HnRNP A1 phosphorylated by VRK1 stimulates telomerase and its binding to telomeric DNA sequence

The telomere integrity is maintained via replication machinery, telomere associated proteins and telomerase. Many telomere associated proteins are regulated in a cell cycle-dependent manner. Heterogeneous nuclear ribonucleoprotein A1 (hnRNP A1), a single-stranded oligonucleotide binding protein, is thought to play a pivotal role in telomere maintenance. Here, we identified hnRNP A1 as a novel substrate for vaccinia-related kinase 1 (VRK1), a cell cycle regulating kinase. Phosphorylation by VRK1 potentiates the binding of hnRNP A1 to telomeric ssDNA and telomerase RNA in vitro and enhances its function for telomerase reaction. VRK1 deficiency induces a shortening of telomeres with an abnormal telomere arrangement and activation of DNA-damage signaling in mouse male germ cells. Together, our data suggest that VRK1 is required for telomere maintenance via phosphorylation of hnRNP A1, which regulates proteins associated with the telomere and telomerase RNA.     

HnRNP L and L-like cooperate in multiple-exon regulation of CD45 alternative splicing

CD45 encodes a trans-membrane protein-tyrosine phosphatase expressed in diverse cells of the immune system. By combinatorial use of three variable exons 4-6, isoforms are generated that differ in their extracellular domain, thereby modulating phosphatase activity and immune response. Alternative splicing of these CD45 exons involves two heterogeneous ribonucleoproteins, hnRNP L and its cell-type specific paralog hnRNP L-like (LL). To address the complex combinatorial splicing of exons 4-6, we investigated hnRNP L/LL protein expression in human B-cells in relation to CD45 splicing patterns, applying RNA-Seq. In addition, mutational and RNA-binding analyses were carried out in HeLa cells. We conclude that hnRNP LL functions as the major CD45 splicing repressor, with two CA elements in exon 6 as its primary target. In exon 4, one element is targeted by both hnRNP L and LL. In contrast, exon 5 was never repressed on its own and only co-regulated with exons 4 and 6. Stable L/LL interaction requires CD45 RNA, specifically exons 4 and 6. We propose a novel model of combinatorial alternative splicing: HnRNP L and LL cooperate on the CD45 pre-mRNA, bridging exons 4 and 6 and looping out exon 5, thereby achieving full repression of the three variable exons.     

Novel functional role of CA repeats and hnRNP L in RNA stability

CA dinucleotide repeat sequences are very common in the human genome. We have recently demonstrated that the polymorphic CA repeats in intron 13 of the human endothelial nitric oxide synthase (eNOS) gene function as an unusual, length-dependent splicing enhancer. The CA repeat enhancer requires for its activity specific binding of hnRNP L. Here we show that in the absence of bound hnRNP L, the pre-mRNA is cleaved directly upstream of the CA repeats. The addition of recombinant hnRNP L restores RNA stability. CA repeats are both necessary and sufficient for this specific cleavage in the 5' adjacent RNA sequence. We conclude that-in addition to its role as a splicing activator-hnRNP L can act in vitro as a sequence-specific RNA protection factor. Based on the wide abundance of CA repetitive sequences in the human genome, this may represent a novel, generally important role of this abundant hnRNP protein.     

Two highly polymorphic CA repeats in the Menkes gene (ATP7A)

Two highly polymorphic CA repeats have been identified in the Menkes gene (ATP7A). These repeats should be useful for prenatal diagnosis and carrier detection in families with Menkes disease and X-linked cutis laxa. The observed heterozygosity for these two repeats was 0.778 and 0.60 in Centre d'Etude du Polymorphisme Humaine (CEPH) families.     

A tailed primers protocol to identify the association of eNOS gene variable number of tandem repeats polymorphism with ischemic stroke in Chinese Han population by capillary electrophoresis

Endothelial nitric oxide synthase (eNOS) plays an important role in mediating endothelium-dependent vasodilatation and antithrombotic action and is thus involved in the development of ischemic stroke (IS). Controversial results regarding the association of eNOS gene variable number of tandem repeats (VNTR) polymorphism with IS have been reported by conventional PCR-polyacrylamide gel electrophoresis methods. We aimed to identify any common association of eNOS gene VNTR polymorphism with IS in Chinese Han population by capillary electrophoresis (CE). The VNTR polymorphism of 27 bp within the eNOS intron-4 was determined by CE with specially designed tailed primers in Chinese Han patients with IS (n = 457) and matched elderly controls without IS (n = 457). Significant differences in BMI, WHR, hypertension, diabetes, smoking, TG, HDL, LDL, LDL, and FBG were observed between cases and controls. The distributions of eNOS VNTR polymorphism were not significantly associated with IS after adjustment for cardiovascular risk factors (OR = 1.18, 95% CI: 0.82–1.69). This finding was consistent with the further meta-analysis in Asians. The meta-analysis in Americans demonstrated that 4a/4b + 4a/4a genotype was significantly associated with IS risk with an OR of 1.54 (95% CI, 1.09–2.17) compared with the 4b/4b genotype. Our data suggests that BMI, WHR, hypertension, diabetes, smoking, TG, LDL, and FBG may increase the risk of IS. However, eNOS VNTR polymorphism may be not an independent major contributor for IS in Chinese Han population. The VNTR polymorphism might be associated with IS in Americans based on meta-analysis.     

AMG531 stimulates megakaryopoiesis in vitro by binding to Mpl

Thrombopoietin (TPO) plays a pivotal role in megakaryopoiesis. TPO initiates its biological effects by binding to its receptor Mpl. A recombinant protein consisting of a carrier Fc domain linked to multiple Mpl-binding domains was constructed, and is called AMG531. To define the biological activity of AMG531, we examined the ability of AMG531 to support CFU-Meg growth and to promote megakaryocyte maturation in vitro. AMG531 stimulates CFU-Meg growth in a dose-dependent manner, and acts in concert with erythropoietin, stem cell factor, interleukin-3, and interleukin-6 to enhance CFU-Meg growth, similar to parallel experiments with TPO. AMG531-stimulated serum-free liquid cultures support the development of mature polyploid megakaryocytes with a predominant DNA content of 32 N and 64 N, identical to that of parallel TPO-stimulated cultures. Competitive binding experiments show that AMG531 effectively competes with 125I-TPO for binding to BaF3-Mpl cells or normal platelets. Treatment of BaF3-Mpl cells with AMG531 or with TPO resulted in rapid tyrosine phosphorylation of Mpl, JAK2, and STAT5. These results indicate that AMG531 is a potent stimulant of megakarypoiesis in vitro, and provide support for its further characterization in vivo.     

Grim stimulates Diap1 poly-ubiquitination by binding to UbcD1

Diap1 is an essential Drosophila cell death regulator that binds to caspases and inhibits their activity. Reaper, Grim and Hid each antagonize Diap1 by binding to its BIR domain, activating the caspases and eventually causing cell death. Reaper and Hid induce cell death in a Ring-dependent manner by stimulating Diap1 auto-ubiquitination and degradation. It was not clear that how Grim causes the ubiquitination and degradation of Diap1 in Grim-dependent cell death. We found that Grim stimulates poly-ubiquitination of Diap1 in the presence of UbcD1 and that it binds to UbcD1 in a GST pull-down assay, so presumably promoting Diap1 degradation. The possibility that dBruce is another E2 interacting with Diap1 was examined. The UBC domain of dBruce slightly stimulated poly-ubiquitination of Diap1 in Drosophila extracts but not in the reconstitution assay. However Grim did not stimulate Diap1 poly-ubiquitination in the presence of the UBC domain of dBruce. Taken together, these results suggest that Grim stimulates the poly-ubiquitination and presumably degradation of Diap1 in a novel way by binding to UbcD1 but not to the UBC domain of dBruce as an E2.     

Expanded CUG repeats Dysregulate RNA splicing by altering the stoichiometry of the muscleblind 1 complex

To understand the role of the splice regulator muscleblind 1 (MBNL1) in the development of RNA splice defects in myotonic dystrophy I (DM1), we purified RNA-independent MBNL1 complexes from normal human myoblasts and examined the behavior of these complexes in DM1 myoblasts. Antibodies recognizing MBNL1 variants (MBNL1(CUG)), which can sequester in the toxic CUG RNA foci that develop in DM1 nuclei, were used to purify MBNL1(CUG) complexes from normal myoblasts. In normal myoblasts, MBNL1(CUG) bind 10 proteins involved in remodeling ribonucleoprotein complexes including hnRNP H, H2, H3, F, A2/B1, K, L, DDX5, DDX17, and DHX9. Of these proteins, only MBNL1(CUG) colocalizes extensively with DM1 CUG foci (>80% of foci) with its partners being present in <10% of foci. Importantly, the stoichiometry of MBNL1(CUG) complexes is altered in DM1 myoblasts, demonstrating an increase in the steady state levels of nine of its partner proteins. These changes are recapitulated by the expression of expanded CUG repeat RNA in Cos7 cells. Altered stoichiometry of MBNL1(CUG) complexes results from aberrant protein synthesis or stability and is unlinked to PKCα function. Modeling these changes in normal myoblasts demonstrates that increased levels of hnRNP H, H2, H3, F, and DDX5 independently dysregulate splicing in overlapping RNA subsets. Thus expression of expanded CUG repeats alters the stoichiometry of MBNL1(CUG) complexes to allow both the reinforcement and expansion of RNA processing defects.     

Specific binding of an exonic splicing enhancer by the pre-mRNA splicing factor SRp55.

Purine-rich exonic splicing enhancers (ESEs) have been identified in many alternatively spliced exons. Alternative splicing of several ESE-containing exons has been shown to depend on subsets of the SR protein family of pre-mRNA splicing factors. In this report, we show that purified SR protein family member SRp55 by itself binds a 30-nt ESE-containing exon, the alternatively spliced exon 5 of avian cardiac troponin T. We show that purified SRp55 binds specifically to this RNA sequence with an apparent Kd of 60 nM as assayed by gel mobility retardation experiments. Mutations in the exon 5 sequence that increase or decrease exon 5 inclusion in vivo and in vitro have correspondingly different affinities for SRp55 in our assays. The exon 5 sequence contains two purine-rich motifs, common to many ESEs, and both are required for SRp55 binding. Hill plot analysis of binding titration reactions indicates that there is a cooperative binding of at least two SRp55 proteins to the exon sequence. Chemical modification interference studies using kethoxal show that SRp55 binding to exon 5 requires the N1 and/or the N2 of almost every G residue in the exon. Dimethylsulfate modification interference studies indicate that none of the N1 positions of A residues in the exon are important for binding. We postulate that SRp55 may recognize both primary sequence and RNA secondary structural elements within pre-mRNA.     

L1 mediated homophilic binding and neurite outgrowth are modulated by alternative splicing of exon 2

The neural cell adhesion molecule (CAM) L1 is a member of the immunoglobulin superfamily that has been implicated in neuronal adhesion, neurite outgrowth, and axon guidance. The clinical importance of L1 is illustrated by pathological mutations that lead to hydrocephalus, mental retardation, motor defects, and early mortality. The L1 gene is composed of 28 exons, including exons 2 and 27 that are spliced alternatively, and mutations in exon 2 are associated with severe neurological abnormalities in humans. To elucidate the role of L1 exon 2, a recombinant Fc fusion protein called Delta2L1 was constructed lacking the second exon in the extracellular domain of L1. When bound to fluorescent beads, L1 exhibited homophilic binding while Delta2L1 did not. However, L1 beads coaggregated with the Delta2L1 beads. Similarly, in cell binding studies, L1 bound to L1 and Delta2L1 did not bind to Delta2L1 but it bound moderately to L1. Given the reduced binding of Delta2L1, we tested its effect on neurons. By comparison to L1, a lower percentage of dissociated neurons extended neurites on Delta2L1, and there was a modest decrease in the length of the neurites that grew. Neurite outgrowth from reaggregated neurons was much less robust on Delta2L1 than on L1. The combined results indicate that Delta2L1 does not bind homophilically but it can interact with L1 containing exon 2. The reduced binding and neurite promoting activity of Delta2L1 provides an explanation for certain pathological mutations in L1 that lead to clinically apparent disease in the absence of the normal form of L1 in the nervous system.     

Quantitative analysis of CUG-BP1 binding to RNA repeats

CUG-binding protein 1 (CUG-BP1) is a member of the CUG-BP1 and ETR-3-like factors (CELF) family of RNA-binding proteins, and is involved in myotonic dystrophy type 1 (DM1). Several mRNA targets of CUG-BP1 have been identified, including the insulin receptor, muscle chloride channel, and cardiac troponin T. On the other hand, CUG-BP1 has only a weak affinity for CUG repeats. We conducted quantitative-binding assays to assess CUG-BP1 affinities for several repeat RNAs by surface plasmon resonance (SPR). Although we detected interactions between CUG-BP1 and CUG repeats, other UG-rich sequences actually showed stronger interactions. Binding constants of CUG-BP1 for RNAs indicated that the affinity for UG repeats was far stronger than for CUG repeats. We also found that N-terminal deletion mutant of CUG-BP1 has UG repeat-binding activity in a yeast three-hybrid system, although C-terminal deletion mutant does not. Our data indicates that CUG-BP1 specifically recognized UG repeats, probably through cooperative binding of RNA recognition motifs at both ends of the protein. This is the first report of a binding constant for CUG-BP1 calculated in vitro.     

Procollagen C-proteinase enhancer stimulates procollagen processing by binding to the C-propeptide region only

Bone morphogenetic protein-1 (BMP-1) and the tolloid-like metalloproteinases control several aspects of embryonic development and tissue repair. Unlike other proteinases whose activities are regulated mainly by endogenous inhibitors, regulation of BMP-1/tolloid-like proteinases relies mostly on proteins that stimulate activity. Among these, procollagen C-proteinase enhancers (PCPEs) markedly increase BMP-1/tolloid-like proteinase activity on fibrillar procollagens, in a substrate-specific manner. Here, we performed a detailed quantitative study of the binding of PCPE-1 and of its minimal active fragment (CUB1-CUB2) to three regions of the procollagen III molecule: the triple helix, the C-telopeptide, and the C-propeptide. Contrary to results described elsewhere, we found the PCPE-1-binding sites to be located exclusively in the C-propeptide region. In addition, binding and enhancing activities were found to be independent of the glycosylation state of the C-propeptide. These data exclude previously proposed mechanisms for the action of PCPEs and also suggest new mechanisms to explain how these proteins can stimulate BMP-1/tolloid-like proteinases by up to 20-fold.     

ATP stimulates binding of retinol-cellular retinol binding protein complex to DNA-cellulose

In calf uterus cytosol a cellular retinol-binding protein (cRBP) was detected which was found to bind to DNA-cellulose. The binding to DNA-cellulose could be enhanced by ATP in a dose-dependent manner. ATP treatment did not change the physico-chemical properties of the retinol-cRBP complex. Our findings suggest a role for ATP in the binding of retinol-cRBP complex to DNA.     

Alternative splicing and gene polymorphism of the human TAP3/SEC14L4 gene

Three closely related human SEC14p-like proteins (hTAP1, hTAP2, hTAP3, or SEC14L2, SEC14L3, SEC14L4, respectively) have been described that are related to the Saccharomyces cerevisiae SEC14 protein. These proteins may participate in intracellular lipid transport and influence regulatory lipid-dependent events. Here we report the isolation of an alternatively spliced hTAP3 cDNA and a polymorphism within the coding region of the hTAP3/SEC14L4 gene.     

Alternative splicing, gene localization, and binding of SH2-B to the insulin receptor kinase domain

The SH2-B protein is an SH2-domain-containing molecule that interacts with a number of phosphorylated kinase and receptor molecules including the insulin receptor. Two isoforms of the SH2-B have been identified and have been proposed to arise through alternate splicing. Here we have identified a third isoform of the SH2-B protein, SH2-Bγ, that interacts specifically with the insulin receptor. This interaction required phosphorylation of residue Y1146 in the triple tyrosine motif within the activation loop of the IR kinase and is one of only two signaling molecules shown to interact directly with this residue of the insulin receptor kinase domain. The intron/exon structure of the SH2-B gene was determined. Alternate splice sites utilized to generate the different isoforms of the SH2-B protein were identified in the 3′ end of the SH2-B gene immediately downstream of the exon encoding the core of the SH2 domain. Additionally, the chromosomal location of the SH2-B gene was determined to be the distal arm of mouse Chromosome (Chr) 7 in a region linked to obesity in mice. Received: 13 May 1999 / Accepted: 13 August 1999     

Repression of alpha-actinin SM exon splicing by assisted binding of PTB to the polypyrimidine tract

Polypyrimidine tract binding protein (PTB) acts as a regulatory repressor of a large number of alternatively spliced exons, often requiring multiple binding sites in order to repress splicing. In one case, cooperative binding of PTB has been shown to accompany repression. The SM exon of the alpha-actinin pre-mRNA is also repressed by PTB, leading to inclusion of the alternative upstream NM exon. The SM exon has a distant branch point located 386 nt upstream of the exon with an adjacent 26 nucleotide pyrimidine tract. Here we have analyzed PTB binding to the NM and SM exon region of the alpha-actinin pre-mRNA. We find that three regions of the intron bind PTB, including the 3' end of the polypyrimidine tract (PPT) and two additional regions between the PPT and the SM exon. The downstream PTB binding sites are essential for full repression and promote binding of PTB to the PPT with a consequent reduction in U2AF(65) binding. Our results are consistent with a repressive mechanism in which cooperative binding of PTB to the PPT competes with binding of U2AF(65), thereby specifically blocking splicing of the SM exon.     

Autoregulation of polypyrimidine tract binding protein by alternative splicing leading to nonsense-mediated decay

Polypyrimdine tract binding protein (PTB) is a regulator of alternative splicing, mRNA 3' end formation, mRNA stability and localization, and IRES-mediated translation. Transient overexpression of PTB can influence alternative splicing, sometimes resulting in nonphysiological splicing patterns. Here, we show that alternative skipping of PTB exon 11 leads to an mRNA that is removed by NMD and that this pathway consumes at least 20% of the PTB mRNA in HeLa cells. We also show that exon 11 skipping is itself promoted by PTB in a negative feedback loop. This autoregulation may serve both to prevent disruptively high levels of PTB expression and to restore nuclear levels when PTB is mobilized to the cytoplasm. Our findings suggest that alternative splicing can act not only to generate protein isoform diversity but also to quantitatively control gene expression and complement recent bioinformatic analyses, indicating a high prevalence of human alternative splicing leading to NMD.