PSKH1, a novel splice factor compartment-associated serine kinase

Small nuclear ribonucleoprotein particles (snRNPs) and non-snRNP splicing factors containing a serine/arginine-rich domain (SR proteins) concentrate in splicing factor compartments (SFCs) within the nucleus of interphase cells. Nuclear SFCs are considered mainly as storage sites for splicing factors, supplying splicing factors to active genes. The mechanisms controlling the interaction of the various spliceosome constituents, and the dynamic nature of the SFCs, are still poorly understood. We show here that endogenous PSKH1, a previously cloned kinase, is located in SFCs. Migration of PSKH1-FLAG into SFCs is enhanced during co-expression of T7-tagged ASF/SF2 as well as other members of the SR protein family, but not by two other non-SR nuclear proteins serving as controls. Similar to the SR protein kinase family, overexpression of PSKH1 led to reorganization of co-expressed T7-SC35 and T7-ASF/SF2 into a more diffuse nuclear pattern. This redistribution was not dependent on PSKH1 kinase activity. Different from the SR protein kinases, the SFC-associating features of PSKH1 were located within its catalytic kinase domain and within its C-terminus. Although no direct interaction was observed between PSKH1 and any of the SR proteins tested in pull-down or yeast two-hybrid assays, forced expression of PSKH1-FLAG was shown to stimulate distal splicing of an E1A minigene in HeLa cells. Moreover, a GST-ASF/SF2 fusion was not phosphorylated by PSKH1, suggesting an indirect mechanism of action on SR proteins. Our data suggest a mutual relationship between PSKH1 and SR proteins, as they are able to target PSKH1 into SFCs, while forced PSKH1 expression modulates nuclear dynamics and the function of co-expressed splicing factors.     

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.     

SR proteins escort the U4/U6.U5 tri-snRNP to the spliceosome.

Pre-spliceosomes, formed in HeLa nuclear extracts and isolated by sedimentation on glycerol gradients, were chased into spliceosomes, the macromolecular enzyme that catalyzes intron removal. We demonstrate that the pre-spliceosome to spliceosome transition was dependent on ATP hydrolysis and required both a U-rich small nuclear ribonucleoprotein (U snRNP)-containing fraction and a fraction of non-snRNP factors. The active components in the non-snRNP fraction were identified as SR proteins and were purified to apparent homogeneity. Recombinant SR proteins (ASF, SC35, SRp55), as well as gel-purified SR proteins, with the exception of SRp20, were able to restore efficient spliceosome formation. We also demonstrate that the pre-spliceosome to spliceosome transition requires phosphorylated SR proteins. This is the first evidence that SR proteins are required for the pre-spliceosome to spliceosome transition, the step at which the U4/U6.U5 tri-snRNP assembles on the pre-mRNA. The results shown here, together with previous data, suggest U snRNPs require SR proteins as escorts to enter the assembling spliceosome.     

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.