Isolation, purification, and in vitro characterization of recessive-lethal-mutant RNA polymerases from Escherichia coli

Abstract

The beta subunit of prokaryotic RNA polymerase shares significant sequence similarity with its eukaryotic and archaeal counterparts across most of the protein. Nine segments of particularly high similarity have been identified and are termed segments A through I. We have isolated severely defective Escherichia coli RNA polymerase mutants, most of which are unable to support bacterial growth. The majority of the substitutions affect residues in one of the conserved segments of beta, including invariant residues in segments D (amino acids 548 to 577), E (amino acids 660 to 678), and I (amino acids 1198 to 1296). In addition, recessive-lethal mutations that affect residues highly conserved only among prokaryotes were identified. They include a substitution in the extreme amino terminus of beta, a region in which no substitutions have previously been identified, and one rpoB mutation that truncates the polypeptide without abolishing minimal polymerase function in vitro. To examine the recessive-lethal alleles in vitro, we devised a novel method to remove nonmutant enzyme from RNA polymerase preparations by affinity tagging the chromosomal rpoB gene. In vitro examination of a subset of purified recessive-lethal RNA polymerases revealed that several substitutions, including all of those altering conserved residues in segment I, severely decrease transcript elongation and increase termination. We discuss the insights these mutants lend to a structure-function analysis of RNA polymerase.