cDNA cloning of U1, U2, U4 and U5 snRNA families expressed in pea nuclei.

Differences observed between plant and animal pre-mRNA splicing may be the result of primary or secondary structure differences in small nuclear RNAs (snRNAs). A cDNA library of pea snRNAs was constructed from anti-trimethylguanosine (m3(2,2,7)G immunoprecipitated pea nuclear RNA. The cDNA library was screened using oligo-deoxyribonucleotide probes specific for the U1, U2, U4 and U5 snRNAs. cDNA clones representing U1, U2, U4 and U5 snRNAs expressed in seedling tissue have been isolated and sequenced. Comparison of the pea snRNA variants with other organisms suggest that functionally important primary sequences are conserved phylogenetically even though the overall sequences have diverged substantially. Structural variations in U1 snRNA occur in regions required for U1-specific protein binding. In light of this sequence analysis, it is clear that the dicot snRNA variants do not differ in sequences implicated in RNA:RNA interactions with pre-mRNA. Instead, sequence differences occur in regions implicated in the binding of small ribonucleoproteins (snRNPs) to snRNAs and may result in the formation of unique snRNP particles.     

Both U2 snRNA and U12 snRNA are required for accurate splicing of exon 5 of the rat calcitonin/CGRP gene

Two classes of spliceosome are present in eukaryotic cells. Most introns in nuclear pre-mRNAs are removed by a spliceosome that requires U1, U2, U4, U5, and U6 small nuclear ribonucleoprotein particles (snRNPs). A minor class of introns are removed by a spliceosome containing U11, U12, U5, U4atac, and U6 atac snRNPs. We describe experiments that demonstrate that splicing of exon 5 of the rat calcitonin/CGRP gene requires both U2 snRNA and U12 snRNA. In vitro, splicing to calcitonin/ CGRP exon 5 RNA was dependent on U2 snRNA, as preincubation of nuclear extract with an oligonucleotide complementary to U2 snRNA abolished exon 5 splicing. Addition of an oligonucleotide complementary to U12 snRNA increased splicing at a cryptic splice site in exon 5 from <5% to 50% of total spliced RNA. Point mutations in a candidate U12 branch sequence in calcitonin/CGRP intron 4, predicted to decrease U12-pre-mRNA base-pairing, also significantly increased cryptic splicing in vitro. Calcitonin/CGRP genes containing base changes disrupting the U12 branch sequence expressed significantly decreased CGRP mRNA levels when expressed in cultured cells. Coexpression of U12 snRNAs containing base changes predicted to restore U12-pre-mRNA base pairing increased CGRP mRNA synthesis to the level of the wild-type gene. These observations indicate that accurate, efficient splicing of calcitonin/CGRP exon 5 is dependent upon both U2 and U12 snRNAs.     

Activity of chimeric RNAs of U6 snRNA and (-)sTRSV in the cleavage of a substrate RNA.

U6 small nuclear RNA is one of the spliceosomal RNAs essential for pre-mRNA splicing. Discovery of mRNA-type introns in the highly conserved region of the U6 snRNA genes led to the hypothesis that U6 snRNA functions as a catalytic element during pre-mRNA splicing. The highly conserved region of U6 snRNA has a structural similarity with the catalytic domain of the negative strand of the satellite RNA of tobacco ring spot virus [(-)sTRSV], suggesting that the highly conserved region of U6 snRNA forms the catalytic center. We examined whether synthetic RNAs consisting of the sequence of the highly conserved region of U6 snRNA or various chimeric RNAs between the U6 region and the catalytic RNA of (-)sTRSV could cleave a substrate RNA that can partially base-pair with them and have a GU sequence. Chimeric RNAs with 70 to 83% sequence identity with the conserved region of S. pombe U6 snRNA cleaved the substrate RNA at the 5' side of the GU sequence, which is shared by the 5' end of an intron in a pre-mRNA. We found that the highly conserved region of U6 snRNA and the catalytic domain of (-)sTRSV are strikingly similar in structure to the catalytic core region of the group I self-splicing intron in cyanobacteria. These results suggest that U6 snRNA, (-)sTRSV and the group I self-splicing intron originated from a common ancestral RNA, and support the hypothesis that U6 snRNA catalyzes pre-mRNA splicing reaction.     

A novel U1/U5 interaction indicates proximity between U1 and U5 snRNAs during an early step of mRNA splicing.

The five spliceosomal snRNAs (U1, U2, U4, U5, and U6) undergo an ordered sequence of conformational changes as mRNA splicing progresses. We have shown that an antisense RNA oligonucleotide complementary to U5 snRNA induces a novel U1/U4/U5 complex that may be a transitional stage in the displacement of U1 from the 5' splice site by U5. Here we identify a novel site-specific crosslink between the 5' end of U1 and the invariant loop of U5 snRNA. This crosslink can be induced in nuclear extract by an antisense oligonucleotide directed against U5 snRNA, but can also be detected during an early step of the splicing reaction in the absence of oligonucleotide. Our data indicate proximity between U1 and U5 snRNPs before the first catalytic step of splicing, and may suggest that U1 helps to direct U5 to the 5' splice site.     

Synthesis of chimeric RNAs between U6 small nuclear RNA and (-)sTRSV and analysis of their cleavage activities against the substrate RNA.

U6 small nuclear RNA (U6 snRNA) is one of the spliceosomal RNAs essential for pre-mRNA splicing. Highly conserved region of U6 snRNA shows a structural similarity with the catalytic center of the negative strand of the satellite RNA of tobacco ring spot virus [(-)sTRSV], supporting the hypothesis that U6 snRNA has a catalytic role in pre-mRNA splicing. To test this hypothesis, we examined in vitro whether synthetic RNAs consisting of the sequence of the highly conserved region of U6 snRNA or various chimeric RNAs between the U6 region and the catalytic center of (-)sTRSV could cleave a substrate RNA that can partially base-pair with them and has a GU sequence between the pairing regions. Chimeric RNAs with 70 to 83% sequence identity with the conserved region of S. pombe U6 snRNA cleaved the substrate RNA at the 5' side of the GU sequence. In addition, we found that the highly conserved region of U6 snRNA is similar in structure to the catalytic core region of the group I self-splicing intron in cyanobacteria. These results support the hypothesis that U6 snRNA catalyzes the pre-mRNA splicing reaction and U6 snRNA may originate from the catalytic domain of an ancient self-splicing intron.     

A new U6 small nuclear ribonucleoprotein-specific protein conserved between cis- and trans-splicing systems.

Spliceosomal U6 small nuclear RNA (snRNA) plays a central role in the pre-mRNA splicing mechanism and is highly conserved throughout evolution. Previously, a sequence element essential for both capping and cytoplasmic-nuclear transport of U6 snRNA was mapped in the 5'-terminal domain of U6 snRNA. We have identified a protein in cytoplasmic extracts of mammalian and Trypanosoma brucei cells that binds specifically to this U6 snRNA element. Competition studies with mutant and heterologous RNAs demonstrated the conserved binding specificity of the mammalian and trypanosomal proteins. The in vitro capping analysis of mutant U6 snRNAs indicated that protein binding is required but not sufficient for capping of U6 snRNA by a gamma-monomethyl phosphate. Through RNA affinity purification of mammalian small nuclear ribonucleoproteins (snRNPs), we detected this protein also in nuclear extract as a new specific component of the U6 snRNP but surprisingly not of the U4/U6 or the U4/U5/U6 multi-snRNP. These results suggest that the U6-specific protein is involved in U6 snRNA maturation and transport and may therefore be functionally related to the Sm proteins of the other spliceosomal snRNPs.     

Metal binding and substrate positioning by evolutionarily invariant U6 sequences in catalytically active protein-free snRNAs

We have previously shown that a base-paired complex formed by two of the spliceosomal RNA components, U6 and U2 small nuclear RNAs (snRNAs), can catalyze a two-step splicing reaction that depended on an evolutionarily invariant region in U6, the ACAGAGA box. Here we further analyze this RNA-catalyzed reaction and show that while the 5′ and 3′ splice site substrates are juxtaposed and positioned near the ACAGAGA sequence in U6, the role of the snRNAs in the reaction is beyond mere juxtaposition of the substrates and likely involves the formation of a sophisticated active site. Interestingly, the snRNA-catalyzed reaction is metal dependent, as is the case with other known splicing RNA enzymes, and terbium(III) cleavage reactions indicate metal binding by the U6/U2 complex within the evolutionarily conserved regions of U6. The above results, combined with the structural similarities between U6 and catalytically critical domains in group II self-splicing introns, suggest that the base-paired complex of U6 and U2 snRNAs is a vestigial ribozyme and a likely descendant of a group II-like self-splicing intron.     

U1, U2, and U4/U6 small nuclear ribonucleoproteins are required for in vitro splicing but not polyadenylation

The requirement for individual U RNAs in splicing and polyadenylation was investigated using oligonucleotide-directed cleavage of snRNAs in in vitro processing extracts. Cleavage of U1, U2, or U4 RNA inhibited splicing but not polyadenylation of short precursor RNAs. Thus each snRNA and the snRNP in which it is assembled participates in the splicing reaction. Splicing activity was recovered when extracts containing cleaved U RNAs were mixed in pairwise combinations, indicating that U1, U2, and U4/U6 snRNPs independently interact with the assembling spliceosome. The involvement of multiple snRNPs in the splicing of simple precursor RNAs suggests that the spliceosome is a large complex assembly consisting of multiple snRNPs whose activity is dependent on the structural integrity of the individual U RNAs.     

An H/ACA guide RNA directs U2 pseudouridylation at two different sites in the branchpoint recognition region in Xenopus oocytes

U2 is the most extensively modified of all spliceosomal snRNAs. We previously showed that at least some of the internally modified nucleotides in U2 snRNA are required for snRNP biogenesis and pre-mRNA splicing. Recent work from several laboratories suggests that nuclear guide RNAs facilitate U2 snRNA internal modification, including pseudouridylation and 2'-O-methylation. Here, we present a novel approach to identifying guide RNAs for U2 pseudouridylation. Several Xenopus oocyte nuclear RNAs were affinity selected with U2 snRNA substituted with 5-fluorouridine, a pseudouridylation inhibitor that sequesters pseudouridylases. One of these RNAs was sequenced and found to be a novel RNA of 134 nt. This small RNA contains an H/ACA motif and folds into a typical H/ACA RNA structure, and its authenticity as an H/ACA RNA was confirmed by immunoprecipitation analysis. The RNA contains two guide sequences for pseudouridylation (psi) of U2 snRNA at positions 34 and 44 in the branch-site recognition region, and we demonstrate that this RNA indeed guides the formation of psi34 and psi44 in U2 using a Xenopus oocyte reconstitution system. Therefore, this novel RNA was designated pugU2-34/44, for pseudouridylation guide for U2 snRNA U34 and U44. Intranuclear localization analyses indicate that pugU2-34/44 resides within the nucleoplasm rather than nucleoli or Cajal bodies where other guide RNAs have been localized. Our results clarify the mechanism of U2 snRNA pseudouridylation in Xenopus oocytes, and have interesting implications with regard to the intranuclear localization of U2 snRNA pseudouridylation.     

Lsm proteins promote regeneration of pre-mRNA splicing activity

Lsm proteins are ubiquitous, multifunctional proteins that affect the processing of most RNAs in eukaryotic cells, but their function is unknown. A complex of seven Lsm proteins, Lsm2-8, associates with the U6 small nuclear RNA (snRNA) that is a component of spliceosome complexes in which pre-mRNA splicing occurs. Spliceosomes contain five snRNAs, U1, U2, U4, U5, and U6, that are packaged as ribonucleoprotein particles (snRNPs). U4 and U6 snRNAs contain extensive sequence complementarity and interact to form U4/U6 di-snRNPs. U4/U6 di-snRNPs associate with U5 snRNPs to form U4/U6.U5 tri-snRNPs prior to spliceosome assembly. Within spliceosomes, disruption of base-paired U4/U6 heterodimer allows U6 snRNA to form part of the catalytic center. Following completion of the splicing reaction, snRNPs must be recycled for subsequent rounds of splicing, although little is known about this process. Here we present evidence that regeneration of splicing activity in vitro is dependent on Lsm proteins. RNP reconstitution experiments with exogenous U6 RNA show that Lsm proteins promote the formation of U6-containing complexes and suggest that Lsm proteins have a chaperone-like function, supporting the assembly or remodeling of RNP complexes involved in splicing. Such a function could explain the involvement of Lsm proteins in a wide variety of RNA processing pathways.     

Molecular comparison of monocot and dicot U1 and U2 snRNAs

To elucidate differences between the pre-mRNA splicing components in monocots and dicots, we have cloned and characterized several U1 and U2 snRNA sequence variants expressed in wheat seedling nuclei. Primer extension sequencing on wheat and pea snRNA populations has demonstrated that two 5'-terminal nucleotides found in most other U1 snRNAs are missing/modified in many plant U1 snRNAs. Comparison of the wheat U1 and U2 snRNA variants with their counterparts expressed in pea nuclei has defined regions of structural divergence between monocot and dicot U1 and U2 snRNAs. The U1 and U2 snRNA sequences involved in RNA:RNA interaction with pre-mRNAs are absolutely conserved. Significant differences occur between wheat and pea U1 snRNAs in stem I and II structures implicated in the binding of U1-specific proteins suggesting that the monocot and dicot U1-specific snRNP proteins differ in their binding specificities. Stem III structures, which are required in mammalian systems for splicing complex formation but not for U1-specific protein binding, differ more extensively than stems I, II, or IV. In U2 snRNAs, the sequence differences between these two species are primarily localized in stem III and in stem IV which has been implicated in snRNP protein binding. These differences suggest that monocot and dicot U1 and U2 snRNPs represent distinct entities that may have monocot- and dicot-specific snRNP protein variants associated with each snRNA.     

U6atac snRNA,the highly divergent counterpart of U6 snRNA,is the specific target that mediates inhibition of AT-AC splicing by the influenza virus NS1 protein.

The influenza virus NS1 protein inhibits the splicing of the major class of mammalian pre-mRNAs (GU-AG Introns) by binding to a specific stem-bulge in U6 snRNA, thereby blocking the formation of U4/U6 and U2/U6 complexes. The splicing of the minor class of AT-AC introns takes place on spliceosomes that do not contain U6 snRNA, but rather U6atac snRNA-a highly divergent U6 snRNA counterpart. Nonetheless, we demonstrate that the NS1 protein inhibits AT-AC splicing in vitro, and specifically binds to only U6atac snRNA among the five minor class snRNAs. Chemical modification/interference assays show that the NS1 protein binds to the stem-bulge near the 3'' end of U6atac snRNA, encompassing nt 82-95 and nt 105-114. Although the sequence of this stem-bulge differs significantly from the sequence of the stem-bulge to which the NS1 protein binds in U6 snRNA, RNA competition experiments Indicate that U6 and U6atac snRNAs likely share the same binding site on the NS1 protein. Previously, the region of U6atac snRNA containing this 3'' stem-bulge had not been implicated in any interactions of this snRNA with either U4atac or U12 snRNA. However, as assayed by psoralen crosslinking, we show that the NS1 protein inhibits the formation of U12/U6atac complexes, but not the formation of U4atac/U6atac complexes. We can conclude that the inhibition of AT-AC splicing results largely from the inhibition of formation of U12/U6atac complexes caused by the binding of the NS1 protein to the 3'' stem-bulge of U6atac snRNA.     

Polypyrimidine tract binding protein inhibits IgM pre-mRNA splicing by diverting U2 snRNA base-pairing away from the branch point

The mouse immunoglobulin (IgM) pre-mRNA contains a splicing inhibitor that bears multiple binding sites for the splicing repressor polypyrimidine tract binding protein (PTB). Here we show that the inhibitor directs assembly of an ATP-dependent complex that contains PTB and U1 and U2 small nuclear RNAs (snRNAs). Unexpectedly, although U2 snRNA is present in the inhibitor complex, it is not base-paired to the branch point. We present evidence that inhibitor-bound PTB contacts U2 snRNA to promote base-pairing to an adjacent branch point–like sequence within the inhibitor, thereby preventing the U2 snRNA–branch point interaction and resulting in splicing repression. Our studies reveal a novel mechanism by which PTB represses splicing.     

The RNA binding protein Cwc2 interacts directly with the U6 snRNA to link the nineteen complex to the spliceosome during pre-mRNA splicing

Intron removal during pre-messenger RNA (pre-mRNA) splicing involves arrangement of snRNAs into conformations that promote the two catalytic steps. The Prp19 complex [nineteen complex (NTC)] can specify U5 and U6 snRNA interactions with pre-mRNA during spliceosome activation. A candidate for linking the NTC to the snRNAs is the NTC protein Cwc2, which contains motifs known to bind RNA, a zinc finger and RNA recognition motif (RRM). In yeast cells mutation of either the zinc finger or RRM destabilize Cwc2 and are lethal. Yeast cells depleted of Cwc2 accumulate pre-mRNA and display reduced levels of U1, U4, U5 and U6 snRNAs. Cwc2 depletion also reduces U4/U6 snRNA complex levels, as found with depletion of other NTC proteins, but without increase in free U4. Purified Cwc2 displays general RNA binding properties and can bind both snRNAs and pre-mRNA in vitro. A Cwc2 RRM fragment alone can bind RNA but with reduced efficiency. Under splicing conditions Cwc2 can associate with U2, U5 and U6 snRNAs, but can only be crosslinked directly to the U6 snRNA. Cwc2 associates with U6 both before and after the first step of splicing. We propose that Cwc2 links the NTC to the spliceosome during pre-mRNA splicing through the U6 snRNA.     

More Sm snRNAs from Vertebrate Cells

There are a number of low-abundance small nuclear RNAs (snRNAs) in eukaryotic cells. Many of them have been assigned functions in the biogenesis of cellular RNAs, such as splicing and 3′ end processing. Here, we present the sequence ofXenopusU12 snRNA and compare the secondary structures of the low-abundance U11 and U12 with those of the high-abundance U1 and U2, respectively. The data suggest functional parallels between these two pairs of snRNAs in pre-mRNA splicing. Using a highly sensitive method, we have identified several new low-abundance snRNAs from HeLa cells. These include five U7 snRNA variants and six novel snRNAs. One of the six novel RNAs is an Sm snRNA, whereas the rest are not immunoprecipitable by either anti-Sm antibodies or anti-trimethylguanosine antibodies. The discovery of these new RNAs suggests that there may be yet more low-abundance snRNAs in the nuclei of eukaryotic cells.     

U2 and U6 snRNA genes in the microsporidian Nosema locustae: evidence for a functional spliceosome.

The removal of introns from pre-messenger RNA is mediated by the spliceosome, a large complex composed of many proteins and five small nuclear RNAs (snRNAs). Of the snRNAs, the U6 and U2 snRNAs are the most conserved in sequence, as they interact extensively with each other and also with the intron, in several base pairings that are necessary for splicing. We have isolated and sequenced the genes encoding both U6 and U2 snRNAs from the intracellularly parasitic microsporidian Nosema locustae . Both genes are expressed. Both RNAs can be folded into secondary structures typical of other known U6 and U2 snRNAs. In addition, the N.locustae U6 and U2 snRNAs have the potential to base pair in the functional intermolecular interactions that have been characterized by extensive analyses in yeast and mammalian systems. These results indicate that the N.locustae U6 and U2 snRNAs may be functional components of an active spliceosome, even though introns have not yet been found in microsporidian genes.