Cell-cycle-specific initiation of replication

The following characteristics are relevant when replication of chromosomes and plasmids is discussed in relation to the cell cycle: the timing or replication, the selection of molecules for replication, and the coordination of multiple initiation events within a single cell cycle. Several fundamentally different methods have been used to study these processes: Meselson—Stahl density-shift experiments, experiments with the so-called‘baby machine', sorting of cells according to size, and flow cytometry. The evidence for precise timing and co-ordination of chromosome replication in Escherichia coli is overwhelming. Similarly, the high-copy-number plasmid ColE1 and the low-copy-number plasmids R1/R100 without any doubt replicate randomly throughout the cell cycle. Data about the low-copy-number plasmids F and P1 are conflicting. This calls for new types of experiments and for a better understanding of how these plasmids control their replication and partitioning.     

Biochemical investigations of control of replication initiation of plasmid R6K

The mechanistic basis of control of replication initiation of plasmid R6K was investigated by addressing the following questions. What are the biochemical attributes of mutations in the pi initiator protein that caused loss of negative control of initiation? Did the primary control involve only initiator protein-ori DNA interaction or did it also involve protein-protein interactions between pi and several host-encoded proteins? Mutations at two different regions of the pi-encoding sequence individually caused some loss of negative control as indicated by a relatively modest increase in copy number. However, combinations of the mutation P42L, which caused loss of DNA looping, with those located in the region between the residues 106 and 113 induced a robust enhancement of copy number. These mutant forms promoted higher levels of replication in vitro in a reconstituted system consisting of 22 purified proteins. The mutant forms of pi were susceptible to pronounced iteron-induced monomerization in comparison with the WT protein. As contrasted with the changes in DNA-protein interaction, we found no detectable differences in protein-protein interaction between wild type pi with DnaA, DnaB helicase, and DnaG primase on one hand and between the high copy mutant forms and the same host proteins on the other. The DnaG-pi interaction reported here is novel. Taken together, the results suggest that both loss of negative control due to iteron-induced monomerization of the initiator and enhanced iteron-initiator interaction appear to be the principal causes of enhanced copy number.     

Positive correlation between size at initiation of chromosome replication in Escherichia coli and size at initiation of cell constriction.

The variability of (i) the length (size) at which cells initiate chromosome replication, (ii) the length at which they initiate cell constriction, and (iii) the time interval between these events has been estimated for Escherichia coli B/r K at two different slow growth rates. Steady-state cultures were pulse-labeled with [3H]thymidine and, after fixation, analyzed by electron microscopic radioautography. The coefficient of variation of length at initiation of chromosome replication was found to be 15 to 22%, the coefficient of variation of length at initiation of cell constriction was 10%, and the coefficient of variation of the time interval between both events was 25%. With the help of these values we calculated a high positive coefficient of correlation (rho) between the length at which a round of chromosome replication is initiated and that at which the onset of cell constriction occurs. At both growth rates rho has a value of 0.6 to 1.0. This correlation excludes a model in which chromosome initiation and cell constriction are independently triggered by some aspects of cell growth. It favors a model in which an event before or at chromosome initiation triggers both.     

Translational control by antisense RNA in control of plasmid replication

Control of replication of plasmids involves two processes: measurement of the copy number of the plasmid and adjustment of the replication frequency accordingly. For both these processes IncFII plasmids use an antisense RNA (CopA RNA) that forms a duplex with the upstream region (CopT) of the mRNA of the rate-limiting RepA protein. The kinetics of duplex formation was measured in vitro for the wild type and for a cop mutant plasmid; the mutant showed a reduction in the second-order rate constant for the formation of the RNA duplex and a similar increase in copy number. Hence, the kinetics of duplex formation and the concentration of CopA RNA determines the copy number of the plasmid.     

Coupling the initiation of chromosome replication to cell size in Escherichia coli

Bacterial cells change size dramatically with change in growth rate, but the ratio between cell volume and the number of copies of the origin of chromosome replication (oriC) is roughly constant at the time of initiation of DNA replication at almost all growth rates. Recent research on the inactivation of initiator protein (DnaA) and depletion of DnaA pools by the high-affinity DnaA-binding locus datA allows us to propose a simple model to explain the long-standing question of how Escherichia coli couples DNA replication to cell size.     

Broad-host-range properties of plasmid RK2: importance of overlapping genes encoding the plasmid replication initiation protein TrfA.

The trfA gene, encoding the essential replication initiation protein of the broad-host-range plasmid RK2, possesses an in-frame overlapping arrangement. This results in the production of TrfA proteins of 33 and 44 kDa, respectively. Utilizing deletion and site-specific mutagenesis to alter the trfA operon, we compared the replication of an RK2-origin plasmid in several distantly related gram-negative bacteria when supported by both TrfA-44 and TrfA-33, TrfA-33 alone, or TrfA-44/98L (a mutant form of the TrfA-44 protein) alone. TrfA-44/98L is identical to wild-type TrfA-44 with the exception of a single conservative amino acid alteration from methionine to leucine at codon 98; this alteration removes the translational start codon for the TrfA-33 protein. Copy number and stability were virtually identical for plasmids containing both TrfA-44 and TrfA-33 proteins or TrfA-44/98L alone in Pseudomonas aeruginosa and Agrobacterium tumefaciens, two unrelated bacteria in which TrfA-33 is poorly functional. This, along with recent in vitro studies comparing TrfA-44, TrfA-33, and TrfA-44/98L, suggests that the functional activity of TrfA-44 is not significantly affected by the 98L mutation. Analysis of minimal RK2 derivatives in certain gram-negative bacterial hosts suggests a role of the overlapping arrangement of trfA in facilitating the broad host range of RK2. RK2 derivatives encoding TrfA-44/98L alone demonstrated decreased copy number and stability in Escherichia coli and Azotobacter vinelandii when compared with derivatives specifying both TrfA-44 and TrfA-33. A strategy employing the trfA-44/98L mutant gene and in vivo homologous recombination was used to eliminate the internal translational start codon of trfA in the intact RK2 plasmid. The mutant intact RK2 plasmid produced only TrfA-44/98L. A small reduction in copy number and beta-lactamase expression resulted in E. coli, suggesting that overlapping trfA genes also enhance the efficiency of replication of the intact RK2 plasmid.     

DNA replication initiation: mechanisms and regulation in bacteria

In all organisms, multi-subunit replicases are responsible for the accurate duplication of genetic material during cellular division. Initiator proteins control the onset of DNA replication and direct the assembly of replisomal components through a series of precisely timed protein-DNA and protein-protein interactions. Recent structural studies of the bacterial protein DnaA have helped to clarify the molecular mechanisms underlying initiator function, and suggest that key structural features of cellular initiators are universally conserved. Moreover, it appears that bacteria use a diverse range of regulatory strategies dedicated to tightly controlling replication initiation; in many cases, these mechanisms are intricately connected to the activities of DnaA at the origin of replication. This Review presents an overview of both the mechanism and regulation of bacterial DNA replication initiation, with emphasis on the features that are similar in eukaryotic and archaeal systems.     

Two functions of the E protein are key elements in the plasmid F replication control system.

By using a plasmid carrying a translational fusion between the E gene of the IncFI plasmid F and the lacZ gene, we located the operator of the autogenously regulated E gene to an inverted repeat overlapping the E-gene promoter and showing perfect homology to part of the sequence found in all the direct repeats of two regions exerting an inhibitory effect on F replication, incB and incC. Excess E protein provided in trans to an F plasmid increased the replication frequency of the F plasmid. This stimulatory effect was counteracted by increased dosages of incB or incC. A model is proposed for the replication control system of F in which the key elements are autoregulation of E-gene expression and titration of E protein by incB and incC.     

Identification of putative DnaN-binding motifs in plasmid replication initiation proteins

Recently the plasmid RK2 replication initiation protein, TrfA, has been shown to bind to the beta subunit of DNA Polymerase III (DnaN) via a short pentapeptide with the consensus QL[S/D]LF. A second consensus peptide, the hexapeptide QLxLxL, has also been demonstrated to mediate binding to DnaN. Here we describe the results of a comprehensive survey of replication initiation proteins encoded by bacterial plasmids to identify putative DnaN-binding sites. Both pentapeptide and hexapeptide motifs have been identified in a number of families of replication initiation proteins. The distribution of sites is sporadic and closely related families of proteins may differ in the presence, location, or type of putative DnaN-binding motif. Neither motif has been identified in replication initiation proteins encoded by plasmids that replicate via rolling circles or strand displacement. The results suggest that the recruitment of DnaN to the origin of replication of a replisome by plasmid replication initiation proteins is not generally required for plasmid replication, but that in some cases it may be beneficial for efficiency of replication initiation.     

Evidence for positive regulation of plasmid prophage P1 replication: integrative suppression by copy mutants.

Like low-copy-number plasmids including P1 wild type, multicopy P1 mutants (P1 cop, maintained at five to eight copies per chromosome) can suppress the thermosensitive phenotype of an Escherichia coli dnaA host by forming a cointegrate. At 40 degrees C in a dnaA host suppressed by P1 cop, the only copy of P1 is the one in the host chromosome. Trivial explanations of the lack of extrachromosomal copies of P1 cop have been eliminated: (i) during integrative suppression, the P1 cop plasmid does not revert to cop+; (ii) the dnaA+ function of the host is not required to maintain P1 cop at a high copy number; and (iii) integrative recombination does not occur within the region of the plasmid involved in regulation of copy number. Since there are no more copies of the chromosomal origin (now located within the integrated P1 plasmid) than in a P1 cop+-suppressed strain, the extra initiation potential of the P1 cop is not used to provide multiple initiations of the chromosome. When a P1 cop-suppressed dnaA strain was grown at 30 degrees C so that replication could initiate from the chromosomal origin as well as from the P1 origin, multicopy supercoiled P1 DNA was found in the cells. This plasmid DNA was lost again when the temperature was shifted back to 40 degrees C.     

Biochemical regulation of the initiation of DNA replication

Abstract

The initiation of DNA replication is a key step in the cell division cycle and in DNA endoreduplication. Initiation of replication takes place at specific places in chromosomes known as replication origins. These are subject to temporal regulation within the cell cycle and may also be regulated as a function of plant development. In yeast, replication origins are recognised and bound by three different groups of proteins at different stages of the cell cycle. Of these, the MCM proteins are the most likely to be involved in activating the origins in order to facilitate initiation. MCM-like proteins also occur in plants, but have not been characterised in detail. Other proteins which bind to origins have been identified, as has a protein with a strong affinity for ds-ss junctions in DNA molecules.     

Discriminatory function of ribonuclease H in the selective initiation of plasmid DNA replication.

The initiation stage of ColE1-type plasmid replication was reconstituted with purified protein fractions from Escherichia coli. The reconstituted system included DNA polymerase I, DNA ligase, RNA polymerase, DNA gyrase, and a discriminating activity copurifying with RNAase H (but free of RNAase III). Initiation of DNA synthesis in the absence of RNAase H did not occur at the normal replication origin and was non-selective with respect to the plasmid template. In the presence of RNAase H the system was selective for ColE1-type plasmids and could not accept the DNA of non-amplifiable plasmids. Electron microscopic analysis of the reaction product formed under discriminatory conditions indicated that origin usage and directionally of ColE1, RSF1030, and CloDF13 replication were consistent with the normal replication pattern of these plasmids. It is proposed that the initiation of ColE1-type replication depends on the formation of an extensive secondary structure in the origin primer RNA that prevents its degradation by RNAase H.     

Robust control of initiation of prokaryotic chromosome replication: essential considerations for a minimal cell

A genomically and chemically detailed mathematical model of a "minimal cell" would be useful to understand better the "design logic" of cellular regulation. A "minimal cell" will be a prokaryote with the minimum number of genes necessary for growth and replication in an ideal environment (i.e., preformed precursors, constant temperature, etc.). The Cornell single-cell model of Escherichia coli serves as the basic framework upon which a minimal cell model can be constructed. A critical issue for any cell model is to describe a mechanism for control of initiation of chromosome replication. There is strong evidence that the essence of chromosome replication control is highly conserved in eubacteria and even extends to the archae. A generalized mechanism is possible based on binding of the protein DnaA-ATP to the origin of replication (oriC) as a primary control. Other features, such as regulatory inactivation of DnaA (RIDA) by conversion of DnaA-ATP to DnaA-ADP and titration of DnaA by binding to other DnaA boxes on the chromosome, have emerged as critical elements in obtaining a functional system to control initiation of chromosome synthesis. We describe a biologically realistic model of chromosome replication initiation control embedded in a complete whole-cell model that explicitly links the external environment to the mechanism of replication control. The base model is deterministic and then modified to include stochastic variation in the components for replication control. The stochastic model allows evaluation of the model's robustness, employing a low standard deviation of interinitiation time as a measure of robustness. Four factors were examined: DnaA synthesis rate; DnaA-ATP binding sites at oriC; the binding rate of DnaA-ATP to the nonfunctional DnaA boxes; and the effect of changing the number of nonfunctional binding sites. The observed DnaA synthesis rate (2000 molecules/cell) and the number of DnaA binding sites per origin (30) are close to the values predicted by the model to provide good control (low variance of interinitiation time), with a reasonable expenditure of cell resources. At relatively high binding rates for DnaA-ATP to the DnaA boxes (10(16) M(-1) s(-1)), increasing the number of DnaA binding sites to about 300, improved control (but little further improvement was seen by extension to 1000 boxes); however, at a low binding rate (10(10) M(-1) s(-1)), an increase in DnaA boxes had an adverse effect on control. The combination of all four factors is probably necessary to obtain a robust control system. Although this mechanism of replication initiation control is highly conserved, it is not clear if simpler control in a minimal cell might exist based on experimental observations with Mycoplasma. This issue is discussed in this investigation.     

P1 plasmid replication: initiator sequestration is inadequate to explain control by initiator-binding sites.

The unit-copy plasmid replicon mini-P1 consists of an origin, a gene for an initiator protein, RepA, and a control locus, incA. Both the origin and the incA locus contain repeat sequences that bind RepA. It has been proposed that the incA repeats control replication by sequestering the rate-limiting RepA initiator protein. Here we show that when the concentration of RepA was increased about fourfold beyond its normal physiological level from an inducible source in trans, the copy number of a plasmid carrying the P1 origin increased about eightfold. However, when the origin and a single copy of incA were present in the same plasmid, the copy number did not even double. The failure of an increased supply of RepA to overcome the inhibitory activity of incA is inconsistent with the hypothesis that incA inhibits replications solely by sequestering RepA. We propose that incA, in addition to sequestration, can also restrain replication by causing steric hindrance to the origin function. Our proposal is based on the observation that incA can bind to a RepA-origin complex in vitro.