%0 Journal Article
%T Systematic analysis of alternative first exons in plant genomes
%A Wei-Hua Chen
%A Guanting Lv
%A Congying Lv
%A Changqing Zeng
%A Songnian Hu
%J BMC Plant Biology
%D 2007
%I BioMed Central
%R 10.1186/1471-2229-7-55
%X We systematically identified 1,378 and 645 AFE-containing clusters in rice and Arabidopsis, respectively. From our data sets, we identified two types of AFEs according to their genomic organisation. In genes with type I AFEs, the first exons are mutually exclusive, while most of the downstream exons are shared among alternative transcripts. Conversely, in genes with type II AFEs, the first exon of one gene structure is an internal exon of an alternative gene structure. The functionality analysis indicated about half and ~19% of the AFEs in Arabidopsis and rice could alter N-terminal protein sequences, and ~5% of the functional alteration in type II AFEs involved protein domain addition/deletion in both genomes. Expression analysis indicated that 20~66% of rice AFE clusters were tissue- and/or development- specifically transcribed, which is consistent with previous observations; however, a much smaller percentage of Arabidopsis AFEs was regulated in this manner, which suggests different regulation mechanisms of AFEs between rice and Arabidopsis. Statistical analysis of some features of AFE clusters, such as splice-site strength and secondary structure formation further revealed differences between these two species. Orthologous search of AFE-containing gene pairs detected only 19 gene pairs conserved between rice and Arabidopsis, accounting only for a few percent of AFE-containing clusters.Our analysis of AFE-containing genes in rice and Arabidopsis indicates that AFEs have multiple functions, from regulating gene expression to generating protein diversity. Comparisons of AFE clusters revealed different features in the two plant species, which indicates that AFEs may have evolved independently after the separation of rice (a model monocot) and Arabidopsis (a model dicot).Alternative splicing (AS) is an important mechanism, which contributes greatly to protein diversity by selectively using different sets of exons of one gene in different tissues or cells under certai
%U http://www.biomedcentral.com/1471-2229/7/55