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.     

Newly assembled snRNPs associate with coiled bodies before speckles, suggesting a nuclear snRNP maturation pathway.

BACKGROUND: Small nuclear ribonucleoproteins (snRNPs), which are essential components of the mRNA splicing machinery, comprise small nuclear RNAs, each complexed with a set of proteins. An early event in the maturation of snRNPs is the binding of the core proteins - the Sm proteins - to snRNAs in the cytoplasm followed by nuclear import. Immunolabelling with antibodies against Sm proteins shows that splicing snRNPs have a complex steady-state localisation within the nucleus, the result of the association of snRNPs with several distinct subnuclear structures. These include speckles, coiled bodies and nucleoli, in addition to a diffuse nucleoplasmic compartment. The reasons for snRNP accumulation in these different structures are unclear. RESULTS: When mammalian cells were microinjected with plasmids encoding the Sm proteins B, D1 and E, each tagged with either the green fluorescent protein (GFP) or yellow-shifted GFP (YFP), a pulse of expression of the tagged proteins was observed. In each case, the newly synthesised GFP/YFP-labelled snRNPs accumulated first in coiled bodies and nucleoli, and later in nuclear speckles. Mature snRNPs localised immediately to speckles upon entering the nucleus after cell division. CONCLUSIONS: The complex nuclear localisation of splicing snRNPs results, at least in part, from a specific pathway for newly assembled snRNPs. The data demonstrate that the distribution of snRNPs between coiled bodies and speckles is directed and not random.     

In vitro reconstitution of mammalian U2 and U5 snRNPs active in splicing: Sm proteins are functionally interchangeable and are essential for the formation of functional U2 and U5 snRNPs.

An in vitro reconstitution/splicing complementation system has been developed which has allowed the investigation of the role of mammalian U2 and U5 snRNP components in splicing. U2 or U5 snRNP cores are first reconstituted from purified native snRNP core proteins and snRNA in the absence of cellular extract and are subsequently added to splicing extracts depleted of either U2 or U5 snRNP. When snRNPs reconstituted with HeLa U2 or U5 snRNA were added to U2- or U5-depleted nuclear extract, splicing was complemented. Addition of naked snRNA, on the other hand, did not restore splicing, demonstrating that the core proteins are essential for both U2 and U5 snRNP functions in splicing. Hybrid U2 or U5 snRNPs, reconstituted with core proteins isolated from U1 or U2 snRNPs, were equally active in splicing complementation, indicating that the snRNP core proteins are functionally interchangeable. U5 snRNPs reconstituted from in vitro transcribed U5 snRNA restored splicing to a level identical to that observed with particles reconstituted from authentic HeLa U5 snRNA. In contrast, splicing could not be restored to U2-depleted extract by the addition of snRNPs reconstituted from synthetic U2 snRNA, suggesting that U2 snRNA base modifications are essential for U2 snRNP function.     

Reassembly and protection of small nuclear ribonucleoprotein particles by heat shock proteins in yeast cells

The process of mRNA splicing is sensitive to in vivo thermal inactivation, but can be protected by pretreatment of cells under conditions that induce heat-shock proteins (Hsps). This latter phenomenon is known as "splicing thermotolerance". In this article we demonstrate that the small nuclear ribonucleoprotein particles (snRNPs) are in vivo targets of thermal damage within the splicing apparatus in heat-shocked yeast cells. Following a heat shock, levels of the tri-snRNP (U4/U6.U5), free U6 snRNP, and a pre-U6 snRNP complex are dramatically reduced. In addition, we observe multiple alterations in U1, U2, U5, and U4/U6 snRNP profiles and the accumulation of precursor forms of U4- and U6-containing snRNPs. Reassembly of snRNPs following a heat shock is correlated with the recovery of mRNA splicing and requires both Hsp104 and the Ssa Hsp70 family of proteins. Furthermore, we correlate splicing thermotolerance with the protection of a subset of snRNPs by Ssa proteins but not Hsp104, and show that Hsp70 directly associates with U4- and U6-containing snRNPs in splicing thermotolerant cells. In addition, our results show that Hsp70 plays a role in snRNP assembly under normal physiological conditions.     

Mg2+ induces a sharp and reversible transition in U1 and U2 small nuclear ribonucleoprotein configurations.

When U1 and U2 small nuclear ribonucleoproteins (snRNPs) purified by a procedure which preserves their immunoprecipitability by autoimmune antibodies (Hinterberger et al., J. Biol. Chem. 258:2604-2613, 1983), were submitted to extensive digestion with micrococcal nuclease, we found that their degradation pattern was sharply dependent upon magnesium concentration, indicating that they undergo a profound structural modification. At low Mg2+ (less than or equal to 5 mM), both particles only exhibit a core-resistant structure previously identified as being common to all but U6 snRNAs (Liautard et al., J. Mol. Biol. 162: 623-643, 1982). At high Mg2+ (greater than or equal to 7 mM), U1 and U2 snRNPs behave differently from one another. In U1 snRNP, most U1 snRNA sequence is protected, except for the 10 5'-terminal nucleotides presumably involved in splicing and a short sequence between nucleotides 102 and 108. Another region spanning nucleotides 60 to 79 is only weakly protected. This structural modification was demonstrated to be reversible. In U2 snRNP, the U2 snRNA sequence remains exposed in its 5' part up to nucleotide 92, and the 3'-terminal hairpin located outside the core structure becomes protected.     

A novel virus-host cell membrane interaction. Membrane voltage-dependent endocytic-like entry of bacteriophage straight phi6 nucleocapsid.

Studies on the virus-cell interactions have proven valuable in elucidating vital cellular processes. Interestingly, certain virus-host membrane interactions found in eukaryotic systems seem also to operate in prokaryotes (Bamford, D.H., M. Romantschuk, and P. J. Somerharju, 1987. EMBO (Eur. Mol. Biol. Organ.) J. 6:1467-1473; Romantschuk, M., V.M. Olkkonen, and D.H. Bamford. 1988. EMBO (Eur. Mol. Biol. Organ.) J. 7:1821-1829). straight phi6 is an enveloped double-stranded RNA virus infecting a gram-negative bacterium. The viral entry is initiated by fusion between the virus membrane and host outer membrane, followed by delivery of the viral nucleocapsid (RNA polymerase complex covered with a protein shell) into the host cytosol via an endocytic-like route. In this study, we analyze the interaction of the nucleocapsid with the host plasma membrane and demonstrate a novel approach for dissecting the early events of the nucleocapsid entry process. The initial binding of the nucleocapsid to the plasma membrane is independent of membrane voltage (DeltaPsi) and the K(+) and H(+) gradients. However, the following internalization is dependent on plasma membrane voltage (DeltaPsi), but does not require a high ATP level or K(+) and H(+) gradients. Moreover, the nucleocapsid shell protein, P8, is the viral component mediating the membrane-nucleocapsid interaction.     

Interaction of snRNAs with rapidly sedimenting nuclear sub-structures (hnRNPs) from HeLa cells.

We have shown previously (Liautard et al., 1982, J. Mol. Biol., 162, 623-643) that digestion with micrococcal nuclease under drastic conditions of a pure U1 snRNP, as well as a mixture containing U2, U1, U4, U5 and U6 snRNPs, gives rise to resistant RNA fragments derived from all but U6 snRNAs. As an attempt to elucidate the way in which snRNPs are attached to their native structure, the same approach was applied to hnRNP which are known to contain snRNP (Guimont-Ducamp et al., 1977, Biochimie, 59, 755-758). Micrococcal nuclease digestion of hnRNPs yielded a population of 15-50 nucleotides long resistant fragments of snRNAs. Sequence analyses showed that all fragments previously identified in core snRNPs were also present. Only U2 and U5 snRNAs were further protected as a result of their association with the hnRNP complex (from the cap to nucleotide 32 for U2 and from nucleotide 22 to nucleotide 70 for U5). No additional protected fragment derived from U1, U4 and U6 snRNAs was found. This finding confirms that the 5' terminal region of U1 snRNP remains available for base-pairing interaction with the premessenger RNA, as predicted by the model of Lerner et al. (Nature, 1980, 283, 220-224).     

Detection of snRNP assembly intermediates in Cajal bodies by fluorescence resonance energy transfer

Spliceosomal small nuclear ribonucleoprotein particles (snRNPs) are required for pre-mRNA splicing throughout the nucleoplasm, yet snRNPs also concentrate in Cajal bodies (CBs). To address a proposed role of CBs in snRNP assembly, we have used fluorescence resonance energy transfer (FRET) microscopy to investigate the subnuclear distribution of specific snRNP intermediates. Two distinct complexes containing the protein SART3 (p110), required for U4/U6 snRNP assembly, were localized: SART3.U6 snRNP and SART3.U4/U6 snRNP. These complexes segregated to different nuclear compartments, with SART3.U6 snRNPs exclusively in the nucleoplasm and SART3.U4/U6 snRNPs preferentially in CBs. Mutant cells lacking the CB-specific protein coilin and consequently lacking CBs exhibited increased nucleoplasmic levels of SART3.U4/U6 snRNP complexes. Reconstitution of CBs in these cells by expression of exogenous coilin restored accumulation of SART3.U4/U6 snRNP in CBs. Thus, while some U4/U6 snRNP assembly can occur in the nucleoplasm, these data provide evidence that SART3.U6 snRNPs form in the nucleoplasm and translocate to CBs where U4/U6 snRNP assembly occurs.     

An ordered pathway of snRNP binding during mammalian pre-mRNA splicing complex assembly.

We have studied the assembly, composition and structure of splicing complexes using biotin-avidin affinity chromatography and RNase protection assays. We find that U1, U2, U4, U5 and U6 snRNPs associate with the pre-mRNA and are in the mature, functional complex. Association of U1 snRNP with the pre-mRNA is rapid and ATP independent; binding of all other snRNPs occurs subsequently and is ATP dependent. Efficient binding of U1 and U2 snRNPs requires a 5' splice site or a 3' splice site/branch point region, respectively. Both sequence elements are required for efficient U4, U5 and U6 snRNP binding. Mutant RNA substrates containing only a 5' splice site or a 3' splice site/branch point region are assembled into 'partial' splicing complexes, which contain a subset of these five snRNPs. RNase protection experiments indicate that in contrast to U1 and U2 snRNPs, U4, U5 and U6 snRNPs do not contact the pre-mRNA. Based upon the time course of snRNP binding and the composition of sucrose gradient fractionated splicing complexes we suggest an assembly pathway proceeding from a 20S (U1 snRNP only) through a 40S (U1 and U2 snRNPs) to the functional 60S splicing complex (U1, U2, U4, U5 and U6 snRNPs).     

Assembly of U7 small nuclear ribonucleoprotein particle and histone RNA 3' processing in Xenopus egg extracts

In animals, replication-dependent histone genes are expressed in dividing somatic cells during S phase to maintain chromatin condensation. Histone mRNA 3'-end formation is an essential regulatory step producing an mRNA with a hairpin structure at the 3'-end. This requires the interaction of the U7 small nuclear ribonucleoprotein particle (snRNP) with a purine-rich spacer element and of the hairpin-binding protein with the hairpin element, respectively, in the 3'-untranslated region of histone RNA. Here, we demonstrate that bona fide histone RNA 3' processing takes place in Xenopus egg extracts in a reaction dependent on the addition of synthetic U7 RNA that is assembled into a ribonucleoprotein particle by protein components available in the extract. In addition to reconstituted U7 snRNP, Xenopus hairpin-binding protein SLBP1 is necessary for efficient processing. Histone RNA 3' processing is not affected by addition of non-destructible cyclin B, which drives the egg extract into M phase, but SLBP1 is phosphorylated in this extract. SPH-1, the Xenopus homologue of human p80-coilin found in coiled bodies, is associated with U7 snRNPs. However, this does not depend on the U7 RNA being able to process histone RNA and also occurs with U1 snRNPs; therefore, association of SPH1 cannot be considered as a hallmark of a functional U7 snRNP.     

Nuclear organization of splicing small nuclear ribonucleoproteins in adenovirus-infected cells.

We have studied the effect of adenovirus infection on the nuclear organization of splicing small nuclear ribonucleoproteins (snRNPs) in HeLa cells. In uninfected HeLa cells, snRNPs are widespread throughout the nucleoplasm but also are concentrated in specific nuclear structures, including coiled bodies, interchromatin granules, and perichromatin fibrils. We have used immunofluorescence microscopy to study the localization of splicing snRNPs relative to centers of viral DNA synthesis and accumulation identified with antiserum against the viral 72,000-molecular-weight single-stranded DNA-binding protein (72K protein). Splicing snRNPs were independently detected with both monoclonal and polyclonal antibodies specific for common snRNP antigens, snRNP-specific proteins, and the snRNA-specific 2,2,7-trimethylguanosine 5' cap structure. We have examined infected cells 2 to 24 h after infection, and, in the majority of these cells, we observed no colocalization of the snRNP and 72K-protein staining patterns. In the late phase, snRNPs were found to markedly concentrate in discrete clusters that were distinct from the centers of viral DNA synthesis and accumulation identified with anti-72K protein. We have treated cells with hydroxyurea at various times after infection to inhibit aspects of the virus infectious program. We have found that the accumulation of snRNP clusters is correlated with late gene expression rather than with DNA synthesis or early gene expression. Finally, we show that the late-phase snRNP clusters colocalize with a monoclonal antibody that primarily stains interchromatin granules. These results suggest that the centers of snRNP concentration in late-phase infected cells are likely to correspond to interchromatin granule clusters.     

Ultrastructural distribution of nuclear ribonucleoproteins as visualized by immunocytochemistry on thin sections

The ultrastructural distribution of nuclear ribonucleoproteins (RNP) has been investigated by incubation of thin sections of mouse or rat liver, embedded in Lowicryl K4M or prepared by cryoultramicrotomy, with antibodies specific for RNP. The antibodies were localized by means of a protein A-colloidal gold complex. Anti-small nuclear (sn)RNP antibodies, specific for determinants of the nucleoplasmic snRNP species containing U1, U2, U4, U5, and U6 RNAs, were found associated preferentially with perichromatin fibrils, interchromatin granules, and coiled bodies. This indicates an early association of snRNP with structural constituents containing newly synthesized heterogeneous nuclear RNA. It also suggests a possible structural role of some snRNPs in nuclear architecture. Antibodies against the core proteins of heterogeneous nuclear RNP particles associate preferentially with the border regions of condensed chromatin, and in particular with perichromatin fibrils and some perichromatin granules. These results are discussed in view of recent knowledge about the possible role of nucleoplasmic RNP-containing components in the functions of the cell nucleus.