Function of RNase H in DNA replication revealed by RNase H defective mutants of Escherichia coli

Initiation of DNA replication in Escherichia coli: RNase H-deficient mutants do not require the dnaA function

A series of temperature-resistant revertants were isolated from strains of Escherichia coli K12 carrying a temperature-sensitive mutation in the dnaA gene. Four independent revertants were found which still carry the original ts mutation. The ability of these strains to grow at high temperature is due to a suppressor mutation, called sin. All four sin mutations are located between the genes metD and proA on the genetic map of E. coli, which suggests that they all affect the same gene. The sin suppressors, which were isolated for their ability to suppress one dnaA mutation, are also able to suppress three other temperature-sensitive dnaA mutations, but they are not able to suppress mutations in either of the two genes dnaB or dnaC. The sin suppressors alone do not confer any particular phenotype on bacteria, but they are deficient in the enzyme RNase H. On the basis of these findings we propose that the function of the dnaA protein is to protect a DNA-RNA hybrid at the origin of replication against RNase H.

dnaA suppressor (dasF) mutants of Escherichia coli are stable DNA replication (sdrA/rnh) mutants

The possible allelic relationship between dasF (dnaA suppressor) and sdrA/rnh (stable DNA replication/RNase H) mutations was examined. dasF mutations could not only suppress various dnaA(ts) mutations, but also the insertional inactivation of the dnaA gene or deletion of the oriC sequence, as could sdrA mutations. dasF mutants were found to exhibit the stable DNA replication phenotype, and the sensitivity to rich media, of sdrA mutants. The dasF and sdrA mutations were mapped very closely between metD and proA on the E. coli genetic map. The mutations were recessive to the wild-type allele for all the above phenotypes. It was concluded that dasF is allelic to sdrA/mh.

Enzymology of DNA in replication in prokaryotes

This review stresses recent developments in the in vitro study of DNA replication in prokaryotes. New insights into the enzymological mechanisms of initiation and elongation of leading and lagging strand DNA synthesis in ongoing studies are emphasized. Data from newly developed systems, such as those replicating oriC containing DNA or which are dependent on the lambda, O, and P proteins, are presented and the information compared to existing mechanisms. Evidence bearing on the coupling of DNA synthesis on both parental strands through protein-protein interactions and on the turnover of the elongation systems are analyzed. The structure of replication origins, and how their tertiary structure affects recognition and interaction with the various replication proteins is discussed.