Regulated expression of the small nuclear ribonucleoprotein particle protein SmN in embryonic stem cell differentiation.

The SmN protein is a component of small nuclear ribonucleoprotein particles and is closely related to the ubiquitous SmB and B' splicing proteins. It is expressed in a limited range of tissues and cell types, including several undifferentiated embryonal carcinoma cell lines and undifferentiated embryonic stem cells. The protein declines to undetectable levels when embryonal carcinoma or embryonic stem cells are induced to differentiate, producing primitive endoderm or parietal endoderm or yielding embryonal bodies. This decline is due to a corresponding decrease in the level of the SmN mRNA. The potential role of SmN in the regulation of alternative splicing in embryonic cell lines and early embryos is discussed.     

The snRNP core protein SmB and tissue-specific SmN protein are differentially distributed between snRNP particles.

The SmN protein is a tissue specific component of the small nuclear ribonucleoprotein particle which is closely related to the ubiquitously expressed SmB protein but is expressed only in the brain and heart. To investigate the function of SmN, its localisation within different snRNP particles was investigated using a range of anti-snRNP monoclonal antibodies. SmN and SmB were found to exhibit different patterns of association with snRNP particles in two cell lines, ND7 and F9 which express SmN. In both cases, SmN was found to be present in the U-2 snRNP but was excluded from the U-1 snRNPs whereas SmB was present in both U-1 and U-2 snRNPs. Data from transfected 3T3 mouse fibroblasts cell lines artificially expressing a low level of SmN also confirm this observation. In contrast, SmN was found to be an integral component of both the U-1 and U-2 snRNPs in both 3T3 cells artificially expressing high levels of SmN and in adult rat brain which has a naturally high level of SmN expression. Taken together, the results suggest that the pre-U1 snRNP particle has a lower affinity for SmN than for SmB. Thus, SmN expressed at low levels incorporates into U2, but SmN expressed at high levels incorporates into both U1 and U2 snRNPs and replaces SmB. The significance of these effects is discussed in terms of the potential role played by SmN in constitutive and alternative splicing pathways in neuronal cells.     

The intronless mouse gene for the tissue specific splicing protein SmN is a processed pseudogene containing a stop codon after thirty-one amino acids.

The SmN protein is a component of small ribonucleoprotein particles which is closely related to the ubiquitously expressed splicing proteins SmB and B' but is expressed in only a small number of cells and tissues. We have isolated a mouse SmN-related sequence which lacks introns and contains multiple changes from the SmN cDNA sequence including a stop codon after thirty-one amino acids which would prevent it encoding functional SmN protein. This indicates that this intronless gene is a processed pseudogene and that the functional gene has yet to be isolated. In agreement with this southern blotting of mouse DNA with SmN probes reveals bands, additional to those derived from the pseudogene, which are characteristic of an intron-containing SmN gene. The relationship of the pseudogene to the functional SmN gene and to an intronless SmN-related sequence in the rat genome is discussed.     

Repressing the neuron within

A myriad of coordinated signals control cellular differentiation. Reprogramming the cell's proteome drives global changes in cell morphology and function that define cell phenotype. A switch in alternative splicing of many pre-mRNAs encoding neuronal-specific proteins accompanies neuronal differentiation. Three groups recently showed that the global splicing repressor, polypyrimidine track-binding protein (PTB), regulates this switch.1-3 Although a subset of neuronal genes are turned on in both non-neuronal and neuronal cells, restricted expression of PTB in non-neuronal cells diverts their mRNAs to nonsense-mediated decay and prevents protein expression. When the PTB brake is released, the cell splices like a neuron.     

Cardiac tissue-specific repression of CELF activity disrupts alternative splicing and causes cardiomyopathy

Members of the CELF family of RNA binding proteins have been implicated in alternative splicing regulation in developing heart. Transgenic mice that express a nuclear dominant-negative CELF protein specifically in the heart (MHC-CELFDelta) develop cardiac hypertrophy and dilated cardiomyopathy with defects in alternative splicing beginning as early as 3 weeks after birth. MHC-CELFDelta mice exhibit extensive cardiac fibrosis, severe cardiac dysfunction, and premature death. Interestingly, the penetrance of the phenotype is greater in females than in males despite similar levels of dominant-negative expression, suggesting that there is sex-specific modulation of splicing activity. The cardiac defects in MHC-CELFdelta mice are directly attributable to reduced levels of CELF activity, as crossing these mice with mice overexpressing CUG-BP1, a wild-type CELF protein, rescues defects in alternative splicing, the severity and incidence of cardiac hypertrophy, and survival. We conclude that CELF protein activity is required for normal alternative splicing in the heart in vivo and that normal CELF-mediated alternative splicing regulation is in turn required for normal cardiac function.     

CD72几种新的剪切形式的发现及它们在红斑狼疮模型鼠中的差异表达

CD72是一个重要的B细胞特异性受体,它以多种选择性剪切形式存在.在小鼠脾细胞中发现并鉴定了8种新的CD72选择性剪切形式,这些剪切形式中包含有2种独特的插入片段,一种选择性剪切保留了一个内含子(intron1),而这个内含子被翻译成氨基酸序列后并没有改变前后外显子的读码框,另一种使用了一个位于内含子之内的3′剪切位点,从而产生移码,提前终止了蛋白质的开放读码框,称为3′AS(3′alternative splicingsite).比较了CD72所有剪切形式在BALB/C小鼠和NZB/W小鼠中的差异表达,发现:a.含有3′AS的剪切形式的表达都很少;b.WT, In1, In1-Ex3和-Ex3的表达在BLAB/C小鼠中比在NZB/W小鼠中高;c.没有ITIM2的-Ex2-Ex3剪切形式在NZB/W小鼠中有特异性高表达.这些结果提示,CD72的多种选择性剪切形式在调控B细胞受体信号转导过程中可能发挥着不同的作用,并与系统性红斑狼疮的发病密切相关.     

ELAV, a Drosophila neuron-specific protein, mediates the generation of an alternatively spliced neural protein isoform

Background Tissue-specific alternative pre-mRNA splicing is a widely used mechanism for gene regulation and the generation of different protein isoforms, but relatively little is known about the factors and mechanisms that mediate this process. Tissue-specific RNA-binding proteins could mediate alternative pre-mRNA splicing. In Drosophila melanogaster, the RNA-binding protein encoded by the elav (embryonic lethal abnormal visual system) gene is a candidate for such a role. The ELAV protein is expressed exclusively in neurons, and is important for the formation and maintenance of the nervous system.Results In this study, photoreceptor neurons genetically depleted of ELAV, and elav-null central nervous system neurons, were analyzed immunocytochemically for the expression of neural proteins. In both situations, the lack of ELAV corresponded with a decrease in the immunohistochemical signal of the neural-specific isoform of Neuroglian, which is generated by alternative splicing. Furthermore, when ELAV was expressed ectopically in cells that normally express only the non-neural isoform of Neuroglian, we observed the generation of the neural isoform of Neuroglian.ConclusionsDrosophila ELAV promotes the generation of the neuron-specific isoform of Neuroglian by the regulation of pre-mRNA splicing. The findings reported in this paper demonstrate that ELAV is necessary, and the ectopic expression of ELAV in imaginal disc cells is sufficient, to mediate neuron-specific alternative splicing.     

Splicing factor and exon profiling across human tissues

It has been shown that alternative splicing is especially prevalent in brain and testis when compared to other tissues. To test whether there is a specific propensity of these tissues to generate splicing variants, we used a single source of high-density microarray data to perform both splicing factor and exon expression profiling across 11 normal human tissues. Paired comparisons between tissues and an original exon-based statistical group analysis demonstrated after extensive RT-PCR validation that the cerebellum, testis, and spleen had the largest proportion of differentially expressed alternative exons. Variations at the exon level correlated with a larger number of splicing factors being expressed at a high level in the cerebellum, testis and spleen than in other tissues. However, this splicing factor expression profile was similar to a more global gene expression pattern as a larger number of genes had a high expression level in the cerebellum, testis and spleen. In addition to providing a unique resource on expression profiling of alternative splicing variants and splicing factors across human tissues, this study demonstrates that the higher prevalence of alternative splicing in a subset of tissues originates from the larger number of genes, including splicing factors, being expressed than in other tissues.