Motorin Y., Keith G., Simon C., Foiret D., Simos G., Hurt E., Grosjean H.
The yeast tRNA:pseudouridine synthase Pus1p displays a multisite substrate specificity Journal Article
In: RNA, vol. 4, no. 7, pp. 856-69, 1998, (1355-8382 Journal Article).
Abstract | BibTeX | Tags: *RNA, cerevisiae, Cloning, Fractions/metabolism, Fungal, Fungal/metabolism, Gov't, Hydro-Lyases/biosynthesis/genetics/*metabolism, Molecular, Mutation, Non-U.S., Plant/metabolism, post-transcriptional, Precursors/*metabolism, Processing, Proteins/biosynthesis, Proteins/biosynthesis/genetics/metabolism, Pseudouridine/*biosynthesis, Recombinant, RNA, Saccharomyces, Specificity, Subcellular, Substrate, Support, Transfer/*metabolism
@article{,
title = {The yeast tRNA:pseudouridine synthase Pus1p displays a multisite substrate specificity},
author = { Y. Motorin and G. Keith and C. Simon and D. Foiret and G. Simos and E. Hurt and H. Grosjean},
year = {1998},
date = {1998-01-01},
journal = {RNA},
volume = {4},
number = {7},
pages = {856-69},
abstract = {We have previously shown that the yeast gene PUS1 codes for a tRNA:pseudouridine synthase and that recombinant Pus1p catalyzes, in an intron-dependent way, the formation of psi34 and psi36 in the anticodon loop of the yeast minor tRNA(Ile) in vitro (Simos G et al., 1996, EMBO J 15:2270-2284). Using a set of T7 transcripts of different tRNA genes, we now demonstrate that yeast pseudouridine synthase 1 catalyzes in vitro pseudouridine formation at positions 27 and/or 28 in several yeast cytoplasmic tRNAs and at position 35 in the intron-containing tRNA(Tyr) (anticodon GUA). Thus, Pus1p not only displays a broad specificity toward the RNA substrates, but is also capable of catalyzing the pseudouridine (psi) formation at distinct noncontiguous sites within the same tRNA molecule. The cell-free extract prepared from the yeast strain bearing disrupted gene PUS1 is unable to catalyze the formation of psi27, psi28, psi34, and psi36 in vitro, however, psi35 formation in the intron-containing tRNA(Tyr)(GUA) remains unaffected. Thus, in yeast, only one gene product accounts for tRNA pseudouridylation at positions 27, 28, 34, and 36, whereas for position 35 in tRNA(Tyr), another site-specific tRNA:pseudouridine synthase with overlapping specificity exists. Mapping of pseudouridine residues present in various tRNAs extracted from the PUS1-disrupted strain confirms the in vitro data obtained with the recombinant Pus1p. In addition, they suggest that Pus1p is implicated in modification at positions U26, U65, and U67 in vivo.},
note = {1355-8382
Journal Article},
keywords = {*RNA, cerevisiae, Cloning, Fractions/metabolism, Fungal, Fungal/metabolism, Gov't, Hydro-Lyases/biosynthesis/genetics/*metabolism, Molecular, Mutation, Non-U.S., Plant/metabolism, post-transcriptional, Precursors/*metabolism, Processing, Proteins/biosynthesis, Proteins/biosynthesis/genetics/metabolism, Pseudouridine/*biosynthesis, Recombinant, RNA, Saccharomyces, Specificity, Subcellular, Substrate, Support, Transfer/*metabolism},
pubstate = {published},
tppubtype = {article}
}
Wilhelm M. L., Keith G., Fix C., Wilhelm F. X.
Pleiotropic effect of a point mutation in the yeast SUP4-o tRNA gene: in vivo pre-tRNA processing in S. cerevisiae Journal Article
In: Nucleic Acids Res, vol. 20, no. 4, pp. 791-6, 1992, (0305-1048 Journal Article).
Abstract | BibTeX | Tags: Base, Blotting, cerevisiae/*genetics/metabolism, Data, Fungal/*genetics, Fungal/genetics/metabolism, Genes, Introns/genetics, Molecular, Mutation/genetics, Northern, Precursors/*metabolism, RNA, Saccharomyces, Sequence, Suppressor/*genetics, Transfer, Tyr/*genetics/metabolism
@article{,
title = {Pleiotropic effect of a point mutation in the yeast SUP4-o tRNA gene: in vivo pre-tRNA processing in S. cerevisiae},
author = { M. L. Wilhelm and G. Keith and C. Fix and F. X. Wilhelm},
year = {1992},
date = {1992-01-01},
journal = {Nucleic Acids Res},
volume = {20},
number = {4},
pages = {791-6},
abstract = {The expression of mutant tyrosine-inserting ochre suppressor SUP4-o tRNA genes in vivo in S. cerevisiae was examined as a basis for further studies of tRNA transcription and processing. In vivo yeast precursor tRNAs have been identified by filter hybridization and primer extension analysis. We have previously shown that a mutant SUP4-o tRNA gene with a C52----A52 transversion at positive 52 (C52----A52(+IVS) allele) was transcribed but that the primary transcript was not processed correctly. We show here that 5' and 3' end processing as well as splicing are defective for this mutant but that the 5' end processing is restored when the intron is removed from the gene by oligonucleotide directed mutagenesis (C52----A52(-IVS) allele). Our results imply that the C52----A52 transversion by itself cannot account for the lack of susceptibility to RNase P cleavage but that the overall tertiary structure of the mutant tRNA precursor is destabilized by the intron/anticodon stem. A second consequence of the C52----A52 transversion is to prevent complete maturation of the tRNA precursor at its 3' end since intermediates containing incompletely processed 3' trailers accumulate in the yeast cells transformed with the C52----A52(-IVS) allele. A correct structure of the T stem might therefore define a structural feature required for the recognition of the 3' processing activity.},
note = {0305-1048
Journal Article},
keywords = {Base, Blotting, cerevisiae/*genetics/metabolism, Data, Fungal/*genetics, Fungal/genetics/metabolism, Genes, Introns/genetics, Molecular, Mutation/genetics, Northern, Precursors/*metabolism, RNA, Saccharomyces, Sequence, Suppressor/*genetics, Transfer, Tyr/*genetics/metabolism},
pubstate = {published},
tppubtype = {article}
}