东方蜜蜂微孢子虫基因的可变剪接及可变腺苷酸化解析

本研究旨在基于已获得的第三代纳米孔全长转录组数据对东方蜜蜂微孢子虫Nosema ceranae基因的可变剪接(alternative splicing,AS)和可变多聚腺苷酸化(alternative polyadenylation,APA)进行分析.通过Astalavista软件鉴定东方蜜蜂微孢子虫基因的AS事件类型...     

Differential splicing in mouse thymus generates two forms of terminal deoxynucleotidyl transferase.

A new form of TdT mRNA has been identified by screening a mouse thymus cDNA library. It contains an open reading frame of 1527 base pairs corresponding to a protein containing 509 aminoacids, whereas the previously identified mouse TdT mRNA is composed of 1587 base pairs and encodes a protein of 529 aminoacids. Analysis of a mouse genomic clone containing the 3' portion of the TdT gene shows that these twenty additional aminoacids are encoded by an additional exon located between exons X and XI. Both forms of TdT mRNA are present in the thymus and could be generated by alternative splicing. The cDNA reported here corresponds to the major form of TdT mRNA in Balb/c mice and closely resembles human and bovine TdT cDNA. Expression of this cDNA in mammalian cells shows that it encodes a functional protein capable of catalysing N region insertions at the recombination junction of an episomic recombination substrate.     

Muscleblind proteins regulate alternative splicing

Although the muscleblind (MBNL) protein family has been implicated in myotonic dystrophy (DM), a specific function for these proteins has not been reported. A key feature of the RNA-mediated pathogenesis model for DM is the disrupted splicing of specific pre-mRNA targets. Here we demonstrate that MBNL proteins regulate alternative splicing of two pre-mRNAs that are misregulated in DM, cardiac troponin T (cTNT) and insulin receptor (IR). Alternative cTNT and IR exons are also regulated by CELF proteins, which were previously implicated in DM pathogenesis. MBNL proteins promote opposite splicing patterns for cTNT and IR alternative exons, both of which are antagonized by CELF proteins. CELF- and MBNL-binding sites are distinct and regulation by MBNL does not require the CELF-binding site. The results are consistent with a mechanism for DM pathogenesis in which expanded repeats cause a loss of MBNL and/or gain of CELF activities, leading to misregulation of alternative splicing of specific pre-mRNA targets.     

An alternative splicing event which occurs in mouse pachytene spermatocytes generates a form of DNA ligase III with distinct biochemical properties that may function in meiotic recombination.

Three mammalian genes encoding DNA ligases have been identified. However, the role of each of these enzymes in mammalian DNA metabolism has not been established. In this study, we show that two forms of mammalian DNA ligase III, alpha and beta, are produced by a conserved tissue-specific alternative splicing mechanism involving exons encoding the C termini of the polypeptides. DNA ligase III-alpha cDNA, which encodes a 103-kDa polypeptide, is expressed in all tissues and cells, whereas DNA ligase III-beta cDNA, which encodes a 96-kDa polypeptide, is expressed only in the testis. During male germ cell differentiation, elevated expression of DNA ligase III-beta mRNA is restricted, beginning only in the latter stages of meiotic prophase and ending in the round spermatid stage. In 96-kDa DNA ligase III-beta, the C-terminal 77 amino acids of DNA ligase III-alpha are replaced by a different 17- to 18-amino acid sequence. As reported previously, the 103-kDa DNA ligase III-alpha interacts with the DNA strand break repair protein encoded by the human XRCC1 gene. In contrast, the 96-kDa DNA ligase III-beta does not interact with XRCC1, indicating that DNA ligase III-beta may play a role in cellular functions distinct from the DNA repair pathways involving the DNA ligase III-alpha x XRCC1 complex. The distinct biochemical properties of DNA ligase III-beta, in combination with the tissue- and cell-type-specific expression of DNA ligase III-beta mRNA, suggest that this form of DNA ligase III is specifically involved in the completion of homologous recombination events that occur during meiotic prophase.