E2F1 is involved in DNA single-strand break repair through cell-cycle-dependent upregulation of XRCC1 expression

The X-ray repair cross complementing group 1 (XRCC1) protein is involved in DNA base excision repair and its expression varies during the cell cycle. Although studies have demonstrated that rapid XRCC1-dependent single-strand break repair (SSBR) takes place specifically during S/G(2) phases, it remains unclear how it is regulated during the cell cycle. We found that XRCC1 is a direct regulatory target of E2F1 and further investigated the role of XRCC1 in DNA repair during the cell cycle. Saos2 primary osteosarcoma cells stably transfected with inducible E2F1-wt or mutant E2F1-132E were treated with hydroxurea (HU) for 36h and were subsequently withdrawn HU for 2-24h to test whether cell-cycle-dependent DNA SSBR requires E2F1-mediated upregulation of XRCC1. We found that SSBR activity, as determined using a qPCR-base method, was correlated with E2F1 levels at different phases of the cell cycle. XRCC1-positive (AA8) and negative (EM9) CHO cells were used to demonstrate that the alterations in SSBR were mediated by XRCC1. The results indicate that E2F1-mediated regulation of XRCC1 is required for cell-cycle-dependent SSBR predominantly in G(1)/S phases. Our observations have provided new mechanistic insight for understanding the role of E2F1 in the maintenance of genomic stability and cell survival during the cell cycle. The regulation of XRCC1 by E2F1 during cell-cycle-dependent SSBR might be an important aspect for practical consideration for resolving the problem of drug resistance in tumor chemotherapies.     

Differential dynamics of splicing factor SC35 during the cell cycle

Pre-mRNA splicing factors are enriched in nuclear domains termed interchromatin granule clusters or nuclear speckles. During mitosis, nuclear speckles are disassembled by metaphase and reassembled in telophase in structures termed mitotic interchromatin granules (MIGs). We analysed the dynamics of the splicing factor SC35 in interphase and mitotic cells. In HeLa cells expressing green fluorescent protein (GFP)-SC35, this was localized in speckles during interphase and dispersed in metaphase. In telophase, GFP-SC35 was highly enriched within telophase nuclei and also detected in MIGs. Fluorescence recovery after photobleaching (FRAP) experiments revealed that the mobility of GFP-SC35 was distinct in different mitotic compartments. Interestingly, the mobility of GFP-SC35 was 3-fold higher in the cytoplasm of metaphase cells compared with interphase speckles, the nucleoplasm or MIGs. Treatment of cells with inhibitors of cyclin-dependent kinases (cdks) caused changes in the organization of nuclear compartments such as nuclear speckles and nucleoli, with corresponding changes in the mobility of GFP-SC35 and GFP-fibrillarin. Our results suggest that the dynamics of SC35 are significantly influenced by the organization of the compartment in which it is localized during the cell cycle.     

Regulation of the alternative splicing of tau exon 10 by SC35 and Dyrk1A

Abnormal alternative splicing of tau exon 10 results in imbalance of 3R-tau and 4R-tau expression, which is sufficient to cause neurofibrillary degeneration. Splicing factor SC35, a member of the superfamily of the serine/arginine-rich (SR) proteins, promotes tau exon 10 inclusion. The molecular mechanism by which SC35 participates in tau exon 10 splicing remains elusive. In the present study, we found that tau pre-mRNA was coprecipitated by SC35 tagged with HA. Mutation of the SC35-like exonic splicing enhancer located at exon 10 of tau affected both the binding of SC35 to tau pre-mRNA and promotion of tau exon 10 inclusion, suggesting that SC35 acts on the SC35-like exonic splicing enhancer to promote tau exon 10 inclusion. Dyrk1A (dual-specificity tyrosine-phosphorylated and regulated kinase 1A) phosphorylated SC35 in vitro and interacted with it in cultured cells. Overexpression of Dyrk1A suppressed SC35's ability to promote tau exon 10 inclusion. Downregulation of Dyrk1A promoted 4R-tau expression. Therefore, upregulation of Dyrk1A in Down syndrome brain or Alzheimer's brain may cause dysregulation of tau exon 10 splicing through SC35, and probably together with other splicing factors, leading to the imbalance in 3R-tau and 4R-tau expression, which may initiate or accelerate tau pathology and cause neurofibrillary degeneration in the diseases.     

E2F1 and E2F3 activate ATM through distinct mechanisms to promote E1A-induced apoptosis

Deregulation of the Rb-E2F pathway occurs in many cancers and results in aberrant cell proliferation as well as an increased propensity to undergo apoptosis. In most cases, apoptosis in response to Rb inactivation involves the activation of p53 but the molecular details of the signaling pathway connecting Rb loss to p53 are poorly understood. Here we demonstrate that the E1A oncoprotein, which binds and inhibits Rb family members, induces the accumulation and phosphorylation of p53 through the DNA damage-responsive ATM kinase. As a result, E1A-induced apoptosis is significantly impaired in cells lacking ATM. In contrast, inactivation of ARF, which is widely believed to activate p53 in response to oncogenic stress, has no effect on p53 induction and only a modest effect on apoptosis in response to E1A. Both E2F1 and E2F3 contribute to ATM-dependent phosphorylation of p53 and apoptosis in cells expressing E1A. However, deregulated E2F3 activity is implicated in the DNA damage caused by E1A while E2F1 stimulates ATM- and NBS1-dependent p53 phosphorylation and apoptosis through a mechanism that does not involve DNA damage.     

ASF/SF2 and SC35 regulate the glutamate receptor subunit 2 alternative flip/flop splicing

The properties of the glutamate receptor subunits 1-4 (GluR1-4) are influenced by the alternative splicing of two homologous and mutually exclusive exons flip and flop. The flip form is most abundant during early development, while the flop form is dominant in adults. From transfections with a GluR2 mini-gene we show that flip is the preferred splice form in all tested cell lines, but coexpression of the SR-proteins ASF/SF2 and SC35 increases the flop to flip splice ratio. The increased flop incorporation depends on ASF/SF2- and SC35-dependent enhancer elements located in the flop exon, which stimulate the splicing between the flop exon and the preceding exon 13.     

SC35 plays a role in T cell development and alternative splicing of CD45

Molecular diversity via alternative splicing is important for cellular function and development. SR proteins are strong candidate regulators of alternative splicing because they can modulate splice site selection. However, endogenous substrates for SR proteins are largely unknown, and their roles as splicing regulators in vertebrate development are unclear. Here we report that Cre-mediated conditional deletion of the prototypical SR protein SC35 in the thymus causes a defect in T cell maturation. Deletion of SC35 alters alternative splicing of CD45, a receptor tyrosine phosphatase known to be regulated by differential splicing during thymocyte development and activation. This study establishes a model to address the function of SR proteins in physiological settings and reveals a critical role of SC35 in a T cell-specific regulated splicing pathway.     

Drosophila muscleblind is involved in troponin T alternative splicing and apoptosis

Background

Muscleblind-like proteins (MBNL) have been involved in a developmental switch in the use of defined cassette exons. Such transition fails in the CTG repeat expansion disease myotonic dystrophy due, in part, to sequestration of MBNL proteins by CUG repeat RNA. Four protein isoforms (MblA-D) are coded by the unique Drosophila muscleblind gene.

Methodology/Principal Findings

We used evolutionary, genetic and cell culture approaches to study muscleblind (mbl) function in flies. The evolutionary study showed that the MblC protein isoform was readily conserved from nematods to Drosophila, which suggests that it performs the most ancestral muscleblind functions. Overexpression of MblC in the fly eye precursors led to an externally rough eye morphology. This phenotype was used in a genetic screen to identify five dominant suppressors and 13 dominant enhancers including Drosophila CUG-BP1 homolog aret, exon junction complex components tsunagi and Aly, and pro-apoptotic genes Traf1 and reaper. We further investigated Muscleblind implication in apoptosis and splicing regulation. We found missplicing of troponin T in muscleblind mutant pupae and confirmed Muscleblind ability to regulate mouse fast skeletal muscle Troponin T (TnnT3) minigene splicing in human HEK cells. MblC overexpression in the wing imaginal disc activated apoptosis in a spatially restricted manner. Bioinformatics analysis identified a conserved FKRP motif, weakly resembling a sumoylation target site, in the MblC-specific sequence. Site-directed mutagenesis of the motif revealed no change in activity of mutant MblC on TnnT3 minigene splicing or aberrant binding to CUG repeat RNA, but altered the ability of the protein to form perinuclear aggregates and enhanced cell death-inducing activity of MblC overexpression.

Conclusions/Significance

Taken together our genetic approach identify cellular processes influenced by Muscleblind function, whereas in vivo and cell culture experiments define Drosophila troponin T as a new Muscleblind target, reveal a potential involvement of MblC in programmed cell death and recognize the FKRP motif as a putative regulator of MblC function and/or subcellular location in the cell.     

A set of U1 snRNA-complementary sequences involved in governing alternative RNA splicing of the kininogen genes

The rat K and T kininogen genes show different modes of mRNA production. The K gene encodes two distinct mRNAs for high molecular weight (HMW) and low molecular weight (LMW) kininogens. These two mRNAs are generated by differential usage of the 3'-terminal exon (LMW exon) and the exon next to and upstream from the LMW exon (HMW exon) through alternative splicing and polyadenylation. In contrast, the T gene generates one mRNA by using selectively the LMW exon, although the T gene is extremely homologous to the K gene. In this study, we constructed a series of chimeric kininogen genes by not only exchanging equivalent restriction fragments of the two genes but also replacing nucleotides that differ between the two genes. We then examined the sequences and the mechanisms governing the different expression patterns of the two genes by transfecting the chimeric genes into heterologous COS cells. The results indicated that the different expression patterns of the K and T genes are governed by two separate internal sequences of the HMW and LMW exons. The internal HMW sequence contains a set of five repetitive sequences, and these repetitive sequences are highly complementary to the 5' portion of U1 snRNA. Furthermore, the nucleotide differences in the U1 snRNA-complementary sequences between the K and T genes have marked effects on the relative formation of the HMW and LMW mRNAs; this indicates that the repetitive sequences complementary to U1 snRNA play a crucial role in determining the relative expression of the two mRNAs. Based on these findings, we discuss a novel mechanism for alternative RNA processing, in which splicing efficiency is controlled by the interaction of U1 small nuclear ribonucleoproteins and the U1 snRNA-complementary repetitive sequences of the kininogen pre-mRNA.     

Nuclear staining for the small heat shock protein alphaB-crystallin colocalizes with splicing factor SC35

AlphaB-Crystallin has for a long time been considered a specific eye lens protein. Later on it appeared that this protein belongs to the family of the small heat shock proteins and that it occurs also extra-lenticularly in many different cell types. AlphaB-Crystallin is mainly present in the cytoplasm, but there are some indications that it might have a function in the nucleus too. However, till now its presence in the nucleus is uncertain. We therefore compared the localization of alphaB-crystallin in nine cell lines cultured under normal conditions using four different antisera. All four antisera gave a diffuse staining for alphaB-crystallin in the cytoplasm, but one of the antibodies consistently showed nuclear staining in eight of the cell types, in the form of distinct speckles. These speckles are equally pronounced in the different cell types, whether or not cytoplasmic alphaB-crystallin is present. Preabsorption of the antiserum with alphaB-crystallin abolished the staining. Furthermore we demonstrate that if only minor amounts of alphaB-crystallin are present, the protein seems to be located exclusively in the nucleus. However, in case of higher amounts of protein, alphaB-crystallin is distributed between cytoplasm and nucleus. The nuclear alphaB-crystallin exists, like the cytoplasmic alphaB-crystallin, in non-phosphorylated and phosphorylated forms, is Triton-insoluble but can be extracted by 2 M NaCl. These data suggest that alphaB-crystallin might be bound to the nuclear matrix per se or to nuclear matrix proteins via other proteins. In agreement with other nuclear matrix proteins, nuclear alphaB-crystallin staining turns diffuse upon mitosis and leaves the chromosomes unstained. Double staining experiments revealed colocalization of alphaB-crystallin with the splicing factor SC35 in nuclear speckles, suggesting a role for alphaB-crystallin in splicing or protection of the splicing machinery.     

Regulation of alternative pre-mRNA splicing by hnRNP A1 and splicing factor SF2.

When messenger RNA precursors (pre-mRNAs) containing alternative 5' splice sites are spliced in vitro, the relative concentrations of the heterogeneous ribonucleoprotein (hnRNP) A1 and the essential splicing factor SF2 precisely determine which 5' splice site is selected. In general, an excess of hnRNP A1 favors distal 5' splice sites, whereas an excess of SF2 results in utilization of proximal 5' splice sites. The regulation of these antagonistic activities may play an important role in the tissue-specific and developmental control of gene expression by alternative splicing.