Assembly of the mitochondrial membrane system. Characterization of a yeast nuclear gene involved in the processing of the cytochrome b pre-mRNA

The cytochrome b gene of Saccharomyces cerevisiae D273-10B was previously shown to be composed of three exons and two introns (Nobrega, F.G., and Tzagoloff, A. (1980) J. Biol. Chem. 255, 9828-9837). In the present study nuclear respiratory deficient mutants of this strain have been screened for defects in processing of the cytochrome b pre-mRNA. Fifteen independently isolated mutants lacking cytochrome b have been assigned to a single genetic complementation group (G36). Members of this complementation group are blocked in the excision of the second intervening sequence of cytochrome b and consequently are unable to produce the mature mRNA. The wild type gene defined by this class of mutants has been named CBP2. A recombinant plasmid with the CBP2 gene has been selected from a library of wild type nuclear DNA and further subcloned by transformation of a cbp2 mutant to respiratory competency. The smallest plasmid (pG36/T5) capable of complementing cbp2 mutants and of restoring their ability to complete processing of the cytochrome b pre-mRNA has a nuclear DNA fragment of 2.6 kilobase pairs inserted at the BamHI site of the yeast vector YEp13. The sequence of the cloned DNA fragment has revealed an 1890-nucleotide-long reading frame encoding a basic protein with a molecular weight of 74,000. Deletion analysis confirms that the entire reading frame is required for complementation of cbp2 mutants. This reading frame is proposed to code for the CBP2 gene product.     

LAMMER kinase Kic1 is involved in pre-mRNA processing

The LAMMER kinases are conserved through evolution. They play vital roles in cell growth/differentiation, development, and metabolism. One of the best known functions of the kinases in animal cells is the regulation of pre-mRNA splicing. Kic1 is the LAMMER kinase in fission yeast Schizosaccharomyces pombe. Despite the reported pleiotropic effects of kic1⁺ deletion/overexpression on various cellular processes the involvement of Kic1 in splicing remains elusive. In this study, we demonstrate for the first time that Kic1 not only is required for efficient splicing but also affects mRNA export, providing evidence for the conserved roles of LAMMER kinases in the unicellular context of fission yeast. Consistent with the hypothesis of its direct participation in multiple steps of pre-mRNA processing, Kic1 is predominantly present in the nucleus during interphase. In addition, the kinase activity of Kic1 plays a role in modulating its own cellular partitioning. Interestingly, Kic1 expression oscillates in a cell cycle-dependent manner and the peak level coincides with mitosis and cytokinesis, revealing a potential mechanism for controlling the kinase activity during the cell cycle. The novel information about the in vivo functions and regulation of Kic1 offers insights into the conserved biological roles fundamental to LAMMER kinases in eukaryotes.     

Associations between distinct pre-mRNA splicing components and the cell nucleus.

SC-35 is a non-snRNP spliceosome component that is specifically recognized by the anti-spliceosome monoclonal antibody alpha SC-35. In this paper we provide direct evidence that SC-35 is an essential splicing factor and we examine the immunolocalization of SC-35 by confocal laser scanning microscopy and by electron microscopy. We have found that the speckled staining pattern observed by fluorescence microscopy corresponds to structures previously designated as interchromatin granules and perichromatin fibrils. Although snRNP antigens are also concentrated in these nuclear regions, we show that the two types of spliceosome components are localized through different molecular interactions: The distribution of SC-35 was not affected by treatment with DNase I or RNase A, or when the cells were heat shocked. In contrast, snRNP antigens become diffusely distributed after RNase A digestion or heat shock. Examination of cells at different stages of mitosis revealed that the SC-35 speckled staining pattern is lost during prophase and speckles containing SC-35 begin to reform in the cytoplasm of anaphase cells. In contrast, snRNP antigens do not associate with speckled regions until late in telophase. These studies reveal a dynamic pattern of assembly and disassembly of the splicing factor SC-35 into discrete nuclear structures that colocalize with interchromatin granules and perichromatin fibrils. These subnuclear regions may therefore be nuclear organelles involved in the assembly of spliceosomes, or splicing itself.     

FRG1P-mediated aggregation of proteins involved in pre-mRNA processing

FRG1 is considered a candidate gene for facioscapulohumeral muscular dystrophy (FSHD) based on its location at chromosome 4qter and its upregulation in FSHD muscle. The FRG1 protein (FRG1P) localizes to nucleoli, Cajal bodies (and speckles), and has been suggested to be a component of the human spliceosome but its exact function is unknown. Recently, transgenic mice overexpressing high levels of FRG1P in skeletal muscle were described to present with muscular dystrophy. Moreover, upregulation of FRG1P was demonstrated to correlate with missplicing of specific pre-mRNAs. In this study, we have combined colocalization studies with yeast two-hybrid screens to identify proteins that associate with FRG1P. We demonstrate that artificially induced nucleolar aggregates of VSV-FRG1P specifically sequester proteins involved in pre-mRNA processing. In addition, we have identified SMN, PABPN1, and FAM71B, a novel speckle and Cajal body protein, as binding partners of FRG1P. All these proteins are, or seem to be, involved in RNA biogenesis. Our data confirm the presence of FRG1P in protein complexes containing human spliceosomes and support a potential role of FRG1P in either splicing or another step in nuclear RNA biogenesis. Intriguingly, among FRG1P-associated proteins are SMN and PABPN1, both being involved in neuromuscular disorders, possibly through RNA biogenesis-related processes.     

Differential nuclease sensitivity identifies tight contacts between yeast pre-mRNA and spliceosomes.

The oligonucleotide-directed RNase H sensitivity of a yeast (Saccharomyces cerevisiae) pre-mRNA was determined in an in vitro splicing reaction. While most of the pre-mRNA was sensitive to cleavage, the regions of the 5' splice site and TACTAAC box were found to be highly resistant. The biochemical requirements for protection against nuclease attack parallel those of both spliceosome formation and splicing. Most of the uncleaved pre-mRNA remaining after RNase H challenge was found associated with two forms of the yeast spliceosome. Differences in the RNase H sensitivity of pre-mRNA found in the two spliceosome forms indicate an increased association of splicing factors with the 5' splice site during spliceosome assembly.     

Separation of factors required for cleavage and polyadenylation of yeast pre-mRNA.

Cleavage and polyadenylation of yeast precursor RNA require at least four functionally distinct factors (cleavage factor I [CF I], CF II, polyadenylation factor I [PF I], and poly(A) polymerase [PAP]) obtained from yeast whole cell extract. Cleavage of precursor occurs upon combination of the CF I and CF II fractions. The cleavage reaction proceeds in the absence of PAP or PF I. The cleavage factors exhibit low but detectable activity without exogenous ATP but are stimulated when this cofactor is included in the reaction. Cleavage by CF I and CF II is dependent on the presence of a (UA)6 sequence upstream of the GAL7 poly(A) site. The factors will also efficiently cleave precursor with the CYC1 poly(A) site. This RNA does not contain a UA repeat, and processing at this site is thought to be directed by a UAG...UAUGUA-type motif. Specific polyadenylation of a precleaved GAL7 RNA requires CF I, PF I, and a crude fraction containing PAP activity. The PAP fraction can be replaced by recombinant PAP, indicating that this enzyme is the only factor in this fraction needed for the reconstituted reaction. The poly(A) addition step is also dependent on the UA repeat. Since CF I is the only factor necessary for both cleavage and poly(A) addition, it is likely that this fraction contains a component which recognizes processing signals located upstream of the poly(A) site. The initial separation of processing factors in yeast cells suggests both interesting differences from and similarities to the mammalian system.     

Isolation of a yeast gene involved in species-specific pre-tRNA processing.

To identify genes involved in pre-tRNA processing, we searched for yeast DNA sequences that specifically enhanced the expression of the SUP4(G37) gene. The SUP4(G37) gene possesses a point mutation at position 37 of suppressor tRNA(Tyr). This lesion results in a reduced rate of pre-tRNA splicing and a decreased level of nonsense suppression. A SUP4(G37) strain was transformed with a yeast genomic library, and the transformants were screened for increased suppressor activity. One transformant contained a plasmid that encoded an unessential gene, STP1, that in multiple copies enhanced the suppression of SUP4(G37) and caused increased production of mature SUP4(G37) product. Disruption of the genomic copy of STP1 resulted in a reduced efficiency of SUP4-mediated suppression and the accumulation of pre-tRNAs. Not all intron-containing pre-tRNAs were affected by the stp1-disruption. At least five of the nine families of pre-tRNAs were affected. Two other species, pre-tRNA(Ile) and pre-tRNA(3Leu), were not. We propose that STP1 encodes a tRNA species-specific product that functions as a helper for pre-tRNA splicing. The STP1 product may interact with pre-tRNAs to generate a structure that is efficiently recognized by splicing machinery.     

Functional analyses of interacting factors involved in both pre-mRNA splicing and cell cycle progression in Saccharomyces cerevisiae

Through a genetic screen to search for factors that interact with Prp17/Cdc40p, a protein involved in both cell cycle progression and pre-mRNA splicing, we identify three novel factors, which we call Syf1p, Syf2p, and Syf3 (SYnthetic lethal with cdc Forty). Here we present evidence that all three proteins are spliceosome associated, that they associate weakly or transiently with U6 and U5 snRNAs, and that Syf1p and Syf3p (also known as Clf1p) are required for pre-mRNA splicing. In addition we show that depletion of Syf1p or Syf3p results in cell cycle arrest at the G2/M transition. Thus, like Prp17/Cdc40p, Syf1p and Syf3p are involved in two distinct cellular processes. We discuss the likelihood that Syf1p, Syf2p, and Syf3p are components of a protein complex that assembles into spliceosomes and also regulates cell cycle progression.     

Cell type specific trans-acting factors are involved in alternative splicing of human fibronectin pre-mRNA.

ED-A and ED-B are facultative type III homologies of fibronectin, encoded by alternatively spliced exons, described in man and in rat. A hybrid alpha-globin-fibronectin minigene containing the ED-B region from the human gene has been transfected in human cell lines derived from various tissues, in order to study the processing of the generated precursor RNA in the different cell environments. In most tested lines the pre-RNA is alternatively spliced and produces two mature RNAs, with and without the ED-B exon, in different ratios that closely resemble the corresponding endogenous fibronectin RNAs. In a hepatoma cell line, Hep 3B, only one RNA is produced, in which the ED-B exon is absent; the same pattern of splicing is observed in liver. The data show that all the information required to produce accurate and regulated alternative splicing of the ED-B exon is contained in the fragment used and cell specific factors are necessary for the pre-RNA to be differentially spliced in the various cell lines. In contrast, expression in Hep 3B of a similar gene containing the ED-A area failed to reproduce the liver specific splicing pattern. Therefore regulation of ED-A processing is likely to involve different mechanisms to those responsible for control of ED-B splicing.