Identification of ten genes that control ribosome formation in yeast

Broad variation in response of individual introns to splicing inhibitors in a humanized yeast strain

Intron branchpoint (BP) recognition by the U2 snRNP is a critical step of splicing, vulnerable to recurrent cancer mutations and bacterial natural product inhibitors. The BP binds a conserved pocket in the SF3B1 (human) or Hsh155 (yeast) U2 snRNP protein. Amino acids that line this pocket affect the binding of splicing inhibitors like Pladienolide-B (Plad-B), such that organisms differ in their sensitivity. To study the mechanism of splicing inhibitor action in a simplified system, we modified the naturally Plad-B resistant yeast Saccharomyces cerevisiae by changing 14 amino acids in the Hsh155 BP pocket to those from human. This humanized yeast grows normally, and splicing is largely unaffected by the mutation. Splicing is inhibited within minutes after the addition of Plad-B, and different introns appear inhibited to different extents. Intron-specific inhibition differences are also observed during cotranscriptional splicing in Plad-B using single-molecule intron tracking to minimize gene-specific transcription and decay rates that cloud estimates of inhibition by standard RNA-seq. Comparison of Plad-B intron sensitivities to those of the structurally distinct inhibitor Thailanstatin-A reveals intron-specific differences in sensitivity to different compounds. This work exposes a complex relationship between the binding of different members of this class of inhibitors to the spliceosome and intron-specific rates of BP recognition and catalysis. Introns with variant BP sequences seem particularly sensitive, echoing observations from mammalian cells, where monitoring individual introns is complicated by multi-intron gene architecture and alternative splicing. The compact yeast system may hasten the characterization of splicing inhibitors, accelerating improvements in selectivity and therapeutic efficacy.

Pre-mRNA Splicing in the Nuclear Landscape

Eukaryotic gene expression requires the cumulative activity of multiple molecular machines to synthesize and process newly transcribed pre-messenger RNA. Introns, the noncoding regions in pre-mRNA, must be removed by the spliceosome, which assembles on the pre-mRNA as it is transcribed by RNA polymerase II (Pol II). The assembly and activity of the spliceosome can be modulated by features including the speed of transcription elongation, chromatin, post-translational modifications of Pol II and histone tails, and other RNA processing events like 5'-end capping. Here, we review recent work that has revealed cooperation and coordination among co-transcriptional processing events and speculate on new avenues of research. We anticipate new mechanistic insights capable of unraveling the relative contribution of coupled processing to gene expression.

Detection of splice isoforms and rare intermediates using multiplexed primer extension sequencing

Targeted RNA-sequencing aims to focus coverage on areas of interest that are inadequately sampled in standard RNA-sequencing experiments. Here we present a novel approach for targeted RNA-sequencing that uses complex pools of reverse transcription primers to enable sequencing enrichment at user-selected locations across the genome. We demonstrate this approach by targeting hundreds to thousands of pre-mRNA splice junctions, revealing high-precision detection of splice isoforms, including rare pre-mRNA splicing intermediates.

Molecular Mechanism and Evolution of Nuclear Pre-mRNA and Group II Intron Splicing: Insights from Cryo-Electron Microscopy Structures

Nuclear pre-mRNA splicing and group II intron self-splicing both proceed by two-step transesterification reactions via a lariat intron intermediate. Recently determined cryo-electron microscopy (cryo-EM) structures of catalytically active spliceosomes revealed the RNA-based catalytic core and showed how pre-mRNA substrates and reaction products are positioned in the active site. These findings highlight a strong structural similarity to the group II intron active site, strengthening the notion that group II introns and spliceosomes evolved from a common ancestor. Prp8, the largest and most conserved protein in the spliceosome, cradles the active site RNA. Prp8 and group II intron maturase have a similar domain architecture, suggesting that they also share a common evolutionary origin. The interactions between maturase and key group II intron RNA elements, such as the exon-binding loop and domains V and VI, are recapitulated in the interactions between Prp8 and key elements in the spliceosome's catalytic RNA core. Structural comparisons suggest that the extensive RNA scaffold of the group II intron was gradually replaced by proteins as the spliceosome evolved. A plausible model of spliceosome evolution is discussed.

Studying structure and function of spliceosomal helicases

The splicing of eukaryotic precursor mRNAs requires the activity of at least three DEAD-box helicases, one Ski2-like helicase and four DEAH-box helicases. High resolution structures for five of these spliceosomal helicases were obtained by means of X-ray crystallography. Additional low resolution structural information could be derived from single particle cryo electron microscopy and small angle X-ray scattering. The functional characterization includes biochemical methods to measure the ATPase and helicase activities. This review gives an overview on the techniques used to gain insights in to the structure and function of spliceosomal helicases.

Workflow for Genome-Wide Determination of Pre-mRNA Splicing Efficiency from Yeast RNA-seq Data

Pre-mRNA splicing represents an important regulatory layer of eukaryotic gene expression. In the simple budding yeast Saccharomyces cerevisiae, about one-third of all mRNA molecules undergo splicing, and splicing efficiency is tightly regulated, for example, during meiotic differentiation. S. cerevisiae features a streamlined, evolutionarily highly conserved splicing machinery and serves as a favourite model for studies of various aspects of splicing. RNA-seq represents a robust, versatile, and affordable technique for transcriptome interrogation, which can also be used to study splicing efficiency. However, convenient bioinformatics tools for the analysis of splicing efficiency from yeast RNA-seq data are lacking. We present a complete workflow for the calculation of genome-wide splicing efficiency in S. cerevisiae using strand-specific RNA-seq data. Our pipeline takes sequencing reads in the FASTQ format and provides splicing efficiency values for the 5′ and 3′ splice junctions of each intron. The pipeline is based on up-to-date open-source software tools and requires very limited input from the user. We provide all relevant scripts in a ready-to-use form. We demonstrate the functionality of the workflow using RNA-seq datasets from three spliceosome mutants. The workflow should prove useful for studies of yeast splicing mutants or of regulated splicing, for example, under specific growth conditions.

Forty-five years of cell-cycle genetics

In the early 1970s, studies in Leland Hartwell’s laboratory at the University of Washington launched the genetic analysis of the eukaryotic cell cycle and set the path that has led to our modern understanding of this centrally important process. This 45th-anniversary Retrospective reviews the steps by which the project took shape, the atmosphere in which this happened, and the possible morals for modern times. It also provides an up-to-date look at the 35 original CDC genes and their human homologues.

Using yeast genetics to study splicing mechanisms

Pre-mRNA splicing is a critical step in eukaryotic gene expression, which involves removal of noncoding intron sequences from pre-mRNA and ligation of the remaining exon sequences to make a mature message. Splicing is carried out by a large ribonucleoprotein complex called the spliceosome. Since the first description of the pre-mRNA splicing reaction in the 1970s, elegant genetic and biochemical studies have revealed that the enzyme that catalyzes the reaction, the spliceosome, is an exquisitely dynamic macromolecular machine, and its RNA and protein components undergo highly ordered, tightly coordinated rearrangements in order to carry out intron recognition and splicing catalysis. Studies using the genetically tractable unicellular eukaryote budding yeast (Saccharomyces cerevisiae) have played an instrumental role in deciphering splicing mechanisms. In this chapter, we discuss how yeast genetics has been used to deepen our understanding of the mechanism of splicing and explore the potential for future mechanistic insights using S. cerevisiae as an experimental tool.

A quantitative, high-throughput reverse genetic screen reveals novel connections between Pre-mRNA splicing and 5' and 3' end transcript determinants

Here we present the development and implementation of a genome-wide reverse genetic screen in the budding yeast, Saccharomyces cerevisiae, that couples high-throughput strain growth, robotic RNA isolation and cDNA synthesis, and quantitative PCR to allow for a robust determination of the level of nearly any cellular RNA in the background of ~5,500 different mutants. As an initial test of this approach, we sought to identify the full complement of factors that impact pre-mRNA splicing. Increasing lines of evidence suggest a relationship between pre-mRNA splicing and other cellular pathways including chromatin remodeling, transcription, and 3' end processing, yet in many cases the specific proteins responsible for functionally connecting these pathways remain unclear. Moreover, it is unclear whether all pathways that are coupled to splicing have been identified. As expected, our approach sensitively detects pre-mRNA accumulation in the vast majority of strains containing mutations in known splicing factors. Remarkably, however, several additional candidates were found to cause increases in pre-mRNA levels similar to that seen for canonical splicing mutants, none of which had previously been implicated in the splicing pathway. Instead, several of these factors have been previously implicated to play roles in chromatin remodeling, 3' end processing, and other novel categories. Further analysis of these factors using splicing-sensitive microarrays confirms that deletion of Bdf1, a factor that links transcription initiation and chromatin remodeling, leads to a global splicing defect, providing evidence for a novel connection between pre-mRNA splicing and this component of the SWR1 complex. By contrast, mutations in 3' end processing factors such as Cft2 and Yth1 also result in pre-mRNA splicing defects, although only for a subset of transcripts, suggesting that spliceosome assembly in S. cerevisiae may more closely resemble mammalian models of exon-definition. More broadly, our work demonstrates the capacity of this approach to identify novel regulators of various cellular RNAs.

Reduction in ribosomal protein synthesis is sufficient to explain major effects on ribosome production after short-term TOR inactivation in Saccharomyces cerevisiae

Ribosome synthesis depends on nutrient availability, sensed by the target of rapamycin (TOR) signaling pathway in eukaryotes. TOR inactivation affects ribosome biogenesis at the level of rRNA gene transcription, expression of ribosomal proteins (r-proteins) and biogenesis factors, preribosome processing, and transport. Here, we demonstrate that upon TOR inactivation, levels of newly synthesized ribosomal subunits drop drastically before the integrity of the RNA polymerase I apparatus is severely impaired but in good correlation with a sharp decrease in r-protein production. Inhibition of translation by cycloheximide mimics the rRNA maturation defect observed immediately after TOR inactivation. Both cycloheximide addition and the depletion of individual r-proteins also reproduce TOR-dependent nucleolar entrapment of specific ribosomal precursor complexes. We suggest that shortage of newly synthesized r-proteins after short-term TOR inactivation is sufficient to explain most of the observed effects on ribosome production.

Prp8 protein: at the heart of the spliceosome

Pre-messenger RNA (pre-mRNA) splicing is a central step in gene expression. Lying between transcription and protein synthesis, pre-mRNA splicing removes sequences (introns) that would otherwise disrupt the coding potential of intron-containing transcripts. This process takes place in the nucleus, catalyzed by a large RNA-protein complex called the spliceosome. Prp8p, one of the largest and most highly conserved of nuclear proteins, occupies a central position in the catalytic core of the spliceosome, and has been implicated in several crucial molecular rearrangements that occur there. Recently, Prp8p has also come under the spotlight for its role in the inherited human disease, Retinitis Pigmentosa.Prp8 is unique, having no obvious homology to other proteins; however, using bioinformatical analysis we reveal the presence of a conserved RNA recognition motif (RRM), an MPN/JAB domain and a putative nuclear localization signal (NLS). Here, we review biochemical and genetical data, mostly related to the human and yeast proteins, that describe Prp8's central role within the spliceosome and its molecular interactions during spliceosome formation, as splicing proceeds, and in post-splicing complexes.

Multiple mechanisms regulate expression of low temperature responsive (LOT) genes in Saccharomyces cerevisiae

Using cDNA subtraction screening, we identified five Saccharomyces cerevisiae genes whose expressions is up-regulated when culture temperature was down-shifted from 30 to 10 degrees C. Among these LOT (low temperature-responsive) genes, three (LOT1, LOT2, and LOT3) were identical to FBA1, RPL2B, and NOP1, encoding a fructose biphosphate aldolase, a ribosomal protein L2B, and a nucleolar protein for rRNA processing, respectively. No functions were assigned for LOT5 and LOT6, which are identical to YKL183w and YLR011w, respectively. Northern hybridization analysis revealed that these genes are not uniformly regulated in response to the change of growth temperature. In addition, all the LOT genes, except for LOT1/FBA1, were induced by a low concentration of cycloheximide. The data indicate that multiple mechanisms, including translational functionality may be involved in the regulation of LOT gene expression in yeast.

A link between secretion and pre-mRNA processing defects in Saccharomyces cerevisiae and the identification of a novel splicing gene, RSE1

Secretory proteins in eukaryotic cells are transported to the cell surface via the endoplasmic reticulum (ER) and the Golgi apparatus by membrane-bounded vesicles. We screened a collection of temperature-sensitive mutants of Saccharomyces cerevisiae for defects in ER-to-Golgi transport. Two of the genes identified in this screen were PRP2, which encodes a known pre-mRNA splicing factor, and RSE1, a novel gene that we show to be important for pre-mRNA splicing. Both prp2-13 and rse1-1 mutants accumulate the ER forms of invertase and the vacuolar protease CPY at restrictive temperature. The secretion defect in each mutant can be suppressed by increasing the amount of SAR1, which encodes a small GTPase essential for COPII vesicle formation from the ER, or by deleting the intron from the SAR1 gene. These data indicate that a failure to splice SAR1 pre-mRNA is the specific cause of the secretion defects in prp2-13 and rse1-1. Moreover, these data imply that Sar1p is a limiting component of the ER-to-Golgi transport machinery and suggest a way that secretory pathway function might be coordinated with the amount of gene expression in a cell.

Cold shock and adaptation

Adaptation to environmental stresses, such as temperature fluctuation, is essential for the survival of all living organisms. Cellular responses in both prokaryotes and eukaryotes to high temperature include the synthesis of a set of highly conserved proteins known as the heat shock proteins. In contrast to the heat shock response, adaptation to low temperatures has not been as extensively studied. However, a family of cold-inducible proteins is evident in prokaryotes. In addition, most organisms have developed adaptive mechanisms that alter both membrane fluidity and the protein translation machinery at low temperature. This review addresses the different adaptive mechanisms used by a variety of organisms with a focus on the molecular mechanisms of cold adaptation that have recently been identified during the cold shock response in Escherichia coli.

Identification of novel genes required for yeast pre-mRNA splicing by means of cold-sensitive mutations

Genetic approaches in Saccharomyces cerevisiae have identified 38 genes required for efficient RNA splicing. The majority have been found by screening (high) temperature-sensitive (ts) mutants for those defective in splicing, an approach limited by the presence of ts hotspots and by the fact that many essential genes rarely mutate to the ts phenotype. To identify novel genes, we screened a collection of 340 cold-sensitive (cs) mutants for those that exhibited diminished splicing of several pre-mRNAs. We isolated 12 mutants in nine complementation groups. Four of these affected known genes (PRP8, PRP16, PRP22, PRP28), three of which encode RNA helicase homologues. Five genes are novel (BRR1, BRR2, BRR3, BRR4, BRR5; Bad Response to Refrigeration); mutations in these genes inhibited splicing before the first chemical step of the reaction. Analysis of BRR2 revealed it to encode an essential member of a new class of RNA helicase-like proteins that includes the yeast antiviral protein Ski2. These data validate the use of cs mutants in genetic screens and raise the possibility that RNA helicase family members are particularly prone to mutation to cold sensitivity.

The PRP31 gene encodes a novel protein required for pre-mRNA splicing in Saccharomyces cerevisiae

The pre-mRNA splicing factor Prp31p was identified in a screen of temperature-sensitive yeast strains for those exhibiting a splicing defect upon shift to the non- permissive temperature. The wild-type PRP31 gene was cloned and shown to be essential for cell viability. The PRP31 gene is predicted to encode a 60 kDa polypeptide. No similarities with other known splicing factors or motifs indicative of protein-protein or RNA-protein interaction domains are discernible in the predicted amino acid sequence. A PRP31 allele bearing a triple repeat of the hemagglutinin epitope has been generated. The tagged protein is functional in vivo and a single polypeptide species of the predicted size was detected by Western analysis with proteins from yeast cell extracts. Functional Prp31p is required for the processing of pre-mRNA species both in vivo and in vitro, indicating that the protein is directly involved in the splicing pathway.

Six novel genes necessary for pre-mRNA splicing in Saccharomyces cerevisiae

We have identified six new genes whose products are necessary for the splicing of nuclear pre-mRNA in the yeast Saccharomyces cerevisiae. A collection of 426 temperature-sensitive yeast strains was generated by EMS mutagenesis. These mutants were screened for pre-mRNA splicing defects by an RNA gel blot assay, using the intron- containing CRY1 and ACT1 genes as hybridization probes. We identified 20 temperature-sensitive mutants defective in pre-mRNA splicing. Twelve appear to be allelic to the previously identified prp2, prp3, prp6, prp16/prp23, prp18, prp19 or prp26 mutations that cause defects in spliceosome assembly or the first or second step of splicing. One is allelic to SNR14 encoding U4 snRNA. Six new complementation groups, prp29-prp34, were identified. Each of these mutants accumulates unspliced pre-mRNA at 37 degrees C and thus is blocked in spliceosome assembly or early steps of pre-mRNA splicing before the first cleavage and ligation reaction. The prp29 mutation is suppressed by multicopy PRP2 and displays incomplete patterns of complementation with prp2 alleles, suggesting that the PRP29 gene product may interact with that of PRP2. There are now at least 42 different gene products, including the five spliceosomal snRNAs and 37 different proteins that are necessary for pre-mRNA splicing in Saccharomyces cerevisiae. However, the number of yeast genes identifiable by this approach has not yet been exhausted.

An extragenic suppressor of prp24-1 defines genetic interaction between PRP24 and PRP21 gene products of Saccharomyces cerevisiae

The temperature-sensitive prp24-1 mutation defines a gene product required for the first step in pre-mRNA splicing. PRP24 is probably a component of the U6 snRNP particle. We have applied genetic reversion analysis to identify proteins that interact with PRP24. Spontaneous revertants of the temperature-sensitive (ts)prp24-1 phenotype were analyzed for those that are due to extragenic suppression. We then extended our analysis to screen for suppressors that confer a distinct conditional phenotype. We have identified a temperature-sensitive extragenic suppressor, which was shown by genetic complementation analysis to be allelic to prp21-1. This suppressor, prp21-2, accumulates pre-mRNA at the non-permissive temperature, a phenotype similar to that of prp21-1. prp21-2 completely suppresses the splicing defect and restores in vivo levels of the U6 snRNA in the prp24-1 strain. Genetic analysis of the suppressor showed that prp21-2 is not a bypass suppressor of prp24-1. The suppression of prp24-1 by prp21-2 is gene specific and also allele specific with respect to both the loci. Genetic interactions with other components of the pre-spliceosome have also been studied. Our results indicate an interaction between PRP21, a component of the U2 snRNP, and PRP24, a component of the U6 snRNP. These results substantiate other data showing U2-U6 snRNA interactions.

The budding yeast U5 snRNP Prp8 is a highly conserved protein which links RNA splicing with cell cycle progression

The dbf3 mutation was originally obtained in a screen for DNA synthesis mutants with a cell cycle phenotype in the budding yeast Saccharomyces cerevisiae. We have now isolated the DBF3 gene and found it to be an essential gene with an ORF of 7239 nucleotides, potentially encoding a large protein of 268 kDa. We also obtained an allele-specific high copy number suppressor of the dbf3-1 allele, encoded by the known SSB1 gene, a member of the Hsp70 family of heat shock proteins. The sequence of the Dbf3 protein is 58% identical over 2300 amino acid residues to a predicted protein from Caenorhabditis elegans. Furthermore, partial sequences with 61% amino acid sequence identity were deduced from two files of human cDNA in the EST nucleotide database so that Dbf3 is a highly conserved protein. The nucleotide sequence of DBF3 turned out to be identical to the yeast gene PRP8, which encodes a U5 snRNP required for pre-mRNA splicing. This surprising result led us to further characterise the phenotype of dbf3 which confirmed its role in the cell cycle and showed it to function early, around the time of S phase. This data suggests a hitherto unexpected link between pre-mRNA splicing and the cell cycle.

Isolation and characterization of Saccharomyces cerevisiae mRNA transport-defective (mtr) mutants

To understand the mechanisms of mRNA transport in eukaryotes, we have isolated Saccharomyces cerevisiae temperature-sensitive (ts) mutants which accumulate poly(A)+ RNA in the nucleus at the restrictive temperature. A total of 21 recessive mutants were isolated and classified into 16 complementation groups. Backcrossed mRNA transport-defective strains from each complementation group have been analyzed. A strain which is ts for heat shock transcription factor was also analyzed since it also shows nuclear accumulation of poly(A)+ RNA at 37 degrees C. At 37 degrees C the mRNA of each mutant is characterized by atypically long polyA tails. Unlike ts pre-mRNA splicing mutants, these strains do not interrupt splicing of pre-mRNA at 37 degrees C; however four strains accumulate oversized RNA polymerase II transcripts. Some show inhibition of rRNA processing and a further subset of these strains is also characterized by inhibition of tRNA maturation. Several strains accumulate nuclear proteins in the cytoplasm when incubated at semipermissive temperature. Remarkably, many strains exhibit nucleolar fragmentation or enlargement at the restrictive temperature. Most strains show dramatic ultrastructural alterations of the nucleoplasm or nuclear membrane. Distinct mutants accumulate poly(A)+ RNA in characteristic patterns in the nucleus.

Mutational analysis of the PRP4 protein of Saccharomyces cerevisiae suggests domain structure and snRNP interactions

The PRP4 protein of Saccharomyces cerevisiae is an essential part of the U4/U6 snRNP, a component of the mRNA splicing apparatus. As an approach to the determination of structure-function relationships in the PRP4 protein, we have isolated more than fifty new alleles of the PRP4 gene through random and site-directed mutagenesis, and have analyzed the phenotypes of many of them. Twelve of the fourteen single-point mutations that give rise to temperature-sensitive (ts) or null phenotypes are located in the portion of the PRP4 gene that corresponds to the beta-transducin-like region of the protein; the remaining two are located in the central portion of the gene, one of them in an arginine-lysine-rich region. Nine additional deletion or deletion/insertion mutations were isolated at both the amino- and carboxy-termini. These data show that the amino-terminal region (108 amino acids) of PRP4 is non-essential, while the carboxy-terminal region is essential up to the penultimate amino acid. A deletion of one entire beta-transducin-like repeat (the third of five) resulted in a null phenotype. All ts mutants show a first-step defect in the splicing of U3 snRNA primary transcript in vivo at the non-permissive temperature. The effects on prp4 mutant growth of increased copy-number of mutant prp4 genes themselves, and of genes for other components of the U4/U6 snRNP (PRP3 and U6 snRNA) have also been studied. We suggest that the PRP4 protein has at least three domains: a non-essential amino-terminal segment of at least 108 amino acids, a central basic region of about 140 residues that is relatively refractile to mutation and might be involved in RNA interaction, and an essential carboxy-terminal region of about 210 residues with the five repeat-regions that are similar to beta-transducins, which might be involved in protein-protein interaction. A model of interactions of snRNP components suggested by these results is presented.

A functional homologue of the RNA1 gene product in Schizosaccharomyces pombe: purification, biochemical characterization, and identification of a leucine-rich repeat motif

The RNA1 gene from Saccharomyces cerevisiae is defined by the temperature-sensitive rna1-1 mutation that interferes with the maturation and/or nucleocytoplasmic transport of RNA. We describe the purification of a 44-kDa protein from the evolutionary distant fission yeast Schizosaccharomyces pombe and the cloning and sequence analysis of the corresponding gene. Although this protein shares only 42% sequence identity with the RNA1 gene product, it represents a functional homologue because the expression of the S. pombe gene in S. cerevisiae complements the rna1-1 defect. Disruption in S. pombe of the gene encoding the 44-kDa protein, for which we propose the name S. pombe rna1p, reveals that it is essential for growth. Our analysis of purified S. pombe rna1p represents the first biochemical characterization of an RNA1 gene product and reveals that it is a monomeric protein of globular shape. Cell fractionation and immunofluorescence microscopy indicate that rna1p is a cytoplasmic protein possibly enriched in the nuclear periphery. We identify a sequence motif of 29 residues, which is rich in leucine and repeated eight times both in S. pombe and in S. cerevisiae rna1p. Similar leucine-rich repeats present in a series of other proteins, e.g., the mammalian ribonuclease/angiogenin inhibitor, adenylyl cyclase from S. cerevisiae, the toll protein from Drosophila melanogaster, and the sds22 protein phosphatase regulatory subunit from S. pombe, are thought to be involved in protein-protein interactions. Thus rna1p may act as a scaffold protein possibly interacting in the nuclear periphery with a protein ligand that could be associated with exported RNA.

The biochemical defects of prp4-1 and prp6-1 yeast splicing mutants reveal that the PRP6 protein is required for the accumulation of the [U4/U6.U5] tri-snRNP

We have raised specific antibodies against the PRP6 protein and shown that the U4, U5 and U6 snRNAs are co-precipitated with this protein. Using splicing extracts prepared from in vivo heat-inactivated cells, we have characterized the prp4-1 and prp6-1 biochemical defects. In inactivated prp4-1 cell extracts, the U6 snRNA content as well as the U6, U4/U6 snRNPs and the [U4/U6.U5] tri-snRNP particles amounts are severely reduced. In inactivated prp6-1 cell extracts, the PRP6 mutant protein is barely detectable. Glycerol gradient analyses indicate that, in these extracts, the [U4/U6.U5] tri-snRNPs are present in very low amounts, but U4/U6 snRNP particles are normally represented. These results establish that the PRP6 protein is required for the accumulation of the [U4/U6.U5] tri-snRNP. We found no evidence for the presence of the PRP6 protein in the U4/U6 particle.

The genetics of nuclear pre-mRNA splicing: a complex story

The occurrence of introns in nuclear precursor RNAs (pre-mRNAs) is widespread in eukaryotes, and the splicing process that removes them is basically the same in yeasts as it is in higher eukaryotes. Splicing takes place in a very large, multi-component complex, the splicesome, and biochemical studies have been complicated by the large number of splicing factors involved. This review describes how genetic approaches used to study RNA splicing in Saccharomyces cerevisiae have complemented the biochemical studies and led to rapid advances in the field.

A conditional yeast mutant deficient in mRNA transport from nucleus to cytoplasm

Transport of mRNA from nucleus to cytoplasm is critical for eukaryotic gene expression; however, the mechanism of export is unknown. Selection and screening procedures have therefore been used to obtain a family of temperature-sensitive conditional mutants of Saccharomyces cerevisiae that accumulate poly(A)+ RNA in the nucleus when incubated at 37 degrees C, as judged by in situ hybridization. In one such mRNA transport mutant, mtr1-1, RNA synthesis continues, the export of poly(A)+ RNA is inhibited, intranuclear poly(A)+ is remarkably stable, and protein synthesis gradually stops. Thus, there is no tight coupling between RNA synthesis and export. The export lesion is reversible. Although mRNA export is clearly not a default option, neither inhibition of protein synthesis, inhibition of mRNA splicing, nor inhibition of poly(A)-binding protein function blocks export of the average poly(A)+, as judged by in situ hybridization. Further analysis of the family of mtr mutants should help map the path of RNA transport.

rna12+, a gene of Saccharomyces cerevisiae involved in pre-rRNA maturation. Characterization of a temperature-sensitive mutant, cloning and sequencing of the gene

RNA12-1 is a dominant temperature-sensitive (Ts) yeast mutant which has previously been reported to exhibit a defect in RNA accumulation at 37 degrees C. We further characterized this mutant through analyses of rRNA transcription rates and maturation. The results show that pre-rRNA is normally synthesized but that subsequent maturation is severely affected by a temperature upshift: the nascent rRNAs are under-methylated and little mature rRNA can be observed at 37 degrees C. Likewise, the accumulation of some mRNAs for ribosomal proteins is also prevented at 37 degrees C. The RNA12-1 mutation is recessive at 32 degrees C, which made it possible to clone the wild-type rna12+ gene by complementation of the Ts phenotype with plasmids from a multicopy yeast genomic library. The predicted gene product is a protein of 96,630 Da with no significant sequence similarity to any known proteins. Gene disruption is not lethal at either the permissive or the restrictive temperature. The gene is located on chromosome XIII, downstream of the ADH2 gene and 10 cM from the ADE4 gene. Furthermore, the mutant allele RNA12-1 was cloned and sequenced. A point mutation found in this allele leads to dominant thermosensitivity at 37 degrees C when the mutant gene is introduced into a wild-type strain. Taken together, these data suggest that the rna12+ gene product plays a dispensable role in early maturation of pre-rRNA but that its mutant gene product can interfere with the normal function of other proteins required for pre-rRNA maturation.

Strategies for the genetic manipulation of Saccharomyces cerevisiae

The budding yeast Saccharomyces cerevisiae is now widely used as a model organism in the study of gene structure, function, and regulation in addition to its more traditional use as a workhorse of the brewing and baking industries. In this article the plethora of methods available for manipulating the genome of S. cerevisiae are reviewed. This will include a discussion of methods for manipulating individual genes and whole chromosomes, and will address both classic genetic and recombinant DNA-based methods. Furthermore, a critical evaluation of the various genetic strategies for genetically manipulating this simple eukaryote will be included, highlighting the requirements of both the new and the more traditional biotechnology industries.

The yeast PRP8 protein interacts directly with pre-mRNA

The PRP8 protein of Saccharomyces cerevisiae is required for nuclear pre-mRNA splicing. Previously, immunological procedures demonstrated that PRP8 is a protein component of the U5 small nuclear ribonucleoprotein particle (U5 snRNP), and that PRP8 protein maintains a stable association with the spliceosome during both step 1 and step 2 of the splicing reaction. We have combined immunological analysis with a UV-crosslinking assay to investigate interaction(s) of PRP8 protein with pre-mRNA. We show that PRP8 protein interacts directly with splicing substrate RNA during in vitro splicing reactions. This contact event is splicing-specific in that it is ATP-dependent, and does not occur with mutant RNAs that contain 5' splice site or branchpoint mutations. The use of truncated RNA substrates demonstrated that the assembly of PRP8 protein into splicing complexes is not, by itself, sufficient for the direct interaction with the RNA; PRP8 protein only becomes UV-crosslinked to RNA substrates capable of participating in step 1 of the splicing reaction. We propose that PRP8 protein may play an important structural and/or regulatory role in the spliceosome.

An approach for isolation of mutants defective in 35S ribosomal RNA synthesis in Saccharomyces cerevisiae

We have developed a method to isolate mutants of Saccharomyces cerevisiae that are primarily defective in the transcription of 35S ribosomal RNA (rRNA) genes by RNA polymerase I. The method uses a system in which the 35S rRNA gene is fused to the GAL7 promoter and is transcribed by RNA polymerase II under control of the GAL regulatory system. Chromosomal mutations affecting components specifically involved in synthesis of 35S rRNA by RNA polymerase I can be suppressed by this hybrid gene in the presence of inducer (galactose) but not in its absence. We looked for mutants the growth of which depended on the presence of plasmid expressing the hybrid gene. For this purpose, we used a red/white-colony color assay as the initial screen followed by a test for galactose-dependent growth. We have thus isolated many mutants and identified at least nine genes (RRN1-RRN9) involved in 35S rRNA synthesis, two of which correspond to known RNA polymerase I subunit genes RPA190 and RPA135.

A cold-sensitive mRNA splicing mutant is a member of the RNA helicase gene family

We have isolated a cold-sensitive mutant of Saccharomyces cerevisiae in which the first step of mRNA splicing is inhibited. The growth and splicing defects are recessive and cosegregate, thus defining a single essential gene (PRP28). The wild-type PRP28 gene was cloned, and sequence analysis reveals extensive homology to a family of proteins that are thought to function as ATP-dependent RNA helicases. The cold sensitivity is caused by a glycine-to-glutamic acid change in a conserved sequence motif. Interestingly, double mutants containing conditional alleles of PRP28 and PRP24, which encodes a U6 snRNA-binding protein, are inviable. In addition, a suppressor of prp28-1 is a mutant allele of PRP8, which encodes a U5 protein, thus linking PRP28 with U5. These data are consistent with a scenario in which PRP28 acts to unwind the U4/U6 base-pairing interaction in the U4/U6/U5 snRNP, facilitating the first covalent step of splicing.

Genetic studies of the PRP11 gene of Saccharomyces cerevisiae

PRP11 is a gene that encodes an essential function for pre-messenger RNA (mRNA) processing in Saccharomyces cerevisiae. We have carried out a mutational study to locate essential and non-essential regions of the PRP11 protein. The existing temperature-sensitive (ts) mutation (prp11-1) was isolated from the chromosome of the original mutant and its position in the gene was determined. When the prp11-1 gene was transcribed from the GAL1 promoter, the overproduced protein was able to reverse the ts prp11-1 phenotype; this is compatible with the possibility that the defect in the prp11-1 gene product affects its binding to the spliceosome. Thirteen linker-insertion mutations were constructed. Only five (prp11-4, 11-6, 11-10, -13 and -14) resulted in a null phenotype. One of these became temperature-sensitive when the insertion was reduced in size from four (prp11-10) to two (prp11-15) amino acids. A sequence of ten amino acids of which also occurs in the human U1 small nuclear ribonucleoprotein particle (snRNP) A protein and the U2 snRNP B" protein, when deleted from PRP11, had no phenotype and thus appears to be nonessential for PRP11 function. However, a linker-insertion mutation (prp11-10) immediately adjacent to this region resulted in a null phenotype.

prp4 from Schizosaccharomyces pombe, a mutant deficient in pre-mRNA splicing isolated using genes containing artificial introns

We have generated a bank of temperature-sensitive (ts) Schizosaccharomyces pombe mutant strains. About 150 of these mutants were transformed with a ura4 gene containing an artificial intron. We screened these ts mutants for mutants deficient in splicing of the ura4 intron. With this approach three mutants were isolated which have a general defect in the splicing process. Two of these mutants fall into the prp1 complementation group and one defines a new complementation group, prp4.

Cloning of the two essential yeast genes, PRP6 and PRP9, and their rapid mapping, disruption and partial sequencing using a linker insertion strategy

In the yeast Saccharomyces cerevisiae, some thermosensitive (ts) mutants have been shown to be impaired in pre-mRNA splicing (prp mutants). From a yeast genomic library, we have isolated plasmids that complement prp6 or prp9 ts mutations. These plasmids also complement the ts growth defect of additional independent mutants identified as new prp6 and prp9 ts alleles, indicating that the cloned DNAs encode PRP6 and PRP9 genes, respectively. Here, we describe the restriction maps of these loci which are localized on chromosome II and IV, respectively. The limits of open reading frames (ORFs) within the cloned inserts have been determined using a linker insertion strategy combined with the ts complementation assay. Double-strand DNA sequencing was also performed directly on the yeast expression vector from the inserted linkers. Gene disruption experiments demonstrate that both genes are essential for viability.

Identification of nuclear proteins that specifically bind to RNAs containing 5' splice sites

Two polypeptides of 26 and 37 kDa (designated SPP-1 and SPP-2) were identified in in vitro splicing extracts by UV crosslinking to splicing precursor RNAs. Crosslinking of both polypeptides required a functional 5' splice site but was not dependent on sequences at the 3' end of the intron. Centrifugation of extract separated the two polypeptides from major U small nuclear ribonucleoproteins (snRNPs), including U1 snRNPs. Both polypeptides crosslinked to precursor RNAs containing 5' splice sites in the absence of U1 RNA. Complexes containing both polypeptides also contained U1 snRNPs, suggesting that SPP-1 and SPP-2 are a part of the functional spliceosome. We propose that SPP-1 and SPP-2 are factors that participate in the recognition of 5' splice sites.

The yeast PRP6 gene encodes a U4/U6 small nuclear ribonucleoprotein particle (snRNP) protein, and the PRP9 gene encodes a protein required for U2 snRNP binding

PRP6 and PRP9 are two yeast genes involved in pre-mRNA splicing. Incubation at 37 degrees C of strains that carry temperature-sensitive mutations at these loci inhibits splicing, and in vivo experiments suggested that they might be involved in commitment complex formation (P. Legrain and M. Rosbash, Cell 57:573-583, 1989). To examine the specific role that the PRP6 and PRP9 products may play in splicing or pre-mRNA transport to the cytoplasm, we have characterized in vitro splicing and spliceosome assembly in extracts derived from prp6 and prp9 mutant strains. We have also characterized RNAs that are specifically immunoprecipitated with the PRP6 and PRP9 proteins. Both approaches indicate that PRP6 encodes a U4/U6 small nuclear ribonucleoprotein particle (snRNP) protein and that the PRP9 protein is required for a stable U2 snRNP-substrate interaction. The results are discussed with reference to the previously observed in vivo phenotypes of these mutants.

The yeast PRP6 gene encodes a U4/U6 small nuclear ribonucleoprotein particle (snRNP) protein, and the PRP9 gene encodes a protein required for U2 snRNP binding

PRP6 and PRP9 are two yeast genes involved in pre-mRNA splicing. Incubation at 37 degrees C of strains that carry temperature-sensitive mutations at these loci inhibits splicing, and in vivo experiments suggested that they might be involved in commitment complex formation (P. Legrain and M. Rosbash, Cell 57:573-583, 1989). To examine the specific role that the PRP6 and PRP9 products may play in splicing or pre-mRNA transport to the cytoplasm, we have characterized in vitro splicing and spliceosome assembly in extracts derived from prp6 and prp9 mutant strains. We have also characterized RNAs that are specifically immunoprecipitated with the PRP6 and PRP9 proteins. Both approaches indicate that PRP6 encodes a U4/U6 small nuclear ribonucleoprotein particle (snRNP) protein and that the PRP9 protein is required for a stable U2 snRNP-substrate interaction. The results are discussed with reference to the previously observed in vivo phenotypes of these mutants.

Interactions of PRP2 protein with pre-mRNA splicing complexes in Saccharomyces cerevisiae

PRP2 protein of Saccharomyces cerevisiae is required for the pre-mRNA splicing reaction but not for the early stages of spliceosome assembly. Using anti-PRP2 antibodies we demonstrate that PRP2 protein is associated with spliceosomes prior to, and throughout step 1 of the splicing reaction. Heat-inactivated prp2 protein, by contrast, does not seem to associate with spliceosomes. By elution of electrophoretically distinct spliceosomal complexes from non-denaturing gels we identify the specific complex with which PRP2 initially interacts in the pathway of spliceosome assembly.

Affinity purification of spliceosomes reveals that the precursor RNA processing protein PRP8, a protein in the U5 small nuclear ribonucleoprotein particle, is a component of yeast spliceosomes

Nuclear pre-mRNA splicing in Saccharomyces cerevisiae, as in higher eukaryotes, occurs in large RNA-protein complexes called spliceosomes. The small nuclear RNA components, U1, U2, U4, U5, and U6, have been extensively studied; however, very little is known about the protein components of yeast spliceosomes. Here we use antibodies against the precursor RNA processing protein PRP8, a protein component of the U5 small nuclear ribonucleoprotein particle, to detect its association with spliceosomes throughout the splicing reaction and in a post-splicing complex containing the excised intron. In addition, an indirect immunological approach has been developed that confirms the presence of precursor RNA processing protein PRP8 in isolated spliceosomes. This method has possible general application for the analysis of ribonucleoprotein particle complexes.

PRP4 (RNA4) from Saccharomyces cerevisiae: its gene product is associated with the U4/U6 small nuclear ribonucleoprotein particle

The PRP4 (RNA4) gene product is involved in nuclear mRNA processing in yeast cells; we have previously cloned the gene by complementation of a temperature-sensitive mutation. Sequence and transcript analyses of the cloned gene predicted the gene product to be a 52-kilodalton protein, which was confirmed with antibodies raised against the PRP4 gene product. These antibodies inhibited precursor mRNA splicing in vitro, demonstrating a direct role of PRP4 in splicing. Immunoprecipitations with the antibodies indicated that the PRP4 protein is associated with the U4/U6 small nuclear ribonucleoprotein particle.

Structural and functional analyses of Saccharomyces cerevisiae wild-type and mutant RNA1 genes

The yeast gene RNA1 has been defined by the thermosensitive rna1-1 lesion. This lesion interferes with the processing and production of all major classes of RNA. Each class of RNA is affected at a distinct and presumably unrelated step. Furthermore, RNA does not appear to exit the nucleus. To investigate how the RNA1 gene product can pleiotropically affect disparate processes, we undertook a structural analysis of wild-type and mutant RNA1 genes. The wild-type gene was found to contain a 407-amino-acid open reading frame that encodes a hydrophilic protein. No clue regarding the function of the RNA1 protein was obtained by searching banks for similarity to other known gene products. Surprisingly, the rna1-1 lesion was found to code for two amino acid differences from wild type. We found that neither single-amino-acid change alone resulted in temperature sensitivity. The carboxy-terminal region of the RNA1 open reading frame contains a highly acidic domain extending from amino acids 334 to 400. We generated genomic deletions that removed C-terminal regions of this protein. Deletion of amino acids 397 to 407 did not appear to affect cell growth. Removal of amino acids 359 to 397, a region containing 24 acidic residues, caused temperature-sensitive growth. This allele, rna1-delta 359-397, defines a second conditional lesion of the RNA1 locus. We found that strains possessing the rna1-delta 359-397 allele did not show thermosensitive defects in pre-rRNA or pre-tRNA processing. Removal of amino acids 330 to 407 resulted in loss of viability.

PRP4 (RNA4) from Saccharomyces cerevisiae: its gene product is associated with the U4/U6 small nuclear ribonucleoprotein particle

The PRP4 (RNA4) gene product is involved in nuclear mRNA processing in yeast cells; we have previously cloned the gene by complementation of a temperature-sensitive mutation. Sequence and transcript analyses of the cloned gene predicted the gene product to be a 52-kilodalton protein, which was confirmed with antibodies raised against the PRP4 gene product. These antibodies inhibited precursor mRNA splicing in vitro, demonstrating a direct role of PRP4 in splicing. Immunoprecipitations with the antibodies indicated that the PRP4 protein is associated with the U4/U6 small nuclear ribonucleoprotein particle.