A small nucleolar RNA is processed from an intron of the human gene encoding ribosomal protein S3.

Tycowski, Kazimierz T.; Shu, Mei‐Di; Steitz, Joan A.

doi:10.1101/gad.7.7a.1176

Cited by 182 publications

(152 citation statements)

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“…This peculiar mechanism has been demonstrated to be involved also in the production of the other snoRNAs recently found to be encoded in introns, U14, U15 U16 and HeLa U17 RNAs (7)(8)(9)41). In the case of U16 RNA, encoded in an intron of the Xenopus gene for r-protein L1, it has been shown that its production is alternative to that of the mature Li mRNA (8).…”

Section: Discussionmentioning

confidence: 99%

U17^XS8, a small nucleolar RNA with a 12 nt complementarity to 18S rRNA and coded by a sequence repeated in the six introns ofXenopus laevisribosomal protein S8 gene

et al. 1994

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Section: Discussionmentioning

confidence: 99%

U17^XS8, a small nucleolar RNA with a 12 nt complementarity to 18S rRNA and coded by a sequence repeated in the six introns ofXenopus laevisribosomal protein S8 gene

et al. 1994

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“…The importance of this helix in accu mulation of a yeast ACA snoRNA, snRl 1, has been dem onstrated (Balakin et al 1996). Interestingly, many box C/D snoRNAs feature a stem structure similar to helix II (Tycowski et al 1993;Watkins et al 1996). Although this helix is dispensable for the accumulation of U14 snoRNA, it has been implicated in the processing of box C/D snoRNAs, which lack a 5',3' terminal stem struc ture (helix I) (Watkins et al 1996).…”

Section: Genes and Developmentmentioning

confidence: 99%

“…Accumulating evidence suggests that excision of intronic snoRNAs relies on exonucleolytic activities Filipowicz 1993, 1995;Xia et al 1997). The C, D, and ACA boxes of snoRNAs have been postulated to bind putative protein factor(s) which could delineate the terminal boundaries by protecting the snoRNAs from exonucleolytic degradation (Huang et al 1992;Tycowski et al 1993;Balakin et al 1994Balakin et al , 1996Caffarelli et al 1996;Watkins et al 1996;Xia et al 1997).…”

Section: The Two Major Classes Of Snornas Show Intriguing Similaritiesmentioning

confidence: 99%

“…The U3 snoRNA is required for an early cleavage in the 5' external transcribed spacer (Kass et al 1990;Hughes and Ares 1991;Mougey et al 1993) and also for subsequent formation of mature 18S rRNA (Savino and Gerbi 1990;Hughes and Ares 1991). Likewise, the U14 and U22 snoRNAs are essential for the accumulation of IBS rRNA (Li et al 1990;Tycowski et al 1994), whereas the US snoRNA is implicated in the processing of 5.8S and 28S rRNAs (PecuUs and Steitz 1993). More recently, a large subset of box C/D snoRNAs have been demon strated to function as guide RNAs in site-specific ribose methylation of pre-rRNAs (Kiss-Laszlo et al 1996;Nicoloso et al 1996).…”

mentioning

confidence: 99%

“…The snoRNAs are either tran scribed by RNA polymerase II (Pol II) from independent genes or they are processed from intron regions of premRNAs (for review, see Maxwell and Fournier 1995). The mature intron-encoded snoRNAs possess mono phosphates at their 5' ends (Kiss and Filipowicz 1993;Tycowski et al 1993), whereas the 5' termini of Pol IItranscribed snoRNAs are blocked by trimethylguanosine caps (Maxwell and Fournier 1995).…”

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confidence: 99%

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The family of box ACA small nucleolar RNAs is defined by an evolutionarily conserved secondary structure and ubiquitous sequence elements essential for RNA accumulation.

Ganot¹,

Caizergues‐Ferrer²,

Kiss³

1997

Genes Dev.

319

387

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Eukaryotic cells contain a large number of small nucleolar RNAs (snoRNAs).A major family of snoRNAs features a consensus ACA motif positioned 3 nucleotides from the 3' end of the RNA. In this study we have characterized nine novel human ACA snoRNAs (U64-U72). Structural probing of U64 RNA followed by systematic computer modeling of all known box ACA snoRNAs revealed that this class of snoRNAs is defined by a phylogenetically conserved secondary structure. The ACA snoRNAs fold into two hairpin structures connected by a single-stranded hinge region and followed by a short 3' tail. In eukaryotic cells, maturation of rRNAs takes place in the nucleolus. The 18S, 5.8S, and 25/28S rRNAs are syn thesized as a large precursor RNA (pre-rRNA) that car ries long external and internal spacer sequences. Shortly after transcription, many nucleotides in the coding re gions of pre-rRNA are methylated at the 2'-0-hydroxyl position and numerous U residues are converted into pseudouridines (Maden 1990;Eichler and Craig 1995). The covalently modified pre-rRNA is than processed into mature rRNAs through a series of endo-and exonucleolytic cleavages (Eichler and Craig 1995; Venema and Tollervey 1995;Sollner-Webb et al. 1996).The nucleolus contains a large number of snoRNAs. More than 80 distinct small nucleolar RNA (snoRNA) sequences have been identified in vertebrate and yeast

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Coiled bodies are predisposed to a spatial association with genes that contain snoRNA sequences in their introns

et al. 1999

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Small nucleolar RNAs (snoRNAs) constitute a group of more than 100 different stable RNA molecules that are found concentrated in the nucleolus where they are involved in the maturation of ribosomal RNA. Most snoRNAs are not produced from their own genes but are encoded in the introns of other genes, referred to as snoRNA host genes. Little is known about the mechanisms by which the snoRNAs are produced from introns and how the snoRNAs mature to functional snoRNP complexes in the nucleolus. One class of intron-encoded snoRNAs binds with high specificity to the protein fibrillarin which is found concentrated in the nucleolus, but also in small nuclear domains known as coiled bodies. It has become clear that genes that code for small stable RNAs, e.g., U1, U2 snRNA, and the U3 snoRNA, are often found adjacent to coiled bodies. High concentrations of transcription factors and RNA processing factors in and around coiled bodies indicate that they may be involved in the expression of the adjacent genes. In order to investigate whether coiled bodies could play a role in the synthesis of intron-encoded snoRNAs the distribution of coiled bodies was studied relative to three different snoRNA host genes, i.e., hsc70, RPS3, UHG. All three were found adjacent to coiled bodies at significantly high frequencies (11-19%), compared to control sequences (0-2%), to conclude a preferential association between the snoRNA host genes and coiled bodies. This association could point to a possible role for coiled bodies in the synthesis and/or maturation of snoRNAs. An involvement in snoRNA production could explain the presence of transcription factors, splicing factors, and fibrillarin in coiled bodies.

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A small nucleolar RNA is processed from an intron of the human gene encoding ribosomal protein S3.

Cited by 182 publications

References 58 publications

U17^XS8, a small nucleolar RNA with a 12 nt complementarity to 18S rRNA and coded by a sequence repeated in the six introns ofXenopus laevisribosomal protein S8 gene

U17^XS8, a small nucleolar RNA with a 12 nt complementarity to 18S rRNA and coded by a sequence repeated in the six introns ofXenopus laevisribosomal protein S8 gene

The family of box ACA small nucleolar RNAs is defined by an evolutionarily conserved secondary structure and ubiquitous sequence elements essential for RNA accumulation.

Coiled bodies are predisposed to a spatial association with genes that contain snoRNA sequences in their introns

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A small nucleolar RNA is processed from an intron of the human gene encoding ribosomal protein S3.

Cited by 182 publications

References 58 publications

U17XS8, a small nucleolar RNA with a 12 nt complementarity to 18S rRNA and coded by a sequence repeated in the six introns ofXenopus laevisribosomal protein S8 gene

U17XS8, a small nucleolar RNA with a 12 nt complementarity to 18S rRNA and coded by a sequence repeated in the six introns ofXenopus laevisribosomal protein S8 gene

The family of box ACA small nucleolar RNAs is defined by an evolutionarily conserved secondary structure and ubiquitous sequence elements essential for RNA accumulation.

Coiled bodies are predisposed to a spatial association with genes that contain snoRNA sequences in their introns

Contact Info

Product

Resources

About

U17^XS8, a small nucleolar RNA with a 12 nt complementarity to 18S rRNA and coded by a sequence repeated in the six introns ofXenopus laevisribosomal protein S8 gene

U17^XS8, a small nucleolar RNA with a 12 nt complementarity to 18S rRNA and coded by a sequence repeated in the six introns ofXenopus laevisribosomal protein S8 gene