Specialized nucleoprotein structures at the origin of replication of bacteriophage lambda: localized unwinding of duplex DNA by a six-protein reaction.

The O protein of bacteriophage lambda localizes the initiation of DNA replication to a unique site on the lambda genome, ori lambda. By means of electron microscopy, we infer that the binding of O to ori lambda initiates a series of protein addition and transfer reactions that culminate in localized unwinding of the origin DNA, generating a prepriming structure for the initiation of DNA replication. We can define three stages of this prepriming reaction, the first two of which we have characterized previously. First, dimeric O protein binds to multiple DNA binding sites and self-associates to form a nucleoprotein structure, the O-some. Second, lambda P and host DnaB proteins interact with the O-some to generate a larger complex that includes additional DNA from an A + T-rich region adjacent to the O binding sites. Third, the addition of the DnaJ, DnaK, and Ssb proteins and ATP results in an origin-specific unwinding reaction, probably catalyzed by the helicase activity of DnaB. The unwinding reaction is unidirectional, proceeding "rightward" from the origin. The minimal DNA sequence competent for unwinding consists of two O binding sites and the adjacent A + T-rich region to the right of the binding sites. We conclude that the lambda O protein localizes and initiates a six-protein sequential reaction responsible for but preceding the precise initiation of DNA replication. Specialized nucleoprotein structures similar to the O-some may be a general feature of DNA transactions requiring extraordinary precision in localization and control.     

Replication of lambda dv plasmid in vitro promoted by purified lambda O and P proteins.

An in vitro system for replication of lambda dv plasmid DNA has been constructed. This system consists of an ammonium sulfate fraction from Escherichia coli extract, exogenously added purified lambda O and P proteins, and lambda dv DNA in closed circular form. More than 85% of the added template DNA replicated semiconservatively. In the same system, another plasmid, pBR322, also replicated, but less efficiently than lambda dv. Furthermore, its replication was independent of O and P proteins. Inhibitors of DNA gyrase entirely blocked the replication activity, whereas rifampicin, an inhibitor of RNA polymerase, showed a significant effect only when added prior to initiation of the DNA replication. DNA replication was initiated from a region near to or within the four direct repeats in lambda origin (lambda ori) and proceeded bidirectionally, as examined by DNA chain elongation termination with dideoxy CTP. A cloned DNA carrying a 350-base-pair region including the initiation site also initiated replication, dependent on O and P proteins, and its initiation occurred at the same position as with native lambda dv DNA. An A + T-rich structure neighboring the repeats was found to be essential for lambda DNA replication. Regions corresponding to ice and oop were not required for O,P-dependent initiation.     

Activity of the Hsp70 chaperone complex--DnaK, DnaJ, and GrpE--in initiating phage lambda DNA replication by sequestering and releasing lambda P protein.

Initiation of DNA replication by phage lambda requires the ordered assembly and disassembly of a specialized nucleoprotein structure at the origin of replication. In the disassembly pathway, a set of Escherichia coli heat shock proteins termed the Hsp70 complex--DnaK, DnaJ, and GrpE--act with ATP to release lambda P protein from the nucleo-protein complex, freeing the DnaB helicase for its DNA-unwinding reaction. To investigate the mechanism of the release reaction, we have examined the interaction between P and the three heat shock proteins by glycerol gradient sedimentation and gel electrophoresis. We have discovered an ATP-dependent ternary interaction between P, DnaK, and DnaJ; this P.DnaK.DnaJ complex is dissociated by GrpE. We have concluded that the function of the Hsp70 complex in sequestering and releasing P protein provides for the critical step in the disassembly pathway. Based on our data and other work on protein folding, the formation of the P.DnaK.DnaJ complex might involve a conformational shift to a folding intermediate of P.     

Initiation of DNA replication on single-stranded DNA templates catalyzed by purified replication proteins of bacteriophage lambda and Escherichia coli.

Initiation of bacteriophage lambda DNA replication at the chromosomal origin depends on the lambda O and P replication proteins. These two viral initiators, together with an Escherichia coli protein fraction, promote the replication in vitro of single-stranded circular DNA chromosomes such as that of bacteriophage M13. This nonspecific strand initiation reaction, which we have termed the "lambda single-strand replication reaction," has now been established with eight purified proteins, each of which is also required for replication of the phage lambda chromosome in vivo. An early rate-limiting step in the overall reaction is the ATP-dependent assembly of an activated nucleoprotein prepriming complex. In this step the lambda O and P initiators cooperate with the E. coli dnaJ and dnaK proteins to transfer the bacterial dnaB protein onto M13 DNA that is coated with the single-stranded DNA-binding protein. Multiple RNA primers are synthesized on each DNA circle when isolated prepriming complex is incubated with primase and rNTPs. In the complete system, DNA polymerase III holoenzyme extends the first primer synthesized into full-length complementary strands. Because the properties of this system are closely analogous to those found for the replication of phi X174 viral DNA by E. coli proteins, we infer that a mobile prepriming or priming complex (primosome) operates in the lambda single-strand replication reaction.     

Initiation of bacteriophage lambda DNA replication in vitro with purified lambda replication proteins.

We have developed a soluble enzyme system that replicates exogenously added plasmid DNA (lambda dv) bearing the replication origin of the bacteriophage lambda chromosome. The system contains pure phage lambda O and P replication proteins and a partially purified mixture of Escherichia coli replication proteins [the enzyme system of Fuller, R.S., Kaguni, J.M. & Kornberg, A. (1981) Proc. Natl. Acad. Sci. USA 78, 7370-7374). The features of lambda dv replication in this system closely resemble the known characteristics of phage lambda DNA replication in vivo. The system (i) depends completely on exogenously supplied DNA, (ii) specifically replicates supercoiled plasmid DNA that contains a lambda replication origin, (iii) depends on both the lambda O protein and the lambda P protein, (iv) depends on RNA polymerase, (v) depends on host replication proteins (e.g., primase, dnaB protein, and several others that function in the priming of DNA synthesis in E. coli) as judged by antibody inhibitions, and (vi) replicates as much as 32% of added lambda dv plasmid DNA through a single complete round to generate catenated daughter molecules. Furthermore, replication of lambda dv DNA in vitro requires DNA gyrase and an ATP-regenerating system. It is notable that addition of lambda O and P proteins to the mixture of E. coli replication proteins inhibits replication of plasmids bearing the origin of the E. coli chromosome. Exploitation of this enzyme system should allow a detailed investigation of the biochemical mechanisms involved in bacteriophage lambda DNA replication and its regulation.     

Multiple initiation sites of DNA replication flanking the origin region of lambda dv genome.

Early replicative intermediates of lambda dv plasmid were prepared by an in vitro replication system in the presence of 2',3'-dideoxycytidine 5'-triphosphate, an inhibitor of DNA chain elongation. Short-chain DNAs produced from regions near the replication origin were purified from the intermediates. A fraction of the DNAs was covalently linked to primer RNA. The transition sites from primer RNA to DNA synthesis were mapped along the nucleotide sequence of the genome, by eliminating the RNA by alkaline hydrolysis and labeling the freshly exposed 5' ends of DNA with 32P. The transition sites were found to be located on both sides of the ori region, which includes four 19-base-pair repeats where one of the lambda specific initiator proteins, O, binds. No transition arose within the ori region. The transition sites are multiple on both sides of the ori region and are clustered in one of the two strands in such a way that DNA syntheses from the two sides converge. The frequency of the "leftward" DNA synthesis is several times higher than that of "rightward" synthesis, reflecting the asymmetric bidirectional replication of lambda dv DNA.     

The replication initiator protein pi of the plasmid R6K specifically interacts with the host-encoded helicase DnaB.

The replication initiator protein pi of plasmid R6K is known to interact with the seven iterons of the gamma origin/enhancer and activate distant replication origins alpha and beta (ori alpha and ori beta) by pi-mediated DNA looping. Here we show that pi protein specifically interacts in vitro with the host-encoded helicase DnaB. The site of interaction of pi on DnaB has been localized to a 37-aa-long region located between amino acids 151 and 189 of DnaB. The surface of pi that interacts with DnaB has been mapped to the N-terminal region of the initiator protein between residues 1 and 116. The results suggest that during initiation of replication, the replicative helicase DnaB is first recruited to the gamma enhancer by the pi protein. In a subsequent step, the helicase probably gets delivered from ori gamma to ori alpha and ori beta by pi-mediated DNA looping.     

Role of the Escherichia coli DnaK and DnaJ heat shock proteins in the initiation of bacteriophage lambda DNA replication.

We examined the role of two Escherichia coli heat shock proteins, the dnaK and dnaJ gene products, during the initiation of lambda dv DNA replication in vitro. Using 14C-labeled lambda P protein we showed that the DnaK and DnaJ heat shock proteins function together to release lambda P protein from the preprimosomal complex consisting of lambda origin of replication-lambda O-lambda P-DnaB protein. Hydrolysis of ATP, catalyzed presumably by DnaK, is required during this reaction. Substitution of DnaK protein with that of the mutant DnaK756 protein blocks lambda P release. After DnaK and DnaJ action, the preprimosomal complex, isolated on Sepharose 4B, can support lambda dv DNA replication without any additional prepriming proteins. Using DnaK-affinity chromatography we showed that both lambda O and lambda P proteins bind to DnaK protein. The lambda P protein interacts with DnaK protein in a salt-resistant, hydrophobic manner, and ATP hydrolysis is necessary to elute at least part of lambda P protein from the DnaK-affinity column. The proposed mechanism of action of the prokaryotic DnaK and DnaJ heat shock proteins agrees with the hypothesis that Hsp70, the DnaK analogue of eukaryotes, uses ATP to disrupt hydrophobic aggregates [Pelham, H. R. B. (1986) Cell 46, 959-961].     

The dnaK protein of Escherichia coli possesses an ATPase and autophosphorylating activity and is essential in an in vitro DNA replication system.

The Escherichia coli dnaK gene product, originally defined by mutations that blocked lambda phage DNA replication, is known to be necessary for E. coli viability. We have purified dnaK protein to homogeneity and have demonstrated that it possesses a weak DNA-independent ATPase activity, which results in the production of ADP and Pi. The proof that this ATPase activity is encoded by the dnaK+ gene relies primarily on the fact that the dnaK756 mutation results in the production of an ATPase activity with altered physical properties. The dnaK protein is phosphorylated in vitro and in vivo, probably as a result of an autophosphorylation reaction. The lambda O and P replication proteins were shown to interact in vitro with the dnaK protein. The ATPase activity of the dnaK protein was inhibited by purified lambda P protein and stimulated by purified lambda O protein. Moreover, the dnaK protein participates in the initiation of DNA synthesis in an in vitro DNA replication system that is dependent on the O and P proteins. Anti-dnaK protein immunoglobulin specifically inhibited DNA synthesis in this system.     

Replication of mini-P1 plasmid DNA in vitro requires two initiation proteins, encoded by the repA gene of phage P1 and the dnaA gene of Escherichia coli.

We have developed an in vitro DNA-replication system that replicates exogenously added mini-P1 plasmid DNA. The system consists of purified P1 RepA protein and a partially purified mixture of Escherichia coli replication proteins. It is essentially the same as that described for the replication of oriC plasmid DNA [Fuller, R.S., Kaguni, J.M. & Kornberg, A. (1981) Proc. Natl. Acad. Sci. USA 78, 7370-7374]. Mini-P1 DNA replication requires the E. coli DnaA initiation protein in addition to the P1 RepA initiation protein. The reaction is inhibited by rifampicin, novobiocin, and antibody to DnaB, suggesting the involvement of RNA polymerase, DNA gyrase, and DnaB protein. Replication is initiated in the region of the P1 origin of replication and proceeds unidirectionally as determined by electron microscopy. Thus, the in vitro system mimics the essential features of mini-P1 replication as suggested by genetic studies.     

Structure of the cooperative Xis-DNA complex reveals a micronucleoprotein filament that regulates phage lambda intasome assembly

The DNA architectural protein Xis regulates the construction of higher-order nucleoprotein intasomes that integrate and excise the genome of phage lambda from the Escherichia coli chromosome. Xis modulates the directionality of site-specific recombination by stimulating phage excision 10(6)-fold, while simultaneously inhibiting phage reintegration. Control is exerted by cooperatively assembling onto a approximately 35-bp DNA regulatory element, which it distorts to preferentially stabilize an excisive intasome. Here, we report the 2.6-A crystal structure of the complex between three cooperatively bound Xis proteins and a 33-bp DNA containing the regulatory element. Xis binds DNA in a head-to-tail orientation to generate a micronucleoprotein filament. Although each protomer is anchored to the duplex by a similar set of nonbase specific contacts, malleable protein-DNA interactions enable binding to sites that differ in nucleotide sequence. Proteins at the ends of the duplex sequence specifically recognize similar binding sites and participate in cooperative binding via protein-protein interactions with a bridging Xis protomer that is bound in a less specific manner. Formation of this polymer introduces approximately 72 degrees of curvature into the DNA with slight positive writhe, which functions to connect disparate segments of DNA bridged by integrase within the excisive intasome.     

Three Escherichia coli heat shock proteins are required for P1 plasmid DNA replication: formation of an active complex between E. coli DnaJ protein and the P1 initiator protein.

DNA containing the plasmid origin of bacteriophage P1 is replicated in vitro by a protein fraction prepared from uninfected Escherichia coli supplemented with purified P1 RepA protein. It has previously been shown that the reaction required the E. coli DnaA initiator protein, the DnaB helicase, DnaC protein, RNA polymerase, and DNA gyrase. I show here that three E. coli heat shock proteins, DnaJ, DnaK, and GrpE, are directly involved in P1 plasmid replication. Purified DnaJ, DnaK, and GrpE proteins were required to stimulate P1 plasmid ori DNA-dependent replication in in vitro complementation assays in which the host protein fractions were prepared from cells mutated in the corresponding gene. I have also found that the DnaJ and RepA proteins form a complex. This complex exists in crude cell extracts and can be isolated as a molecular species of about 160,000 Da containing one dimer of DnaJ protein and one dimer of RepA. The complex can also be reconstituted by mixing purified DnaJ and RepA proteins. These results imply that the DnaJ-RepA complex, DnaK, and GrpE are directly involved in P1 plasmid replication.     

Interaction of the lambda site-specific recombination protein Xis with attachment site DNA.

Nuclease protection experiments show that Xis protein of bacteriophage lambda specifically binds attachment (att) site DNA. The region of Xis binding, present in both the phage att site and the right prophage att site, extends from position -102 to position -62 in the P arm. The sequence of this region, the positions of purines protected by Xis against methylation, and the binding of Xis to a resected att site indicate the presence of two binding sites. The postulated recognition elements, contained in 13-base-pair direct repeats separated by 7 base pairs, are situated on the same face of the DNA helix. Protection experiments performed with DNase I suggest that the DNA wraps around (or along the surface of) the bound Xis protein. The Xis binding data presented here establishes that Xis, like the other two proteins involved in lambda site-specific recombination, interacts specifically with att DNA. This rules out that class of models in which the profound effects of Xis on the directionality of site-specific recombination are mediated solely through protein-protein interactions or modification of another protein. In addition, nuclease protection experiments with pairwise combinations of the proteins show that Xis and integration host factor (IHF), or Xis and Int, can bind simultaneously to either the phage or right prophage att sites, and the DNA sequences protected are the sum of those protected with each protein alone. It is therefore unlikely that the effect of Xis on the direction of recombination is exerted by directly blocking the binding of Int or IHF to one or more of their respective binding sites.     

RepA and DnaA proteins are required for initiation of R1 plasmid replication in vitro and interact with the oriR sequence.

RepA, an initiation protein of R1 plasmid replication, was purified from an Escherichia coli strain overproducing the protein. The purified RepA protein specifically initiated replication in vitro of plasmid DNA bearing the replication origin of R1 plasmid (oriR). The replication, strictly dependent on added RepA protein, was independent of host RNA polymerase but required other host replication functions (DnaB and DnaC proteins, the single-stranded-DNA-binding protein SSB, and DNA gyrase). The replication was also completely dependent on the host DnaA function. In filter binding assays in high salt (0.5 M KCl) conditions, RepA specifically binds to both supercoiled and linear plasmid DNA containing the oriR sequence, whereas it binds to nonspecific DNA in low salt. DNase I-protection studies on a linearized DNA fragment revealed that DnaA protein specifically binds to a 9-base-pair DnaA-recognition sequence ("DnaA box") within oriR only when RepA is bound to the sequence immediately downstream of the DnaA box. These results indicate that initiation of R1 plasmid replication is triggered by interaction of RepA and DnaA proteins with the oriR sequence.     

A multifunctional plasmid-encoded replication initiation protein both recruits and positions an active helicase at the replication origin

The DnaA replication initiation protein has been shown to be essential for DNA strand opening at the AT-rich region of the replication origin of the Escherichia coli chromosome as well as serving to recruit and position the DnaB replicative helicase at this open region. Homologues of the dnaA gene of E. coli have been found in most bacterial species, and the DnaA protein has been shown to be required for the initiation of replication of both chromosomal and plasmid DNA. For several plasmid elements it has been found that a plasmid-encoded initiation protein is required along with the DnaA protein to bring about opening of the AT-rich region at the replication origin. The broad host range plasmid RK2 encodes two forms of its replication initiation protein (TrfA-33 and TrfA-44) that differ by an additional 98 aa at the N terminus of the larger (TrfA-44) form. Both forms initiate replication of RK2 in E. coli in vitro by a DnaA-dependent mechanism. However, as shown in this study, TrfA-44 specifically interacts with the DnaB replicative helicase of Pseudomonas putida and Pseudomonas aeruginosa and initiates the formation of a prepriming open complex in the absence of DnaA protein. Thus, the TrfA-44 initiation protein has the multifunctional properties of recruiting and positioning an active form of the DnaB helicase at the RK2 replication origin by a DnaA-independent process. This unique property for a replication initiation protein undoubtedly plays an important role in extending the host range of the RK2 antibiotic resistance plasmid.     

An additional function for bacteriophage lambda rex: the rexB product prevents degradation of the lambda O protein.

The rex operon of bacteriophage lambda excludes the development of several unrelated bacteriophages. Here we present an additional lambda rexB function: it prevents degradation of the short-lived protein lambda O known to be involved in lambda DNA replication. We have shown that it is the product of rexB that is responsible for the stabilization of lambda O: when a nonsense mutation is present in rexB, lambda O protein is labile; suppression of the mutation by the corresponding nonsense suppressor causes partial restabilization of lambda O. lambda rexB also stabilizes lambda O in trans. We discuss our results in relation to the function of rexB in lambda DNA replication and its role in the protein degradation pathways of bacteriophage lambda.     

ATP-dependent formation of a specialized nucleoprotein structure by simian virus 40 (SV40) large tumor antigen at the SV40 replication origin.

The large tumor antigen (T antigen) specified by simian virus 40 (SV40) is required for viral DNA replication. To carry out its function, T antigen binds to duplex DNA at the origin of replication (oriSV40) and exerts a helicase activity that unwinds the two DNA strands. Previous work has defined two binding sites for T antigen near oriSV40, designated sites I and II; site II is within the 64-base-pair core sequence absolutely required for viral DNA replication. We have used electron microscopy and gel electrophoresis to characterize the interaction of T antigen with the origin region. We have found that effective binding to site II under conditions that support DNA replication requires ATP or a nonhydrolyzable analog. In the absence of ATP, T antigen binds mainly to site I; in the presence of ATP, both sites I and II are occupied, and binding is markedly increased. The ATP-dependent reaction generates a complex multimeric structure for T antigen. We conclude that T antigen forms an ATP-dependent nucleoprotein structure at oriSV40. We suggest that this nucleoprotein complex provides for the precise initiation of SV40 DNA replication.     

Nucleoprotein complex formed between herpes simplex virus UL9 protein and the origin of DNA replication: inter- and intramolecular interactions.

The UL9 gene of herpes simplex virus type 1 encodes an origin-binding protein. UL9 protein purified from baculovirus vector-infected insect cells forms a stable complex with DNA containing the herpes simplex virus origin of DNA replication, oriS. Contained within oriS are two UL9 protein-binding sites, I and II, bracketing an (A + T)-rich region. UL9 protein, visualized by electron microscopy, binds selectively at the site of the origin and covers approximately 120 base pairs. Upon formation of the nucleoprotein complex, the apparent contour length of the DNA is shortened, suggesting that this amount of DNA is wrapped or condensed by the protein. A nucleoprotein complex of similar size and structure forms on an inactive origin deleted for binding site II. Multiple intermolecular interactions occur. In particular, UL9 nucleoprotein complexes interact in trans with other UL9 nucleoprotein complexes such that dimer DNA molecules are formed with a junction at the position of protein binding. The DNA molecules in these intermolecular complexes are aligned predominantly in a parallel orientation.     

DNA binding site for a factor(s) required to initiate simian virus 40 DNA replication.

Efficient initiation of DNA replication in the absence of nonspecific DNA repair synthesis was obtained by using a modification of the system developed by J.J. Li and T.J. Kelly [(1984) Proc. Natl. Acad. Sci. USA 81, 6973-6977]. Circular double-stranded DNA plasmids replicated in extracts of CV-1 cells only when the plasmids contained the cis-acting origin sequence for simian virus 40 DNA replication (ori) and the extract contained simian virus 40 large tumor antigen. Competition between plasmids containing ori and plasmids carrying deletions in and about ori served to identify a sequence that binds the rate-limiting factor(s) required to initiate DNA replication. The minimum binding site (nucleotides 72-5243) encompassed one-half of the simian virus 40 ori sequence that is required for initiation of replication (ori-core) plus the contiguous sequence on the late gene side of ori-core containing G + C-rich repeats that facilitates initiation (ori-auxiliary). This initiation factor binding site was specific for the simian virus 40 ori region, even though it excluded the high-affinity large tumor antigen DNA binding sites.