Cajal body surveillance of U snRNA export complex assembly

Phosphorylated adaptor for RNA export (PHAX) is the key export mediator for spliceosomal U small nuclear RNA (snRNA) precursors in metazoa. PHAX is enriched in Cajal bodies (CBs), nuclear subdomains involved in the biogenesis of small ribonucleoproteins. However, CBs’ role in U snRNA export has not been demonstrated. In this study, we show that U snRNA precursors microinjected into Xenopus laevis oocyte nuclei temporarily concentrate in CBs but gradually decrease as RNA export proceeds. Inhibition of PHAX activity by the coinjection of a specific anti-PHAX antibody or a dominant-negative PHAX mutant inhibits U snRNA export and simultaneously enhances accumulation of U snRNA precursors in CBs, indicating that U snRNAs transit through CBs before export and that binding to PHAX is required for efficient exit of U snRNAs from CBs. Similar results were obtained with U snRNAs transcribed from microinjected genes. These results reveal a novel function for CBs, which ensure that U snRNA precursors are properly bound by PHAX.     

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.     

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.     

The trimethylguanosine cap structure of U1 snRNA is a component of a bipartite nuclear targeting signal

The ability of series of U1 snRNAs and U6 snRNAs to migrate into the nucleus of Xenopus oocytes after injection into the cytoplasm was analyzed. The U snRNAs were made either by injecting U snRNA genes into the nucleus of oocytes or, synthetically, by T7 RNA polymerase, incorporating a variety of cap structures. The results indicate that nuclear targeting of U1 snRNA requires both a trimethylguanosine cap structure and binding of at least one common U snRNP protein. Using synthetic U6 snRNAs, it is further demonstrated that the trimethylguanosine cap structure can act in nuclear targeting in the absence of the common U snRNP proteins. These results imply that U snRNP nuclear targeting signals are of a modular nature.     

Conserved sequences in the U2 snRNA-encoding genes of Kinetoplastida do not include the putative branchpoint recognition region

The U2 small nuclear RNA (snRNA) of Trypanosoma brucei gambiense, a flagellated protozoon of the order Kinetoplastida, is 148 nucleotides (nt) long, and thus the smallest U2 snRNA identified so far. To examine the evolutionary conservation of this RNA among Kinetoplastida, we have cloned and sequenced the U2 genes from Trypanosoma congolense and Leishmania mexicana amazonensis, which are 145 and 141 nt in length, respectively. The sequences of the Kinetoplastida U2 snRNAs are essentially identical in the 5' half of the molecule. Surprisingly, the putative branch site recognition sequence of L. m. amazonensis U2 snRNA shows two nt changes when compared with the other two U2 snRNAs. The sequence of the 3' half of the Kinetoplastida U2 snRNAs is less conserved with T. congolense and L. m. amazonensis RNAs showing 23 and 35 nt sequence variations, respectively, when compared with the corresponding sequence of the T. b. gambiense U2 snRNA. Alignment of the flanking regions of the U2 genes revealed several elements which are conserved both in sequence and in position relative to the U2 coding region and which may function in the biosynthesis of U2 snRNAs. One upstream element specifically binds protein factor(s) present in T. brucei nuclear extracts.     

High level of complexity of small nuclear RNAs in fungi and plants

The complexity of the trimethylguanosine-capped, small nuclear RNA (snRNA) populations in a number of organisms has been examined using immunoprecipitation and two-dimensional gels. From the fungi Aspergillus nidulans and Schizosaccharomyces pombe, over 30 major snRNAs can be resolved. The most abundant of these correspond to the putative analogues of vertebrate U1, U2, U4 and U5, which have been reported to be precipitated by anti-Sm antibodies, but other snRNAs are little less abundant than the major Sm-precipitable species. A similarly high level of complexity of snRNAs is detected in pea plants. In Candida albicans, the snRNAs are somewhat less numerous (about 22 major species) and are substantially less abundant than those of the above fungi, features shared with another budding yeast, Saccharomyces cerevisiae. Ten species of human snRNA have been reported; on two-dimensional gels, a number of additional snRNAs can be resolved from human cells. Each fungus, as well as pea plants, contains snRNAs substantially larger than any reported from vertebrates or detected in the human RNA used here. It appears that many eukaryotes contain substantially more species of snRNA than was previously believed.     

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.     

U1 small nuclear ribonucleoprotein particle-protein interactions are revealed in Saccharomyces cerevisiae by in vivo competition assays.

Two highly conserved regions of the 586-nucleotide yeast (Saccharomyces cerevisiae) U1 small nuclear RNA (snRNA) can be mutated or deleted with little or no effect on growth rate: the universally conserved loop II (corresponding to the metazoan A loop) and the yeast core region (X. Liao, L. Kretzner, B. Séraphin, and M. Rosbash, Genes Dev. 4:1766-1774, 1990). To examine the contribution of these regions to U1 small nuclear ribonucleoprotein particle (snRNP) activity, a competitor U1 gene, encoding a nonfunctional U1 snRNA molecule, was introduced into a number of strains carrying a U1 snRNA gene with loop II or yeast core mutations. The presence of the nonfunctional U1 gene lowered the growth rate of these mutant strains but not wild-type strains, consistent with the notion that mutant U1 RNAs are less active than wild-type U1 snRNAs. A detailed analysis of the U1 snRNA levels and half-lives in a number of merodiploid strains suggests that these mutant U1 snRNAs interact with U1 snRNP proteins less well than do their wild-type counterparts. Competition for protein factors during snRNP assembly could account for a number of previous observations in both yeast and mammalian cells.     

U1-like snRNAs lacking complementarity to canonical 5' splice sites

We have detected a surprising heterogeneity among human spliceosomal U1 small nuclear RNA (snRNA). Most interestingly, we have identified three U1 snRNA variants that lack complementarity to the canonical 5' splice site (5'SS) GU dinucleotide. Furthermore, we have observed heterogeneity among the identified variant U1 snRNA genes caused by single nucleotide polymorphism (SNP). The identified snRNAs were ubiquitously expressed in a variety of human tissues representing different stages of development and displayed features of functional spliceosomal snRNAs, i.e., trimethylated cap structures, association with Sm proteins and presence in nuclear RNA-protein complexes. The unanticipated heterogeneity among spliceosomal snRNAs could contribute to the complexity of vertebrates by expanding the coding capacity of their genomes.     

Evolution of small nuclear RNAs in S. cerevisiae, C. albicans, and other hemiascomycetous yeasts

The spliceosome is a large, dynamic ribonuclear protein complex, required for the removal of intron sequences from newly synthesized eukaryotic RNAs. The spliceosome contains five essential small nuclear RNAs (snRNAs): U1, U2, U4, U5, and U6. Phylogenetic comparisons of snRNAs from protists to mammals have long demonstrated remarkable conservation in both primary sequence and secondary structure. In contrast, the snRNAs of the hemiascomycetous yeast Saccharomyces cerevisiae have highly unusual features that set them apart from the snRNAs of other eukaryotes. With an emphasis on the pathogenic yeast Candida albicans, we have now identified and compared snRNAs from newly sequenced yeast genomes, providing a perspective on spliceosome evolution within the hemiascomycetes. In addition to tracing the origins of previously identified snRNA variations present in Saccharomyces cerevisiae, we have found numerous unexpected changes occurring throughout the hemiascomycetous lineages. Our observations reveal interesting examples of RNA and protein coevolution, giving rise to altered interaction domains, losses of deeply conserved snRNA-binding proteins, and unique snRNA sequence changes within the catalytic center of the spliceosome. These same yeast lineages have experienced exceptionally high rates of intron loss, such that modern hemiascomycetous genomes contain introns in only approximately 5% of their genes. Also, the splice site sequences of those introns that remain adhere to an unusually strict consensus. Some of the snRNA variations we observe may thus reflect the altered intron landscape with which the hemiascomycetous spliceosome must contend.     

Molecular analysis of dicot and monocot small nuclear RNA populations.

Oligonucleotides directed against conserved small nuclear RNA (snRNA) sequences have been used to identify the individual U1, U2, U4, U5, and U6 snRNAs in dicot and monocot nuclei. The plant snRNA populations are significantly more heterogeneous than the mammalian or Saccharomyces cerevisiae snRNA populations. U6 snRNA exists as a single species of similar size in monocot and dicot nuclei. The abundance and molecular weights of the U1, U2, U4, and U5 snRNAs expressed in monocot and dicot nuclei are significantly different. Whereas most dicot nuclei contain one or two predominant forms of U2 snRNA and a small number of U4 snRNAs, monocot nuclei contain multiple forms of U2 snRNA ranging from 208 to 260 nucleotides and multiple forms of U4 snRNA from 159 to 176 nucleotides. Multiple forms of U1 and U5 snRNA exist in both plant groups. All prominent size variants of U1, U2, U4, and U5 snRNA identified in monocot nuclei can be immunoprecipitated with anti-trimethylguanosine antibody. We conclude that the sizes and number of snRNA molecules involved in intron excision differ considerably in dicot and monocot nuclei. In wheat nuclei, we have identified an additional U1-like RNA that is differentially expressed during development.     

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.     

The genes coding for 4 snRNAs of Drosophila melanogaster: localization and determination of gene numbers.

Four small nuclear RNAs (snRNAs) have been isolated from Drosophila melanogaster flies. They have been characterized by base analysis, fingerprinting, and injection into Axolotl oocytes. The size of the molecules and the modified base composition suggest that the following correlations can be made: snRNA1 approximately U2-snRNA; snRNA2 approximately U3-snRNA; snRNA3 approximately U4-snRNA; snRNA4 approximately U6-snRNA. The snRNAs injected into Axolotl oocytes move into the nuclei, where they are protected from degradation. The genes coding for these snRNAs have been localized by "in situ" hybridization of 125-I-snRNAs to salivary gland chromosomes. Most of the snRNAs hybridize to different regions of the genome: snRNA1 to the cytological regions 39B and 40AB; snRNA2 to 22A, 82E, and 95C; snRNA3 to 14B, 23D, 34A, 35EF, 39B, and 63A; snRNA4 to 96A. The estimated gene numbers (Southern-blot analysis) are: snRNA1:3; snRNA2:7; snRNA3:7; snRNA4:1-3. The gene numbers correspond to the number of sites labeled on the polytene salivary gland chromosomes.