Protein inheritance: lambda plasmid replication perpetuated by the heritable replication complex

BACKGROUND: Replication of a plasmid derived from the Escherichia coli phage lambda initiates by binding of the lambda O protein initiator to the origin of lambda DNA replication, ori lambda. The lambda P protein participates in subsequent steps of assembly of the lambda replication complex. A function of lambda P required for replication complex assembly is inactivated at 43 degrees C by the ts1 mutation. RESULTS: We found that the lambda replication complex assembled at 30 degrees C survives the temperature upshift in lambda crotsPts1 plasmid-harbouring bacteria. We present several lines of evidence that in this system (in which the replication complex assembly does not occur), the replication complex assembled prior to the temperature upshift is inherited by one of two daughter plasmid copies at each replication round for more than 30 cell generations. The 'old' replication complex-driven replication is chloramphenicol-resistant and rifampicin-sensitive. This replication is dependent on lambda O and host dnaK, dnaJ and grpE chaperone gene functions. CONCLUSIONS: The lambda O-containing replication complex is inherited together with DNA and bears information how to initiate the next round of replication at ori lambda; thus, we consider that this phenomenon deserves to be called protein inheritance.     

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It was previously demonstrated that while lysogenic development of bacteriophage lambda in Escherichia coli proceeds normally at low temperature (20-25 degrees C), lytic development is blocked under these conditions owing to the increased stability of the phage CII protein. This effect was proposed to be responsible for the increased stimulation of the pE promoter, which interferes with expression of the replication genes, leading to inhibition of phage DNA synthesis. Here we demonstrate that the burst size of phage lambda cIb2, which is incapable of lysogenic development, increases gradually over the temperature range from 20 to 37 degrees C, while no phage progeny are observed at 20 degrees C. Contrary to previous reports, it is possible to demonstrate that pE promoter activation by CII may be more efficient at lower temperature. Using density-shift experiments, we found that phage DNA replication is completely blocked at 20 degrees C. Phage growth was also inhibited in cells overexpressing cII, which confirms that CII is responsible for inhibition of phage DNA replication. Unexpectedly, we found that replication of plasmids derived from bacteriophage lambda is neither inhibited at 20 degrees C nor in cells overexpressing cII. We propose a model to explanation the differences in replication observed between lambda phage and lambda plasmid DNA at low temperature.     

Stationary phase induction of dnaN and recF, two genes of Escherichia coli involved in DNA replication and repair

The beta subunit of DNA polymerase III holoenzyme, the Escherichia coli chromosomal replicase, is a sliding DNA clamp responsible for tethering the polymerase to DNA and endowing it with high processivity. The gene encoding beta, dnaN, maps between dnaA and recF, which are involved in initiation of DNA replication at oriC and resumption of DNA replication at disrupted replication forks, respectively. In exponentially growing cells, dnaN and recF are expressed predominantly from the dnaA promoters. However, we have found that stationary phase induction of the dnaN promoters drastically changes the expression pattern of the dnaA operon genes. As a striking consequence, synthesis of the beta subunit and RecF protein increases when cell metabolism is slowing down. Such an induction is dependent on the stationary phase sigma factor, RpoS, although the accumulation of this factor alone is not sufficient to activate the dnaN promoters. These promoters are located in DNA regions without static bending, and the -35 hexamer element is essential for their RpoS-dependent induction. Our results suggest that stationary phase-dependent mechanisms have evolved in order to coordinate expression of dnaN and recF independently of the dnaA regulatory region. These mechanisms might be part of a developmental programme aimed at maintaining DNA integrity under stress conditions.     

Molecular mechanism of heat shock-provoked disassembly of the coliphage lambda replication complex

We have found previously that, in contrast to the free O initiator protein of lambda phage or plasmid rapidly degraded by the Escherichia coli ClpP/ClpX protease, the lambdaO present in the replication complex (RC) is protected from proteolysis. However, in cells growing in a complete medium, a temperature shift from 30 to 43 degrees C resulted in the decay of the lambdaO fraction, which indicated disassembly of RC. This process occurred due to heat shock induction of the groE operon, coding for molecular chaperones of the Hsp60 system. Here we demonstrate that an increase in the cellular concentration of GroEL and GroES proteins is not in itself sufficient to cause RC disassembly. Another requirement is a DNA gyrase-mediated negative resupercoiling of lambda plasmid DNA, which counteracts DNA relaxation and starts to dominate 10 min after the temperature upshift. We presume that RC dissociates from lambda DNA during the negative resupercoiling, becoming susceptible to the subsequent action of GroELS and ClpP/ClpX proteins. In contrast to lambda cro+, in lambda cro- plasmid-harboring cells, the RC reveals heat shock resistance. After temperature upshift of the lambda crots plasmid-harboring cells, a Cro repressor-independent control of lambda DNA replication and heat shock resistance of RC are established before the period of DNA gyrase-mediated negative supercoiling. We suggest that the tight binding of RC to lambda DNA is due to interaction of RC with other DNA-bound proteins, and is related to the molecular basis of the lambda cro- plasmid replication control.     

E. coli SeqA protein binds oriC in two different methyl-modulated reactions appropriate to its roles in DNA replication initiation and origin sequestration

The seqA gene negatively modulates replication initiation at the E. coli origin, oriC. seqA is also essential for sequestration, which acts at oriC and the dnaA promoter to ensure that replication initiation occurs exactly once per chromosome per cell cycle. Initiation is promoted by full methylation of GATC sites clustered in oriC; sequestration is specific to the hemimethylated forms generated by replication. SeqA protein purification and DNA binding are described. SeqA interacts with fully methylated oriC strongly and specifically. This reaction requires multiple molecules of SeqA and determinants throughout oriC, including segments involved in open complex formation. SeqA interacts more strongly with hemimethylated DNA; in this case, oriC and non-oriC sequences are bound similarly. Also, binding of hemimethylated oriC by membrane fractions is due to SeqA. Direct interaction of SeqA protein with the replication origin is likely to be involved in both replication initiation and sequestration.     

An origin of DNA replication from Lactococcus lactis bacteriophage c2

An origin of DNA relication was identified in the intergenic region between the early and late gene regions of prolate lactococcal phage c2. A DNA fragment containing this origin, designated ori, was shown to direct DNA replication in Lactococcus lactis but not in Escherichia coli. A comparison of ori with the corresponding regions of other prolate phages revealed strict conservation of the nucleotide sequence in one half of this intergenic region. This conserved region alone would not support DNA replication. No open reading frames were identified in the ori fragment, suggesting that host factors alone are sufficient to initiate DNA replication at ori. A novel class of lactococcal vectors and E. coli-L. lactis shuttle vectors based on ori have been constructed.     

Disassembly of the coliphage lambda replication complex due to heat shock induction of the groE operon

We have found previously that, in contrast to the free O initiator protein of lambda phage or plasmid rapidly degraded by the Escherichia coli ClpP/ClpX protease, the lambda O present in the replication complex (RC) is protected from proteolysis. In amino acid-starved E. coli relA cells, a temperature shift from 30 to 43 degrees did not affect RC integrity, as judged from the unchanged level of stable lambda O observed; however, the same temperature shift in a complete medium resulted in the decay of this lambda O fraction, which suggested disassembly of the RC. Examination of this phenomenon revealed that for lambda RC disassembly, heat shock induction of the groE operon, coding for molecular chaperones of the Hsp60 class, is indispensable. Heat shock induction of the groE operon present on a multicopy plasmid inhibited the growth of infecting phage.     

Increased expression of a hemimethylated oriC binding protein, SeqA, in an aphA mutant

In Escherichia coli, the origin of DNA replication, oriC, becomes transiently hemimethylated at the GATC sequences immediately after initiation of replication and this hemimethylated state is prolonged because of its sequestration by a fraction of outer membrane. This sequestration is dependent on a hemimethylated oriC binding protein such as SeqA. We previously isolated a clone of phage lambda gt11 called hobH, producing a LacZ fusion protein which recognizes hemimethylated oriC DNA. Very recently, Thaller et al. (FEMS Microbiol. Lett. 146 (1997) 191-198) found that the same DNA segment encodes a non-specific acid phosphatase, and named the gene aphA. We show here that the interruption of the aphA reading frame by kanamycin resistance gene insertion, abolishes acid phosphatase (NAP) activity. Interestingly, in the membrane of the null mutant, the amount of SeqA protein is about six times higher than that in the parental strain, suggesting the existence of a regulatory mechanism between SeqA and NAP expression.     

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The Escherichia coli DnaA protein is a sequence-specific DNA binding protein that promotes the initiation of replication of the bacterial chromosome, and of several plasmids including pSC101. Twenty-eight novel missense mutations of the E. coli dnaA gene were isolated by selecting for their inability to replicate a derivative of pSC101 when contained in a lambda vector. Characterization of these as well as seven novel nonsense mutations and one in-frame deletion mutation are described here. Results suggest that E. coli DnaA protein contains four functional domains. Mutations that affect residues in the P-loop or Walker A motif thought to be involved in ATP binding identify one domain. The second domain maps to a region near the C terminus and is involved in DNA binding. The function of the third domain that maps near the N terminus is unknown but may be involved in the ability of DnaA protein to oligomerize. Two alleles encoding different truncated gene products retained the ability to promote replication from the pSC101 origin but not oriC, identifying a fourth domain dispensable for replication of pSC101 but essential for replication from the bacterial chromosomal origin, oriC.     

A cruciform-dumbbell model for inverted dimer formation mediated by inverted repeats

Small inverted repeats (small palindromes) on plasmids have been shown to mediate a recombinational rearrangement event in Escherichia coli leading to the formation of inverted dimers (giant palindromes). This recombinational rearrangement event is efficient and independent of RecA and RecBCD. In this report, we propose a cruciform-dumbbell model to explain the inverted dimer formation mediated by inverted repeats. In this model, the inverted repeats promote the formation of a DNA cruciform which is processed by an endonuclease into a linear DNA with two hairpin loops at its ends. Upon DNA replication, this linear dumbbell-like DNA is then converted to the inverted dimer. In support of this model, linear dumbbell DNA molecules with unidirectional origin of DNA replication (ColE1 ori ) have been constructed and shown to transform E.coli efficiently resulting in the formation of the inverted dimer. The ability of linear dumbbell DNA to transform E.coli suggests that the terminal loops may be important in bypassing the requirement of DNA supercoiling for initiation of replication of the ColE1 ori.     

Double-strand end repair via the RecBC pathway in Escherichia coli primes DNA replication

To study the relationship between homologous recombination and DNA replication in Escherichia coli, we monitored the behavior of phage lambda chromosomes, repressed or not for lambda gene activities. Recombination in our system is stimulated both by DNA replication and by experimentally introduced double-strand ends, supporting the idea that DNA replication generates occasional double-strand ends. We report that the RecBC recombinational pathway of E. coli uses double-strand ends to prime DNA synthesis, implying a circular relationship between DNA replication and recombination and suggesting that the primary role of recombination is in the repair of disintegrated replication forks arising during vegetative reproduction.     

Primase couples leading- and lagging-strand DNA synthesis from oriC

Coupling of leading- and lagging-strand DNA synthesis at replication forks formed at Escherichia coli oriC has been studied in vitro using a replication system reconstituted with purified proteins. At low concentrations of primase (8 nM), the major replication products were multigenome-length molecules, generated by a rolling circle-type mechanism, and unit-length molecules. Rolling circle DNA replication was inhibited at high concentrations of primase (80 nM) and the major replication products were half-unit-length leading strands and a distinct population of short Okazaki fragments. At low primase concentrations, an asymmetric mode of DNA synthesis occurred. Each strand was made independently and initiation could occur outside of oriC. At high primase concentrations, initiation occurred exclusively at oriC and two coupled replication forks proceeded bidirectionally around the plasmid. Presumably, at low concentrations of primase, DnaB (the replication fork helicase) unwound the plasmid DNA before replication forks could form, leading to initiation at sites other than oriC. On the other hand, high concentrations of primase resulted in successful capture of the helicase leading to the formation at oriC of coupled replication forks capable of coordinated leading- and lagging-strand synthesis.