3' RNA processing efficiency plays a primary role in generating termination-competent RNA polymerase II elongation complexes.

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Mol Cell Biol. 1993 June; 13(6): 3472-3480

3' RNA processing efficiency plays a primary role in generating termination-competent RNA polymerase II elongation complexes.

G Edwalds-Gilbert, J Prescott and E Falck-Pedersen

Department of Microbiology, W. R. Hearst Research Foundation, Cornell University Medical College, New York, New York 10021.

ABSTRACT

In several mammalian transcription units, a transcription terminationmechanism in which efficient termination is dependent on thepresence of an intact 3' RNA processing site has been identified.The mouse beta maj-globin transcription unit is one such example,in which an intact poly(A) site is required for efficient transcriptiontermination. It is now evident that 3' mRNA processing sitesare not always processed with the same efficiency. In this study,we characterized several pre-mRNAs as substrates for the 3'mRNA processing reaction of cleavage and polyadenylation. Wethen determined whether poly(A) sites which vary in processingefficiency support a poly(A) site-dependent termination event.The level of processing efficiency was determined in vitro byassays measuring the efficiency of the pre-mRNA cleavage eventand in vivo by the level of poly(A) site-dependent mRNA andgene product expression generated in transient transfectionassays. The beta maj globin pre-mRNA is very efficiently processed.This efficient processing correlates with its function in terminationassays using recombinant adenovirus termination vectors in nuclearrun-on assays. When the beta maj globin poly(A) site was replacedby the L1 poly(A) site of the adenovirus major late transcriptionunit (Ad-ml), which is a poor processing substrate, terminationefficiency decreased dramatically. When the beta maj globinpoly(A) site was replaced by the Ad-ml L3 poly(A) site, whichis 10- to 20-fold more efficiently processed than the Ad-mlL1 poly(A) site, termination efficiency remained high. Terminationis therefore dependent on the yield of the processing event.We then tested chimeric poly(A) sites containing the L3 coreAAUAAA but varied downstream GU-rich elements. The change indownstream GU-rich elements affected processing efficiency ina manner which correlated with termination efficiency. Theseexperiments provide evidence that the efficiency of 3' processingcomplex formation is directly correlated to the efficiency ofRNA polymerase II termination at the 3' end of a mammalian transcriptionunit.

Mol Cell Biol. 1993 June; 13(6): 3472-3480

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