DNA replication termination in Escherichia coli parB (a dnaG allele), parA, and gyrB mutants affected in DNA distribution

Abstract

We investigated the Escherichia coli mutants carrying the parB, parA, and gyrB mutations, all of which display faulty chromosome partitioning at the nonpermissive temperature, to see whether their phenotype reflected a defect in the termination of DNA replication. In the parB strain DNA synthesis slowed down at 42 degrees C and the SOS response was induced, whereas in the parA strain DNA synthesis continued normally for 120 min and there was no SOS induction. To see whether replication forks accumulated in the vicinity of terC at the nonpermissive temperature, the mutants were incubated for 60 min at 42 degrees C and then returned to low temperature and pulse-labeled with [3H]thymidine. In all cases the restriction pattern of the labeled DNA was incompatible with that of the terC region, suggesting that replication termination was normal. In the parA mutant no DNA sequences were preferentially labeled, whereas in the parB and gyrB strains there was specific labeling of sequences whose restriction pattern resembled that of oriC. In the case of parB this was confirmed by DNA-DNA hybridization with appropriate probes. This test further revealed that the parB mutant over initiates at oriC after the return to the permissive temperature. Like dna(Ts) strains, the parB mutant formed filaments at 42 degrees C in the absence of SOS-associated division inhibition, accompanied by the appearance of anucleate cells of nearly normal size (28% of the population after 3 h), as revealed by autoradiography. The DNA in the filaments was either centrally located or distributed throughout. The parB mutation lies at 67 min, and the ParB- phenotype is corrected by a cloned dnaG gene or by a plasmid primase, strongly suggesting that parB is an allele of dnaG, the structural gene of the E. coli primase. It is thus likely that the parB mutant possesses an altered primase which does not affect replication termination but causes a partial defect in replication initiation and elongation and in chromosome distribution.