4 genes as well as in the promoters of the Drosophila EF-1 alpha F1 gene and of several highly expressed plant genes.

Purification and characterization of a nuclear factor which binds specifically to the upstream activation sequence of Saccharomyces cerevisiae enolase 1 gene

The nuclear factor which specifically binds to the upstream activation sequence (UAS) of the enolase 1 gene (ENO1) of yeast Saccharomyces cerevisiae was purified by sequence-specific affinity chromatography. The purified factor gave two closely migrated bands at 32 kDa on SDS/PAGE. The binding activities were eluted from a gel filtration column at molecular masses of 110 kDa and 60 kDa, suggesting a dimeric and a tetrameric assembly of the factor in the native form. The region protected by the purified factor against deoxyribonuclease I digestion contained the sequence ACCCAAACACC which is highly similar to the consensus sequence present in the 5'-flanking region of the ribosomal protein genes (RPG box). We also identified the other factor specific to the ENO1 UAS which gave a single peak at a molecular mass of 120 kDa in gel filtration. We suggest the existence of multiple binding to the ENO1 UAS by at least two factors: one is the factor which we purified with a molecular mass of 32 kDa on SDS/PAGE and the other is the factor like RAP1 protein which generally recognizes the RPG-box-like sequence.

RAP-1 factor is necessary for DNA loop formation in vitro at the silent mating type locus HML

DNA fragments containing the silencers that flank the mating type genes at HML alpha are shown to bind specifically to the nuclear scaffold of yeast. The scaffold proteins are solubilized with urea and then renatured to form a soluble extract which allows reconstitution of sequence-specific DNA loops. At the silent mating type locus HML alpha, loops are formed by either silencer-silencer (E-I) interaction or silencer-promoter interactions (E-P and I-P). The nuclear protein RAP-1 fractionates efficiently with the nuclear scaffold, and binds to the E, I, and promoter regions. Affinity purification of RAP-1 and oligonucleotide competition show that RAP-1 is necessary for reconstitution of loops in vitro. These results are consistent with a model in which silencers define a chromatin loop within which occur modifications that maintain the promoter in an inactive state.

The Escherichia coli protein, Fis: specific binding to the ends of phage Mu DNA and modulation of phage growth

We show, using gel retardation, that crude Escherichia coli cell extracts contain a protein which binds specifically to DNA fragments carrying either end of the phage Mu genome. We have identified this protein as Fis, a factor involved in several site-specific recombinational switches. Furthermore, we show that induction of a Mucts62 prophage in a fis lysogen occurs at a lower temperature than that of a wild-type strain, and that spontaneous induction of Mucts62 is increased in the fis mutant. DNasel footprinting using either crude extracts or purified Fis indicate that binding on the left end of Mu occurs at a site which overlaps a weak transposase binding site. Thus, Fis may modulate Mu growth by influencing the binding of transposase, or other proteins, to the transposase binding site(s), in a way similar to its influence on Xis binding in phage lambda.

Mutational analysis of the upstream activation site of yeast ribosomal protein genes

Most ribosomal protein (rp-)genes in yeast are preceded by conserved sequence motifs that act as upstream transcription-activating sites (RPG box). These sequence elements have previously been shown to represent specific binding sites for a protein factor, TUF. Comparison of the various nucleotide elements identified so far indicates a remarkably high degree of variation in the respective sequences. On the other hand, a methylation interference study performed with one RPG box revealed close contact points with the TUF protein along the entire sequence. To investigate the sequence requirements of the RPG box, we inserted synthetic oligonucleotides that differed from the general consensus sequence ACACCCATACATTT at single positions into a deletion mutant of the L25 promoter that lacked its natural RPG elements. Transcription activity was estimated by Northern analyses of the cellular level of L25-galK hybrid transcripts. The results show that in the 3' part of this sequence element single substitutions are allowed at all positions, in the 5' part, however, the nucleotide requirements appear to be more stringent. In particular, the invariant C at position 5 of the consensus sequence is absolutely necessary for its enhancer function.

Cloning and sequence determination of the gene encoding the largest subunit of the fission yeast Schizosaccharomyces pombe RNA polymerase I

The gene encoding the largest subunit of RNA polymerase I (SPRPA190) was cloned from the fission yeast Schizosaccharomyces pombe by cross-hybridization with a probe containing part of the corresponding Saccharomyces cerevisiae gene RPA190. The SPRPA190 gene is present in a single copy per haploid genome and is essential for cell growth. The polypeptide encoded by this gene, as deduced from the nucleotide sequence of the uninterrupted coding frame, consists of 1689 amino acids and its calculated Mr is 189,300. The amino acid identity between the subunits of the two yeast species is 50%. Amino acid sequence conservation covers the regions previously suggested to be functionally important for the S. cerevisiae enzyme. In addition, two markedly hydrophilic regions recognized in the S. cerevisiae polypeptide can also be recognized in the S. pombe polypeptide in approximately the same positions, even though the amino acid sequences in these regions are diverged from each other. In the 5'-flanking region of the gene, several nucleotide sequence elements are detected which are also found in the two S. pombe ribosomal protein genes so far sequenced.

Nucleotide sequence of the SUP2 (SUP35) gene of Saccharomyces cerevisiae

A nucleotide sequence of the yeast Saccharomyces cerevisiae omnipotent suppressor SUP2 (SUP35) gene is presented. The sequence contains a single open reading frame (ORF) of 2055 bp, which may encode a 76.5-kDa protein. A single transcript of 2.3 kb corresponding to a complete ORF is found. Analysis of codon bias suggests that the SUP2 gene is not highly expressed. The C-terminal part of the deduced amino acid sequence shows a high homology to yeast elongation factor EF-1 alpha, whereas the N-terminal part is unique for the SUP2 protein. The N terminus contains a number of short repeating elements and possesses an unusual amino acid composition. Analysis of the nucleotide and deduced amino acid sequences indicates that three additional proteins could possibly be expressed, two of which might be initiated on internal ATG codons and a third might be formed by alternative splicing. One of these proteins is supposed to be imported into mitochondria. Possible functions of the SUP2 gene product(s), especially its putative activity as a soluble factor controlling the fidelity of translation, are discussed.

Structure of the mouse nucleolin gene. The complete sequence reveals that each RNA binding domain is encoded by two independent exons

Nucleolin is a multifunctional nucleolar protein involved in the synthesis, packaging and maturation of pre-rRNA in eukaryotic cells. We describe the molecular organization and complete sequence of the mouse nucleolin gene, the first higher eukaryotic gene encoding a protein that is both an RNA binding protein involved in rRNA processing and a specific nucleolar protein. The nucleolin gene extends over 9000 base-pairs and is split into 14 exons that encode the 706 amino acid residues of the protein. The promoter sequence is G + C-rich (67% G + C) with four G/C boxes, it lacks bona fide TATA and CAAT boxes and shows capping site heterogeneity. The existence of pyrimidine-rich motifs, similar to those found in the promoter of ribosomal protein genes, could be relevant to the co-regulation of genes whose products are involved in ribosome biogenesis. Nucleolin contains four RNA binding domains, each about 80 amino acid residues long, which include the 11-residue core ribonucleoprotein consensus motif. Each domain is encoded by two exons, with an intervening sequence interrupting the conserved core motif at roughly the same amino acid position. This latter result suggests that the RNA binding domains are composed of two independent subdomains, whose functions remain to be determined.

SUF12 suppressor protein of yeast. A fusion protein related to the EF-1 family of elongation factors

Mutations at the suf12 locus were isolated in Saccharomyces cerevisiae as extragenic suppressors of +1 frameshift mutations in glycine (GGX) and proline (CCX) codons, as well as UGA and UAG nonsense mutations. To identify the SUF12 function in translation and to understand the relationship between suf12-mediated misreading and translational frameshifting, we have isolated an SUF12+ clone from a centromeric plasmid library by complementation. SUF12+ is an essential, single-copy gene that is identical with the omnipotent suppressor gene SUP35+. The 2.3 x 10(3) base SUF12+ transcript contains an open reading frame sufficient to encode a 88 x 10(3) Mr protein. The pattern of codon usage and transcript abundance suggests that SUF12+ is not a highly expressed gene. The linear SUF12 amino acid sequence suggests that SUF12 has evolved as a fusion protein of unique N-terminal domains fused to domains that exhibit essentially co-linear homology to the EF-1 family of elongation factors. Beginning internally at amino acid 254, homology is more extensive between the SUF12 protein and EF-1 alpha of yeast (36% identity; 65% with conservative substitutions) than between EF-1 alpha of yeast and EF-Tu of Escherichia coli. The most extensive regions of SUF12/EF-1 alpha homology are those regions that have been conserved in the EF-1 family, including domains involved in GTP and tRNA binding. It is clear that SUF12 and EF-1 alpha are not functionally equivalent, since both are essential in vivo. The N-terminal domains of SUF12 are unique and may reflect, in part, the functional distinction between these proteins. These domains exhibit unusual amino acid composition and extensive repeated structure. The behavior of suf12-null/SUF12+ heterozygotes indicates that suf12 is co-dominantly expressed and suggests that suf12 allele-specific suppression may result from functionally distinct mutant proteins rather than variation in residual wild-type SUF12+ activity. We propose a model of suf12-mediated frameshift and nonsense suppression that is based on a primary defect in the normal process of codon recognition.

Purification and cloning of a DNA binding protein from yeast that binds to both silencer and activator elements

A DNA binding protein (RAP1, previously called SBF-E) has been shown to bind to putative regulatory sites at both yeast mating-type silencers, yet is not the product of genetically identified regulators of the silent loci. Here, we report the purification of RAP1 by DNA affinity chromatography, and the isolation of its gene from a lambda gt11 genomic library using antibodies raised against the protein. Disruption of the chromosomal copy of this gene is lethal. We show that RAP1 protein also binds in vitro to the upstream activation site (UAS) of MAT alpha and ribosomal protein genes. In addition, we show that two different UAS-associated RAP1 binding sites can substitute in vivo for a silencer binding site. Our results suggest that RAP1 may be a transcriptional regulator that can play a role in either repression or activation of transcription, depending upon the context of its binding site.

Transcriptional regulation in the yeast life cycle

The transition from haploid to diploid in homothallic yeast involves a defined sequence of events which are regulated at the level of transcription. Transcription factors encoded by SWI genes activate the HO endonuclease gene at a precise stage in the cell cycle of mother cells. The HO endonuclease initiates a transposition event which activates genes of the opposite mating type by causing them to move away from a silencer element. The activated mating type genes then regulate genes involved in cell signaling such as the mating type-specific pheromones and their receptors. Since HO is only activated in one of the sister cells after division (the mother), adjacent cells of opposite mating type are generated which respond to each others' secreted pheromones by inducing genes involved in conjugation. This leads to the formation of a diploid in which many of the genes involved in mating and mating-type switching become repressed due to the heterozygosity of the mating-type locus. This article summarizes what is known about these transcriptional controls and discusses possible parallels in higher eukaryotes.

Structural and putative regulatory sequences of the gene encoding ribosomal protein L25 in Candida utilis

Using a heterologous probe containing a fragment of the L25-gene from Saccharomyces carlsbergensis we have isolated a DNA-fragment of Candida utilis carrying the gene encoding ribosomal protein L25. This gene is present in a single copy on the C. utilis genome, though as two distinguishable alleles. Both alleles have been isolated and sequenced including their flanking regions. The nucleotide sequence of the amino acid coding region of the C. utilis gene turned out to be highly homologous (83%) to the L25-gene of S. carlsbergensis. At the protein level the degree of homology is about 87%. Codon usage in both organisms appears to be somewhat different. Just like the Saccharomyces gene, the L25 gene in C. utilis appears to be split in its 5th codon, though the identity of this codon has changed. Intron as well as 5'- and 3'-flanking sequences have almost completely diverged, with some notable exceptions. Of the intervening sequences the 5'- and 3'-splice sites as well as the putative lariat branch site are conserved. In the 5'-flanking region, at a distance of about 330 n from the initiation codon, a conserved nucleotide element is present that is very similar to the upstream transcription activation site previously found in front of the ribosomal protein genes in Saccharomyces.

Selective proteolysis defines two DNA binding domains in yeast transcription factor tau

Transcription of eukaryotic transfer RNA genes involves, as a primary event, the stable binding of a protein factor to the intragenic promoter. The internal control region is composed of two non-contiguous conserved sequence elements, the A and B blocks. These are variably spaced depending on the genes. tau, a large transcription factor purified from yeast cells, interacts with these two control elements as shown by DNase I footprinting, exonuclease digestion, dimethyl sulphate protection experiments and by analysis of point mutations. Here we used a limited proteolysis treatment to obtain a smaller form of tau with drastically altered DNA binding properties. A protease-resistant domain interacts solely with the B block region of tRNA genes.