The herpes simplex virus type 1 regulatory protein ICP27 coimmunoprecipitates with anti-Sm antiserum, and the C terminus appears to be required for this interaction.

The herpes simplex virus type 1 (HSV-1) immediate-early regulatory protein ICP27 is required for the inhibition of host cell splicing during viral infection and for the reorganization of antigens associated with the small nuclear ribonucleoprotein particles (snRNPs). To determine what effect ICP27 had on splicing proteins that might cause their redistribution, we looked at proteins that were immunoprecipitated with anti-Sm antisera. No significant changes were seen in the migration or amounts of several snRNP common and snRNP-specific proteins from infected cells labeled with [35S]methionine, suggesting that the synthesis of these proteins was not altered by viral infection. However, when cells were labeled with 32Pi, differences were seen in the phosphorylation of at least two proteins depending on whether ICP27 was expressed. One protein, which had an apparent molecular mass of about 85 kDa, was highly phosphorylated during wild-type HSV-1 infection but much less so during infection with an ICP27 null mutant. The other protein, which migrated at the position of the U1 70-kDa protein and was precipitated with U1-specific antiserum, was also more highly phosphorylated when ICP27 was expressed during infection. Furthermore, a phosphoprotein with an apparent molecular mass of 63 kDa was found to coimmunoprecipitate with anti-Sm antisera during wild-type HSV-1 infection. ICP27 has an apparent molecular mass of 63 kDa, and immunoblot analysis confirmed that ICP27 coimmunoprecipitated with snRNPs. Analysis of mutations throughout the ICP27 protein demonstrated that the region that was required for this interaction was the C terminus of the protein, which includes a cysteine-histidine-rich region that resembles a zinc-finger-like motif. These data suggest that ICP27 interacts with snRNPs during infection and that it fosters changes in the phosphorylation state of at least two proteins that immunoprecipitate with snRNPs, although these studies do not demonstrate whether it does so directly or indirectly.     

Multiple properties of the splicing repressor SRp38 distinguish it from typical SR proteins

The SR protein SRp38 is a general splicing repressor that is activated by dephosphorylation during mitosis and in response to heat shock. Here we describe experiments that provide insights into the mechanism by which SRp38 functions in splicing repression. We first show that SRp38 redistributes and colocalizes with snRNPs, but not with a typical SR protein, SC35, during mitosis and following heat shock. Supporting the functional significance of this association, a micrococcal nuclease-sensitive component, i.e., an snRNP(s), completely rescued heat shock-induced splicing repression in vitro, and purified U1 snRNP did so partially. SRp38 contains an N-terminal RNA binding domain (RBD) and a C-terminal RS domain composed of two subdomains (RS1 and RS2 domains). Unexpectedly, an RS1 deletion mutant derivative specifically inhibited the second step of splicing, while an RS2 deletion mutant retained significant dephosphorylation-dependent repression activity. Using chimeric SRp38/SC35 proteins, we show that SC35-RBD/SRp38-RS can function as a general splicing activator and that the dephosphorylated version can act as a strong splicing repressor. SRp38-RBD/SC35-RS, however, was essentially inactive in these assays. Together, our results help to define the unusual features of SRp38 that distinguish it from other SR proteins.     

Exonic splicing enhancer motif recognized by human SC35 under splicing conditions

Exonic splicing enhancers (ESEs) are important cis elements required for exon inclusion. Using an in vitro functional selection and amplification procedure, we have identified a novel ESE motif recognized by the human SR protein SC35 under splicing conditions. The selected sequences are functional and specific: they promote splicing in nuclear extract or in S100 extract complemented by SC35 but not by SF2/ASF. They can also function in a different exonic context from the one used for the selection procedure. The selected sequences share one or two close matches to a short and highly degenerate octamer consensus, GRYYcSYR. A score matrix was generated from the selected sequences according to the nucleotide frequency at each position of their best match to the consensus motif. The SC35 score matrix, along with our previously reported SF2/ASF score matrix, was used to search the sequences of two well-characterized splicing substrates derived from the mouse immunoglobulin M (IgM) and human immunodeficiency virus tat genes. Multiple SC35 high-score motifs, but only two widely separated SF2/ASF motifs, were found in the IgM C4 exon, which can be spliced in S100 extract complemented by SC35. In contrast, multiple high-score motifs for both SF2/ASF and SC35 were found in a variant of the Tat T3 exon (lacking an SC35-specific silencer) whose splicing can be complemented by either SF2/ASF or SC35. The motif score matrix can help locate SC35-specific enhancers in natural exon sequences.     

SC35 autoregulates its expression by promoting splicing events that destabilize its mRNAs

SC35 belongs to the family of SR proteins that regulate alternative splicing in a concentration-dependent manner in vitro and in vivo. We previously reported that SC35 is expressed through alternatively spliced mRNAs with differing 3' untranslated sequences and stabilities. Here, we show that overexpression of SC35 in HeLa cells results in a significant decrease of endogenous SC35 mRNA levels along with changes in the relative abundance of SC35 alternatively spliced mRNAs. Remarkably, SC35 leads to both an exon inclusion and an intron excision in the 3' untranslated region of its mRNAs. In vitro splicing experiments performed with recombinant SR proteins demonstrate that SC35, but not ASF/SF2 or 9G8, specifically activates these alternative splicing events. Interestingly, the resulting mRNA is very unstable and we present evidence that mRNA surveillance is likely to be involved in this instability. SC35 therefore constitutes the first example of a splicing factor that controls its own expression through activation of splicing events leading to expression of unstable mRNA.     

ICP27 interacts with SRPK1 to mediate HSV splicing inhibition by altering SR protein phosphorylation

Infection with some viruses can alter cellular mRNA processing to favor viral gene expression. We present evidence that herpes simplex virus 1 (HSV-1) protein ICP27, which contributes to host shut-off by inhibiting pre-mRNA splicing, interacts with essential splicing factors termed SR proteins and affects their phosphorylation. During HSV-1 infection, phosphorylation of several SR proteins was reduced and this correlated with a subnuclear redistribution. Exogenous SR proteins restored splicing in ICP27-inhibited nuclear extracts and SR proteins isolated from HSV-1-infected cells activated splicing in uninfected S100 extracts, indicating that inhibition occurs by a reversible mechanism. Spliceosome assembly was blocked at the pre-spliceosomal complex A stage. Furthermore, we show that ICP27 interacts with SRPK1 and relocalizes it to the nucleus; moreover, SRPK1 activity was altered in the presence of ICP27 in vitro. We propose that ICP27 modifies SRPK1 activity resulting in hypophosphorylation of SR proteins impairing their ability to function in spliceosome assembly.     

Oogenesis in turbellarians of the genus Geocentrophora studied by light and electron microscopy. V. Oocyte nuclear structures containing factors of pre-mRNA splicing and pre-rRNA processing

An immunoelectron study of nuclear distribution of pre-mRNA splicing and pre-rRNA processing factors was carried out for oocytes of two turbellarian species: the Baikal endemic Geocentrophora wagini and a cosmopolitan G. baltica. Using monoclonal antibodies against Sm-epitope of small nuclear RNPs (snRNPs) and SR-protein SC35, it has been shown that on different stages of oocyte growth splicing factors (snRNPs and SC35) are distributed within the whole nucleus. A fibrogranular material located near heterochromatin clumps is labeled with these antibodies. A fibrillar part of this material seems to represent perichromatin fibrils. The features of intranuclear distribution of splicing factors in Geocentrophora oocyte nuclei and their ultrastructural features suggest that pre-mRNA synthesis and splicing may occur up to the end of diplotene. In Geocentrophora oocyte nuclei a few nuclear bodies (NBs) were found. Splicing factors (snRNPs and SC35) and fibrillarin were revealed in these NBs. Homology of Geocentrophora oocyte NBs to coiled bodies of oocyte and somatic cell nuclei of other animals is discussed. During diplotene, Geocentrophora oocyte nucleoli were found to lose their granular component and to change to large fibrillar structures named "postnucleoli". The postnucleoli contain both fibrillarin and non-nucleolar spliceosomal components (snRNPs and SC35). Geocentrophora oocyte postnucleoi are compared with similar structures of mammalian oocyte nuclei, taken as an example of morphological convergence of nuclear structure organization in phylogenetically distant animal species.     

ICP27 interacts with the RNA export factor Aly/REF to direct herpes simplex virus type 1 intronless mRNAs to the TAP export pathway

Herpes simplex virus type 1 (HSV-1) protein ICP27 facilitates the export of viral intronless mRNAs. ICP27 shuttles between the nucleus and cytoplasm, which has been shown to require a leucine-rich nuclear export sequence (NES). ICP27 export was reported to be sensitive to the CRM1 inhibitor leptomycin B (LMB) in HSV-1-infected cells but not in Xenopus oocytes, where ICP27 interacts with the export factor Aly/REF to access the TAP export pathway. Here, we show that ICP27 interacts with Aly/REF in HSV-1-infected mammalian cells and that Aly/REF stimulates export of viral intronless RNAs but does not cross-link to these RNAs. During infection, Aly/REF was no longer associated with splicing factor SC35 but moved into structures that colocalized with ICP27, suggesting that ICP27 recruits Aly/REF from spliceosomes to viral intronless RNAs. Further, ICP27 was found to interact in vivo with TAP but not with CRM1. In vitro export assays showed that ICP27 export was not sensitive to LMB but was blocked by a dominant-negative TAP deletion mutant lacking the nucleoporin interaction domain. These data suggest that ICP27 uses the TAP pathway to export viral RNAs. Interestingly, the leucine-rich N-terminal sequence was required for efficient export, even though ICP27 export was LMB insensitive. Thus, this region is required for efficient ICP27 export but does not function as a CRM1-dependent NES.     

An immunoelectron study of karyosphere and nuclear bodies in oocytes of mealworm beetle, Tenebrio molitor (Coleoptera: Polyphaga)

The karyosphere and nuclear bodies (NBs) were studied in Tenebrio molitor oocytes using immunoelectron cytochemistry. During early diplotene (previtellogenic stage), oocyte chromosomes begin to unite in a small nuclear volume forming the karyosphere. In vitellogenic oocyte nuclei, the chromatin undergoes condensation, and the karyosphere acquires a ring-shaped structure. The karyosphere is the only structure containing DNA in the oocyte nucleus. Pre-mRNA splicing factors [small nuclear ribonucleoproteins (snRNPs) and SC35] are not found in the karyosphere itself. In previtellogenic oocyte nuclei, these factors are present in NBs and in a fibrogranular substance surrounding the chromosomes in the early stages of karyosphere formation. At this stage, larger fibrillar NBs contain the non-snRNP splicing factor SC35. Smaller roundish NBs were shown to contain snRNPs. Some NBs with the same morphology contain neither snRNPs nor SC35. In the vitellogenic oocyte, there are fibrogranular NBs containing both snRNPs and SC35 splicing factors, fibrillar NBs containing snRNPs only, and complex NBs containing both. Complex NBs are often connected with the ring-shaped karyosphere. Based on the obtained immunoelectron data, we suggest that T. molitor oocyte NBs containing both snRNPs and the non-snRNP splicing factor SC35 are homologs of the well-characterized B-snurposomes in amphibian germinal vesicles and clusters of interchromatin granules in mammalian oocyte nuclei. Other NBs containing only snRNPs are suggested to represent a special class of insect oocyte snurposomes. The nuclear organelles mentioned seem to play a role as storage domains for pre-mRNA splicing factors during T. molitor oogenesis.     

Associations between distinct pre-mRNA splicing components and the cell nucleus.

SC-35 is a non-snRNP spliceosome component that is specifically recognized by the anti-spliceosome monoclonal antibody alpha SC-35. In this paper we provide direct evidence that SC-35 is an essential splicing factor and we examine the immunolocalization of SC-35 by confocal laser scanning microscopy and by electron microscopy. We have found that the speckled staining pattern observed by fluorescence microscopy corresponds to structures previously designated as interchromatin granules and perichromatin fibrils. Although snRNP antigens are also concentrated in these nuclear regions, we show that the two types of spliceosome components are localized through different molecular interactions: The distribution of SC-35 was not affected by treatment with DNase I or RNase A, or when the cells were heat shocked. In contrast, snRNP antigens become diffusely distributed after RNase A digestion or heat shock. Examination of cells at different stages of mitosis revealed that the SC-35 speckled staining pattern is lost during prophase and speckles containing SC-35 begin to reform in the cytoplasm of anaphase cells. In contrast, snRNP antigens do not associate with speckled regions until late in telophase. These studies reveal a dynamic pattern of assembly and disassembly of the splicing factor SC-35 into discrete nuclear structures that colocalize with interchromatin granules and perichromatin fibrils. These subnuclear regions may therefore be nuclear organelles involved in the assembly of spliceosomes, or splicing itself.