M Winey scite author profile

M Winey

2Publications

33Citation Statements Received

43Citation Statements Given

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University of Wisconsin–Madison

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Mutations in the anticodon stem affect removal of introns from pre-tRNA in Saccharomyces cerevisiae.

Mathison¹,

Winey²,

Soref³

et al. 1989

Mol. Cell. Biol.

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To evaluate the role of exon domains in tRNA splicing, the anti-codon stem of proline pre-tRNAUGG from Saccharomyces cerevisiae was altered by site-directed mutagenesis of the suJ8 gene. Sixteen alleles were constructed that encode mutant pre-tRNAs containing all possible base combinations in the last base pair of the anticodon stem adjacent to the anticodon loop (positions 31 and 39). The altered pre-tRNAs were screened by using an in vitro endonucleolytic cleavage assay to determine whether perturbations in secondary structure affect the intron excision reaction. The pre-tRNAs were cleaved efficiently whenever secondary structure in the anticodon stem was maintained through standard base pairing or G-U interactions. However, most of the pre-tRNAs with disrupted secondary structure were poor substrates for intron excision. We also determined the extent to which the suJ8 alleles produce functional products in vivo. Each allele was integrated in one to three copies into a yeast chromosome or introduced on a high-copy-number plasmid by transformation. The formation of a functional product was assayed by the ability of each allele to suppress the + 1 frameshift mutation his4-713 through four-base codon reading, as shown previously for the SUF8-1 suppressor allele. We found that alleles containing any standard base pair or G U pair at position 31/39 in the anticodon stem failed to suppress his4-713. We could not assess in vivo splicing with these alleles because the tRNA products, even if they are made, would be expected to read a normal triplet rather than a quadruplet codon. However, all of the alleles that contained a disrupted base pair at position 31/ 39 in the anticodon stem altered the structure of the tRNA in a manner that caused frameshift suppression. Suppression indicated that splicing must have occurred to some extent in vivo even though most of the suppressor alleles produced pre-tRNAs that were cleaved with low efficiency or not at all in vitro. These results have important implications for the interpretation of in vitro cleavage assays in general and for the potential use of suppressors to select mutations that affect tRNA splicing.Splicing of transfer RNA in Saccharomyces cerevisiae requires three separate enzymes: a detergent-extractable endonuclease, a soluble ligase, and a 2'-phosphatase (26). The endonuclease cleaves the pre-tRNA, releasing the intron as a linear molecule (25). The ligase joins the half molecules through an ATP-dependent, three-step mechanism involving cyclic phosphodiesterase, polynucleotide kinase, and RNA ligase activities (12, 28). Finally, the residual 2'-phosphate at the splice site is removed to produce a mature, primary tRNA sequence.The splicing enzymes of S. cerevisiae process all introncontaining intermediates in the synthesis of 10 of the 46 cytoplasmic tRNA isoacceptors (14, 23). The enzymes form an in vitro complex composed minimally of the endonuclease and the ligase (11). The ligase, and by extension probably the complex as well, is localized in vivo in associatio...

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SEN1, a Positive Effector of tRNA-Splicing Endonuclease in Saccharomyces cerevisiae

DeMarini

Winey

Ursic

et al. 1992

Molecular and Cellular Biology

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The SEN1 gene, which is essential for growth in the yeast Saccharomyces cerevisiae, is required for endonucleolytic cleavage of introns from all 10 families of precursor tRNAs. A mutation in SEN1 conferring temperature-sensitive lethality also causes in vivo accumulation of pre-tRNAs and a deficiency of in vitro endonuclease activity. Biochemical evidence suggests that the gene product may be one of several components of a nuclear-localized splicing complex. We have cloned the SEN1 gene and characterized the SEN1 mRNA, the SEN1 gene product, the temperature-sensitive sen1-1 mutation, and three SEN1 null alleles. The SEN1 gene corresponds to a 6,336-bp open reading frame coding for a 2,112-amino-acid protein (molecular mass, 239 kDa). Using antisera directed against the C-terminal end of SEN1, we detect a protein corresponding to the predicted molecular weight of SEN1. The SEN1 protein contains a leucine zipper motif, consensus elements for nucleoside triphosphate binding, and a potential nuclear localization signal sequence. The carboxy-terminal 1,214 amino acids of the SEN1 protein are essential for growth, whereas the amino-terminal 898 amino acids are dispensable. A sequence of approximately 500 amino acids located in the essential region of SEN1 has significant similarity to the yeast UPF1 gene product, which is involved in mRNA turnover, and the mouse Mov-10 gene product, whose function is unknown. The mutation that creates the temperature-sensitive sen1-1 allele is located within this 500-amino-acid region, and it causes a substitution for an amino acid that is conserved in all three proteins.

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M Winey

Mutations in the anticodon stem affect removal of introns from pre-tRNA in Saccharomyces cerevisiae.

SEN1, a Positive Effector of tRNA-Splicing Endonuclease in Saccharomyces cerevisiae

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