The life of U6 small nuclear RNA, from cradle to grave

Didychuk, Allison L.; Butcher, Samuel E.; Brow, David A.

doi:10.1261/rna.065136.117

Cited by 96 publications

(104 citation statements)

References 273 publications

(423 reference statements)

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“…Early work to identify and characterize snRNA genes revealed that U1 and U2 snRNA genes are present as both large multi-copy clusters and pseudogenes of similar sequence spread throughout the genomes of many model organisms (Denison et al, 1981;Denison and Weiner, 1982;Lindgren et al, 1985;Lund and Dahlberg, 1984;Manser and Gesteland, 1982;Van Arsdell and Weiner, 1984). Later, conserved sequence elements were discovered in the promoters of all canonical snRNA genes, and all major snRNAs were discovered to be transcribed by RNA polymerase II (Pol II), except U6 snRNA which is transcribed by RNA polymerase III (reviewed in Didychuk et al, 2018;Guiro and Murphy, 2017). Identification of sequence heterogeneity of U1, U4, and U5 suggested that snRNA variants could be differentially expressed, and it was hypothesized that expression of low abundance snRNAs may regulate alternative splicing (Branlant et al, 1983;Forbes et al, 1984;Krol et al, 1981;Lund, 1988;Lund and Dahlberg, 1987;Sontheimer and Steitz, 1992).…”

Section: Introductionmentioning

confidence: 99%

Transcriptional analysis supports the expression of human snRNA variants and reveals U2 snRNA homeostasis by an abundant U2 variant

Kosmyna

Gupta²,

Query³

2020

Preprint

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Although expansion of snRNA genes in the human genome and sequence variation in expressed transcripts were both identified long ago, no study has comprehensively analyzed which genes are transcriptionally active. Here, we use comprehensive bioinformatic analysis to differentiate between similar or identical genomic loci to determine that 49 snRNA genes are actively transcribed. This greatly expands on previous observation of sequence variation within snRNA transcripts. Further analysis of U2 snRNA variants reveals sequence variation maintains conserved secondary structures, yet sensitizes these U2 snRNAs to modulation of assembly factors. Homeostasis of total U2 snRNA level is maintained by altering the ratio of canonical and an abundant U2 snRNA variant. Both canonical and variant snRNA promoters respond to MYC and appear differentially sensitive to increased MYC levels. Thus, we identify transcribed snRNA variants and the sequence variation within, and propose mechanisms of transcriptional and posttranscriptional regulation of snRNA levels and pre-mRNA splicing. (Summary: 150/150 words) KEYWORDS: U2 snRNA, snRNA pseudogene, spliceosome, Sm binding site HIGHLIGHTS • ChIP-seq of active promoters identifies uncharacterized snRNA genes • Transcribed repetitive snRNA genes are distinguished from falsely-mapped snRNA loci • U2 snRNA variants are sensitive to modulations in snRNP assembly • Widely expressed U2 snRNA variants provide homeostasis for total U2 snRNP levels

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Section: Introductionmentioning

confidence: 99%

Transcriptional analysis supports the expression of human snRNA variants and reveals U2 snRNA homeostasis by an abundant U2 variant

Kosmyna

Gupta²,

Query³

2020

Preprint

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“…U2-U6 and U4-U6 snRNAs are critical structural elements of the spliceosome that are rich in Nm modifications (3). These snRNAs undergo changes in secondary structure and base-pairing which are essential for the assembly and disassembly of the spliceosome as well as in cycling between different conformational states required for catalysis (49,50). Nm modifications in the active core of the spliceosome U2-U6 snRNA complex have been shown to promote a conformational transition between a three-way and four-way junction proposed to aid correct positioning of pre-mRNA for exon ligation (51).…”

Section: Introductionmentioning

confidence: 99%

2’-O-methylation alters the RNA secondary structural ensemble

Assi

Shi

Liu

et al. 2020

Preprint

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2′-O-methyl (Nm) is a highly abundant post-transcriptional RNA modification that plays important biological roles through mechanisms that are not entirely understood. There is evidence that Nm can alter the biological activities of RNAs by biasing the ribose sugar pucker equilibrium toward the C3′endo conformation formed in canonical duplexes. However, little is known about how Nm might more broadly alter the dynamic ensembles of non-canonical RNA motifs. Here, using NMR and the HIV-1 transactivation response (TAR) element as a model system, we show that Nm preferentially stabilizes alternative secondary structures in which the Nm-modified nucleotides are paired, increasing both the abundance and lifetime of a low-populated short-lived excited state by up to 10-fold. The extent of stabilization increased with number of Nm modifications and was also dependent on Mg 2+ . Through phi (Φ) value analysis, the Nm modification also provided rare insights into the structure of the transition state for conformational exchange. Our results suggest that Nm could alter the biological activities of Nm-modified RNAs by modulating their secondary structural ensembles as well as establish the utility of Nm as a tool for the discovery and characterization of RNA excited state conformations.

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“…The Lsm2-8 complex shares 6 out of 7 subunits with Lsm1-7, localizes in the nucleus, and binds the 3' ends of U6 and U6 atac snRNAs (25)(26)(27)(28). U6 snRNA is transcribed by RNA polymerase III, which terminates transcription after synthesis of an oligoU tail at the end of U6 snRNA (29). This tail can then be elongated by the enzyme Tutase (29).…”

Section: Introductionmentioning

confidence: 99%

“…U6 snRNA is transcribed by RNA polymerase III, which terminates transcription after synthesis of an oligoU tail at the end of U6 snRNA (29). This tail can then be elongated by the enzyme Tutase (29). Finally, U6 snRNA is processed by the 3′-5′ exoribonuclease Usb1 (29), resulting in a 2′,3′ cyclic phosphate in most organisms (30) (Figure 1).…”

Section: Introductionmentioning

confidence: 99%

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Molecular basis for the distinct cellular functions of the Lsm1-7 and Lsm2-8 complexes

Eric

Virta

Hayes

et al. 2020

Preprint

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Eukaryotes possess eight highly conserved Lsm (like Sm) proteins that assemble into circular, heteroheptameric complexes, bind RNA, and direct a diverse range of biological processes. Among the many essential functions of Lsm proteins, the cytoplasmic Lsm1-7 complex initiates mRNA decay, while the nuclear Lsm2-8 complex acts as a chaperone for U6 spliceosomal RNA. It has been unclear how these complexes perform their distinct functions while differing by only one out of seven subunits. Here, we elucidate the molecular basis for Lsm-RNA recognition and present four high-resolution structures of Lsm complexes bound to RNAs. The structures of Lsm2-8 bound to RNA identify the unique 2′,3′ cyclic phosphate end of U6 as a prime determinant of specificity. In contrast, the Lsm1-7 complex strongly discriminates against cyclic phosphates and tightly binds to oligouridylate tracts with terminal purines. Lsm5 uniquely recognizes purine bases, explaining its divergent sequence relative to other Lsm subunits. Lsm1-7 loads onto RNA from the 3′ end and removal of the Lsm1 C-terminal region allows Lsm1-7 to scan along RNA, suggesting a gated mechanism for accessing internal binding sites. These data reveal the molecular basis for RNA binding by Lsm proteins, a fundamental step in the formation of molecular assemblies that are central to eukaryotic mRNA metabolism.

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The life of U6 small nuclear RNA, from cradle to grave

Cited by 96 publications

References 273 publications

Transcriptional analysis supports the expression of human snRNA variants and reveals U2 snRNA homeostasis by an abundant U2 variant

Transcriptional analysis supports the expression of human snRNA variants and reveals U2 snRNA homeostasis by an abundant U2 variant

2’-O-methylation alters the RNA secondary structural ensemble

Molecular basis for the distinct cellular functions of the Lsm1-7 and Lsm2-8 complexes

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