Libraries enriched for alternatively spliced exons reveal splicing patterns in melanocytes and melanomas

It is becoming increasingly clear that alternative splicing enables the complex development and homeostasis of higher organisms. To gain a better understanding of how splicing contributes to regulatory pathways, we have developed an alternative splicing library approach for the identification of alternatively spliced exons and their flanking regions by alternative splicing sequence enriched tags sequencing. Here, we have applied our approach to mouse melan-c melanocyte and B16-F10Y melanoma cell lines, in which 5,401 genes were found to be alternatively spliced. These genes include those encoding important regulatory factors such as cyclin D2, Ilk, MAPK12, MAPK14, RAB4, melastatin 1 and previously unidentified splicing events for 436 genes. Real-time PCR further identified cell line-specific exons for Tmc6, Abi1, Sorbs1, Ndel1 and Snx16. Thus, the ASL approach proved effective in identifying splicing events, which suggest that alternative splicing is important in melanoma development.     

Characteristics and regulatory elements defining constitutive splicing and different modes of alternative splicing in human and mouse

Alternative splicing is a major contributor to genomic complexity, disease, and development. Previous studies have captured some of the characteristics that distinguish alternative splicing from constitutive splicing. However, most published work only focuses on skipped exons and/or a single species. Here we take advantage of the highly curated data in the MAASE database (see related paper in this issue) to analyze features that characterize different modes of splicing. Our analysis confirms previous observations about alternative splicing, including weaker splicing signals at alternative splice sites, higher sequence conservation surrounding orthologous alternative exons, shorter exon length, and more frequent reading frame maintenance in skipped exons. In addition, our study reveals potentially novel regulatory principles underlying distinct modes of alternative splicing and a role of a specific class of repeat elements (transposons) in the origin/evolution of alternative exons. These features suggest diverse regulatory mechanisms and evolutionary paths for different modes of alternative splicing.     

The multifunctional peptidylglycine alpha-amidating monooxygenase gene: exon/intron organization of catalytic, processing, and routing domains.

Peptidylglycine alpha-amidating monooxygenase (PAM; EC 1.14.17.3) is a multifunctional protein containing two enzymes that act sequentially to catalyze the alpha-amidation of neuroendocrine peptides. Peptidylglycine alpha-hydroxylating monooxygenase (PHM) catalyzes the first step of the reaction and is dependent on copper, ascorbate, and molecular oxygen. Peptidyl-alpha-hydroxyglycine alpha-amidating lyase (PAL) catalyzes the second step of the reaction. Previous studies demonstrated that alternative splicing results in the production of bifunctional PAM proteins that are integral membrane or soluble proteins as well as soluble monofunctional PHM proteins. Rat PAM is encoded by a complex single copy gene that consists of 27 exons and encompasses more than 160 kilobases (kb) of genomic DNA. The 12 exons comprising PHM are distributed over at least 76 kb genomic DNA and range in size from 49-185 base pairs; four of the introns within the PHM domain are over 10 kb in length. Alternative splicing in the PHM region can result in a truncated, inactive PHM protein (rPAM-5), or a soluble, monofunctional PHM protein (rPAM-4) instead of a bifunctional protein. The eight exons comprising PAL are distributed over at least 19 kb genomic DNA. The exons encoding PAL range in size from 54-209 base pairs and have not been found to undergo alternative splicing. The PHM and PAL domains are separated by a single alternatively spliced exon surrounded by lengthy introns; inclusion of this exon results in the production of a form of PAM (rPAM-1) in which endoproteolytic cleavage at a paired basic site can separate the two catalytic domains. The exon following the PAL domain encodes the trans-membrane domain of PAM; alternative splicing at this site produces integral membrane or soluble PAM proteins. The COOH-terminal domain of PAM is comprised of a short exon subject to alternative splicing and a long exon encoding the final 68 amino acids present in all bifunctional PAM proteins along with the entire 3'-untranslated region. Analysis of hybrid cell panels indicates that the human PAM gene is situated on the long arm of chromosome 5.     

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.     

Evidence for the regulation of alternative splicing via complementary DNA sequence repeats

MOTIVATION: While the mechanism for regulating alternative splicing is poorly understood, secondary structure has been shown to be integral to this process. Due to their propensity for forming complementary hairpin loops and their elevated mutation rates, tandem repeated sequences have the potential to influence splicing regulation. RESULTS: An analysis of human intronic sequences reveals a strong correlation between alternative splicing and the prevalence of mono- through hexanucleotide tandem repeats that may engage in complementary pairing in introns that flank alternatively spliced exons. While only 44% of the 18 173 genes in the Human Alternative Splicing Database are known to be alternatively spliced, they contain 84% of the 694 237 intronic complementary repeat pairs. Significantly, the normalized frequency and distribution of repeat sequences, independent of their potential for pairing, are indistinguishable between alternatively spliced and non-alternatively spliced genes. Thus, the increased prevalence of repeats with pairing potential in alternatively spliced genes is not merely a consequence of more repeats or repeat composition bias. These results suggest that complementary repeats may play a role in the regulation of alternative splicing. CONTACT: harold.garner@utsouthwestern.edu.