Mechanism of dnaB protein action. V. Association of dnaB protein, protein n', and other repriming proteins in the primosome of DNA replication

DNA-protein interactions during replication of genetic elements of bacteria

Specific interactions of DNA with proteins are required for both the replication of deoxyribonucleic acid proper and its regulation. Genetic elements of bacteria, their extrachromosomal elements in particular, represent a suitable model system for studies of these processes at the molecular level. In addition to replication enzymes (DNA polymerases), a series of other protein factors (e.g. topoisomerases, DNA unwinding enzymes, and DNA binding proteins) are involved in the replication of the chromosomal, phage and plasmid DNA. Specific interactions of proteins with DNA are particularly important in the regulation of initiation of DNA synthesis. Association of DNAs with the cell membrane also plays an important role in their replication in bacteria.

Initiation of DNA synthesis on single-stranded DNA templates in vitro promoted by the bacteriophage lambda O and P replication proteins

The bacteriophage lambda O and P protein replication initiators, in conjunction with six purified Escherichia coli replication proteins, replicate the single-stranded chromosomes of phages M13 and phi X174 to a duplex form. Several discrete steps are involved in this DNA synthesis reaction. In an ATP-dependent step that precedes priming, the lambda O and P proteins interact with the Escherichia coli dnaJ and dnaK proteins to transfer the bacterial dnaB protein onto DNA coated with single-stranded DNA binding protein. This creates a stable prepriming intermediate, isolable by gel filtration, that is rapidly primed and replicated upon the addition of primase and DNA polymerase III holoenzyme. Each of the eight proteins required for this nonspecific single strand replication reaction also have physiological roles in the replication of the bacteriophage lambda chromosome in vivo. We propose a scheme for the lambda O and P protein-dependent initiation of DNA synthesis that may be relevant to strand initiation events occurring during lambda DNA replication.

Selective cloning of a DNA single-strand initiation determinant from phi X174 replicative-form DNA

An M13 phage deletion mutant, M13 delta E101, developed as a vector for selecting DNA sequences that direct DNA strand initiation on a single-stranded template, has been used for cloning restriction enzyme digests of phi X174 replicative-form DNA. Initiation determinants, detected on the basis of clear-plaque formation by the chimeric phage, were found only in restriction fragments containing the unique effector site in phi X174 DNA for the Escherichia coli protein n' dATPase (ATPase). Furthermore, these sequences were functional only when cloned in the orientation in which the phi X174 viral strand was joined to the M13 viral strand. A 181-nucleotide viral strand fragment containing this initiation determinant confers a phi X174-type complementary-strand replication mechanism on M13 chimeras. The chimeric phage is converted to the parental replicative form in vivo by a mechanism resistant to rifampin, a specific inhibitor of the normal RNA polymerase-dependent mechanism of M13. In vitro, the chimeric single-stranded DNA promotes the assembly of a functional multiprotein priming complex, or primosome, identical to that utilized by intact phi X174 viral strand DNA. Chimeric phage containing the sequence complementary to the 181-nucleotide viral strand sequence shows no initiation capability, either in vivo or in vitro.

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.

A cellular factor involved in the formation of a DNA-synthesizing complex from DNA polymerase I in Escherichia coli

A factor ('E') has been identified which stabilizes an endogenous DNA-synthesizing complex involving DNA polymerase I. The complex is separated from free DNA polymerase by polyacrylamide gel electrophoresis. The factor will reform the complex after it has been dissociated and will convert a preparation of DNA polymerase I to complex. The factor and the DNA-synthesizing complex both appear to be localized at the cell membrane.

Suppression of Escherichia coli dnaA46 mutations by integration of plasmid R100.1. derivatives: constraints imposed by the replication terminus

We have studies the phenotypic suppression of a dnaA46 mutation by plasmid integration at preselected chromosomal sites after introducing homologous sequences (Mu prophages) onto both the chromosomes and the suppressive plasmid. The plasmids used were all derived from plasmid R100.1. We found that the conditions required to get viable suppressive integration varied as the plasmid integration site moved from the origin to the terminus of chromosome replication. Two constraints were observed. Both appeared to be linked to the new characteristics acquired by chromosome replication from the integrated plasmid. One constraint was that strains with integrative suppression near the terminus terC were viable only in minimal medium. The rich medium sensitivity of these strains was correlated with a loss of regulation of initiation. The other constraint was a requirement for a specific orientation in certain regions of the chromosome. The two branches defined by normally initiated replication, between oriC and terC, were also symmetrical with respect to these plasmid orientation constraints. In studying the possible reasons for a plasmid orientation constraint, we found that, of the two forks initiated in bidirectional replication from the integrated plasmid, one was capable of moving across the terC region with a higher movability than the other.