Feedback Inhibition of the Yeast Ribosomal Protein Gene <i>CRY2</i> Is Mediated by the Nucleotide Sequence and Secondary Structure of <i>CRY2</i> Pre-mRNA

Li, Zhen; Paulovich, Amanda G.; Woolford, John L.

doi:10.1128/mcb.15.11.6454

Cited by 45 publications

(53 citation statements)

References 82 publications

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“…In heterozygous diploid strains of genotype RPL41A/rpl41A or RPL41B/ rpl41B, the amount of L41A or L41B mRNA is reduced ϳ50%, respectively, as expected. Interestingly, in a haploid ⌬RPL41A strain the amount of L41B transcript increases about 35%, suggesting some measure of dosage compensation as has been shown for CRY2, encoding ribosomal protein S14 (32). No obvious change in the level of L41 mRNA was observed in a haploid ⌬RPL41B strain, perhaps reflecting the relatively larger amount of RPL41A transcript that is normally present.…”

Section: Rpl41 Mrna Has Unusually Short 5ј-utrs and Unusuallymentioning

confidence: 88%

Expression of a Micro-protein

Yu¹,

Warner

2001

Journal of Biological Chemistry

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The smallest known open reading frame encodes the ribosomal protein L41, which in yeast is composed of only 24 amino acids, 17 of which are arginine or lysine. Because of the unique problems that might attend the translation of such a short open reading frame, we have investigated the properties and the translation of the mRNAs encoding L41. In Saccharomyces cerevisiae L41 is encoded by two linked genes, RPL41A and RPL41B. These genes give rise to mRNAs that have short 5 leaders of 18 and 22 nucleotides and rather long 3 leaders of 203 and 210 nucleotides not including their poly(A) tails. The mRNAs are translated exclusively on monosomes, suggesting that ribosomes do not remain attached to the mRNA after termination of translation. Calculations based on the abundance of ribosomes and of L41 mRNA indicate that the entire translation event, from initiation through termination, must occur in ϳ2 s. Termination of translation after only 25 codons does not subject the mRNAs encoding L41 to nonsense-mediated decay. Surprisingly, despite the L41 ribosomal protein being conserved from the archaea through the mammalia, S. cerevisiae can grow relatively normally after deletion of both RPL41A and RPL41B.

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Section: Rpl41 Mrna Has Unusually Short 5ј-utrs and Unusuallymentioning

confidence: 88%

Expression of a Micro-protein

Yu¹,

Warner

2001

Journal of Biological Chemistry

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confidence: 99%

“…The coordination of pre-mRNA processing with ribosome biogenesis is especially relevant in the intron-poor environment of the yeast genome, where the highly expressed ribosomal protein transcripts represent a disproportionate amount of the spliced mRNA (Ares et al 1999;Staley and Woolford 2009). Our understanding of how this coordination is accomplished is limited, however, to general principles supported by a few specific examples where individual ribosomal proteins act as feedback regulators to inhibit the processing or stability of cognate ribosomal protein transcripts (Li et al 1995(Li et al , 1996Vilardell et al 2000;Pleiss et al 2007;Gudipati et al 2012).The chemistry of pre-mRNA splicing and the initial stages of rRNA processing occur in spatially separable nuclear Leeds et al 2006;Bohnsack et al 2009;Rodriguez-Galan et al 2013). The yeast Prp43 protein and its mammalian homolog DHX15 also act to dislodge the intron from the postcatalytic spliceosome and to recycle essential snRNP factors for use in subsequent rounds of splicing (Arenas and Abelson 1997;Martin et al 2002;Tsai et al 2005;Wen et al 2008;Fourmann et al 2013).…”

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Limited Portability of G-Patch Domains in Regulators of the Prp43 RNA Helicase Required for Pre-mRNA Splicing and Ribosomal RNA Maturation in Saccharomyces cerevisiae

Banerjee¹,

McDaniel²,

Rymond

2015

Genetics

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The Prp43 DExD/H-box protein is required for progression of the biochemically distinct pre-messenger RNA and ribosomal RNA (rRNA) maturation pathways. In Saccharomyces cerevisiae, the Spp382/Ntr1, Sqs1/Pfa1, and Pxr1/Gno1 proteins are implicated as cofactors necessary for Prp43 helicase activation during spliceosome dissociation (Spp382) and rRNA processing (Sqs1 and Pxr1). While otherwise dissimilar in primary sequence, these Prp43-binding proteins each contain a short glycine-rich G-patch motif required for function and thought to act in protein or nucleic acid recognition. Here yeast two-hybrid, domain-swap, and site-directed mutagenesis approaches are used to investigate G-patch domain activity and portability. Our results reveal that the Spp382, Sqs1, and Pxr1 G-patches differ in Prp43 two-hybrid response and in the ability to reconstitute the Spp382 and Pxr1 RNA processing factors. G-patch protein reconstitution did not correlate with the apparent strength of the Prp43 two-hybrid response, suggesting that this domain has function beyond that of a Prp43 tether. Indeed, while critical for Pxr1 activity, the Pxr1 G-patch appears to contribute little to the yeast two-hybrid interaction. Conversely, deletion of the primary Prp43 binding site within Pxr1 (amino acids 102-149) does not impede rRNA processing but affects small nucleolar RNA (snoRNA) biogenesis, resulting in the accumulation of slightly extended forms of select snoRNAs, a phenotype unexpectedly shared by the prp43 loss-of-function mutant. These and related observations reveal differences in how the Spp382, Sqs1, and Pxr1 proteins interact with Prp43 and provide evidence linking G-patch identity with pathway-specific DExD/H-box helicase activity.KEYWORDS Saccharomyces cerevisiae; spliceosome; rRNA processing; DExD/H-box protein; pre-mRNA splicing N UMEROUS genome-wide interaction and gene expression studies identify ribosome biogenesis as a central integrative feature of Saccharomyces cerevisiae metabolism (see, e.g ., Mnaimneh et al. 2004;Davierwala et al. 2005;Gavin et al. 2006;Collins et al. 2007;Hu et al. 2007;Magtanong et al. 2011). In rapidly dividing organisms such as this budding yeast, ribosomal RNAs (rRNAs) make up the lion's share of cellular nucleic acid by mass, while ribosomal protein transcripts can account for more than half the transcribed messenger RNA (mRNA). Because ribosome biogenesis is so energetically costly, eukaryotes have evolved multiple means to regulate rRNA and ribosomal protein production in response to changes in cellular demand and surveillance systems to remove aberrant ribosomal protein complexes formed during assembly or after environmental insult (Jorgensen et al. 2002;Fingerman et al. 2003; FromontRacine et al. 2003;Jorgensen et al. 2004;Marion et al. 2004;Henras et al. 2008;Kressler et al. 2010;Lafontaine 2010). The coordination of pre-mRNA processing with ribosome biogenesis is especially relevant in the intron-poor environment of the yeast genome, where the highly expressed ribosomal protein transcr...

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“…Only a handful of natural targets of mRNA surveillance have been identified to date. In yeast, unspliced cytoplasmic pre-mRNAs of CYH2, RP51B, MER2, and CRY2 contain stop codons within the retained introns and are efficiently eliminated by mRNA surveillance (He et al 1993;Li et al 1995). Certain mRNAs that undergo leaky scanning for translation initiation sites are also subject to mRNA surveillance in yeast (Welch and Jacobson 1999).…”

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Unproductively spliced ribosomal protein mRNAs are natural targets of mRNA surveillance in C. elegans

Mitrovich¹,

Anderson²

2000

Genes Dev.

186

172

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Messenger RNA surveillance, the selective and rapid degradation of mRNAs containing premature stop codons, occurs in all eukaryotes tested. The biological role of this decay pathway, however, is not well understood. To identify natural substrates of mRNA surveillance, we used a cDNA-based representational difference analysis to identify mRNAs whose abundance increases in Caenorhabditis elegans smg(−) mutants, which are deficient for mRNA surveillance. Alternatively spliced mRNAs of genes encoding ribosomal proteins L3, L7a, L10a, and L12 are abundant natural targets of mRNA surveillance. Each of these genes expresses two distinct mRNAs. A productively spliced mRNA, whose abundance does not change in smg(−) mutants, encodes a normal, full-length, ribosomal protein. An unproductively spliced mRNA, whose abundance increases dramatically in smg(−) mutants, contains premature stop codons because of incomplete removal of an alternatively spliced intron. In transgenic animals expressing elevated quantities of RPL-12, a greater proportion of endogenous rpl-12 transcript is spliced unproductively. Thus, RPL-12 appears to autoregulate its own splicing, with unproductively spliced mRNAs being degraded by mRNA surveillance. We demonstrate further that alternative splicing of rpl introns is conserved among widely diverged nematodes. Our results suggest that one important role of mRNA surveillance is to eliminate unproductive by-products of gene regulation.

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Feedback Inhibition of the Yeast Ribosomal Protein Gene CRY2 Is Mediated by the Nucleotide Sequence and Secondary Structure of CRY2 Pre-mRNA

Cited by 45 publications

References 82 publications

Expression of a Micro-protein

Expression of a Micro-protein

Limited Portability of G-Patch Domains in Regulators of the Prp43 RNA Helicase Required for Pre-mRNA Splicing and Ribosomal RNA Maturation in Saccharomyces cerevisiae

Unproductively spliced ribosomal protein mRNAs are natural targets of mRNA surveillance in C. elegans

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