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. 1988 May;7(5):1431–1437. doi: 10.1002/j.1460-2075.1988.tb02960.x

Trypanosome trans-splicing utilizes 2'-5' branches and a corresponding debranching activity.

R E Sutton 1, J C Boothroyd 1
PMCID: PMC458393  PMID: 3409870

Abstract

The 5' ends of trypanosome mRNAs consist of an identical sequence of 39 nucleotides which is derived from a discrete transcript of approximately 140 nucleotides (medRNA). It has been proposed that generation of chimeric mRNAs in trypanosomes occurs by the process of trans-splicing involving medRNA and an acceptor RNA. Part of the basis for this suggestion comes from the ability of HeLa cell extracts (known to contain debranching activity) to catalyze the release of the intron portion of medRNA (minRNA) implying a Y-branched intermediate in the splicing process. Here we provide direct chemical analysis that miniRNA is attached to higher mol. wt RNA molecules by a 2'-5' phosphodiester bond (i.e. as a branched structure). We also demonstrate that trypanosomes have substantial amounts of debranching activity which is similar in nature to that of HeLa cells. These results provide further evidence for trans-splicing in trypanosomes and highlights its similarity to cis-splicing in other eukaryotes.

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