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Article Abstract
Although seven proteins unique to U12 intron-specific minor spliceosomes, denoted as U11/U12-65K, -59K, -48K, -35K, -31K, -25K, and -20K, have been identified in humans and the roles of some of them have been demonstrated, the functional role of most of these proteins in plants is not understood. A recent study demonstrated that Arabidopsis U11/U12-65K is essential for U12 intron splicing and normal plant development. However, the structural features and sequence motifs important for 65 K binding to U12 snRNA and other spliceosomal proteins remain unclear. Here, we demonstrated by domain-deletion analysis that the C-terminal region of the 65 K protein bound specifically to the stem-loop III of U12 snRNA, whereas the N-terminal region of the 65 K protein was responsible for interacting with the 59 K protein. Analysis of the interactions between each snRNP protein using yeast two-hybrid analysis and in planta bimolecular fluorescence complementation and luciferase complementation imaging assays demonstrated that the core interactions among the 65 K, 59 K, and 48 K proteins were conserved between plants and animals, and multiple interactions were observed among the U11/U12-snRNP proteins. Taken together, these results reveal that U11/U12-65K is an indispensible component of the minor spliceosome complex by binding to both U11/U12-59K and U12 snRNA, and that multiple interactions among the U11/U12-snRNP proteins are necessary for minor spliceosome assembly.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC4962810 | PMC |
| http://dx.doi.org/10.1080/15476286.2016.1191736 | DOI Listing |
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