Ro ribonucleoproteins (RNP) constitute a class of evolutionarily conserved small cytoplasmic (sc) RNPs whose functions are unknown. In human cells four distinctive scRNAs designated hY1, hY3, hY4 and hY5 are synthesized by RNA polymerase III (pol III) and accumulate as components of Ro scRNPs. The previously isolated hY1 and hY3 genes contain upstream sequences similar to the class III promoters for U6 and 7SK snRNAs. Additional mammalian Y scRNA genes have been refractory to cloning due to interference from numerous hY-homologous pseudogenes and studies of hY RNA genes have been sparse. Although homologs of hY1 and hY3 RNAs exist in rodent cells, the smaller Y4 and Y5 RNAs do not which has allowed us to localize the hY4 scRNA gene to human chromosome 7 by assaying for its transcript in rodent X human somatic cell hybrids (SCH). A chromosome 7-enriched yeast artificial chromosome (YAC) library was then screened and the authentic hY4 sequence was isolated by strepavidin--biotin-mediated hybrid-selection followed by poly(dA)-tailing and hemispecific PCR. The region upstream of the hY4 sequence contains a TATAAAA motif centered at -26, a candidate proximal sequence element at -63, and three octamer-like sequences located between -260 and -200. hY4 RNA is readily detectable on Northern blots after transient transfection of the hY4 gene into mouse cells but not after transfection of a construct in which the 5' flanking region was deleted. SCHs and chromosome 7-enriched YACs were used to demonstrate that all four hY RNA genes reside on human chromosome 7.
Nearly 1 million Alu elements in human DNA were inserted by an RNA-mediated retroposition-amplification process that clearly decelerated about 30 million years ago. Since then, Alu sequences have proliferated at a lower rate, including within the human genome, in which Alu mobility continues to generate genetic variability. Initially derived from 7SL RNA of the signal recognition particle (SRP), Alu became a dominant retroposon while retaining secondary structures found in 7SL RNA. We previously identified a human Alu RNA-binding protein as a homolog of the 14-kDa Alu-specific protein of SRP and have shown that its expression is associated with accumulation of 3-processed Alu RNA. Here, we show that in early anthropoids, the gene encoding SRP14 Alu RNA-binding protein was duplicated and that SRP14-homologous sequences currently reside on different human chromosomes. In anthropoids, the active SRP14 gene acquired a GCA trinucleotide repeat in its 3-coding region that produces SRP14 polypeptides with extended C-terminal tails. A C3G substitution in this region converted the mouse sequence CCA GCA to GCA GCA in prosimians, which presumably predisposed this locus to GCA expansion in anthropoids and provides a model for other triplet expansions. Moreover, the presence of the trinucleotide repeat in SRP14 DNA and the corresponding C-terminal tail in SRP14 are associated with a significant increase in SRP14 polypeptide and Alu RNA-binding activity. These genetic events occurred during the period in which an acceleration in Alu retroposition was followed by a sharp deceleration, suggesting that Alu repeats coevolved with C-terminal variants of SRP14 in higher primates.Ample evidence indicates that amplification of short interspersed elements (SINEs) occurred via reverse transcription of small RNA intermediaries in a process termed retroposition (52). The SINEs of many organisms are related to one or another tRNA, and these have been found widely distributed in nature, including in plants, fish, and mammals (see references 13, 43, and 44 and references therein). The Alu family of SINEs was derived from the terminal portions of the 7SL RNA component of the signal recognition particle (SRP), a small ribonucleoprotein involved in intracellular protein trafficking (6,24,27,70,71,74,77). In contrast to tRNA-like SINEs, and despite the ubiquity of 7SL SRP RNAs, Alu-related SINEs are for unknown reasons mostly limited to rodents and primates (for a recent review, see reference 13).Evolution of Alu-related SINEs apparently occurred in two major phases: an ancient period during which Alu sequences emerged as monomeric elements followed by a period of remodelling and proliferation (see reference 50 and references therein). The discovery of fossil Alu sequences provided evidence that an Alu monomer originated in an ancestor common to rodents and primates (50). The monomeric Alu-equivalent SINE referred to as B1 has since undergone substantial divergence from 7SL during its amplification to ϳ50,000 to 80,000 copies per haploid genom...
We synthesized two types of chimeric RNAs between the catalytic RNA subunit of RNase P from Escherichia coli (M1 RNA) and a tRNA precursor (pre-tRNA); one had pre-tRNA at the 3' side to the M1 RNA (M1 RNA-pre-tRNA). The second had pre-tRNA at the 5' side of the M1 RNA (pre-tRNA-M1 RNA). Both molecules were self-cleaving RNAs. The self-cleavage of M1 RNA-pre-tRNA occurred at the normal site (5'-end of mature tRNA sequence) and proceeded under the condition of 10 mM Mg2+ concentration. This reaction at 10 mM Mg2+ was an intramolecular reaction (cis-cleavage), while, at 40 mM and 80 mM Mg2+, trans-cleavage partially occurred. The self-cleavage rate was strictly affected by the distance between the M1 RNA and the pre-tRNA in the molecule. The self-cleavage of pre-tRNA-M1 RNA occurred mainly at three sites within the mature tRNA sequence. This cleavage did not occur at 10 mM Mg2+. Use of M1 RNA-pre-tRNA molecule for the in vitro evolution of M1 RNA is discussed.
The hairpin rtbozyme cleaves a phosphodiester bond at the 5' side of a 5'GUC3' sequence of an RNA with high efficiency. An RNA having a 5'GUA3' sequence instead of the GUC sequence is a poor substrate for this ribozyme Here, we show that this is indeed so in a frcms-acting ribozyme system. but in a cis-acting ribozyme system this ribozyme cleaves the 5' side of a GUA sequence as efficiently as the wild-type cleaves the GUC sequence. One base substitution in the ribozyme also affected the target-site specificity in the cu-acting system. Catalytic RNA; Satellite RNA: Tobacco rmgspot virus; Arabis mosaic virus: Chicory yellow mottle virus
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