Nuclear transport of U1 snRNP in somatic cells: differences in signal requirement compared with Xenopus laevis oocytes

The SMN complex drives structural changes in human snRNAs to enable snRNP assembly

Spliceosomal snRNPs are multicomponent particles that undergo a complex maturation pathway. Human Sm-class snRNAs are generated as 3'-end extended precursors, which are exported to the cytoplasm and assembled together with Sm proteins into core RNPs by the SMN complex. Here, we provide evidence that these pre-snRNA substrates contain compact, evolutionarily conserved secondary structures that overlap with the Sm binding site. These structural motifs in pre-snRNAs are predicted to interfere with Sm core assembly. We model structural rearrangements that lead to an open pre-snRNA conformation compatible with Sm protein interaction. The predicted rearrangement pathway is conserved in Metazoa and requires an external factor that initiates snRNA remodeling. We show that the essential helicase Gemin3, which is a component of the SMN complex, is crucial for snRNA structural rearrangements during snRNP maturation. The SMN complex thus facilitates ATP-driven structural changes in snRNAs that expose the Sm site and enable Sm protein binding.

TGS1 impacts snRNA 3'-end processing, ameliorates survival motor neuron-dependent neurological phenotypes in vivo and prevents neurodegeneration

Trimethylguanosine synthase 1 (TGS1) is a highly conserved enzyme that converts the 5'-monomethylguanosine cap of small nuclear RNAs (snRNAs) to a trimethylguanosine cap. Here, we show that loss of TGS1 in Caenorhabditis elegans, Drosophila melanogaster and Danio rerio results in neurological phenotypes similar to those caused by survival motor neuron (SMN) deficiency. Importantly, expression of human TGS1 ameliorates the SMN-dependent neurological phenotypes in both flies and worms, revealing that TGS1 can partly counteract the effects of SMN deficiency. TGS1 loss in HeLa cells leads to the accumulation of immature U2 and U4atac snRNAs with long 3' tails that are often uridylated. snRNAs with defective 3' terminations also accumulate in Drosophila Tgs1 mutants. Consistent with defective snRNA maturation, TGS1 and SMN mutant cells also exhibit partially overlapping transcriptome alterations that include aberrantly spliced and readthrough transcripts. Together, these results identify a neuroprotective function for TGS1 and reinforce the view that defective snRNA maturation affects neuronal viability and function.

Trimethylguanosine synthase 1 (Tgs1) is involved in Swi6/HP1-independent siRNA production and establishment of heterochromatin in fission yeast

In fission yeast, siRNA generated by RNA interference (RNAi) factors plays critical roles in establishment and maintenance of heterochromatin. To achieve efficient siRNA synthesis, RNAi factors assemble on heterochromatin via association with Swi6, a homologue of heterochromatin protein 1 (HP1), and heterochromatic noncoding RNA (hncRNA) retained on chromatin. In addition, spliceosomes formed on hncRNA introns recruit RNAi factors to hncRNA and heterochromatin. Small nuclear RNAs, components of the spliceosome, have a trimethylguanosine (TMG) cap that is generated by Tgs1-dependent hypermethylation of the normal m7G cap; this cap is required for efficient splicing of some mRNAs in budding yeast and Drosophila. In this study, we found that loss of Tgs1 in fission yeast destabilizes centromeric heterochromatin. Tgs1 was required for Swi6-independent siRNA synthesis, as well as for the establishment of centromeric heterochromatin. Loss of Tgs1 affected the splicing efficiency of hncRNA introns in the absence of Swi6. Furthermore, some hncRNAs have a TMG cap, and we found that loss of Tgs1 diminished the chromatin binding of these hncRNAs. Together, these results suggest that the Tgs1-dependent TMG cap plays critical roles in establishment of heterochromatin by ensuring spliceosome-dependent recruitment of RNAi factors and regulating the binding between chromatin and hncRNA.

Loss of the RNA trimethylguanosine cap is compatible with nuclear accumulation of spliceosomal snRNAs but not pre-mRNA splicing or snRNA processing during animal development

The 2,2,7-trimethylguanosine (TMG) cap is one of the first identified modifications on eukaryotic RNAs. TMG, synthesized by the conserved Tgs1 enzyme, is abundantly present on snRNAs essential for pre-mRNA splicing. Results from ex vivo experiments in vertebrate cells suggested that TMG ensures nuclear localization of snRNAs. Functional studies of TMG using tgs1 mutations in unicellular organisms yield results inconsistent with TMG being indispensable for either nuclear import or splicing. Utilizing a hypomorphic tgs1 mutation in Drosophila, we show that TMG reduction impairs germline development by disrupting the processing, particularly of introns with smaller sizes and weaker splice sites. Unexpectedly, loss of TMG does not disrupt snRNAs localization to the nucleus, disputing an essential role of TMG in snRNA transport. Tgs1 loss also leads to defective 3' processing of snRNAs. Remarkably, stronger tgs1 mutations cause lethality without severely disrupting splicing, likely due to the preponderance of TMG-capped snRNPs. Tgs1, a predominantly nucleolar protein in Drosophila, likely carries out splicing-independent functions indispensable for animal development. Taken together, our results suggest that nuclear import is not a conserved function of TMG. As a distinctive structure on RNA, particularly non-coding RNA, we suggest that TMG prevents spurious interactions detrimental to the function of RNAs that it modifies.

Nuclear Pre-snRNA Export Is an Essential Quality Assurance Mechanism for Functional Spliceosomes

Removal of introns from pre-mRNAs is an essential step in eukaryotic gene expression, mediated by spliceosomes that contain snRNAs as key components. Although snRNAs are transcribed in the nucleus and function in the same compartment, all except U6 shuttle to the cytoplasm. Surprisingly, the physiological relevance for shuttling is unclear, in particular because the snRNAs in Saccharomyces cerevisiae were reported to remain nuclear. Here, we show that all yeast pre-snRNAs including U6 undergo a stepwise maturation process after nuclear export by Mex67 and Xpo1. Sm- and Lsm-ring attachment occurs in the cytoplasm and is important for the snRNA re-import, mediated by Cse1 and Mtr10. Finally, nuclear pre-snRNA cleavage and trimethylation of the 5'-cap finalizes shuttling. Importantly, preventing pre-snRNAs from being exported or processed results in faulty spliceosome assembly and subsequent genome-wide splicing defects. Thus, pre-snRNA export is obligatory for functional splicing and resembles an essential evolutionarily conserved quality assurance step.

Cajal bodies and snRNPs - friends with benefits

Spliceosomal snRNPs are complex particles that proceed through a fascinating maturation pathway. Several steps of this pathway are closely linked to nuclear non-membrane structures called Cajal bodies. In this review, I summarize the last 20 y of research in this field. I primarily focus on snRNP biogenesis, specifically on the steps that involve Cajal bodies. I also evaluate the contribution of the Cajal body in snRNP quality control and discuss the role of snRNPs in Cajal body formation.

Identification and characterization of Drosophila Snurportin reveals a role for the import receptor Moleskin/importin-7 in snRNP biogenesis

Previous work established Importin-β and Snurportin1 as the vertebrate snRNP import receptor and adaptor proteins, respectively. This study identifies Drosophila Snurportin and shows that it uses an alternative import receptor, Importin7/Moleskin. Moleskin is required for the stability of other snRNP biogenesis factors.

Nuclear import is an essential step in small nuclear ribonucleoprotein (snRNP) biogenesis. Snurportin1 (SPN1), the import adaptor, binds to trimethylguanosine (TMG) caps on spliceosomal small nuclear RNAs. Previous studies indicated that vertebrate snRNP import requires importin-β, the transport receptor that binds directly to SPN1. We identify CG42303/snup as the Drosophila orthologue of human snurportin1 (SNUPN). Of interest, the importin-β binding (IBB) domain of SPN1, which is essential for TMG cap–mediated snRNP import in humans, is not well conserved in flies. Consistent with its lack of an IBB domain, we find that Drosophila SNUP (dSNUP) does not interact with Ketel/importin-β. Fruit fly snRNPs also fail to bind Ketel; however, the importin-7 orthologue Moleskin (Msk) physically associates with both dSNUP and spliceosomal snRNPs and localizes to nuclear Cajal bodies. Strikingly, we find that msk-null mutants are depleted of the snRNP assembly factor, survival motor neuron, and the Cajal body marker, coilin. Consistent with a loss of snRNP import function, long-lived msk larvae show an accumulation of TMG cap signal in the cytoplasm. These data indicate that Ketel/importin-β does not play a significant role in Drosophila snRNP import and demonstrate a crucial function for Msk in snRNP biogenesis.

Biogenesis of spliceosomal small nuclear ribonucleoproteins

Virtually, all eukaryotic mRNAs are synthesized as precursor molecules that need to be extensively processed in order to serve as a blueprint for proteins. The three most prevalent processing steps are the capping reaction at the 5'-end, the removal of intervening sequences by splicing, and the formation of poly (A)-tails at the 3'-end of the message by polyadenylation. A large number of proteins and small nuclear ribonucleoprotein complexes (snRNPs) interact with the mRNA and enable the different maturation steps. This chapter focuses on the biogenesis of snRNPs, the major components of the pre-mRNA splicing machinery (spliceosome). A large body of evidence has revealed an intricate and segmented pathway for the formation of snRNPs that involves nucleo-cytoplasmic transport events and elaborates assembly strategies. We summarize the knowledge about the different steps with an emphasis on trans-acting factors of snRNP maturation of higher eukaryotes. WIREs RNA 2011 2 718-731 DOI: 10.1002/wrna.87 For further resources related to this article, please visit the WIREs website.

Cellular strategies for the assembly of molecular machines

Molecular machines are supramolecular assemblies of biomolecules (proteins, RNA and/or DNA) that facilitate a diversity of biological tasks in the cells of all organisms. How these complex structures are built within the crowded cellular environment is, therefore, a central question in the biological sciences. Recent studies on spliceosomal uridine-rich small nuclear ribonucleoproteins (snRNPs) have unveiled cellular assembly strategies for RNA-protein complexes. snRNPs form in vivo by the coordinated action of an elaborate assembly line consisting of assembly chaperones, scaffolding proteins and catalysts. These newly discovered strategies exhibit similarities to those employed by protein complexes such as ribulose-1,5-bisphosphate-carboxylase (Rubisco) and allow the elucidation of general rules for how molecular machines are formed in vivo.

Enhancement of U4/U6 small nuclear ribonucleoprotein particle association in Cajal bodies predicted by mathematical modeling

Spliceosomal small nuclear ribonucleoprotein particles (snRNPs) undergo specific assembly steps in Cajal bodies (CBs), nonmembrane-bound compartments within cell nuclei. An example is the U4/U6 di-snRNP, assembled from U4 and U6 monomers. These snRNPs can also assemble in the nucleoplasm when cells lack CBs. Here, we address the hypothesis that snRNP concentration in CBs facilitates assembly, by comparing the predicted rates of U4 and U6 snRNP association in nuclei with and without CBs. This was accomplished by a random walk-and-capture simulation applied to a three-dimensional model of the HeLa cell nucleus, derived from measurements of living cells. Results of the simulations indicated that snRNP capture is optimal when nuclei contain three to four CBs. Interestingly, this is the observed number of CBs in most cells. Microinjection experiments showed that U4 snRNA targeting to CBs was U6 snRNP independent and that snRNA concentration in CBs is approximately 20-fold higher than in nucleoplasm. Finally, combination of the simulation with calculated association rates predicted that the presence of CBs enhances U4 and U6 snRNP association by up to 11-fold, largely owing to this concentration difference. This provides a chemical foundation for the proposal that these and other cellular compartments promote molecular interactions, by increasing the local concentration of individual components.

Ongoing U snRNP biogenesis is required for the integrity of Cajal bodies

Cajal bodies (CBs) have been implicated in the nuclear phase of the biogenesis of spliceosomal U small nuclear ribonucleoproteins (U snRNPs). Here, we have investigated the distribution of the CB marker protein coilin, U snRNPs, and proteins present in C/D box small nucleolar (sno)RNPs in cells depleted of hTGS1, SMN, or PHAX. Knockdown of any of these three proteins by RNAi interferes with U snRNP maturation before the reentry of U snRNA Sm cores into the nucleus. Strikingly, CBs are lost in the absence of hTGS1, SMN, or PHAX and coilin is dispersed in the nucleoplasm into numerous small foci. This indicates that the integrity of canonical CBs is dependent on ongoing U snRNP biogenesis. Spliceosomal U snRNPs show no detectable concentration in nuclear foci and do not colocalize with coilin in cells lacking hTGS1, SMN, or PHAX. In contrast, C/D box snoRNP components concentrate into nuclear foci that partially colocalize with coilin after inhibition of U snRNP maturation. We demonstrate by siRNA-mediated depletion that coilin is required for the condensation of U snRNPs, but not C/D box snoRNP components, into nucleoplasmic foci, and also for merging these factors into canonical CBs. Altogether, our data suggest that CBs have a modular structure with distinct domains for spliceosomal U snRNPs and snoRNPs.

Coupled in vitro import of U snRNPs and SMN, the spinal muscular atrophy protein

Cytoplasmic assembly of Sm-class small nuclear ribonucleoproteins (snRNPs) is a central process in eukaryotic gene expression. A large macromolecular complex containing the survival of motor neurons (SMN) protein is required for proper snRNP assembly in vivo. Defects in SMN function lead to a human neuromuscular disorder, spinal muscular atrophy (SMA). SMN protein localizes to both nuclear and cytoplasmic compartments, and a reduction in nuclear levels of SMN is correlated with the disease. The mechanism of SMN nuclear import, however, is unknown. Using digitonin-permeabilized cells, we show that SMN import depends on the presence of Sm snRNPs. Conversely, import of labeled U1 snRNPs was SMN complex dependent. Thus, import of SMN and U snRNPs are coupled in vitro. Furthermore, we identify nuclear import defects in SMA patient-derived SMN mutants, uncovering a potential mechanism for SMN dysfunction.

The Herpesvirus saimiri small nuclear RNAs recruit AU-rich element-binding proteins but do not alter host AU-rich element-containing mRNA levels in virally transformed T cells

Herpesvirus saimiri (HVS) encodes seven Sm-class small nuclear RNAs, called HSURs (for Herpesvirus saimiri U RNAs), that are abundantly expressed in HVS-transformed, latently infected marmoset T cells but are of unknown function. HSURs 1, 2, and 5 have highly conserved 5'-end sequences containing the AUUUA pentamer characteristic of AU-rich elements (AREs) that regulate the stability of many host mRNAs, including those encoding most proto-oncogenes and cytokines. To test whether the ARE-containing HSURs act to sequester host proteins that regulate the decay of these mRNAs, we demonstrate their in vivo interaction with the ARE-binding proteins hnRNP D and HuR in HVS-transformed T cells using a new cross-linking assay. Comprehensive Northern and microarray analyses revealed, however, that the levels of endogenous ARE-containing mRNAs are not altered in T cells latently infected with HVS mutants lacking HSURs 1 and 2. HSUR 1 binds the destabilizing ARE-binding protein tristetraprolin induced following activation of HVS-transformed T cells, but even in such stimulated cells, the levels of host ARE-containing mRNAs are not altered by deletion of HSURs 1 and 2. Instead, HSUR 1 itself is degraded by an ARE-dependent pathway in HVS-transformed T cells, suggesting that HVS may take advantage of the host ARE-mediated mRNA decay pathway to regulate HSUR expression. This is the first example of posttranscriptional regulation of the expression of an Sm small nuclear RNA.

U4 snRNA nucleolar localization requires the NHPX/15.5-kD protein binding site but not Sm protein or U6 snRNA association

All small nuclear RNAs (snRNAs) of the [U4/U6.U5] tri-snRNP localize transiently to nucleoli, as visualized by microscopy after injection of fluorescein-labeled transcripts into Xenopus laevis oocyte nuclei. Here, we demonstrate that these RNAs traffic to nucleoli independently of one another, because U4 snRNA deleted in the U6 base-pairing region still localizes to nucleoli. Furthermore, depletion of endogenous U6 snRNA does not affect nucleolar localization of injected U4 or U5. The wild-type U4 transcripts used here are functional: they exhibit normal nucleocytoplasmic traffic, associate with Sm proteins, form the [U4/U6] di-snRNP, and localize to nucleoli and Cajal bodies. The nucleolar localization element (NoLE) of U4 snRNA was mapped by mutagenesis. Neither the 5'-cap nor the 3'-region of U4, which includes the Sm protein binding site, are essential for nucleolar localization. The only region in U4 snRNA required for nucleolar localization is the 5'-proximal stem loop, which contains the binding site for the NHPX/15.5-kD protein. Even mutation of just five nucleotides, essential for binding this protein, impaired U4 nucleolar localization. Intriguingly, the NHPX/15.5-kD protein also binds the nucleolar localization element of box C/D small nucleolar RNAs, suggesting that this protein might mediate nucleolar localization of several small RNAs.

Regulation of nuclear import and export by the GTPase Ran

This review focuses on the control of nuclear import and export pathways by the small GTPase Ran. Transport of signal-containing cargo substrates is mediated by receptors that bind to the cargo proteins and RNAs and deliver them to the appropriate cellular compartment. Ran is an evolutionarily conserved member of the Ras superfamily that regulates all receptor-mediated transport between the nucleus and the cytoplasm. We describe the identification and characterization of the RanGTPase and its binding partners: the guanine nucleotide exchange factor, RanGEF; the GTPase activating protein, RanGAP; the soluble import and export receptors; Ran-binding domain-(RBD) containing proteins; and NTF2 and related factors.

SMN, the spinal muscular atrophy protein, forms a pre-import snRNP complex with snurportin1 and importin beta

The survival of motor neuron (SMN) protein is mutated in patients with spinal muscular atrophy (SMA). SMN is part of a multiprotein complex required for biogenesis of the Sm class of small nuclear ribonucleoproteins (snRNPs). Following assembly of the Sm core domain, snRNPs are transported to the nucleus via importin beta. Sm snRNPs contain a nuclear localization signal (NLS) consisting of a 2,2,7-trimethylguanosine (TMG) cap and the Sm core. Snurportin1 (SPN) is the adaptor protein that recognizes both the TMG cap and importin beta. Here, we report that a mutant SPN construct lacking the importin beta binding domain (IBB), but containing an intact TMG cap-binding domain, localizes primarily to the nucleus, whereas full-length SPN localizes to the cytoplasm. The nuclear localization of the mutant SPN was not a result of passive diffusion through the nuclear pores. Importantly, we found that SPN interacts with SMN, Gemin3, Sm snRNPs and importin beta. In the presence of ribonucleases, the interactions with SMN and Sm proteins were abolished, indicating that snRNAs mediate this interplay. Cell fractionation studies showed that SPN binds preferentially to cytoplasmic SMN complexes. Notably, we found that SMN directly interacts with importin beta in a GST-pulldown assay, suggesting that the SMN complex might represent the Sm core NLS receptor predicted by previous studies. Therefore, we conclude that, following Sm protein assembly, the SMN complex persists until the final stages of cytoplasmic snRNP maturation and may provide somatic cell RNPs with an alternative NLS.

Hypermethylation of the cap structure of both yeast snRNAs and snoRNAs requires a conserved methyltransferase that is localized to the nucleolus

The m(7)G caps of most spliceosomal snRNAs and certain snoRNAs are converted posttranscriptionally to 2,2,7-trimethylguanosine (m(3)G) cap structures. Here, we show that yeast Tgs1p, an evolutionarily conserved protein carrying a signature of S-AdoMet methyltransferase, is essential for hypermethylation of the m(7)G caps of both snRNAs and snoRNAs. Deletion of the yeast TGS1 gene abolishes the conversion of the m(7)G to m(3)G caps and produces a cold-sensitive splicing defect that correlates with the retention of U1 snRNA in the nucleolus. Consistently, Tgs1p is also localized in the nucleolus. Our results suggest a trafficking pathway in which yeast snRNAs and snoRNAs cycle through the nucleolus to undergo m(7)G cap hypermethylation.

The importin-beta binding domain of snurportin1 is responsible for the Ran- and energy-independent nuclear import of spliceosomal U snRNPs in vitro

The nuclear localization signal (NLS) of spliceosomal U snRNPs is composed of the U snRNA's 2,2,7-trimethyl-guanosine (m3G)-cap and the Sm core domain. The m3G-cap is specifically bound by snurportin1, which contains an NH2-terminal importin-beta binding (IBB) domain and a COOH-terminal m3G-cap--binding region that bears no structural similarity to known import adaptors like importin-alpha (impalpha). Here, we show that recombinant snurportin1 and importin-beta (impbeta) are not only necessary, but also sufficient for U1 snRNP transport to the nuclei of digitonin-permeabilized HeLa cells. In contrast to impalpha-dependent import, single rounds of U1 snRNP import, mediated by the nuclear import receptor complex snurportin1-impbeta, did not require Ran and energy. The same Ran- and energy-independent import was even observed for U5 snRNP, which has a molecular weight of more than one million. Interestingly, in the presence of impbeta and a snurportin1 mutant containing an impalpha IBB domain (IBBimpalpha), nuclear U1 snRNP import was Ran dependent. Furthermore, beta-galactosidase (betaGal) containing a snurportin1 IBB domain, but not IBBimpalpha-betaGal, was imported into the nucleus in a Ran-independent manner. Our results suggest that the nature of the IBB domain modulates the strength and/or site of interaction of impbeta with nucleoporins of the nuclear pore complex, and thus whether or not Ran is required to dissociate these interactions.

The box C/D motif directs snoRNA 5'-cap hypermethylation

The 5'-cap structure of most spliceosomal small nuclear RNAs (snRNAs) and certain small nucleolar RNAs (snoRNAs) undergoes hypermethylation from a 7-methylguanosine to a 2,2, 7-trimethylguanosine structure. 5'-Cap hypermethylation of snRNAs is dependent upon a conserved sequence element known as the Sm site common to most snRNAs. Here we have performed a mutational analysis of U3 and U14 to determine the cis-acting sequences required for 5'-cap hypermethylation of Box C/D snoRNAs. We have found that both the conserved sequence elements Box C (termed C' in U3) and Box D are necessary for cap hypermethylation. Furthermore, the terminal stem structure that is formed by sequences that flank Box C (C' in U3) and Box D is also required. However, mutation of other conserved sequences has no effect on hypermethylation of the cap. Finally, the analysis of fragments of U3 and U14 RNAs indicates that the Box C/D motif, including Box C (C' in U3), Box D and the terminal stem, is capable of directing cap hypermethylation. Thus, the Box C/D motif, which is important for snoRNA processing, stability, nuclear retention, protein binding, nucleolar localization and function, is also necessary and sufficient for cap hypermethylation of these RNAs.

Functional characterization of nuclear localization signals in yeast Sm proteins

In mammals, nuclear localization of U-snRNP particles requires the snRNA hypermethylated cap structure and the Sm core complex. The nature of the signal located within the Sm core proteins is still unknown, both in humans and yeast. Close examination of the sequences of the yeast SmB, SmD1, and SmD3 carboxyl-terminal domains reveals the presence of basic regions that are reminiscent of nuclear localization signals (NLSs). Fluorescence microscopy studies using green fluorescent protein (GFP)-fusion proteins indicate that both yeast SmB and SmD1 basic amino acid stretches exhibit nuclear localization properties. Accordingly, deletions or mutations in the NLS-like motifs of SmB and SmD1 dramatically reduce nuclear fluorescence of the GFP-Sm mutant fusion alleles. Phenotypic analyses indicate that the NLS-like motifs of SmB and SmD1 are functionally redundant: each NLS-like motif can be deleted without affecting yeast viability whereas a simultaneous deletion of both NLS-like motifs is lethal. Taken together, these findings suggest that, in the doughnut-like structure formed by the Sm core complex, the carboxyl-terminal extensions of Sm proteins may form an evolutionarily conserved basic amino acid-rich protuberance that functions as a nuclear localization determinant.

Functional modules in ribosomal protein L5 for ribonucleoprotein complex formation and nucleocytoplasmic transport

Ribosomal protein L5 forms a small, extraribosomal complex with 5 S ribosomal RNA, referred to as the 5 S ribonucleoprotein complex, which shuttles between nucleus and cytoplasm in Xenopus oocytes. Mapping elements in L5 that mediate nuclear protein import defines three separate such activities (L5-nuclear localization sequence (NLS)-1, -2, and -3), which are functional in both oocytes and somatic cells. RNA binding activity involves N-terminal as well as C-terminal elements of L5. In contrast to the full-length protein, none of the individual NLSs carrying L5 fragments are able to allow for the predominating accumulation in the nucleoli that is observed with the full-length protein. The separate L5-NLSs differ in respect to two activities. Firstly, only L5-NLS-1 and -3, not L5-NLS-2, are capable of promoting the nuclear transfer of a heterologous, covalently attached ribonucleoprotein complex. Secondly, only L5-NLS-1 is able to bind strongly to a variety of different import receptors; those that recognize L5-NLS-2 and -3 have yet to be identified.

The Sm core domain mediates targeting of U1 snRNP to subnuclear compartments involved in transcription and splicing

In the mammalian cell nucleus pre-mRNA splicing factors such as U snRNPs are concentrated in distinct subnuclear compartments named perichromatin fibrils (PFs), interchromatin granules (IGs), interchromatin granule-associated zones (IG-associated zones), and coiled bodies (CBs). The structural requirement for the localization of U snRNPs to these domains was investigated by microinjection of digoxygenin-labeled in vitro-reconstituted U1 snRNPs and mutants thereof and subsequent analysis by immunoelectron microscopy. Wild-type U1 snRNP was targeted, after injection into the cytoplasm, to the nucleus and localized in PFs, IGs, IG-associated zones, and CBs. Thus, microinjected U1 snRNP particles exhibited a subnuclear localization similar to that previously observed for endogenous U1 snRNPs. Specific U snRNP proteins were shown not to be essential for subnuclear targeting since U1 snRNP mutants that did not bind to 70K, A, or C peptides were distributed in the cell nucleus in a pattern indistinguishable from that of wild-type U1 snRNP. Moreover, the Sm core domain, common to all spliceosomal U snRNPs, was shown to be sufficient for appropriate subnuclear distribution. Thus, these observations indicate that the Sm core domain, previously shown to be essential for nuclear import of spliceosomal U1 snRNPs, is also important for mediating the targeting to distinct nuclear subcompartments.

Sm and Sm-like proteins assemble in two related complexes of deep evolutionary origin

A group of seven Sm proteins forms a complex that binds to several RNAs in metazoans. All Sm proteins contain a sequence signature, the Sm domain, also found in two yeast Sm-like proteins associated with the U6 snRNA. We have performed database searches revealing the presence of 16 proteins carrying an Sm domain in the yeast genome. Analysis of this protein family confirmed that seven of its members, encoded by essential genes, are homologues of metazoan Sm proteins. Immunoprecipitation revealed that an evolutionarily related subgroup of seven Sm-like proteins is directly associated with the nuclear U6 and pre-RNase P RNAs. The corresponding genes are essential or required for normal vegetative growth. These proteins appear functionally important to stabilize U6 snRNA. The two last yeast Sm-like proteins were not found associated with RNA, and neither was essential for vegetative growth. To investigate whether U6-associated Sm-like protein function is widespread, we cloned several cDNAs encoding homologous human proteins. Two representative human proteins were shown to associate with U6 snRNA-containing complexes. We also identified archaeal proteins related to Sm and Sm-like proteins. Our results demonstrate that Sm and Sm-like proteins assemble in at least two functionally conserved complexes of deep evolutionary origin.

Snurportin1, an m3G-cap-specific nuclear import receptor with a novel domain structure

The nuclear import of the spliceosomal snRNPs U1, U2, U4 and U5, is dependent on the presence of a complex nuclear localization signal (NLS). The latter is composed of the 5'-2,2,7-terminal trimethylguanosine (m3G) cap structure of the U snRNA and the Sm core domain. Here, we describe the isolation and cDNA cloning of a 45 kDa protein, termed snurportin1, which interacts specifically with m3G-cap but not m7G-cap structures. Snurportin1 enhances the m3G-capdependent nuclear import of U snRNPs in both Xenopus laevis oocytes and digitonin-permeabilized HeLa cells, demonstrating that it functions as an snRNP-specific nuclear import receptor. Interestingly, solely the m3G-cap and not the Sm core NLS appears to be recognized by snurportin1, indicating that at least two distinct import receptors interact with the complex snRNP NLS. Snurportin1 represents a novel nuclear import receptor which contains an N-terminal importin beta binding (IBB) domain, essential for function, and a C-terminal m3G-cap-binding region with no structural similarity to the arm repeat domain of importin alpha.

Nucleolar localization elements in U8 snoRNA differ from sequences required for rRNA processing

U8 small nucleolar RNA (snoRNA) is essential for metazoan ribosomal RNA (rRNA) processing in nucleoli. The sequences and structural features in Xenopus U8 snoRNA that are required for its nucleolar localization were analyzed. Fluorescein-labeled U8 snoRNA was injected into Xenopus oocyte nuclei, and fluorescence microscopy of nucleolar preparations revealed that wild-type Xenopus U8 snoRNA localized to nucleoli, regardless of the presence or nature of the 5' cap on the injected U8 snoRNA. Nucleolar localization was observed when loops or stems in the 5' portion of U8 that are critical for U8 snoRNA function in rRNA processing were mutated. Therefore, sites of interaction in U8 snoRNA that potentially tether it to pre-rRNA are not essential for nucleolar localization of U8. Boxes C and D are known to be nucleolar localization elements (NoLEs) for U8 snoRNA and other snoRNAs of the Box C/D family. However, the spatial relationship of Box C to Box D was not crucial for U8 nucleolar localization, as demonstrated here by deletion of sequences in the two stems that separate them. These U8 mutants can localize to nucleoli and function in rRNA processing as well. The single-stranded Cup region in U8, adjacent to evolutionarily conserved Box C, functions as a NoLE in addition to Boxes C and D. Cup is unique to U8 snoRNA and may help bind putative protein(s) needed for nucleolar localization. Alternatively, Cup may help to retain U8 snoRNA within the nucleolus.

Interactions within the yeast Sm core complex: from proteins to amino acids

Sm core proteins play an essential role in the formation of small nuclear ribonucleoprotein particles (snRNPs) by binding to small nuclear RNAs and participating in a network of protein interactions. The two-hybrid system was used to identify SmE interacting proteins and to test for interactions between all pairwise combinations of yeast Sm proteins. We observed interactions between SmB and SmD3, SmE and SmF, and SmE and SmG. For these interactions, a direct biochemical assay confirmed the validity of the results obtained in vivo. To map the protein-protein interaction surface of Sm proteins, we generated a library of SmE mutants and investigated their ability to interact with SmF and/or SmG proteins in the two-hybrid system. Several classes of mutants were observed: some mutants are unable to interact with either SmF or SmG proteins, some interact with SmG but not with SmF, while others interact moderately with SmF but not with SmG. Our mutational analysis of yeast SmE protein shows that conserved hydrophobic residues are essential for interactions with SmF and SmG as well as for viability. Surprisingly, we observed that other evolutionarily conserved positions are tolerant to mutations, with substitutions affecting binding to SmF and SmG only mildly and conferring a wild-type growth phenotype.

A 7-methylguanosine cap commits U3 and U8 small nuclear RNAs to the nucleolar localization pathway

U3 and U8 small nucleolar RNAs (snRNAs) participate in pre-rRNA processing. Like the U1, U2, U4 and U5 major spliceosomal snRNAs, U3 and U8 RNAs are transcribed by RNA polymerase II and their initial 7-methylguanosine (m7G) 5' cap structures subsequently become converted to 2,2,7-trimethylguanosine. However, unlike the polymerase II transcribed spliceosomal snRNAs, which are exported to the cytoplasm for cap hypermethylation, U3 and U8 RNAs undergo cap hypermethylation within the nucleus. Human U3 and U8 RNAs with various cap structures were generated by in vitro transcription, fluorescently labeled and microinjected into nuclei of normal rat kidney (NRK) epithelial cells. When U3 and U8 RNAs containing a m7G cap were microinjected they became extensively localized in nucleoli. U3 and U8 RNAs containing alternative cap structures did not localize in nucleoli nor did U3 or U8 RNAs containing triphosphate 5'-termini. The nucleolar localization of m7G-capped U3 RNA was competed by co-microinjection into the nucleus of a 100-fold molar excess of dinucleotide m7GpppG but not by a 100-fold excess of ApppG dinucleotide. Although it was obviously not possible to assess formation of di- and trimethylguanosine caps on the microinjected U3 and U8 RNAs in these single cell experiments, these results indicate that the initial presence of a m7G cap on U3 and U8 RNAs, most likely together with internal sequence elements, commits these transcripts to the nucleolar localization pathway and point to diverse roles of the m7G cap in the intracellular traffic of various RNAs transcribed by RNA polymerase II.

AU-rich elements target small nuclear RNAs as well as mRNAs for rapid degradation

AU-rich elements (AREs, usually containing repeated copies of AUUUA), when present in the 3'-untranslated regions (UTRs) of many mammalian mRNAs, confer instability on their host RNA molecules. The viral small nuclear RNA (snRNA) Herpesvirus saimiri U RNA 1 (HSUR 1) also contains an AUUUA-rich sequence. Here, we report that this ARE induces rapid degradation of HSUR 1 itself and of other snRNAs including HSUR 2 and cellular U1. Mutational analyses of the viral ARE establish that sequence requirements for mRNA and snRNA decay are the same, suggesting a similar mechanism. Moreover, the in vivo degradation activity of mutant AREs correlates with their in vitro binding to the HuR protein, implicated previously as a component of the mRNA degradation machinery. Our results suggest that ARE-mediated instability can be uncoupled from both ongoing translation and deadenylation of the target RNA.

Nuclear accumulation of the U1 snRNP-specific protein C is due to diffusion and retention in the nucleus

The U1 small nuclear ribonucleoprotein particle (snRNP) has an important function in the early formation of the spliceosome, the multicomponent complex in which pre-mRNA splicing takes place. The nuclear localization signals of two of the three U1 snRNP-specific proteins, U1-70K and U1A, have been mapped. Both proteins are transported actively to the nucleus. Here we show by microinjection of Xenopus laevis oocytes that the third U1 snRNP-specific protein, U1C, passively enters the nucleus. Furthermore, we show that in both X. laevis oocytes and cultured HeLa cells mutant U1C proteins that are not able to bind to the U1 snRNP do not accumulate in the nucleus, indicating that nuclear accumulation of U1C is due to incorporation of the protein into the U1 snRNP.

RNA transport

RNA molecules synthesized in the nucleus are transported to their sites of function throughout the eukaryotic cell by specific transport pathways. This review focuses on transport of messenger RNA, small nuclear RNA, ribosomal RNA, and transfer RNA between the nucleus and the cytoplasm. The general molecular mechanisms involved in nucleocytoplasmic transport of RNA are only beginning to be understood. However, during the past few years, substantial progress has been made. A major theme that emerges from recent studies of RNA transport is that specific signals mediate the transport of each class of RNA, and these signals are provided largely by the specific proteins with which each RNA is associated.

The KRAB zinc finger gene ZNF74 encodes an RNA-binding protein tightly associated with the nuclear matrix

We previously cloned ZNF74, a developmentally expressed zinc finger gene commonly deleted in DiGeorge syndrome. Here, the intron/exon organization of the human gene and the functional properties of the expressed protein are presented. This zinc finger gene from the transcription factor IIIA/Kruppel family contains three exons. A truncated Kruppel-associated box (KRAB) located at the N terminus of the predicted 64-kDa zinc finger protein is encoded by exon 2. The remainder of the protein including the zinc finger domain as well as the 3'-untranslated region (UTR) is encoded by exon 3. Both 5'-UTR (exon 1) and 3'-UTR contain repetitive Alu elements. In vitro translation of a cDNA encoding the entire ZNF74 coding region produced a 63-kDa protein as determined on sodium dodecyl sulfate-polyacrylamide gel. A bacterially expressed fusion protein shown to bind tightly to 65zinc was used to test the nucleic acid binding properties of ZNF74. By RNA binding assays, ZNF74 was found to bind specifically to poly(U) and poly(G) RNA homopolymers. The restricted binding to these homopolymers and not to poly(A) and poly(C) suggested that ZNF74 displays RNA sequence preferences. RNA binding was mediated by the zinc finger domain. Immunofluorescence studies on transfected cells revealed ZNF74 nuclear localization. The labeling pattern observed in the nuclei clearly excluded the nucleoli. The zinc finger region lacks a classical nuclear localization signal but was found to be responsible for nuclear targeting. Subcellular and in situ sequential fractionations further showed that ZNF74 is associated with the nuclear matrix. The RNA binding properties of this protein and its tight association with the nuclear matrix, a subnuclear compartment involved in DNA replication as well as RNA synthesis and processing, suggest a role for ZNF74 in RNA metabolism.

Fine structural cytochemical and immunocytochemical analysis of nucleic acids and ribonucleoprotein distribution in nuclei of pig oocytes and early preimplantation embryos

The fine structure of pig oocytes at the germinal vesicle (GV) stage and early preimplantation embryos (one to four blastomeres) isolated at slaughter was investigated by cytochemical and immunocytochemical methods. The distribution of nucleic acids and ribonucleoproteins (RNPs) in "compact nucleoli" [denominated nucleolus-like bodies (NLB) in oocytes and nucleolus precursor bodies (NPB) in early embryos] and in intranuclear bodies or granules was investigated by staining methods preferential for nuclear RNPs or using the osmium ammine or ethidium bromide-phosphotungstic acid (EB-PTA) reactions for nucleic acids. The distributions of the Sm antigen of nucleoplasmic small nuclear RNPs (snRNPs), the methyl-3 guanosine (m3G) cap of snRNAs and the splicing factor SC-35 were detected by immunoelectron microscopy using specific antibodies. The RNP nature of both NLBs and NPBs, and of nuclear granules in oocytes and embryos, and of fibrillar strands radially projecting from NLBs was revealed. Cytochemical evidence for RNA as a component of NLBs was further provided by EB-PTA staining in combination with the enzymatic removal of RNA, or by osmium-ammine staining without previous acid hydrolysis, while the absence of DNA in NLBs was established by Feulgen-like osmium-ammine staining. In addition, autoradiography demonstrated the absence of [6-3H]thymidine incorporation into NPBs. Other autoradiographic evidence attested the accumulation of RNA in NLBs of oocytes after a 60 min in vitro pulse of [5-3H]uridine. Immunoelectron microscopy using specific antibodies revealed the occurrence of nucleoplasmic snRNPs in both NLBs and NPBs. The presence of snRNA in NLB was confirmed by means of an antibody recognizing the m3G-cap structure. Another spliceosomal component, the protein SC-35 was also detected in NLBs. Among the numerous and variable intranuclear granules occurring mostly in aggregates, the Sm antigen was clearly detected only in the interchromatin granule-type component. Some Sm labeling was occasionally seen in other categories of larger granules. No reaction was detected over any granules when using the anti-m3G-cap antibody. The aggregates consisting of large granules and a finely fibrillar component were intensely immunolabeled by the anti-SC-35 splicing factor probe. Our observations suggest that the compact nucleoli, known to be present before and after fertilization in mammals (NLBs of oocytes and NPBs of early embryos), represent nuclear structural elements containing nonnucleolar, spliceosomal components.

In vitro and in vivo evidence that protein and U1 snRNP nuclear import in somatic cells differ in their requirement for GTP-hydrolysis, Ran/TC4 and RCC1

GTP-hydrolysis, the small ras-related GTP-binding protein Ran and its cognate guanosine nucleotide exchange factor, the RCC1 gene product, have recently been identified as essential components of the protein nuclear import pathway. In this report we use three independent approaches to investigate the role of these components in U1 snRNP nuclear import in somatic cells. (i) Using a somatic cell based in vitro nuclear import system we show that U1 snRNP nuclear import, in marked contrast to protein transport, is not significantly inhibited by non-hydrolyzable GTP-analogs and is therefore unlikely to require GTP-hydrolysis. (ii) Using the dominant negative Ran mutant RanQ69L, which is defective in GTP-hydrolysis, we show that Ran-mediated GTP-hydrolysis is not essential for the nuclear import of U1 snRNP in microinjected cultured cells. (iii) Using a cell line expressing a thermolabile RCC1 gene product, we show that the nuclear accumulation of microinjected U1 snRNP is not significantly affected by RCC1 depletion at the non-permissive temperature, indicating that RCC1 function is not essential for U-snRNP nuclear import. Based on these observations we conclude that protein and U-snRNP nuclear import in somatic cells differ in their requirements for GTP-hydrolysis, and Ran or RCC1 function. Based on these results, the substrates for nucleocytoplasmic exchange across the NPC can be divided into two classes, those absolutely requiring Ran, including protein import and mRNA export, and those for which Ran is not essential, including U-snRNP nuclear import, together with tRNA and U1 snRNA nuclear export.

Assembly, nuclear import and function of U7 snRNPs studied by microinjection of synthetic U7 RNA into Xenopus oocytes

In Xenopus oocytes in vitro transcribed mouse U7 RNA is assembled into small nuclear ribonucleoproteins (snRNPs) that are functional in histone RNA 3' processing. If the special Sm binding site of U7 (AAUUUGUCUAG, U7 Sm WT) is converted into the canonical Sm sequence derived from the major snRNAs (AAUUUUUGGAG, U7 Sm OPT) the RNA assembles into a particle which accumulates more efficiently in the nucleus, but which is non-functional. U7 RNA with a heavily mutated Sm binding site (AACGCGUCAUG, U7 Sm MUT) is deficient in nuclear accumulation and function. By UV cross-linking U7 Sm WT RNA can be linked to three proteins, i.e. the common snRNP proteins G and B/B' and an apparently U7-specific protein of 40 kDa. As a result of altering the Sm binding site, U7 Sm OPT RNA cannot be cross-linked to the 40 kDa protein and no cross-links are obtained with U7 Sm MUT RNA. The fact that the Sm site also interacts with at least one U7-specific protein is so far unique to U7 RNA and may provide an explanation for the atypical sequence of this site. All described RNA-protein interactions, including that with the 40 kDa protein, already occur in the cytoplasm. An additional cytoplasmic photoadduct obtained with U7 Sm WT and U7 Sm OPT, but not U7 Sm MUT, RNAs is indicative of a protein of 60-80 kDa. The m7G cap structure of U7 Sm WT and U7 Sm OPT RNA becomes hypermethylated. However, the 3mG cap enhances, but is not required for, nuclear accumulation. Finally, U7 Sm WT RNA is functional in histone RNA processing even when bearing an ApppG cap.

The HIV-1 Rev activation domain is a nuclear export signal that accesses an export pathway used by specific cellular RNAs

HIV-1 Rev protein directs nuclear export of pre-mRNAs and mRNAs containing its binding site, the Rev response element (RRE). To define how Rev acts, we used conjugates between bovine serum albumin (BSA) and peptides comprising the Rev activation domain (BSA-R). BSA-R inhibited Rev-mediated nuclear RNA export, whereas a mutant activation domain peptide conjugate did not. BSA-R did not affect the export of mRNA, tRNA, or ribosomal subunits, but did inhibit export of 5S rRNA and spliceosomal U snRNAs. BSA-R was itself exported from the nucleus in an active, saturable manner. Thus, the Rev activation domain constitutes a nuclear export signal that redirects RRE-containing viral RNAs to a non-mRNA export pathway.

Nucleocytoplasmic transport: factors and mechanisms

In the past two years, our knowledge concerning the mechanisms of nucleocytoplasmic transport through the nuclear pore complex (NPC) has considerably expanded. The application of in vitro systems that reconstitute nuclear protein import has allowed the identification of cytosolic factors that are required for the import process. Microinjection into Xenopus oocytes and yeast genetic systems have provided interesting candidates for RNA export mediators. Functional and structural analysis of nucleoporins has demonstrated the involvement of NPC components in the transport process. Finally, new concepts have emerged such as the integration of the mechanisms of the nuclear protein import and RNA export reactions and the assembly of the transport machinery at specialised domains of the NPC.

Splinkerettes--improved vectorettes for greater efficiency in PCR walking

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