利用RT-PCR技术验证基于小鼠外显子芯片发现的缺血相关基因的表达

目的:利用RT-PCR技术验证并确认基于小鼠外显子芯片发现的部分缺血相关基因的表达,以鉴定候选基因的外显子是否发生可变剪接,从而实现对外显子芯片结果的鉴定。方法:根据生物信息学分析结果,选取小鼠外显子芯片中的3个基因(Ube3c,6330439K17Rik,Atp7a),在预测发生可变剪接的外显子两侧设计上下游引物,PCR后进行凝胶回收,再克隆到载体中进行测序。结果:RT-PCR及测序结果表明,Ube3c基因在6号外显子、6330439K17Rik基因在12号外显子、Atp7a基因在3号外显子发生可变剪接,与芯片预测结果一致。结论:RT-PCR技术可针对外显子芯片的结果进行可靠性验证,为可变剪接基因表达研究提供了一种有效手段。     

A network of conserved co-occurring motifs for the regulation of alternative splicing

Cis-acting short sequence motifs play important roles in alternative splicing. It is now possible to identify such sequence motifs as conserved sequence patterns in genome sequence alignments. Here, we report the systematic search for motifs in the neighboring introns of alternatively spliced exons by using comparative analysis of mammalian genome alignments. We identified 11 conserved sequence motifs that might be involved in the regulation of alternative splicing. These motifs are not only significantly overrepresented near alternatively spliced exons, but they also co-occur with each other, thus, forming a network of cis-elements, likely to be the basis for context-dependent regulation. Based on this finding, we applied the motif co-occurrence to predict alternatively skipped exons. We verified exon skipping in 29 cases out of 118 predictions (25%) by EST and mRNA sequences in the databases. For the predictions not verified by the database sequences, we confirmed exon skipping in 10 additional cases by using both RT–PCR experiments and the publicly available RNA-Seq data. These results indicate that even more alternative splicing events will be found with the progress of large-scale and high-throughput analyses for various tissue samples and developmental stages.     

Expression of the unique NCAM VASE exon is independently regulated in distinct tissues during development

During development of the rat central nervous system, neural cell adhesion molecule (NCAM) mRNAs containing in the extracellular domain a 30-bp alternative exon, here named VASE, replace RNAs that lack this exon. The presence of this alternative exon between previously described exons 7 and 8 changes the predicted loop structure of the derived polypeptide from one resembling an immunoglobulin constant region domain to one resembling an immunoglobulin variable domain. This change could have significant effects on NCAM polypeptide function and cell-cell interaction. In this report we test multiple rat tissues for the presence of additional alternative exons at this position and also examine the regulation of splicing of the previously described exon. To sensitively examine alternative splicing, polymerase chain reactions (PCRs) with primers flanking the exon 7/exon 8 alternative splicing site were performed. Four categories of RNA samples were tested for new exons: whole brain from embryonic day 11 to adult, specific brain regions dissected from adult brain, clonal lines of neural cells in vitro, and muscle cells and tissues cultured in vitro and obtained by dissection. Within the limits of the PCR methodology, no evidence for any alternative exon other than the previously identified VASE was obtained. The regulation of expression of this exon was found to be complex and tissue specific. Expression of the 30-bp exon in the heart and nervous system was found to be regulated independently; a significant proportion of embryonic day 15 heart NCAM mRNAs contain VASE while only a very small amount of day 15 nervous system mRNAs contain VASE. Some adult central nervous system regions, notably the olfactory bulb and the peripheral nervous system structures adrenal gland and dorsal root ganglia, express NCAM which contains very little VASE. VASE is undetectable in NCAM PCR products from the olfactory epithelium. Other nervous system regions express significant quantities of NCAM both with and without VASE. Clonal cell lines in culture generally expressed very little VASE. These results indicate that a single alternative exon, VASE, is found in NCAM immunoglobulin-like loop 4 and that distinct tissues and nervous system regions regulate expression of VASE independently both during development and in adult animals.     

Evolution of Alternative Splicing Regulation: Changes in Predicted Exonic Splicing Regulators Are Not Associated with Changes in Alternative Splicing Levels in Primates

Alternative splicing is tightly regulated in a spatio-temporal and quantitative manner. This regulation is achieved by a complex interplay between spliceosomal (trans) factors that bind to different sequence (cis) elements. cis-elements reside in both introns and exons and may either enhance or silence splicing. Differential combinations of cis-elements allows for a huge diversity of overall splicing signals, together comprising a complex ‘splicing code’. Many cis-elements have been identified, and their effects on exon inclusion levels demonstrated in reporter systems. However, the impact of interspecific differences in these elements on the evolution of alternative splicing levels has not yet been investigated at genomic level. Here we study the effect of interspecific differences in predicted exonic splicing regulators (ESRs) on exon inclusion levels in human and chimpanzee. For this purpose, we compiled and studied comprehensive datasets of predicted ESRs, identified by several computational and experimental approaches, as well as microarray data for changes in alternative splicing levels between human and chimpanzee. Surprisingly, we found no association between changes in predicted ESRs and changes in alternative splicing levels. This observation holds across different ESR exon positions, exon lengths, and 5′ splice site strengths. We suggest that this lack of association is mainly due to the great importance of context for ESR functionality: many ESR-like motifs in primates may have little or no effect on splicing, and thus interspecific changes at short-time scales may primarily occur in these effectively neutral ESRs. These results underscore the difficulties of using current computational ESR prediction algorithms to identify truly functionally important motifs, and provide a cautionary tale for studies of the effect of SNPs on splicing in human disease.     

An apparent pseudo-exon acts both as an alternative exon that leads to nonsense-mediated decay and as a zero-length exon

Pseudo-exons are intronic sequences that are flanked by apparent consensus splice sites but that are not observed in spliced mRNAs. Pseudo-exons are often difficult to activate by mutation and have typically been viewed as a conceptual challenge to our understanding of how the spliceosome discriminates between authentic and cryptic splice sites. We have analyzed an apparent pseudo-exon located downstream of mutually exclusive exons 2 and 3 of the rat alpha-tropomyosin (TM) gene. The TM pseudo-exon is conserved among mammals and has a conserved profile of predicted splicing enhancers and silencers that is more typical of a genuine exon than a pseudo-exon. Splicing of the pseudo-exon is fully activated for splicing to exon 3 by a number of simple mutations. Splicing of the pseudo-exon to exon 3 is predicted to lead to nonsense-mediated decay (NMD). In contrast, when "prespliced" to exon 2 it follows a "zero length exon" splicing pathway in which a newly generated 5' splice site at the junction with exon 2 is spliced to exon 4. We propose that a subset of apparent pseudo-exons, as exemplified here, are actually authentic alternative exons whose inclusion leads to NMD.     

The relative strengths of SR protein-mediated associations of alternative and constitutive exons can influence alternative splicing.

We have characterized the functional role of SR protein-mediated exon/exon associations in the alternative splicing of exon 5 of chicken cardiac troponin T (cTnT). We have previously shown that SR proteins can promote the association of the alternative exon 5 with the flanking constitutive exon 6 of this pre-mRNA. In this study, we have shown that when exons 2, 3, and 4 of the cTnT pre-mRNA are spliced together, the composite exon 2/3/4 contains an additional SR protein binding site. Furthermore, we have found that SR proteins can also promote interactions between the pairs of exons 2/3/4-5 and 2/3/4-6. We then asked whether the SR protein binding sites in these exons play a role in cTnT alternative splicing in vivo. We found that the SR protein binding sites in exons 2/3/4 and 6 promote exon 5 skipping, and it has previously been shown that the SR protein binding site in exon 5 promotes exon 5 inclusion. Consistent with these results, we find that the SR protein-mediated association of exon 2/3/4 with 6 is preferred over associations involving exon 5, in that exons 2/3/4 and 6 are more efficient than exon 5 in competing an SR protein-mediated exon/exon association. We suggest that the relative strengths of SR protein-mediated associations of alternative and constitutive exons play a role in determining alternative splicing patterns.