Determinants of mRNA stability in Dictyostelium discoideum amoebae: differences in poly(A) tail length, ribosome loading, and mRNA size cannot account for the heterogeneity of mRNA decay rates.

Shapiro, Robert A.; Herrick, David; Manrow, Richard E.; Blinder, Dmitry B.; Jacobson, Allan

doi:10.1128/mcb.8.5.1957

Cited by 43 publications

(40 citation statements)

References 91 publications

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“…In conclusion, our data with the rpbl-J mutant and the thiolutin-inhibited wild-type strain confirm previous results dissociating mRNA stability and the presence and length of the poly(A) tail (41,49,69,72). Nevertheless, in our mutants these two parameters seem correlated since despite continuous transcription, the mRNA levels, as well as the lengths of the poly(A) tracts, are strongly reduced.…”

Section: Discussionsupporting

confidence: 73%

“…One of the major roles for the poly(A) tail was suggested by its involvement in protein biosynthesis (47,63), and in yeast cells the poly(A)-binding protein (PABP [1,68]) was shown to be required for translation initiation (69). More recently, in vitro data have supported the idea that the poly(A) tail enhances translation through the interaction of an initiation factor or the ribosomal subunit with the PABP (59).Besides the implication of the poly(A) tail in translation (reviewed in reference 46), its role in mRNA half-life has been evoked as many times (30,44,82,83,86), sometimes in association with the PABP (11, 12, 17), as refuted (41,49,69,72). Nevertheless, it appears that the poly(A) tail is not solely responsible for determination of the stability of mRNA in vivo, but that it acts in association with other factors.…”

mentioning

confidence: 67%

“…Besides the implication of the poly(A) tail in translation (reviewed in reference 46), its role in mRNA half-life has been evoked as many times (30,44,82,83,86), sometimes in association with the PABP (11, 12, 17), as refuted (41,49,69,72). Nevertheless, it appears that the poly(A) tail is not solely responsible for determination of the stability of mRNA in vivo, but that it acts in association with other factors.…”

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confidence: 99%

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Mutations in the yeast RNA14 and RNA15 genes result in an abnormal mRNA decay rate; sequence analysis reveals an RNA-binding domain in the RNA15 protein.

Minvielle‐Sebastia¹,

Winsor²,

Bonneaud³

et al. 1991

Mol. Cell. Biol.

126

110

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In Saccharomyces cerevisiae, temperature-sensitive mutations in the genes RNA14 and RNA15 correlate with a reduction of mRNA stability and poly(A) tail length. Although mRNA transcription is not abolished in these mutants, the transcripts are rapidly deadenylated as in a strain carrying an RNA polymerase B(II) temperature-sensitive mutation. This suggests that the primary defect could be in the control of the poly(A) status of the mRNAs and that the fast decay rate may be due to the loss of this control. By complementation of their temperature-sensitive phenotype, we have cloned the wild-type genes. They are essential for cell viability and are unique in the haploid genome. The RNA14 gene, located on chromosome II, is transcribed as three mRNAs, one major and two minor, which are 2.2, 1.5, and 1.1 kb in length. The RNA15 gene gives rise to a single 1.2-kb transcript and maps to chromosome XVI. Sequence analysis indicates that RNA14 encodes a 636-amino-acid protein with a calculated molecular weight of 75,295. No homology was found between RNA14 and RNA15 or between RNA14 and other proteins contained in data banks. The RNA15 DNA sequence predicts a protein of 296 amino acids with a molecular weight of 32,770. Sequence comparison reveals an N-terminal putative RNA-binding domain in the RNA15-encoded protein, followed by a glutamine and asparagine stretch similar to the opa sequences. Both RNA14 and RNA15 wild-type genes, when cloned on a multicopy plasmid, are able to suppress the temperature-sensitive phenotype of strains bearing either the rnal4 or the rnal5 mutation, suggesting that the encoded proteins could interact with each other.In yeast cells, all known mRNAs terminate in a poly(A) tail that is probably added to the 3' end of the pre-mature RNA in the nucleus in a posttranscriptional manner (18), as was previously shown to be the case in higher eucaryotes (57). One of the major roles for the poly(A) tail was suggested by its involvement in protein biosynthesis (47,63), and in yeast cells the poly(A)-binding protein (PABP [1,68]) was shown to be required for translation initiation (69). More recently, in vitro data have supported the idea that the poly(A) tail enhances translation through the interaction of an initiation factor or the ribosomal subunit with the PABP (59).Besides the implication of the poly(A) tail in translation (reviewed in reference 46), its role in mRNA half-life has been evoked as many times (30,44,82,83,86), sometimes in association with the PABP (11, 12, 17), as refuted (41,49,69,72). Nevertheless, it appears that the poly(A) tail is not solely responsible for determination of the stability of mRNA in vivo, but that it acts in association with other factors.To obtain mutants of Saccharomyces cerevisiae impaired in poly(A) mRNA metabolism, two mutants simultaneously cordycepin (3'-deoxyadenosine) sensitive and temperature sensitive were isolated by using a selective approach (13). The mutations, located at two independent loci, were renamed rnal4 and rnal5 for reasons of homonymy (see...

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Section: Discussionsupporting

confidence: 73%

mentioning

confidence: 67%

mentioning

confidence: 99%

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Mutations in the yeast RNA14 and RNA15 genes result in an abnormal mRNA decay rate; sequence analysis reveals an RNA-binding domain in the RNA15 protein.

Minvielle‐Sebastia¹,

Winsor²,

Bonneaud³

et al. 1991

Mol. Cell. Biol.

126

110

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“…A number of examples demonstrate the positive effect that the poly(A) tail has on translation initiation (Jacobson and Favreau 1983;Palatnik et al 1984;Shapiro et al 1988). The rapid degradation of human interferon, granulocyte-macrophage colony-stimulating factor, and c-los mRNAs is mediated by an AUUUA element in the 3'-UTR, and this element can also regulate their translational efficiencies (Kruys et al 1987(Kruys et al , 1989.…”

mentioning

confidence: 99%

RNA pseudoknot domain of tobacco mosaic virus can functionally substitute for a poly(A) tail in plant and animal cells.

Gallie¹,

Walbot²

1990

Genes Dev.

144

119

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The genomes of many RNA viruses terminate in a tertiary structure similar to the L-conformation of tRNAs and this structure is recognized by many tRNA-specific enzymes such as aminoacyl-tRNA synthetase. Virtually the entire 3'-untranslated region (UTR) of tobacco mosaic virus (TMV) RNA is involved in an extended tertiary structure containing, in addition to a tRNA-like structure, a pseudoknot domain that lies immediately upstream. Although the functions of these structures are not well understood, they are essential to the virus. We demonstrate that the addition of the 204-base TMV 3'-untranslated region to foreign mRNA constructs can increase gene expression up to 100-fold compared to nonadenylated mRNA. The 3'-UTR of TMV was equal to or greater than a polyadenylated tail in enhancing gene expression in electroporated dicot and monocot protoplasts. The TMV 3'-UTR is functionally similar to a polyadenylated tail in that it increases mRNA stability and translation and must be positioned at the 3' terminus to function efficiently. Similar effects on expression were observed in Chinese hamster ovary cells, demonstrating that the sequence functions in a wide range of eukaryotes. When the extended tertiary structure was dissected, the upstream pseudoknot domain was found to be largely responsible for increasing expression. The inclusion of the tRNA-like structure, however, was important for full regulation.

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“…The poly(A) tail plays roles in both stability and translocation into the cytoplasm of mRNA. There are several reports about the connection of the length of poly(A) tails with mRNA stability (Shapiro et al, 1988;Herrick et al, 1990;Nie et al, 2004). Also, the poly(A) tail provides a binding site for poly(A)-binding proteins (PABPs: for review, Mangus et al, 2003).…”

Section: Discussionmentioning

confidence: 99%

Genetic and molecular analysis of the temperature-sensitive mutant un-17 carrying a mutation in the gene encoding poly(A)-polymerase in Neurospora crassa

et al. 2007

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The un-17 mutant was originally isolated as an irreparable temperature-sensitive (ts) mutant in Neurospora crassa. Early experiments showed that cells of this mutant immediately stopped growing and died when the temperature of the culture was shifted from a permissive temperature (25°C) to non-permissive temperature (35°C). This ts phenotype is suppressed by addition of cycloheximide or in some conditions of growth repression. Even at the permissive temperature, it shows a female sterile phenotype and is deficient in production of exocellular superoxide dismutase SOD4 (EC 1.15.1.1). By searching for a DNA fragment that complements the ts phenotype of the un-17 mutant from a N. crassa genome library, we found the un-17 gene. The cloned un-17 gene encodes a homolog of the Saccharomyces cerevisiae poly(A) polymerase (PAP). The un-17 mutant had a one-base substitution mutation in the gene. The cloned un-17 genes from the wild-type strain and the un-17 mutant were introduced into both the un-17 mutant and wild-type strain. The un-17 mutant introduced by un-17 DNA from the wild-type strain showed recovery of both the ts and female sterile phenotypes. Moreover, the purified product derived from the wild-type strain showed PAP activity in vitro. These findings indicate that the un-17 mutant carries a ts mutation in the gene encoding PAP.

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Determinants of mRNA stability in Dictyostelium discoideum amoebae: differences in poly(A) tail length, ribosome loading, and mRNA size cannot account for the heterogeneity of mRNA decay rates.

Cited by 43 publications

References 91 publications

Mutations in the yeast RNA14 and RNA15 genes result in an abnormal mRNA decay rate; sequence analysis reveals an RNA-binding domain in the RNA15 protein.

Mutations in the yeast RNA14 and RNA15 genes result in an abnormal mRNA decay rate; sequence analysis reveals an RNA-binding domain in the RNA15 protein.

RNA pseudoknot domain of tobacco mosaic virus can functionally substitute for a poly(A) tail in plant and animal cells.

Genetic and molecular analysis of the temperature-sensitive mutant un-17 carrying a mutation in the gene encoding poly(A)-polymerase in Neurospora crassa

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