Alternative splicing,gene duplication and connectivity in the genetic interaction network of the nematode worm <Emphasis Type="Italic">Caenorhabditis elegans</Emphasis>

We examined the relationship between gene duplication, alternative splicing, and connectedness in a predicted genetic interaction network using published data from the nematode worm Caenorhabditis elegans. Similar to previous results from mammals, genes belonging to families with only one member ("singletons") were significantly more likely to lack alternative splicing than were members of large multi-gene families. Genes belonging to multi-gene families lacking alternative splicing tended to have higher connectedness in the genetic interaction network than did genes in families that included one or more alternatively spliced members. Moreover, alternatively spliced genes were significantly more likely to interact with other alternatively spliced genes. These results support the hypothesis that certain key proteins with high degrees of network connectedness are subject to selection opposing the occurrence of alternatively spliced forms.     

Identification of Two APOBEC3F Splice Variants Displaying HIV-1 Antiviral Activity and Contrasting Sensitivity to Vif

Approximately half of all human genes undergo alternative mRNA splicing. This process often yields homologous gene products exhibiting diverse functions. Alternative splicing of APOBEC3G (A3G) and APOBEC3F (A3F), the major host resistance factors targeted by the HIV-1 protein Vif, has not been explored. We investigated the effects of alternative splicing on A3G/A3F gene expression and antiviral activity. Three alternatively spliced A3G mRNAs and two alternatively spliced A3F mRNAs were detected in peripheral blood mononuclear cells in each of 10 uninfected, healthy donors. Expression of these splice variants was altered in different cell subsets and in response to cellular stimulation. Alternatively spliced A3G variants were insensitive to degradation by Vif but displayed no antiviral activity against HIV-1. Conversely, alternative splicing of A3F produced a 37-kDa variant lacking exon 2 (A3FΔ2) that was prominently expressed in macrophages and monocytes and was resistant to Vif-mediated degradation. Alternative splicing also produced a 24-kDa variant of A3F lacking exons 2–4 (A3FΔ2–4) that was highly sensitive to Vif. Both A3FΔ2 and A3FΔ2–4 displayed reduced cytidine deaminase activity and moderate antiviral activity. These alternatively spliced A3F gene products, particularly A3FΔ2, were incorporated into HIV virions, albeit at levels less than wild-type A3F. Thus, alternative splicing of A3F mRNA generates truncated antiviral proteins that differ sharply in their sensitivity to Vif.     

Alternative Splicing and Subfunctionalization Generates Functional Diversity in Fungal Proteomes

Alternative splicing is commonly used by the Metazoa to generate more than one protein from a gene. However, such diversification of the proteome by alternative splicing is much rarer in fungi. We describe here an ancient fungal alternative splicing event in which these two proteins are generated from a single alternatively spliced ancestral SKI7/HBS1 gene retained in many species in both the Ascomycota and Basidiomycota. While the ability to express two proteins from a single SKI7/HBS1 gene is conserved in many fungi, the exact mechanism by which they achieve this varies. The alternative splicing was lost in Saccharomyces cerevisiae following the whole-genome duplication event as these two genes subfunctionalized into the present functionally distinct HBS1 and SKI7 genes. When expressed in yeast, the single gene from Lachancea kluyveri generates two functionally distinct proteins. Expression of one of these proteins complements hbs1, but not ski7 mutations, while the other protein complements ski7, but not hbs1. This is the first known case of subfunctionalization by loss of alternative splicing in yeast. By coincidence, the ancestral alternatively spliced gene was also duplicated in Schizosaccharomyces pombe with subsequent subfunctionalization and loss of splicing. Similar subfunctionalization by loss of alternative splicing in fungi also explains the presence of two PTC7 genes in the budding yeast Tetrapisispora blattae, suggesting that this is a common mechanism to preserve duplicate alternatively spliced genes.     

Novel alternative splicing of mRNAs encoding poly(A) polymerases in Arabidopsis

The Arabidopsis thaliana genome possesses four genes whose predicted products are similar to eukaryotic poly(A) polymerases from yeasts and animals. These genes are all expressed, as indicated by RT/PCR and Northern blot analysis. The four Arabidopsis PAPs share a conserved N-terminal catalytic core with other eukaryotic enzymes, but differ substantially in their C-termini. Moreover, one of the four Arabidopsis enzymes is significantly shorter than the other three, and is more divergent even within the conserved core of the protein. Nonetheless, the protein encoded by this gene, when produced in and purified from E. coli, possesses nonspecific poly(A) polymerase activity. Genes encoding these Arabidopsis PAPs give rise to a number of alternatively spliced mRNAs. While the specific nature of the alternative splicing varied amongst these three genes, mRNAs from the three "larger" genes could be alternatively spliced in the vicinity of the 5th and 6th introns of each gene. Interestingly, the patterns of alternative splicing vary in different tissues. The ubiquity of alternative splicing in this gene family, as well as the differences in specific mechanisms of alternative processing in the different genes, suggests an important function for alternatively spliced PAP mRNAs in Arabidopsis.     

Alternative 5'' splice site selection induced by heat shock.

The mouse HSP47 gene consists of six exons separated by five introns. Three HSP47 cDNAs differing only in their 5' noncoding regions have been reported. One of these alternatively spliced mRNAs was detected only after heat shock, which caused an alternative 5' splice donor site selection. Other stress inducers, including an amino acid analog and sodium arsenite, had no effect on the alternative splicing. The alternatively spliced mRNA, which was 169 nucleotides longer in the 5' noncoding region compared to mRNA transcribed in non-heat shock conditions, was efficiently translated under heat shock conditions. This novel finding that alternative splicing is caused by artificial treatment like heat shock will provide a useful in vivo model for understanding the exon-intron recognition mechanism as well as heat shock-induced alterations in gene expression.     

Evolution of alternative splicing: deletions,insertions and origin of functional parts of proteins from intron sequences

Alternative splicing is thought to be a major source of functional diversity in animal proteins. We analyzed the evolutionary conservation of proteins encoded by alternatively spliced genes and predicted the ancestral state for 73 cases of alternative splicing (25 insertions and 48 deletions). The amino acid sequences of most of the inserts in proteins produced by alternative splicing are as conserved as the surrounding sequences. Thus, alternative splicing often creates novel isoforms by the insertion of new, functional protein sequences that probably originated from noncoding sequences of introns.     

Alternative splice variants encoding unstable protein domains exist in the human brain

Alternative splicing has been recognized as a major mechanism by which protein diversity is increased without significantly increasing genome size in animals and has crucial medical implications, as many alternative splice variants are known to cause diseases. Despite the importance of knowing what structural changes alternative splicing introduces to the encoded proteins for the consideration of its significance, the problem has not been adequately explored. Therefore, we systematically examined the structures of the proteins encoded by the alternative splice variants in the HUGE protein database derived from long (>4 kb) human brain cDNAs. Limiting our analyses to reliable alternative splice junctions, we found alternative splice junctions to have a slight tendency to avoid the interior of SCOP domains and a strong statistically significant tendency to coincide with SCOP domain boundaries. These findings reflect the occurrence of some alternative splicing events that utilize protein structural units as a cassette. However, 50 cases were identified in which SCOP domains are disrupted in the middle by alternative splicing. In six of the cases, insertions are introduced at the molecular surface, presumably affecting protein functions, while in 11 of the cases alternatively spliced variants were found to encode pairs of stable and unstable proteins. The mRNAs encoding such unstable proteins are much less abundant than those encoding stable proteins and tend not to have corresponding mRNAs in non-primate species. We propose that most unstable proteins encoded by alternative splice variants lack normal functions and are an evolutionary dead-end.     

Expression of CETP and of splice variants induces the same level of ER stress despite secretion efficiency differences

The cholesteryl ester transfer protein (CETP) gene has been associated with a variety of phenotypes, including HDL-cholesterol levels and, more sporadically, with cardiovascular disease, obesity, and extreme longevity. Alterations of CETP activity levels can be caused by single-base polymorphisms as well as by alternative splicing. In addition to the previously characterized alternative splicing that skips exon 9, we found additional minor variants and characterized the activity of the resultant proteins. The novel variants skipped exon 9 sequences and inserted one of two in-frame exons from Alu-derived intronic sequences. None of the alternatively spliced variants are efficiently secreted, and coexpression of them inhibits wild-type CETP secretion. Expression of the alternative spliced variants causes an induction of genes linked to the endoplasmic reticulum (ER) stress response, including the neighboring HERPUD1 (homocysteine- and ER stress-inducible protein, ubiquitin-like domain-containing) gene. Unexpectedly, even though wild-type CETP is secreted much more efficiently than spliced variants, it induces the same degree of stress response as spliced variants, whereas a control secreted protein does not. CETP plays a complex role in modulating ER stress, with its expression inducing the response and its cholesteryl ester transfer activity and differential splicing modulating the response in other ways.     

Regulation of apoptosis by alternative pre-mRNA splicing

Apoptosis, a phenomenon that allows the regulated destruction and disposal of damaged or unwanted cells, is common to many cellular processes in multicellular organisms. In humans more than 200 proteins are involved in apoptosis, many of which are dysregulated or defective in human diseases including cancer. A large number of apoptotic factors are regulated via alternative splicing, a process that allows for the production of discrete protein isoforms with often distinct functions from a common mRNA precursor. The abundance of apoptosis genes that are alternatively spliced and the often antagonistic roles of the generated protein isoforms strongly imply that alternative splicing is a crucial mechanism for regulating life and death decisions. Importantly, modulation of isoform production of cell death proteins via pharmaceutical manipulation of alternative splicing may open up new therapeutic avenues for the treatment of disease.     

Splicing of internal large exons is defined by novel cis-acting sequence elements

Human internal exons have an average size of 147 nt, and most are <300 nt. This small size is thought to facilitate exon definition. A small number of large internal exons have been identified and shown to be alternatively spliced. We identified 1115 internal exons >1000 nt in the human genome; these were found in 5% of all protein-coding genes, and most were expressed and translated. Surprisingly, 40% of these were expressed at levels similar to the flanking exons, suggesting they were constitutively spliced. While all of the large exons had strong splice sites, the constitutively spliced large exons had a higher ratio of splicing enhancers/silencers and were more conserved across mammals than the alternatively spliced large exons. We asked if large exons contain specific sequences that promote splicing and identified 38 sequences enriched in the large exons relative to small exons. The consensus sequence is C-rich with a central invariant CA dinucleotide. Mutation of these sequences in a candidate large exon indicated that these are important for recognition of large exons by the splicing machinery. We propose that these sequences are large exon splicing enhancers (LESEs).     

Structural and functional diversity generated by alternative mRNA splicing

Alternative mRNA splicing is becoming increasingly recognized as an important mechanism for the generation of structural and functional diversity in proteins. Recent estimations predict that approximately 50% of all eukaryotic proteins can be alternatively spliced. Several lines of evidence suggest that alternative mRNA splicing results in small changes in protein structure and is likely to fine-tune the function and specificity of the affected protein. However, knowledge of how alternative splicing regulates cellular processes on the molecular level is still limited. It is only recently that structures of alternatively spliced proteins have been solved. These studies have shown that alternative splicing affects the structure not only in the vicinity of the splice site but also at long distance.     

No statistical support for correlation between the positions of protein interaction sites and alternatively spliced regions

Background  

Alternative splicing is an efficient mechanism for increasing the variety of functions fulfilled by proteins in a living cell. It has been previously demonstrated that alternatively spliced regions often comprise functionally important and conserved sequence motifs. The objective of this work was to test the hypothesis that alternative splicing is correlated with contact regions of protein-protein interactions.