Sequences required for 3' end formation of human U2 small nuclear RNA

Xenopus oocytes injected with human U2 snRNA genes synthesize mature U2 as well as a U2 precursor with about 10 extra 3' nucleotides (human pre-U2 RNA). Formation of the pre-U2 3' end requires a downstream element located between position +16 and +37 in the U2 3'-flanking sequence. The distance between this element and the U2 coding region can be increased without affecting formation of the pre-U2 3' end. When the natural sequence surrounding the pre-U2 3' end is changed, novel 3' ends are still generated within a narrow range upstream from the element. The 3' terminal stem-loop of U2 snRNA is not required for pre-U2 3' end formation. A sequence within the 3' element (GTTTN0-3AAAPuNNAGA) is conserved among snRNA genes transcribed by RNA polymerase II. Our results suggest that the 3' ends of pre-U2 RNA and histone mRNA may be generated by related but distinct RNA processing mechanisms.     

Formation of the 3'' end of U1 snRNA is directed by a conserved sequence located downstream of the coding region.

U1 is a small non-polyadenylated nuclear RNA that is transcribed by RNA polymerase II and is known to play a role in mRNA splicing. The mature 3' end of U1 snRNA is formed in at least two steps. The first step generates precursors of U1 RNA with a few extra nucleotides at the 3' end; in the second step, these precursors are shortened to mature U1 RNA. Here, I have determined the sequences required for the first step. Human U1 genes with various deletions and substitutions near the 3' end of the coding region were constructed and introduced into HeLa cells by DNA transfection. The structure of the RNA synthesized during transient expression of the exogenous U1 gene was analyzed by S1 mapping. The results show that a 13 nucleotide sequence located downstream from the U1 coding region and conserved among U1, U2 and U3 genes of different species is the only sequence required to direct the first step in the formation of the 3' end of U1 snRNA.     

The highly conserved U small nuclear RNA 3''-end formation signal is quite tolerant to mutation.

Formation of the 3' end of U1 and U2 small nuclear RNA (snRNA) precursors is directed by a conserved sequence called the 3' box located 9 to 28 nucleotides downstream of all metazoan U1 to U4 snRNA genes sequenced so far. Deletion of part or all of the 3' box from human U1 and U2 genes drastically reduces 3'-end formation. To define the essential nucleotides within this box that direct 3'-end formation, we constructed a set of point mutations in the conserved residues of the human U1 3' box. The ability of the various mutations to direct 3'-end formation was tested by microinjection into Xenopus oocytes and transfection into HeLa cells. We found that the point mutations had diverse effects on 3'-end formation, ranging from no effect at all to severe inhibition; however, no single or double point mutation we tested completely eliminated 3'-end formation. We also showed that a rat U3 3' flank can effectively substitute for the human U1 3' flank, indicating that the 3' boxes of the different U snRNA genes are functionally equivalent.     

Specific contacts between mammalian U7 snRNA and histone precursor RNA are indispensable for the in vitro 3'' RNA processing reaction.

We have made a detailed molecular analysis of the reactions leading to the formation of mature 3' ends in mammalian histone mRNAs. Using two analytical protocols we have identified an essential sequence motif in the downstream spacer which is consistently present, albeit in diffuse form, mammalian histone genes. Tampering with this sequence element completely abolishes 3' processing. However, 3' cleavage in vitro, although at a very much reduced rate, can be detected when the conserved hairpin is deleted from histone precursor mRNAs. U7 snRNA, previously shown to be essential for the maturation of sea urchin histone messages, was isolated from murine cells and the sequence was determined. The approximately 63-nucleotide, trimethyl-G-capped, murine U7 snRNA possesses a sequence shown in the sea urchin U7 to be required for Sm-precipitability, and like the sea urchin U7, the 3' end of murine U7 is encased in a hairpin structure. The 5' sequence of murine U7 exhibits extensive sequence complementarity to the conserved downstream motif of the histone precursor. As expected, oligo-nucleotide-directed RNase H cleavage of this portion of murine U7 inhibits the in vitro processing reaction. These experiments identify a set of specific contacts between mammalian U7 and histone precursor RNA which is indispensable for the maturation reaction.     

Defining a 5' splice site by functional selection in the presence and absence of U1 snRNA 5' end

Pre-mRNA splicing in metazoans is mainly specified by sequences at the termini of introns. We have selected functional 5' splice sites from randomized intron sequences through repetitive rounds of in vitro splicing in HeLa cell nuclear extract. The consensus sequence obtained after one round of selection in normal extract closely resembled the consensus of natural occurring 5' splice sites, suggesting that the selection pressures in vitro and in vivo are similar. After three rounds of selection under competitive splicing conditions, the base pairing potential to the U1 snRNA increased, yielding a G100%U100%R94%A67%G89%U76%R83% intronic consensus sequence. Surprisingly, a nearly identical consensus sequence was obtained when the selection was performed in nuclear extract containing U1 snRNA with a deleted 5' end, suggesting that other factors than the U1 snRNA are involved in 5' splice site recognition. The importance of a consecutive complementarity between the 5' splice site and the U1 snRNA was analyzed systematically in the natural range for in vitro splicing efficiency and complex formation. Extended complementarity was inhibitory to splicing at a late step in spliceosome assembly when pre-mRNA substrates were incubated in normal extract, but favorable for splicing under competitive splicing conditions or in the presence of truncated U1 snRNA where transition from complex A to complex B occurred more rapidly. This suggests that stable U1 snRNA binding is advantageous for assembly of commitment complexes, but inhibitory for the entry of the U4/U6.U5 tri-snRNP, probably due to a delayed release of the U1 snRNP.