Small molecule activators of pre-mRNA 3′ cleavage

3′ Cleavage and polyadenylation are obligatory steps in the biogenesis of most mammalian pre-mRNAs. In vitro reconstitution of the 3′ cleavage reaction from human cleavage factors requires high concentrations of creatine phosphate (CP), though how CP activates cleavage is not known. Previously, we proposed that CP might work by competitively inhibiting a cleavage-suppressing serine/threonine (S/T) phosphatase. Here we show that fluoride/EDTA, a general S/T phosphatase inhibitor, activates in vitro cleavage in place of CP. Subsequent testing of inhibitors specific for different S/T phosphatases showed that inhibitors of the PPM family of S/T phosphatases, which includes PP2C, but not the PPP family, which includes PP1, PP2A, and PP2B, activated 3′ cleavage in vitro. In particular, NCI 83633, an inhibitor of PP2C, activated extensive 3′ cleavage at a concentration 50-fold below that required by fluoride or CP. The testing of structural analogs led to the identification of a more potent compound that activated 3′ cleavage at 200 μM. While testing CP analogs to understand the origin of its cleavage activation effect, we found phosphocholine to be a more effective activator than CP. The minimal structural determinants of 3′ cleavage activation by phosphocholine were identified. Our results describe a much improved small molecule activator of in vitro pre-mRNA cleavage, identify the molecular determinants of cleavage activation by phosphoamines such as phosphocholine, and suggest that a PPM family phosphatase is involved in the negative regulation of mammalian pre-mRNA 3′ cleavage.     

A novel plant in vitro assay system for pre-mRNA cleavage during 3'-end formation

Messenger RNA (mRNA) maturation in eukaryotic cells requires the formation of the 3' end, which includes two tightly coupled steps: the committing cleavage reaction that requires both correct cis-element signals and cleavage complex formation, and the polyadenylation step that adds a polyadenosine [poly(A)] tract to the newly generated 3' end. An in vitro biochemical assay plays a critical role in studying this process. The lack of such an assay system in plants hampered the study of plant mRNA 3'-end formation for the last two decades. To address this, we have now established and characterized a plant in vitro cleavage assay system, in which nuclear protein extracts from Arabidopsis (Arabidopsis thaliana) suspension cell cultures can accurately cleave different pre-mRNAs at expected in vivo authenticated poly(A) sites. The specific activity is dependent on appropriate cis-elements on the substrate RNA. When complemented by yeast (Saccharomyces cerevisiae) poly(A) polymerase, about 150-nucleotide poly(A) tracts were added specifically to the newly cleaved 3' ends in a cooperative manner. The reconstituted polyadenylation reaction is indicative that authentic cleavage products were generated. Our results not only provide a novel plant pre-mRNA cleavage assay system, but also suggest a cross-kingdom functional complementation of yeast poly(A) polymerase in a plant system.     

Co-transcriptional splicing regulates 3′ end cleavage during mammalian erythropoiesis

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