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The polypyrimidine tract of βIVS‐II induces efficient 3′‐end formation

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Presentation on theme: "The polypyrimidine tract of βIVS‐II induces efficient 3′‐end formation"— Presentation transcript:

1 The polypyrimidine tract of βIVS‐II induces efficient 3′‐end formation.
The polypyrimidine tract of βIVS‐II induces efficient 3′‐end formation. Nuclear RNAs (5 μg) from MEL cells transfected with human β‐globin genes harbouring mutations of βIVS‐II were analysed for transgene expression by an S1‐nuclease protection assay after 4 days of induced erythroid differentiation. (A) The probe used for S1‐nuclease protection assay detects transcripts that have not undergone correct 3′ cleavage as a 257‐nucleotide product (U) and correctly cleaved RNA as 212‐nucleotide fragments (C). Simultaneous probing for mouse β‐major globin (5′ β Maj) mRNA acted as an internal reference control. (B) Lanes 1–3, SM‐PYR, single (C→A) mutation at −3 from the 3′ splice acceptor site; lanes 4–6, DM‐PYR, double PYR‐tract mutation at −7 C→G and −8 U→G; lanes 7–9, TM‐PYR, triple mutant combining all three of the point mutations of SM‐PYR and DM‐PYR. Lanes 10–11, WT, wild‐type β‐globin gene; lane C, total RNA from untransfected MEL cells. C/U represents the 3′ cleaved‐to‐uncleaved ratio. (C) S1‐nuclease protection analysis with human β‐globin genes in which the βIVS‐II intron was replaced by a 21‐nucleotide‐long sequence corresponding to the PYR tract of this intron either with a wild‐type (PYR‐AG) or a mutant (PYR) 3′ AG splice acceptor site. Stefania Millevoi et al. EMBO Rep. 2002;3: © as stated in the article, figure or figure legend

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