Mutadons in the
Escherichia coli
heat shock genes,
dnaK
,
dnaJ
or
grpE
, alter host DNA and RNA synthesis, degradation of other proteins, cell division and expression of other heat shock genes. They also block the initiation of DNA replication of bacteriophages λ and P1, and the mini-F plasmid. An
in vitro
λDNA replication system, composed entirely of purified components, enabled us to describe the molecular mechanism of the
dnaK
,
dnaJ
and
grpE
gene products. DnaK , the bacterial hsp 70 homologue, releases λP protein from the preprimosomal complex in an ATP- and DnaJ-dependent reaction (GrpEindependent initiation of λDNA replication). In this paper, I show that, when GrpE is present, λP protein is not released from the preprimosomal complex, rather it is translocated within the complex in such a way that it does not inhibit DnaB helicase activity. Translocation of λP triggers the initiation event allowing DnaB helicase to unwind DNA near the
ori
λ sequence, leading to efficient λDNA replication. Chaperone activity of the DnaK -DnaJ-GrpE system is first manifested in the selective binding of these heat shock proteins to the preprimosomal complex, followed by its ATP-dependent rearrangement. I show that DnaJ not only tags the preprimosomal complex for recognition by DnaK, but also stabilizes the multi-protein structure. GrpE also participates in the binding of DnaK to the preprimosomal complex by increasing DnaK ’s affinity to those λP proteins which are already associated with DnaJ. After attracting DnaK to the preprimosomal complex, DnaJ and GrpE stimulate the ATPase activity of DnaK , triggering conformational changes in DnaK which are responsible for the rearrangement of proteins in the preprimosomal complex and recycling of these heat shock proteins. The role of DnaK , DnaJ and GrpE in λDNA replication is in sharp contrast to our understanding of their role in the
oriC
, P1, and probably mini-F DNA replication systems. In the cases of
oriC
and P1 DNA replication, these heat shock proteins activate initiation factors before they are in contact with DNA, and are not required during the subsequent steps leading to the initiation of DNA replication. The common feature of DnaK , DnaJ and GrpE action in these systems is their ATP-dependent disaggregation or rearrangement of protein complexes formed before or during initiation of DNA replication.