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.     

A human U2 RNA mutant stalled in 3' end processing is impaired in nuclear import.

The biosynthesis of U1, U2, U4 and U5 spliceosomal small nuclear RNAs (snRNAs) involves the nuclear export of precursor molecules extended at their 3' ends, followed by a cytoplasmic phase during which the pre-snRNAs assemble into ribonucleoprotein particles and undergo hypermethylation of their 5' caps and 3' end processing prior to nuclear import. Previous studies have demonstrated that the assembly of pre-snRNAs into ribonucleoprotein particles containing the Sm core proteins is essential for nuclear import in mammalian cells but that 5' cap hypermethylation is not. In the present investigation we have asked whether or not 3' end processing is required for nuclear import of U2 RNA. We designed human pre-U2 RNAs that carried modified 3' tails, and identified one that was stalled (or greatly slowed) in 3' end processing, leading to its accumulation in the cytoplasm of human cells. Nonetheless, this 3' processing arrested pre-U2 RNA molecule was found to undergo cytoplasmic assembly into Sm protein-containing complexes to the same extent as normal pre-U2 RNA. The Sm protein-associated, unprocessed mutant pre-U2 RNA was not observed in the nuclear fraction. Using an assay based on suppression of a genetically blocked SV40 pre-mRNA splicing pathway, we found that the 3' processing deficient U2 RNA was significantly reduced in its ability to rescue splicing, consistent with its impaired nuclear import.     

Nuclear processing of the 3''-terminal nucleotides of pre-U1 RNA in Xenopus laevis oocytes.

U1 small nuclear RNA is synthesized as a precursor with several extra nucleotides at its 3' end. We show that in Xenopus laevis oocytes, removal of the terminal two nucleotides occurs after the RNA has transited through the cytoplasm and returned to the nucleus. The activity is controlled by an inhibitor of processing, which we call TPI, for 3'-terminal processing inhibitor. This inhibitor is sensitive to both micrococcal nuclease and trypsin treatment, indicating that it is a nucleoprotein. TPI inhibits the 3' processing of pre-U1 RNAs that have 5' ends containing m7G caps but not mature m2,2,7G caps; this finding suggests that TPI interacts directly or indirectly with the 5' end of pre-U1 RNA. The inhibition of processing by TPI, almost complete at 19 degrees C, is reversibly inactivated at slightly higher temperatures. TPI activity is solely in the soluble fraction of oocyte nuclear extracts, in contrast to the 3'-terminal processing activity, which is present in both the particulate and soluble fractions. We propose that the differential processing of the 3'-terminal nucleotides of pre-U1 RNA after its return from the cytoplasm, but not before its exit from the nucleus, may be due to the association of TPI with the m7G cap on the newly synthesized pre-U1 RNA.     

Ribonucleoprotein organization of eukaryotic RNA. XXXII. U2 small nuclear RNA precursors and their accurate 3' processing in vitro as ribonucleoprotein particles

Biosynthetic precursors of U2 small nuclear RNA have been identified in cultured human cells by hybrid-selection of pulse-labeled RNA with cloned U2 DNA. These precursor molecules are one to approximately 16 nucleotides longer than mature U2 RNA and contain 2,2,7-trimethylguanosine "caps". The U2 RNA precursors are associated with proteins that react with a monoclonal antibody for antigens characteristic of small nuclear ribonucleoprotein particles. Like previously described precursors of U1 and U4 small nuclear RNAs, the pre-U2 RNAs are recovered in cytoplasmic fractions, although it is not known if this is their location in vivo. The precursors are processed to mature-size U2 RNA when cytoplasmic extracts are incubated in vitro at 37 degrees C. Mg2+ is required but ATP is not. The ribonucleoprotein structure of the pre-U2 RNA is maintained during the processing reaction in vitro, as are the 2,2,7-trimethylguanosine caps. The ribonucleoprotein organization is of major importance, as exogenous, protein-free U2 RNA precursors are degraded rapidly in the in vitro system. Two lines of evidence indicate that the conversion of U2 precursors to mature-size U2 RNA involves a 3' processing reaction. First, the reaction is unaffected by a large excess of mature U2 small nuclear RNP, whose 5' trimethylguanosine caps would be expected to compete for a 5' processing activity. Second, when pre-U2 RNA precursors are first stoichiometrically decorated with an antibody specific for 2,2,7-trimethylguanosine, the extent of subsequent processing in vitro is unaffected. These results provide the first demonstration of a eukaryotic RNA processing reaction in vitro occurring within a ribonucleoprotein particle.     

A new interaction between the mouse 5'' external transcribed spacer of pre-rRNA and U3 snRNA detected by psoralen crosslinking.

The first cleavage in mammalian pre-rRNA processing occurs within the 5' external transcribed spacer (ETS). We have recently shown that the U3 snRNP is required for this cleavage reaction, binds to the rRNA precursor, and remains complexed with the downstream processing product after the reaction has been completed (1). Using psoralen crosslinking in mouse cell extract we have detected a new interaction between U3 RNA and the mouse ETS processing substrate and its processed product. The crosslinked sites on both U3 and ETS RNAs have been mapped by RNase H cleavage and primer extension analyses. The crosslinked sites in U3 RNA map to C5, U6, and U8. U8 lies within and C5 and U6 are adjacent to an evolutionarily conserved U3 sequence termed box A'. In the ETS the crosslinked sites are U1012 and U1013, 362 nucleotides downstream from the processing site. Although the crosslinked site is dispensable for the primary processing reaction in vitro, a short conserved sequence just 3' to the cleavage site (nucleotides 650-668) is absolutely required for crosslink formation. We conclude that the interaction between U3 RNA and the 5' ETS detected by psoralen crosslinking may play a role in subsequent step(s) of pre-rRNA processing.     

The site of 3'' end formation of histone messenger RNA is a fixed distance from the downstream element recognized by the U7 snRNP.

Two conserved elements direct the 3' end processing of histone messenger RNA: a stem-loop structure immediately upstream of the site of cleavage and the histone downstream element (HDE), located 12-19 nucleotides downstream of the stem-loop in the premessenger RNA. We studied the role of these two elements by systematically inserting up to 10 C residues between them in the mouse H2A-614 histone pre-mRNA. 3' End mapping of RNAs processed in vitro demonstrated that as the HDE is move downstream, the site of cleavage correspondingly moves 3'. In addition, the efficiency of processing declines. In the wild-type substrate, cleavage occurs 3' of an A residue; modest increases in the efficiency of processing of the insertion mutants were observed when an A residue was placed at the new cleavage site. The results of psoralen cross-linking studies and immunoprecipitations using anti-trimethylguanosine antibodies indicated that the decreased processing efficiency of the insertion mutants is not due to impaired binding of the U7 small nuclear ribonucleoprotein (snRNP). We conclude that the mammalian U7 snRNP acts as a molecular ruler, targeting enzymatic components of cleave histone pre-mRNAs a fixed distance from its binding site, the HDE.     

A complex pathway for 3' processing of the yeast U3 snoRNA

Mature U3 snoRNA in yeast is generated from the 3′-extended precursors by endonucleolytic cleavage followed by exonucleolytic trimming. These precursors terminate in poly(U) tracts and are normally stabilised by binding of the yeast La homologue, Lhp1p. We report that normal 3′ processing of U3 requires the nuclear Lsm proteins. On depletion of any of the five essential proteins, Lsm2–5p or Lsm8p, the normal 3′-extended precursors to the U3 snoRNA were lost. Truncated fragments of both mature and pre-U3 accumulated in the Lsm-depleted strains, consistent with substantial RNA degradation. Pre-U3 species were co-precipitated with TAP-tagged Lsm3p, but the association with spliced pre-U3 was lost in strains lacking Lhp1p. The association of Lhp1p with pre-U3 was also reduced on depletion of Lsm3p or Lsm5p, indicating that binding of Lhp1p and the Lsm proteins is interdependent. In contrast, a tagged Sm-protein detectably co-precipitated spliced pre-U3 species only in strains lacking Lhp1p. We propose that the Lsm2–8p complex functions as a chaperone in conjunction with Lhp1p to stabilise pre-U3 RNA species during 3′ processing. The Sm complex may function as a back-up to stabilise 3′ ends that are not protected by Lhp1p.     

The sequence of the 5' end of the U8 small nucleolar RNA is critical for 5.8S and 28S rRNA maturation.

Ribosome biogenesis in eucaryotes involves many small nucleolar ribonucleoprotein particles (snoRNP), a few of which are essential for processing pre-rRNA. Previously, U8 snoRNA was shown to play a critical role in pre-rRNA processing, being essential for accumulation of mature 28S and 5.8S rRNAs. Here, evidence which identifies a functional site of interaction on the U8 RNA is presented. RNAs with mutations, insertions, or deletions within the 5'-most 15 nucleotides of U8 do not function in pre-rRNA processing. In vivo competitions in Xenopus oocytes with 2'O-methyl oligoribonucleotides have confirmed this region as a functional site of a base-pairing interaction. Cross-species hybrid molecules of U8 RNA show that this region of the U8 snoRNP is necessary for processing of pre-rRNA but not sufficient to direct efficient cleavage of the pre-rRNA substrate; the structure or proteins comprising, or recruited by, the U8 snoRNP modulate the efficiency of cleavage. Intriguingly, these 15 nucleotides have the potential to base pair with the 5' end of 28S rRNA in a region where, in the mature ribosome, the 5' end of 28S interacts with the 3' end of 5.8S. The 28S-5.8S interaction is evolutionarily conserved and critical for pre-rRNA processing in Xenopus laevis. Taken together these data strongly suggest that the 5' end of U8 RNA has the potential to bind pre-rRNA and in so doing, may regulate or alter the pre-rRNA folding pathway. The rest of the U8 particle may then facilitate cleavage or recruitment of other factors which are essential for pre-rRNA processing.     

3' end processing of mouse histone pre-mRNA: evidence for additional base-pairing between U7 snRNA and pre-mRNA.

We have analysed the extent of base-pairing interactions between spacer sequences of histone pre-mRNA and U7 snRNA present in the trans-acting U7 snRNP and their importance for histone RNA 3' end processing in vitro. For the efficiently processed mouse H4-12 gene, a computer analysis revealed that additional base pairs could be formed with U7 RNA outside of the previously recognised spacer element (stem II). One complementarity (stem III) is located more 3' and involves nucleotides from the very 5' end of U7 RNA. The other, more 5' located complementarity (stem I) involves nucleotides of the Sm binding site of U7 RNA, a part known to interact with snRNP structural proteins. These potential stem structures are separated from each other by short internal loops of unpaired nucleotides. Mutational analyses of the pre-mRNA indicate that stems II and III are equally important for interaction with the U7 snRNP and for processing, whereas mutations in stem I have moderate effects on processing efficiency, but do not impair complex formation with the U7 snRNP. Thus nucleotides near the processing site may be important for processing, but do not contribute to the assembly of an active complex by forming a stem I structure. The importance of stem III was confirmed by the ability of a complementary mutation in U7 RNA to suppress a stem III mutation in a complementation assay using Xenopus laevis oocytes. The main role of the factor(s) binding to the upstream hairpin loop is to stabilise the U7-pre-mRNA complex. This was shown by either stabilising (by mutation) or destabilising (by increased temperature) the U7-pre-mRNA base-pairing under conditions where hairpin factor binding was either allowed or prevented (by mutation or competition). The hairpin dependence of processing was found to be inversely related to the strength of the U7-pre-mRNA interaction.     

Nucleocytoplasmic transport and processing of small nuclear RNA precursors.

We have analyzed the structures and locations of small nuclear RNA (snRNA) precursors at various stages in their synthesis and maturation. In the nuclei of pulse-labeled Xenopus laevis oocytes, we detected snRNAs that were longer than their mature forms at their 3' ends by up to 10 nucleotides. Analysis of the 5' caps of these RNAs and pulse-chase experiments showed that these nuclear snRNAs were precursors of the cytoplasmic pre-snRNAs that have been observed in the past. Synthesis of pre-snRNAs was not abolished by wheat germ agglutinin, which inhibits export of the pre-snRNAs from the nucleus, indicating that synthesis of these RNAs is not obligatorily coupled to their export. Newly synthesized U1 RNAs could be exported from the nucleus regardless of the length of the 3' extension, but pre-U1 RNAs that were elongated at their 3' ends by more than about 10 nucleotides were poor substrates for trimming in the cytoplasm. The structure at the 3' end was critical for subsequent transport of the RNA back to the nucleus. This requirement ensures that truncated and incompletely processed U1 RNAs are excluded from the nucleus.     

A 5'-3' exonuclease activity involved in forming the 3' products of histone pre-mRNA processing in vitro.

Histone RNA 3' processing in vitro produces one or more 5' cleavage products corresponding to the mature histone mRNA 3' end, and a group of 3' cleavage products whose 5' ends are mostly located several nucleotides downstream of the mRNA 3' end. The formation of these 3' products is coupled to the formation of 5' products and dependent on the U7 snRNP and a heat-labile processing factor. These short 3' products therefore are a true and general feature of the processing reaction. Identical 3' products are also formed from a model RNA containing all spacer nucleotides downstream of the mature mRNA 3' end, but no sequences from the mature mRNA. Again, this reaction is dependent on both the U7 snRNP and a heat-labile factor. Unlike the processing with a full-length histone pre-mRNA, this reaction produces only 3' but no 5' fragments. In addition, product formation is inhibited by addition of cap structures at the model RNA 5' end, indicating that product formation occurs by 5'-3' exonucleolytic degradation. This degradation of a model 3' product by a 5'-3' exonuclease suggests a mechanism for the release of the U7 snRNP after processing by shortening the cut-off histone spacer sequences base paired to U7 RNA.     

Early evolution of histone mRNA 3' end processing

The replication-dependent histone mRNAs in metazoa are not polyadenylated, in contrast to the bulk of mRNA. Instead, they contain an RNA stem-loop (SL) structure close to the 3' end of the mature RNA, and this 3' end is generated by cleavage using a machinery involving the U7 snRNP and protein factors such as the stem-loop binding protein (SLBP). This machinery of 3' end processing is related to that of polyadenylation as protein components are shared between the systems. It is commonly believed that histone 3' end processing is restricted to metazoa and green algae. In contrast, polyadenylation is ubiquitous in Eukarya. However, using computational approaches, we have now identified components of histone 3' end processing in a number of protozoa. Thus, the histone mRNA stem-loop structure as well as the SLBP protein are present in many different protozoa, including Dictyostelium, alveolates, Trypanosoma, and Trichomonas. These results show that the histone 3' end processing machinery is more ancient than previously anticipated and can be traced to the root of the eukaryotic phylogenetic tree. We also identified histone mRNAs from both metazoa and protozoa that are polyadenylated but also contain the signals characteristic of histone 3' end processing. These results provide further evidence that some histone genes are regulated at the level of 3' end processing to produce either polyadenylated RNAs or RNAs with the 3' end characteristic of replication-dependent histone mRNAs.     

RNA heptamers that direct RNA cleavage by mammalian tRNA 3' processing endoribonuclease.

Mammalian tRNA 3' processing endoribonuclease (3' tRNase) can recognize and cleave any target RNA that forms a precursor tRNA-like complex with another RNA. Various sets of RNA molecules were tested to identify the smallest RNA that can direct target RNA cleavage by 3' tRNase. A 3' half tRNAArgwas cleaved efficiently by 3' tRNase in the presence of small 5' half tRNAArgvariants, the D stem-loop region of which was partially deleted. Remarkably, 3' tRNase also cleaved the 3' half tRNAArgin the presence of a 7 nt 5' tRNAArg composed only of the acceptor stem region with a catalytic efficiency comparable with that of cleavage directed by an intact 5' half tRNAArg. The catalytic efficiency of cleavage directed by the heptamer decreased as the stability of the T stem-loop structures of 3' half tRNAArg variants decreased. No heptamer-directed cleavage of a 3' half tRNAArg without T stem base pairs was detected. A heptamer also directed cleavage of an HIV-1 RNA containing a stable hairpin structure. These findings suggest that in the presence of an RNA heptamer, 3' tRNase can discriminate and eliminate target RNAs that possess a stable hairpin adjacent to the heptamer binding sequence from a large complex RNA pool.     

Characterization of 3'hExo, a 3' exonuclease specifically interacting with the 3' end of histone mRNA

The 3' end of mammalian histone mRNAs consisting of a conserved stem-loop and a terminal ACCCA interacts with a recently identified human 3' exonuclease designated 3'hExo. The sequence-specific interaction suggests that 3'hExo may participate in the degradation of histone mRNAs. ERI-1, a Caenorhabditis elegans homologue of 3'hExo, has been implicated in degradation of small interfering RNAs. We introduced a number of mutations to 3'hExo to identify residues required for RNA binding and catalysis. To assure that the introduced mutations specifically target one of these two activities of 3'hExo rather than cause global structural defects, the mutant proteins were tested in parallel for the ability both to bind the stem-loop RNA and to degrade RNA substrates. Our analysis confirms that 3'hExo is a member of the DEDDh family of 3' exonucleases. Specific binding to the RNA requires the SAP domain and two lysines located immediately to its C terminus. 3'hExo binds with the highest affinity to the wild-type 3' end of histone mRNA, and any changes to this sequence reduce efficiency of binding. 3'hExo has only residual, if any, 3' exonuclease activity on DNA substrates and localizes mostly to the cytoplasm, suggesting that in vivo it performs exclusively RNA-specific functions. Efficient degradation of RNA substrates by 3'hExo requires 2' and 3' hydroxyl groups at the last nucleotide. 3'hExo removes 3' overhangs of small interfering RNAs, whereas the double-stranded region is resistant to the enzymatic activity.