A+U Content Rather Than a Particular Nucleotide Order Determines the Specificity of RNase E Cleavage

Overview

Journal J Biol Chem

Specialty Biochemistry

Date 1994 Apr 8

PMID 7511606

Citations 112

Authors

K J McDowall

S Lin-Chao

S N Cohen

Affiliations

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Abstract

Ribonuclease E has a central role in Escherichia coli mRNA decay and is dependent on a functional product of the rne (also called ams or hmp1) gene. We investigated the requirements for RNase E cleavage by introducing random mutations into the decanucleotide region at the 5' end of pACYC184 RNA I and studying the effects of these mutations on the position of rne-dependent cleavage in vivo and RNase E-mediated cutting in vitro. We find that the precise point of RNase E cleavage can be altered specifically and reproducibly by sequence changes in the region cleaved and, therefore, is not determined by a distance measured in nucleotides from any other sequence or region of secondary structure in RNA I. Although cleavage by RNase E occurs within sequences rich in A and/or U nucleotides and is affected by the extent of continuity of A and U nucleotides in the regions cleaved, there is no simple relationship between the order of nucleotides and the phosphodiester bond cleaved. Thus, our results are not consistent with either the notion that RNase E cleavages are determined by a simple consensus sequence or the contrary view that RNase E has few primary structural constraints other than a preference for cleaving 5' to an AU dinucleotide.

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