Signals that produce 3' termini in CYC1 mRNA of the yeast Saccharomyces cerevisiae

Effects of sequence motifs in the yeast 3' untranslated region determined from massively parallel assays of random sequences

BACKGROUND

The 3' untranslated region (UTR) plays critical roles in determining the level of gene expression through effects on activities such as mRNA stability and translation. Functional elements within this region have largely been identified through analyses of native genes, which contain multiple co-evolved sequence features.

RESULTS

To explore the effects of 3' UTR sequence elements outside of native sequence contexts, we analyze hundreds of thousands of random 50-mers inserted into the 3' UTR of a reporter gene in the yeast Saccharomyces cerevisiae. We determine relative protein expression levels from the fitness of transformants in a growth selection. We find that the consensus 3' UTR efficiency element significantly boosts expression, independent of sequence context; on the other hand, the consensus positioning element has only a small effect on expression. Some sequence motifs that are binding sites for Puf proteins substantially increase expression in the library, despite these proteins generally being associated with post-transcriptional downregulation of native mRNAs. Our measurements also allow a systematic examination of the effects of point mutations within efficiency element motifs across diverse sequence backgrounds. These mutational scans reveal the relative in vivo importance of individual bases in the efficiency element, which likely reflects their roles in binding the Hrp1 protein involved in cleavage and polyadenylation.

CONCLUSIONS

The regulatory effects of some 3' UTR sequence features, like the efficiency element, are consistent regardless of sequence context. In contrast, the consequences of other 3' UTR features appear to be strongly dependent on their evolved context within native genes.

Systematic dissection of the sequence determinants of gene 3' end mediated expression control

The 3'end genomic region encodes a wide range of regulatory process including mRNA stability, 3' end processing and translation. Here, we systematically investigate the sequence determinants of 3' end mediated expression control by measuring the effect of 13,000 designed 3' end sequence variants on constitutive expression levels in yeast. By including a high resolution scanning mutagenesis of more than 200 native 3' end sequences in this designed set, we found that most mutations had only a mild effect on expression, and that the vast majority (~90%) of strongly effecting mutations localized to a single positive TA-rich element, similar to a previously described 3' end processing efficiency element, and resulted in up to ten-fold decrease in expression. Measurements of 3' UTR lengths revealed that these mutations result in mRNAs with aberrantly long 3'UTRs, confirming the role for this element in 3' end processing. Interestingly, we found that other sequence elements that were previously described in the literature to be part of the polyadenylation signal had a minor effect on expression. We further characterize the sequence specificities of the TA-rich element using additional synthetic 3' end sequences and show that its activity is sensitive to single base pair mutations and strongly depends on the A/T content of the surrounding sequences. Finally, using a computational model, we show that the strength of this element in native 3' end sequences can explain some of their measured expression variability (R = 0.41). Together, our results emphasize the importance of efficient 3' end processing for endogenous protein levels and contribute to an improved understanding of the sequence elements involved in this process.

Measurements of the impact of 3' end sequences on gene expression reveal wide range and sequence dependent effects

A full understanding of gene regulation requires an understanding of the contributions that the various regulatory regions have on gene expression. Although it is well established that sequences downstream of the main promoter can affect expression, our understanding of the scale of this effect and how it is encoded in the DNA is limited. Here, to measure the effect of native S. cerevisiae 3′ end sequences on expression, we constructed a library of 85 fluorescent reporter strains that differ only in their 3′ end region. Notably, despite being driven by the same strong promoter, our library spans a continuous twelve-fold range of expression values. These measurements correlate with endogenous mRNA levels, suggesting that the 3′ end contributes to constitutive differences in mRNA levels. We used deep sequencing to map the 3′UTR ends of our strains and show that determination of polyadenylation sites is intrinsic to the local 3′ end sequence. Polyadenylation mapping was followed by sequence analysis, we found that increased A/T content upstream of the main polyadenylation site correlates with higher expression, both in the library and genome-wide, suggesting that native genes differ by the encoded efficiency of 3′ end processing. Finally, we use single cells fluorescence measurements, in different promoter activation levels, to show that 3′ end sequences modulate protein expression dynamics differently than promoters, by predominantly affecting the size of protein production bursts as opposed to the frequency at which these bursts occur. Altogether, our results lead to a more complete understanding of gene regulation by demonstrating that 3′ end regions have a unique and sequence dependent effect on gene expression.

A basic question in gene expression is the relative contribution of different regulatory layers and genomic regions to the differences in protein levels. In this work we concentrated on the effect of 3′ end sequences. For this, we constructed a library of yeast strains that differ only by a native 3′ end region integrated downstream to a reported gene driven by a constant inducible promoter. Thus we could attribute all differences in reporter expression between the strains to the different 3′ end sequences. Interestingly, we found that despite being driven by the same strong, inducible promoter, our library spanned a wide and continuous range of expression levels of more than twelve-fold. As these measurements represent the sole effect of the 3′ end region, we quantify the contribution of these sequences to the variance in mRNA levels by comparing our measurements to endogenous mRNA levels. We follow by sequence analysis to find a simple sequence signature that correlates with expression. In addition, single cell analysis reveals distinct noise dynamics of 3′ end mediated differences in expression compared to different levels of promoter activation leading to a more complete understanding of gene expression which also incorporates the effect of these regions.

Signals for pre-mRNA cleavage and polyadenylation

Pre-mRNA cleavage and polyadenylation is an essential step for 3' end formation of almost all protein-coding transcripts in eukaryotes. The reaction, involving cleavage of nascent mRNA followed by addition of a polyadenylate or poly(A) tail, is controlled by cis-acting elements in the pre-mRNA surrounding the cleavage site. Experimental and bioinformatic studies in the past three decades have elucidated conserved and divergent elements across eukaryotes, from yeast to human. Here we review histories and current models of these elements in a broad range of species.

Validation of a new yeast-based reporter assay consisting of human estrogen receptors alpha/beta and coactivator SRC-1: application for detection of estrogenic activity in environmental samples

Endocrine disruptors are exogenous substances that act like hormones in the endocrine system and disrupt the physiologic function of endogenous hormones. In the present study, we established reporter yeast strains (Saccharomyces cerevisiae) expressing human estrogen receptors, ERalpha or ERbeta. These strains contain a reporter plasmid carrying an estrogen responsive element (ERE) upstream of the beta-galactosidase gene, and a plasmid expressing a steroid receptor coactivator, SRC-1e. Using these reporter strains, we demonstrated dose-dependent estrogenic activities of different categories of ligands, a natural hormone, 17beta-estradiol (E2); a synthetic drug, diethylstilbestrol (DES); phytoestrogens, genistein, daizein and emodin; and an environmental endocrine disrupter, bisphenol A. EC(50) values of E2 for ERalpha and ERbeta are 5.31 x 10(-10) and 5.85 x 10(-10) M, respectively. We also demonstrated that these yeasts were applicable for measuring estrogenic activities of environmental water samples. Most downstream sites of a river showed similar activity in both ERalpha and ERbeta assays. These yeast strains are useful and convenient for detecting and comparing the estrogenic ligand activities of environmental samples in response to ERalpha and ERbeta.

Competitive processivity-clamp usage by DNA polymerases during DNA replication and repair

Protein clamps are ubiquitous and essential components of DNA metabolic machineries, where they serve as mobile platforms that interact with a large variety of proteins. In this report we identify residues that are required for binding of the beta-clamp to DNA polymerase III of Escherichia coli, a polymerase of the Pol C family. We show that the alpha polymerase subunit of DNA polymerase III interacts with the beta-clamp via its extreme seven C-terminal residues, some of which are conserved. Moreover, interaction of Pol III with the clamp takes place at the same site as that of the delta-subunit of the clamp loader, providing the basis for a switch between the clamp loading machinery and the polymerase itself. Escherichia coli DNA polymerases I, II, IV and V (UmuC) interact with beta at the same site. Given the limited amounts of clamps in the cell, these results suggest that clamp binding may be competitive and regulated, and that the different polymerases may use the same clamp sequentially during replication and repair.

Variations in yeast 3'-processing cis-elements correlate with transcript stability

A large set of yeast mRNA 3'-processing regulatory sequences was analyzed statistically, revealing a systematic variation that correlates with measured mRNA stability. Transcripts with relatively short half-lives have a high frequency of inclusion of 3'-processing elements that include the core sequence of binding sites for the PUF proteins, which enhance mRNA turnover. These results suggest that regulatory sequence variation, typically modeled as random, could arise instead from the necessity or advantage of specifying multiple functions in a common sequence element.

A history of poly A sequences: from formation to factors to function

Biological polyadenylation, first recognized as an enzymatic activity, remained an orphan enzyme until poly A sequences were found on the 3' ends of eukarvotic mRNAs. Their presence in bacteria viruses and later in archeae (ref. 338) established their universality. The lack of compelling evidence for a specific function limited attention to their cellular formation. Eventually the newer techniques of molecular biology and development of accurate nuclear processing extracts showed 3' end formation to be a two-step process. Pre-mRNA was first cleaved endonucleolytically at a specific site that was followed by sequential addition of AMPs from ATP to the 3' hydroxyl group at the end of mRNA. The site of cleavage was specified by a conserved hexanucleotide, AAUAAA, from 10 to 30 nt upstream of this 3' end. Extensive purification of these two activities showed that more than 10 polypeptides were needed for mRNA 3' end formation. Most of these were in complexes involved in the cleavage step. Two of the best characterized are CstF and CPSF, while two other remain partially purified but essential. Oddly, the specific proteins involved in phosphodiester bond hydrolysis have yet to be identified. The polyadenylation step occurs within the complex of poly A polymerase and poly A-binding protein, PABII, that controls poly A length. That the cleavage complex, CPSF, is also required for this step attests to a tight coupling of the two steps of 3' and formation. The reaction reconstituted from these RNA-free purified factors correctly processes pre-mRNAs. Meaningful analysis of the role of poly A in mRNA metabolism or function was possible once quantities of these proteins most often over-expressed from cDNA clones became available. The large number needed for two simple reactions of an endonuclease, a polymerase and a sequence recognition factor, pointed to 3' end formation as a regulated process. Polyadenylation itself had appeared to require regulation in cases where two poly A sites were alternatively processed to produce mRNA coding for two different proteins. The 64-KDa subunit of CstF is now known to be a regulator of poly A site choice between two sites in the immunoglobulin heavy chain of B cells. In resting cells the site used favors the mRNA for a membrane-bound protein. Upon differentiation to plasma cells, an upstream site is used the produce a secreted form of the heavy chain. Poly A site choice in the calcitonin pre-mRNA involves splicing factors at a pseudo splice site in an intron downstream of the active poly site that interacts with cleavage factors for most tissues. The molecular basis for choice of the alternate site in neuronal tissue is unknown. Proteins needed for mRNA 3' end formation also participate in other RNA-processing reactions: cleavage factors bind to the C-terminal domain of RNA polymerase during transcription; splicing of 3' terminal exons is stimulated port of by cleavage factors that bind to splicing factors at 3' splice sites. nuclear ex mRNAs is linked to cleavage factors and requires the poly A II-binding protein. Most striking is the long-sought evidence for a role for poly A in translation in yeast where it provides the surface on which the poly A-binding protein assembles the factors needed for the initiation of translation. This adaptability of eukaryotic cells to use a sequence of low information content extends to bacteria where poly A serves as a site for assembly of an mRNA degradation complex in E. coli. Vaccinia virus creates mRNA poly A tails by a streamlined mechanism independent of cleavage that requires only two proteins that recognize unique poly A signals. Thus, in spite of 40 years of study of poly A sequences, this growing multiplicity of uses and even mechanisms of formation seem destined to continue.

Optimization of the expression of equistatin in Pichia pastoris

To improve the expression of equistatin, a proteinase inhibitor from the sea anemone Actinia equina, in the yeast Pichia pastoris, we prepared gene variants with yeast-preferred codon usage and lower repetitive AT and GC content. The full gene optimization approximately doubled the level of steady-state mRNA and protein accumulated in the culture medium. The removal of a short stretch of 12 additional nucleotides from the multiple cloning site (MCS) sequence in the vector pPIC9 had an enhancement effect similar to full gene optimization (factor 1.5) at the mRNA level. However, at the protein level, this increase was 4- to 10-fold. The optimized gene without the MCS sequence yielded 1.66 g/L active protein in a bioreactor and was purified by a new two-step procedure with a recovery of activity that was >95%. This production level constitutes an overall improvement of about 20-fold relative to our previously published results. The characteristics of the MCS sequence element are discussed in the light of its apparent ability to act as negative expression regulator.

The KlCYC1 gene, a downstream region for two differentially regulated transcripts

KlCYC1 encodes for cytochrome c in the yeast Kluyveromyces lactis and is transcribed in two mRNAs with different 3'-processing points. This is an uncommon transcription mechanism in yeast mRNAs. The 3' sequence encompassing the whole region that is needed to produce both mRNAs is analysed. We have determined identical processing points in K.lactis and in Saccharomyces cerevisiae cells transformed with KlCYC1; positions 698 and 1092 (with respect to the TAA) are the major polyadenylation points. This shows that the cis-elements present in the KlCYC1 3'-untranslated region (3'-UTR) direct a processing mechanism that has been conserved in yeast. In K. lactis there is a high predominance of the shorter transcript (1.14 kb) only at the initial logarithmic growth phase. Interestingly, this growth phase-dependent regulation of 3'-UTR processing is lost when the gene is expressed in S. cerevisiae.

Diazaborine treatment of Baker's yeast results in stabilization of aberrant mRNAs

Upon Northern blotting, Saccharomyces cerevisiae that was treated with diazaborine showed aberrant mRNAs that were extended at the 3'-end and terminated at secondary processing sites. These bands were also detected in untreated Deltaupf1, Deltaxrn1, and rat7-1 mutants. This finding demonstrates that the aberrant mRNAs also occur in untreated strains in small quantities and can reach the cytoplasm, where they are normally degraded by Xrn1p. Diazaborine treatment stabilizes these mRNAs. The detection of the aberrant bands in the untreated rat7-1 strain indicates that Rat7 is involved in quality control of RNA. The aberrant mRNAs were not detected after diazaborine treatment of a DRG1-1 mutant. Drg1p, a member of the family of AAA (ATPases associated with a variety of cellular activities) proteins, which are thought to represent specific chaperones, may be involved in the process of unfolding the mRNA-ribonucleoprotein complex or in the recognition of aberrant mRNA molecules in the cytoplasm.

Genomic detection of new yeast pre-mRNA 3'-end-processing signals

To investigate Saccharomyces cerevisiae 3'-end-processing signals, a set of 1352 unique pre-mRNA 3'-end-processing sites, corresponding to 861 different genes, was identified by alignment of expressed sequence tag sequences with the complete yeast genome. Nucleotide word frequencies in the vicinity of the cleavage sites were analyzed to reveal the signal element features. In addition to previously recognized processing signals, two previously uncharacterized components of the 3'-end-processing signal sequence were discovered, specifically a predominance of U-rich sequences located on either side of the cleavage site. One of these, the downstream U-rich signal, provides a further link between the 3'-end-processing mechanisms of yeast and higher eukaryotes. Analysis of the complete set of 3'-end-processing sites by means of a discrimination function supports a 'contextual' model in which the sum total effectiveness of the signals in all four elements determines whether or not processing occurs.

The yeast FBP1 poly(A) signal functions in both orientations and overlaps with a gene promoter

This report provides an analysis of a region of chromosome XII in which the FBP1 and YLR376c genes transcribe in the same direction. Our investigation indicates that the Saccharomyces cerevisiae FBP1 gene contains strong signals for polyadenylation and transcription termination in both orientations in vivo . A (TA)14 element plays a major role in directing polyadenylation in both orientations. While this region has four nonoverlapping copies of a TATATA hexanucleotide, which is a very potent polyadenylation efficiency element in yeast, it alone is not sufficient for full activation in the reverse orientation of a cluster of downstream poly(A) sites, and an additional upstream sequence is required. The putative RNA hairpin formed from the (TA)14 element is not involved in 3'-end formation. Surprisingly, deletion of the entire (TA)14 stretch affects transcription termination in the reverse orientation, in contrast to our previous results with the forward orientation, indicating that the transcription termination element operating in the reverse orientation has very different sequence requirements. Promoter elements for the YLR376c gene overlap with the signal for FBP1 3'-end formation. To our knowledge, this is the first time that overlapping of both types of regulatory signals has been found in two adjacent yeast genes.

Regulation of poly(A) site choice of several yeast mRNAs

Several yeast genes produce multiple transcripts with different 3'-ends. Of these, four genes are known to produce truncated transcripts that end within the coding sequence of longer transcripts: CBP1 , AEP2 / ATP13 , RNA14 and SIR1 . It has been shown that the level of the truncated CBP1 transcript increases during the switch to respiratory growth while that of the full-length transcript decreases. To determine whether this phenomenon is unique to CBP1 , northern analysis was used to determine whether the levels of other truncated transcripts are regulated similarly by carbon source. The levels of the shortest transcripts of AEP2 / ATP13 and RNA14 increased during respiration while the shortest SIR1 transcript remained constant. However, two longer SIR1 transcripts were regulated reciprocally by carbon source. Mapping the 3'-ends of each transcript by sequencing partial cDNA clones revealed multiple 3'-ends for each transcript. Examination of the sequences surrounding the 3'-ends of the induced transcripts failed to identify a consensus sequence but did reveal weak putative 3'-end formation signals in all of the transcripts. Similarly, no consensus sequence was found when the sequences surrounding the 3'-ends of the longest transcripts were compared, but again weak putative 3'-end formation signals were identified. These data are suggestive of carbon source regulation of alternative poly(A) site choice in yeast.

Transcription termination downstream of the Saccharomyces cerevisiae FBP1 [changed from FPB1] poly(A) site does not depend on efficient 3'end processing

Efficient transcription termination downstream of poly(A) sites has been shown to correlate with the strength of an upstream polyadenylation signal and the presence of a polymerase pause site. To further investigate the mechanism linking termination with 3'-end processing, we analyzed the cis-acting elements that contribute to these events in the Saccharomyces cerevisiae FBP1 gene. FBP1 has a complex polyadenylation signal, and at least three efficiency elements must be present for efficient processing. However, not all combinations of these elements are equally effective. This gene also shows a novel organization of sequence elements. A strong positioning element is located upstream, rather than downstream, of the efficiency elements, and functions to select the cleavage site in vitro and in vivo. Transcription run-on analysis indicated that termination occurs within 61 nt past the poly(A) site. Deletion of two UAUAUA-type efficiency elements greatly reduces polyadenylation in vivo and in vitro, but transcription termination is still efficient, implying that FBP1 termination signals may be distinct from those for polyadenylation. Alternatively, assembly of a partial, but nonfunctional, polyadenylation complex on the nascent transcript may be sufficient to cause termination.

Saccharomyces carlsbergensis contains two functional genes encoding the acyl-CoA binding protein, one similar to the ACB1 gene from S. cerevisiae and one identical to the ACB1 gene from S. monacensis

Saccharomyces carlsbergensis is an amphiploid, and it has previously been suggested that the genomes of S. carlsbergensis originate from S. cerevisiae and S. monacensis. We have cloned the ACB1 genes encoding the acyl-CoA binding protein (ACBP) from S. carlsbergensis, S. cerevisiae and S. monacensis. Two genes were found in S. carlsbergensis and named ACB1 type 1 and type 2, respectively. The type 1 gene is identical to the S. cerevisiae ACB1 gene except for three substitutions, one single base pair deletion and one double base pair insertion, all located in the promoter region. The type 2 gene is completely identical to the S. monacensis ACB1 gene. These findings substantiate the notion that S. carlsbergensis is a hybrid between S. cerevisiae and S. monacensis. Both ACB1 type 1 and type 2 are actively transcribed in S. carlsbergensis and transcription is initiated at sites identical to those used for transcriptional initiation of the ACB1 genes in S. cerevisiae and S. monacensis, respectively. Two polyadenylation sites, spaced 225 bp apart, are present in the S. cerevisiae ACB1 gene. The upstream polyadenylation site is used exclusively during exponential growth, whereas both sites are utilized during later stages of growth.

Molecular characterization of the glyceraldehyde-3-phosphate dehydrogenase gene of Phaffia rhodozyma

The glyceraldehyde-3-phosphate dehydrogenase (GPD; EC1.2.1.12)-encoding gene (gpd) was isolated from a genomic library of Phaffia rhodozyma CBS 6938. Unlike some other eukaryotic organisms the gpd gene is represented by a single copy in P. rhodozyma. The complete nucleotide sequence of the coding, as well as the flanking non-coding regions was determined. The nucleotide sequence of gpd predicted six introns and a polypeptide chain of 339 amino acids. The codon usage in the gpd gene of P. rhodozyma was highly biased and was significantly different from the codon usage in other yeasts. Phylogenetic analysis of different yeasts and filamentous asco- and basidiomycetes gpd sequences indicated that the gpd gene of P. rhodozyma forms a cluster with the corresponding genes of filamentous basidiomycetes.

Paralogous histidine biosynthetic genes: evolutionary analysis of the Saccharomyces cerevisiae HIS6 and HIS7 genes

The HIS6 gene from Saccharomyces cerevisiae strain YNN282 is able to complement both the S. cerevisiae his6 and the Escherichia coli hisA mutations. The cloning and the nucleotide sequence indicated that this gene encodes a putative phosphoribosyl-5-amino-1-phosphoribosyl-4-imidazolecarboxiamide isomerase (5' Pro-FAR isomerase, EC 5.3.1.16) of 261 amino acids, with a molecular weight of 29,554. The HIS6 gene product shares a significant degree of sequence similarity with the prokaryotic HisA proteins and HisF proteins, and with the C-terminal domain of the S. cerevisiae HIS7 protein (homologous to HisF), indicating that the yeast HIS6 and HIS7 genes are paralogous. Moreover, the HIS6 gene is organized into two homologous modules half the size of the entire gene, typical of all the known prokaryotic hisA and hisF genes. The structure of the yeast HIS6 gene supports the two-step evolutionary model suggested by Fani et al. (J. Mol. Evol. 1994; 38: 489-495) to explain the present-day hisA and hisF genes. According to this idea, the hisF gene originated from the duplication of an ancestral hisA gene which, in turn, was the result of an earlier gene elongation event involving an ancestral module half the size of the extant gene. Results reported in this paper also suggest that these two successive paralogous gene duplications took probably place in the early steps of molecular evolution of the histidine pathway, well before the diversification of the three domains, and that this pathway was one of the metabolic activities of the last common ancestor. The molecular evolution of the yeast HIS6 and HIS7 genes is also discussed.

A Candida albicans RAS-related gene (CaRSR1) is involved in budding, cell morphogenesis and hypha development

Candida albicans, the most important human fungal pathogen, is a dimorphic fungus that can grow either as a yeast or as a hyphal form in response to medium conditions. A RAS-related C. albicans gene (CaRSR1) was isolated as a suppressor of a cdc24ts bud-emergence mutation of the baker's yeast, Saccharomyces cerevisiae. The deduced protein encoded by CaRSR1 is 248 amino acids long and 56% identical to that encoded by the S. cerevisiae RSR1 (BUD1) gene. Disruption of CaRSR1 in C. albicans indicated that CaRSR1 is involved in both yeast and hypha development. In the yeast phase, CaRSR1 is required for normal (polar) bud site selection and is involved in cell morphogenesis; in the yeast-mycelial transition it is involved in germ tube emergence; and in the development of the hyphae it is involved in cell elongation. The disruption of CaRSR1 leads to reduced virulence in both heterozygote and homozygote disruptants in a dose-dependent manner. The reduced virulence can be attributed to the reduced germination and shorter hyphae resulting from the disruption of CaRSR1.

Enhancement of recombinant glucoamylase expression by introducing yeast GAL7 mRNA termination sequence

Glucoamylase gene (STA1) of Saccharomyces diastaticus was expressed in recombinant Saccharomyces cerevisiae systems. The yeast, GAL7 mRNA termination sequence, was introduced in the 3' noncoding region of the STA1 structural gene which was under the control of the SUC2 promoter and STA1 secretion signal sequence. This plasmid was named YEpSSG7 and was introduced into yeast S. cerevisiae MMY2 to construct recombinant S. cerevisiae MMY2SSG7. The GAL7 mRNA termination sequence enhanced the glucoamylase expression level by 3-5 times depending on the culture conditions compared to the result from the strain S. cerevisiae MMY2SUCSTA which did not contain the GAL7 mRNA termination sequence. Such an enhancement was not due to plasmid stability or plasmid copy number effects. Such an enhancement was primarily due to the fact that GAL7 mRNA termination sequence stabilized the STA1 mRNA 3' end.

Characterisation of 3' end formation of the yeast HIS3 mRNA

The nucleotide (nt) sequence of the 3' end of the yeast HIS3 mRNA was determined by PCR amplification of the 3' end. Analysis of 28 individual clones revealed that at least 13 distinct polyadenylation sites are present. The sites of polyadenylation are extremely heterogeneous and do not show any obvious similarity other than that they occur after pyrimidine residues in most cases. Most mutants carrying internal deletions of the 3' untranslated region (3' UTR) did not abolish 3' end formation and showed polyadenylation at normal sites. Deletion of a 90-nt region that contains an A+T-rich sequence close to the 3' end of the HIS3 coding sequence and a subset of processing sites resulted in a drastic reduction in the levels of full-length HIS3 mRNA and concomitant transcription past the normal HIS3 3' end. The 90-nt region appears to be sufficient to direct the formation of at least a subset of the HIS3 3' ends since mutants that carry deletions of flanking regions of this sequence show detectable levels of HIS3 mRNA. Spacing between the upstream A-T sequence and the site of processing is variable. In the light of the extreme heterogeneity of the sites, a possible mechanism for 3' processing is discussed.

Purification of the Saccharomyces cerevisiae cleavage/polyadenylation factor I. Separation into two components that are required for both cleavage and polyadenylation of mRNA 3' ends

The cleavage/polyadenylation factor I (CF I) is one of four factors required for mRNA 3' end formation in the yeast Saccharomyces cerevisiae. Here we describe the purification of CF I and its separation into two components, CF IA and CF IB. Both components are needed to reconstitute CF I activity in cleavage and poly(A) addition. CF IA consists of a complex of four polypeptides of 76, 70, 50, and 38 kDa, and CF IB is a single 73-kDa polypeptide. The 76- and 38-kDa subunits of CF IA correspond to the previously identified RNA14 and RNA15 proteins. The RNA14 protein, but not the 70- or 50-kDa proteins, coimmunoprecipitates with the RNA15 protein, indicating that RNA14 and RNA15 proteins exist in a tight complex. RNA15 is the only subunit of CF I that can be cross-linked to pre-mRNA.

A putative helicase, the SUA5, PMR1, tRNALys1 genes and four open reading frames have been detected in the DNA sequence of an 8.8 kb fragment of the left arm of chromosome VII of Saccharomyces cerevisiae

We report the sequence of an 8.8 kb segment of DNA from the left arm of chromosome VII of Saccharomyces cerevisiae. The sequence reveals seven open reading frames (ORFs) G1651, G1654, G1660, G1663, G1666, G1667 and G1669 greater than 100 amino acids in length and the tRNALys1 gene. ORF G1651 shows 100% identity with the ROK1 protein which is a putative RNA helicase of the 'DEAD box' protein family. ORF G1654 exhibits a motif highly conserved in ATP/GTP binding proteins generally referred to as 'P-loop'. From FastA analysis, G1660 and G1666 were found to be previously sequenced genes, respectively SUA5 and PMR1. The three other ORFs identified are partially (G1663) or completely (G1667 and G1669) overlapping with the PMR1 sequence on the complementary strand. This feature, together with their low codon adaptation indexes and the absence of significant homology with known proteins suggest that they do not correspond to real genes.

A near-upstream element in a plant polyadenylation signal consists of more than six nucleotides

A plant polyadenylation signal consists of three distinct components: a far-upstream element (FUE) that can control utilization of several polyadenylation sites, one or more near-upstream elements (NUEs) that control utilization of each site in a transcription unit, and polyadenylation site (CSs) themselves. NUEs have previously been suggested to be related to the mammalian polyadenylation signal AAUAAA. However, many plant genes do not contain AAUAAA-like motifs near their polyadenylation sites. To better understand the nature of NUEs, we conducted a systematic analysis of the NUE for one polyadenylation site (site 1) in the pea rbcS-E9 gene; this NUE lacks an AAUAAA motif. Linker substitution studies showed that the NUE for site 1 in this gene resides in the sequence AAAUGGAAA. Single-nucleotide substitutions in this domain had modest effects on the functioning of this NUE. Replacement of part of this sequence with the sequence AAUAAA increased the efficiency of this NUE. However, alteration of nucleotides immediately 3' of the AAUAAA reversed this effect. Our results indicate that the NUE for site 1 consists of as many as 9 nucleotides, that these 9 bases do not include an element that is intolerant of single base changes, that the sequence AAUAAA can function as a NUE for site 1, and that sequences flanking AAUAAA can affect the efficiency of functioning as a NUE.

The FIP1 gene encodes a component of a yeast pre-mRNA polyadenylation factor that directly interacts with poly(A) polymerase

We have identified an essential gene, called FIP1, encoding a 327 amino acid protein interacting with yeast poly(A) polymerase (PAP1) in the two-hybrid assay. Recombinant FIP1 protein forms a 1:1 complex with PAP1 in vitro. At 37 degrees C, a thermosensitive allele of FIP1 shows a shortening of poly(A) tails and a decrease in the steady-state level of actin transcripts. When assayed for 3'-end processing in vitro, fip1 mutant extracts exhibit normal cleavage activity, but fail to polyadenylate the upstream cleavage product. Polyadenylation activity is restored by adding polyadenylation factor I (PF I). Antibodies directed against FIP1 specifically recognize a polypeptide in these fractions. Coimmunoprecipitation experiments reveal that RNA14, a subunit of cleavage factor I (CF I), directly interacts with FIP1, but not with PAP1. We propose a model in which PF I tethers PAP1 to CF I, thereby conferring specificity to poly(A) polymerase for pre-mRNA substrates.

Cloning and characterization of an ATPase gene from Pneumocystis carinii which closely resembles fungal H+ ATPases

A gene encoding a P-type cation translocating ATPase was cloned from a genomic library of rat-derived Pneumocystis carinii. The nucleotide sequence of the gene contains a 2781 base-pair open reading frame that is predicted to encode a 101,401 dalton protein composed of 927 amino acids. The P. carinii ATPase protein (pcal) is 69-75% identical when compared with eight proton pumps from six fungal species. The Pneumocystis ATPase is less than 34% identical to ATPase proteins from protozoans, vertebrates or the Ca++ ATPases of yeast. The P. carinii ATPase contains 115 of 121 residues previously identified as characteristic of H+ ATPases. Alignment of the Pneumocystis and fungal proton pumps reveals five homologous domains specific for fungal H+ ATPases.

Saccharomyces cerevisiae mRNA 3' end forming signals are also involved in transcription termination

Previously, a 38-base-pair (bp) region in the 3' untranslated portion of the Saccharomyces cerevisiae iso-1-cytochrome c gene, was shown to be required for both normal CYC1 mRNA 3' end formation (Zaret and Sherman, 1982), and efficient transcription termination (Russo and Sherman, 1989). In another study, specific sequences such as TATATA, TACATA, and TAGTAGTA were shown to be involved in mRNA 3' end formation in S. cerevisiae (Russo et al., 1991). In this report, an in vivo plasmid stability assay has been utilized to show that these and related sequences are also involved in transcription termination, at varying efficiencies, and in an orientation-dependent manner. For example: the sequence TATATA appeared to terminate transcription almost as efficiently as the original wild type 38-bp region; whereas, the sequences TAGATATATGTAA and TACATA were less efficient, and TTTTTTTATA had little, if any, transcription termination function. In contrast, none of these sequences appeared to terminate transcription in the reverse orientation. Therefore, it appears that certain sequence signals capable of promoting mRNA 3' end formation in yeast, are also directly involved in transcription termination.

Identification and characterization of myophilin, a muscle-specific antigen of Echinococcus granulosus

A muscle-specific gene of Echinococcus granulosus has been identified and characterized. A lambda gt11 clone (10P1), containing an incomplete copy of the gene, was originally isolated from a larval E. granulosus cDNA library by serum antibodies from dogs infected with the parasite. The full-length cDNA sequence was obtained by PCR amplification of cDNA from an adult E. granulosus lambda gt22A library. Southern blot analysis indicated the presence of the gene as a single copy in the genome of E. granulosus and also detected homologous genes in genomic DNA of E. multilocularis and Taenia saginata. The 21.2-kDa protein deduced from the complete cDNA sequence contains two regions of 12 amino acids with similarity to the EF-hand motif of calcium binding proteins. Antibodies raised against the purified 10P1-GST fusion protein detected a 22-kDa antigen in the E. granulosus developmental stages examined. Immunoelectron microscopy localized the native protein in the muscle of the parasite. The amino-acid sequence of the E. granulosus protein shows significant homology to the muscle proteins mp20 of Drosophila melanogaster, chicken SM22 alpha and mammalian calponin, and also to the neuronal protein NP25 of rats. A conserved carboxy-terminal motif of 17 amino acids is present in all the homologous proteins and is proposed to be the characteristic feature of a novel protein family. The term myophilin is proposed for the E. granulosus protein due to its localization and homology to other muscle proteins.