Characterization of the catalytic activity of U2 and U6 snRNAs

Hydrolytic stability of 2′,3′-O-methyleneadenos-5′-yl 2′,5′-di-O-methylurid-3′-yl 5′-O-methylurid-3′(2′)-yl phosphate: implications to feasibility of existence of phosphate-branched RNA under physiological conditions

Hydrolytic reactions of 2',3'-O-methyleneadenos-5'-yl 2',5'-di-O-methylurid-3'-yl 5'-O-methylurid-3'(2')-yl phosphate (1a,b) have been followed by RP-HPLC over a wide pH range to evaluate the feasibility of occurrence of phosphate-branched RNA under physiological conditions. At pH <2, where the decomposition of is first order in [H3O+], the P-O5' bond is cleaved 1.5 times as rapidly as the P-O3' bond. Under these conditions, the reaction probably proceeds by an attack of the 2'-OH on the phosphotriester monocation. Over a relatively wide range from pH 2 to 5, the hydrolysis is pH-independent, referring to rapid initial deprotonation of the attacking 2'-OH followed by general acid catalyzed departure of the leaving nucleoside. The P-O5' bond is cleaved 3 times as rapidly as the P-O3' bond. At pH 6, the reaction becomes first order in [HO-], consistent with an attack of the 2'-oxyanion on neutral phosphate. The product distribution is gradually inversed: in 10 mmol L(-1) aqueous sodium hydroxide, cleavage of the P-O3' bond is favored over P-O5' by a factor of 7.3. The results of the present study suggest that the half-life for the cleavage of under physiological conditions is only 100 s. Even at pH 2, where is most stable, the half-life for its cleavage is less than one hour and the isomerization between and is even more rapid than cleavage. The mechanisms of the partial reactions are discussed.

Psi35 in the branch site recognition region of U2 small nuclear RNA is important for pre-mRNA splicing in Saccharomyces cerevisiae

Pseudouridine 35 (psi35) in the branch site recognition region of yeast U2 small nuclear RNA is absolutely conserved in all eukaryotes examined. Pus7p catalyzes pseudouridylation at position 35 in Saccharomyces cerevisiae U2. The pus7 deletion strain, although viable in rich medium, is growth-disadvantaged under certain conditions. To clarify the function of U2 psi35 in yeast, we used this pus7 deletion strain to screen a collection of mutant U2 small nuclear RNAs, each containing a point mutation near the branch site recognition sequence, for a synthetic growth defect phenotype. The screen identified two U2 mutants, one containing a U40 --> G40 substitution (U40G) and another having a U40 deletion (U40Delta). Yeast strains carrying either of these U2 mutations grew as well as the wild-type strain in the selection medium, but they exhibited a temperature-sensitive growth defect phenotype when coupled with the pus7 deletion (pus7Delta). A subsequent temperature shift assay and a conditional pus7 depletion (via GAL promoter shutoff) in the U2-U40 mutant genetic background caused pre-mRNA accumulation, suggesting that psi35 is required for pre-mRNA splicing under certain conditions.

U2-U6 RNA folding reveals a group II intron-like domain and a four-helix junction

Intron removal in nuclear precursor mRNA is catalyzed through two transesterification reactions by a multi-megaDalton ribonucleoprotein machine called the spliceosome. A complex between U2 and U6 small nuclear RNAs is a core component of the spliceosome. Here we present an NMR structural analysis of a protein-free U2-U6 complex from Saccharomyces cerevisiae. The observed folding of the U2-U6 complex is a four-helix junction, in which the catalytically important AGC triad base-pairs only within U6 and not with U2. The base-pairing of the AGC triad extends the U6 intramolecular stem-loop (U6 ISL), and the NMR structure of this extended U6 ISL reveals structural similarities with domain 5 of group II self-splicing introns. The observed conformation of the four-helix junction could be relevant to the first, but not the second, step of splicing and may help to position the U6 ISL adjacent to the 5' splice site.

Pseudouridines in and near the branch site recognition region of U2 snRNA are required for snRNP biogenesis and pre-mRNA splicing in Xenopus oocytes

Virtually all uridines in the branch site recognition region (BSRR) of vertebrate U2 are converted into pseudouridines after initial transcription. Here, we report a functional analysis of these modified nucleotides using the Xenopus oocyte reconstitution system. Using site-specific (32)P-labeling and TLC, we show that U2 pseudouridylation occurs much faster in the BSRR than in the 5'-terminal region. To functionally dissect the pseudouridines in the BSRR, we replaced each uridine with 5-fluorouridine (unmodifiable nucleotide) using site-specific RNase H cleavage directed by 2'-O-methyl-RNA-DNA chimeras followed by three-piece ligation. Whereas in vitro transcribed U2 containing no 5-fluorouridines rescued splicing in U2-depleted oocytes, no rescue was observed with U2 RNA containing 5-fluorouridines introduced into the BSRR. Additionally, U2 RNA containing 5-fluorouridines in the BSRR specifically inhibited pseudouridylation in the BSRR of in vitro transcribed U2 injected at a later time, although pseudouridylation in the 5'-end region was not affected. Our reconstitution results indicated that prior injection into U2-depleted oocytes with U2 RNA containing 5-fluorouridines in the BSRR almost completely abrogated the ability of in vitro transcribed U2 to rescue splicing, whereas full rescue was obtained with either cellular U2 or U2 containing pseudouridines in the BSRR. Further analyses using glycerol-gradient and native gel electrophoresis indicated that U2 RNAs lacking the BSRR pseudouridines do not participate in the assembly of the functionally active 17S U2 snRNP and the spliceosome. We conclude that the BSRR pseudouridines of vertebrate U2 are required for complete snRNP assembly and pre-mRNA splicing in Xenopus oocytes.

Small nucleolar RNAs that guide modification in trypanosomatids: repertoire, targets, genome organisation, and unique functions

Small nucleolar RNAs constitute a family of newly discovered non-coding small RNAs, most of which function in guiding RNA modifications. Two prevalent types of modifications are 2'-O-methylation and pseudouridylation. The modification is directed by the formation of a canonical small nucleolar RNA-target duplex. Initially, RNA-guided modification was shown to take place on rRNA, but recent studies suggest that small nuclear RNA, mRNA, tRNA, and the trypanosome spliced leader RNA also undergo guided modifications. Trypanosomes contain more modifications and potentially more small nucleolar RNAs than yeast, and the increased number of modifications may help to preserve ribosome function under adverse environmental conditions during the cycling between the insect and mammalian host. The genome organisation in clusters carrying the two types of small nucleolar RNAs, C/D and H/ACA-like RNAs, resembles that in plants. However, the trypanosomatid H/ACA RNAs are similar to those found in Archaea and are composed of a single hairpin that may represent the primordial H/ACA RNA. In this review we summarise this new field of trypanosome small nucleolar RNAs, emphasising the open questions regarding the number of small nucleolar RNAs, the repertoire, genome organisation, and the unique function of guided modifications in these protozoan parasites.

Inhibition of pre-mRNA splicing by synthetic branched nucleic acids

The cellular transformation of a precursor mRNA (pre-mRNA) into its mature or functional form proceeds by way of a splicing reaction, in which the exons are ligated to form the mature linear RNA and the introns are excised as branched or lariat RNAs. We have prepared a series of branched compounds (bRNA and bDNA), and studied the effects of such molecules on the efficiency of mammalian pre-mRNA splicing in vitro. Y-shaped RNAs containing an unnatural L-2'-deoxycytidine unit (L-dC) at the 3' termini are highly stabilized against exonuclease hydrolysis in HeLa nuclear extracts, and are potent inhibitors of the splicing pathway. A bRNA containing internal 2'-O-methyl ribopyrimidine units and L-dC at the 3' ends was at least twice as potent as the most potent of the bRNAs containing no 2' modifications, with an IC50 of approximately 5 micro M. Inhibitory activity was maintained in a branched molecule containing an arabino-adenosine branchpoint which, unlike the native bRNAs, resisted cleavage by the lariat- debranching enzyme. The data obtained suggest that binding and sequestering of a branch recognition factor by the branched nucleic acids is an early event, which occurs prior to the first chemical step of splicing. Probably, an early recognition element preferentially binds to the synthetic branched molecules over the native pre-mRNA. As such, synthetic bRNAs may prove to be invaluable tools for the purification and identification of the putative branchpoint recognition factor.