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1 molecules formed by back splicing of linear precursor RNA.
2 inct miRNAs that are transcribed in a common precursor RNA.
3 inding domains and interacts with capped 21U precursor RNA.
4 BF1 and UBF2 are splice variants of a common precursor RNA.
5 repressing alternative splicing of the viral precursor RNA.
6 becomes associated with complexes containing precursor RNA.
7 ing from processing of a circularly permuted precursor RNA.
8 ngle gene and the same alternatively spliced precursor RNA.
9 romoter and transcribed into a monocistronic precursor RNA.
10 splicing of multiple products from a single precursor RNA.
11 he complex correctly processes the 3'-end of precursor RNA.
12 on of mtDNA entails multi-step maturation of precursor RNA.
13 reveal the existence of four different psbH precursor RNAs.
14 RNAs from dsRNA as well as synthetic miR167b precursor RNAs.
15 ecessary and sufficient for processing miRNA precursor RNAs.
16 nvolving trans-splicing of two discontinuous precursor RNAs.
17 to liberate stable 3' fragments from various precursor RNAs.
18 t Pol II inactivated splicing of this set of precursor RNAs and addition of recombinant CTD restored
19 drives transcription of both pachytene piRNA precursor RNAs and the mRNAs for core piRNA biogenesis f
20 the 5' splice site, cross-linking of U2AF to precursor RNA, and assembly of the active spliceosome, s
21 lated in extract, became associated with the precursor RNA, and stimulated the association of U1 snRN
22 th in its processed form and as a repetitive precursor RNA, and this inhibition is linked to the self
24 Group II introns are usually removed from precursor RNAs as lariats comprised of a circular compon
25 smaller amount is associated with unspliced precursor RNA, as expected from the role of the protein
26 occurs by reverse transcription of unspliced precursor RNA at a break in double-strand DNA made by an
28 Unlike most introns, which are removed from precursor RNAs by the spliceosome in two sequential but
29 ing introns catalyze their own excision from precursor RNAs by way of a two-step transesterification
30 ernative splicing of a single neosynthesized precursor RNA can result in production of different prot
31 re we show that in splicing reactions with a precursor RNA containing a 3'-sulphur substitution at th
34 tivated in vitro polyadenylation cleavage of precursor RNAs containing the CT/CGRP exon 4 poly(A) sit
35 eaves two phosphodiester bonds within folded precursor RNAs during intron removal, producing the func
37 t for the observed increase in nuclear P450R precursor RNA, followed by a decrease back to basal tran
38 nd clusters and block production of putative precursor RNAs from both strands of the major 42AB dual-
40 response elements in the promoter of the LAT precursor RNA; (iii) ATF3 is induced nearly 100-fold in
42 s occurs soon after the synthesis of its 47S precursor RNA in the nucleolus before cleavage to smalle
43 ted disruption of PTB interaction with FGFR1 precursor RNA in vivo by an antisense oligonucleotide al
45 ila melanogaster a developmentally regulated precursor RNA is cleaved by an RNA interference-like mec
46 aberrant RNA splicing, the process by which precursor RNA is converted into mature messenger RNA, in
50 plausible mechanism by which RNA itself (or precursor RNA-like polymers) can be synthesized nonenzym
51 ory pathways, the endonuclease Dicer cleaves precursor RNA molecules to produce microRNAs (miRNAs) an
52 nce and results in accumulation of unspliced precursor RNAs of dimeric tRNA(Ser)-tRNA(Met)i, suggesti
54 II-mediated transcription of a single common precursor RNA (pri-miRNA) encoding both mature miRNAs.
55 , function in mitochondria being involved in precursor RNA processing and mitoribosome biogenesis. Is
58 We further determined the size of CopepodSL precursor RNA (slRNA; 108-158 nt) through genomic analys
59 ed from either the 5' or 3' ends of the same precursor RNA strand, are increased in the hippocampus f
60 the overall binding isotherm of Cbp2 for the precursor RNA, suggesting that contacts critical for act
63 The proteins bind specifically to unspliced precursor RNA to promote splicing, and then remain assoc
64 ll ribonucleoproteins (sRNPs) target nascent precursor RNAs to guide folding, modification, and splic
65 ding transcription and cleavage of the miRNA precursor RNAs, to generate a mature miRNA, which is tho
67 -splicing introns catalyze autoexcision from precursor RNA transcripts by a mechanism strikingly simi
70 nad5 requires the assembly of three distinct precursor RNAs via trans-splicing reactions, and the acc
71 ate transcription of gene pieces, joining of precursor RNAs via trans-splicing, and RNA editing by su
72 NA for viral protein synthesis and as virion precursor RNA (vpRNA) for encapsidation remains an impor
73 uclear extracts if, and only if, the assayed precursor RNA was recognized via exon definition, i.e.,
74 Rlp7p-depleted cells accumulate the 27SA(3) precursor RNA, which is normally the major substrate (85
75 ific splicing factor that binds to unspliced precursor RNA with a K(d) of </=0.12 pM at 30 degrees C.