Crystallization and preliminary crystallographic characterization of the origin-binding domain of the bacteriophage lambda O replication initiator.

The bacteriophage lambda O protein binds to the lambda replication origin (orilambda) and serves as the primary replication initiator for the viral genome. The binding energy derived from the binding of O to orilambda is thought to help drive DNA opening to facilitate initiation of DNA replication. Detailed understanding of this process is severely limited by the lack of high-resolution structures of O protein or of any lambdoid phage-encoded paralogs either with or without DNA. The production of crystals of the origin-binding domain of lambda O that diffract to 2.5 A is reported. Anomalous dispersion methods will be used to solve this structure.

Thermodynamic and structural analysis of the folding/unfolding transitions of the Escherichia coli molecular chaperone DnaK.

The thermal unfolding of the Escherichia coli 70 kDa heat shock protein, DnaK, exhibits three well defined transitions. At pH 7.6, these transitions are centered at 45.2, 58.0 and 73.3 degrees C. High sensitivity calorimetric scans as a function of pH indicate that the folding/unfolding behavior is well described by a four-state model which includes a delta H, tm and delta Cp for each state. Calorimetric scans of a 44 kDa N-terminal proteolytic fragment show a major transition centered at 47.5 degrees C (N1) and a minor transition at 79.4 degrees C (N2). A calorimetric scan of a 23 kDa C-terminal proteolytic fragment exhibits a low temperature peak at 58.5 degrees C (C1) and a high temperature peak at 70.6 degrees C (C2). Deconvolution analysis of the low temperature peak reveals that it is actually composed of two transitions of roughly equal delta H centered at 50.4 degrees C (C1a) and 58.2 degrees C(C1b). These experiments have allowed us to assign the transitions of the intact protein as follows. The low temperature transition of DnaK can be assigned to the N-terminal region on the basis of the similarity between the delta H and tm values for the low temperature transition and those obtained for the N1 transition of the isolated N-terminal fragment. This assignment is also supported by measurements of the intrinsic fluorescence emission as a function of temperature. DnaK contains a single tryptophan localized at residue 102 in the N-terminal domain of the protein. Additionally, calorimetric scans show that the tm of the low temperature transition increases by 9.2 degrees C in the presence of excess ADP, which is known to bind to the N-terminal domain. The middle transition can be assigned to the C1a and C1b transitions of the C-terminal fragment on the basis of the similarity of delta H and tm. In the intact protein C1a and C1b form a single cooperative unit; however, the cooperative interactions between these folding/unfolding domains are disrupted in the isolated fragment. The high temperature transition of the intact protein is composed of contributions from both the N-terminal and C-terminal regions of the protein. These studies have allowed us to develop a quantitative model of the folding/unfolding behavior of DnaK.

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.

Modulation of the ATPase activity of the molecular chaperone DnaK by peptides and the DnaJ and GrpE heat shock proteins.

Previous studies have demonstrated that the Escherichia coli DnaK, DnaJ, and GrpE heat shock proteins participate in the initiation of bacteriophage lambda DNA replication by mediating the required disassembly of a preinitiation nucleoprotein structure that is formed at the phage replication origin. To gain some understanding in a simpler system of how the DnaJ and GrpE cochaperonins influence the activity of DnaK, we have examined the effect of the cochaperonins on the weak intrinsic ATPase activity of the molecular chaperone DnaK in the presence and absence of peptide effectors. We have found that random sequence peptide chains of 8 or 9 amino acid residues in length yield optimal (10-fold) activation of the DnaK ATPase, whereas peptides with 5 or fewer residues fail to stimulate the ATPase of this bacterial hsp70 homologue. Furthermore, we have discovered that those peptides that interact best with DnaK, as judged by their KA as activators of ATP hydrolysis by DnaK, also act as strong inhibitors of lambda DNA replication in vitro. The inhibitory effect of peptides on lambda DNA replication was overcome by increasing the concentration of DnaK in the replication system. Diminished inhibition was also found when the replication system was supplemented with GrpE cochaperonin, a protein known to increase the effectiveness of DnaK action in lambda DNA replication. These and other results suggest that the peptide-binding site of DnaK is required for its function in lambda DNA replication. Apparently, peptides sequester free DnaK protein and block lambda DNA replication by reducing the amount of DnaK that is free to mediate disassembly of nucleoprotein preinitiation structures. In related studies, we have found that DnaJ, like short peptides, activates the intrinsic ATPase activity of DnaK. DnaJ, however, is substantially more potent in this regard, since it activates DnaK at concentrations 1000-fold below those required for a peptide of random sequence. By itself, the GrpE cochaperonin has no effect on the peptide-independent ATPase activity of DnaK, but GrpE does vigorously stimulate the peptide-dependent ATPase of the DnaK chaperone. Under steady-state conditions, the Vmax of ATP hydrolysis by DnaK was elevated approximately 40-fold by the presence of GrpE and saturating levels of peptides.

A multienzyme system for priming the replication of phiX174 viral DNA.

Synthesis of the oligonucleotides that prime replication of phiX174 single-stranded DNA employs complex protein machinery of the host cell which is probably used by the cell to replicate its own chromosome. Primer synthesis depends on at least five proteins (DNA binding protein, dnaB and dnaC proteins, protein i, and protein n) and ATP to form a replication intermediate and another protein, primase (dnaG protein), to assemble the oligonucleotide by template transcription. The data in this paper show that ribo- and deoxyribonucleoside triphosphates can serve as substrates and form hybrid primers when present together. Both RNA and DNA primers were initiated with ATP. At least three of the four base-pairing nucleoside triphosphates were required for the transcription that generates effective primers. Over 90% of the RNA and DNA transcripts were extended into complementary strands by DNA polymerase III holoenzyme. At optimal triphosphate concentrations, the rate and extent of primer formation were greater from ribonucleoside triphosphates than from deoxyribonucleoside triphosphates. Uncoupled from DNA replication, the length of RNA primers was 14 to 50 residues, the DNA primers 4 to 20 residues. The fingerprint pattern of an RNase digest of RNA primers has a complexity suggestive of transcription from many sites on the phiX174 template. The multienzyme priming system is highly specific for phiX174 DNA as template.

The role of template superhelicity in the initiation of bacteriophage lambda DNA replication.

The prepriming steps in the initiation of bacteriophage lambda DNA replication depend on the action of the lambda O and P proteins and on the DnaB helicase, single-stranded DNA binding protein (SSB), and DnaJ and DnaK heat shock proteins of the E. coli host. The binding of multiple copies of the lambda O protein to the phage replication origin (ori lambda) initiates the ordered assembly of a series of nucleoprotein structures that form at ori lambda prior to DNA unwinding, priming and DNA synthesis steps. Since the initiation of lambda DNA replication is known to occur only on supercoiled templates in vivo and in vitro, we examined how the early steps in lambda DNA replication are influenced by superhelical tension. All initiation complexes formed prior to helicase-mediated DNA-unwinding form with high efficiency on relaxed ori lambda DNA. Nonetheless, the DNA templates in these structures must be negatively supertwisted before they can be replicated. Once DNA helicase unwinding is initiated at ori lambda, however, later steps in lambda DNA replication proceed efficiently in the absence of superhelical tension. We conclude that supercoiling is required during the initiation of lambda DNA replication to facilitate entry of a DNA helicase, presumably the DnaB protein, between the DNA strands.

Ordered assembly of nucleoprotein structures at the bacteriophage lambda replication origin during the initiation of DNA replication.

Replication of the chromosome of bacteriophage lambda depends on the cooperative action of two phage-coded proteins and seven replication and heat shock proteins from its Escherichia coli host. As previously described, the first stage in this process is the binding of multiple copies of the lambda O initiator to the lambda replication origin (ori lambda) to form the nucleosomelike O-some. The O-some serves to localize subsequent protein-protein and protein-DNA interactions involved in the initiation of lambda DNA replication to ori lambda. To study these interactions, we have developed a sensitive immunoblotting protocol that permits the protein constituents of complex nucleoprotein structures to be identified. Using this approach, we have defined a series of sequential protein assembly and protein disassembly events that occur at ori lambda during the initiation of lambda DNA replication. A second-stage ori lambda.O (lambda O protein).P (lambda P protein).DnaB nucleoprotein structure is formed when O, P, and E. coli DnaB helicase are incubated with ori lambda DNA. In a third-stage reaction the E. coli DnaJ heat shock protein specifically binds to the second-stage structure to form an ori lambda.O.P.DnaB.DnaJ complex. Each of the nucleoprotein structures formed in the first three stages was isolated and shown to be a physiological intermediate in the initiation of lambda DNA replication. The E. coli DnaK heat shock protein can bind to any of these early stage nucleoprotein structures, and in a fourth-stage reaction a complete ori lambda.O.P.DnaB.DnaJ.DnaK initiation complex is assembled. Addition of ATP to the reaction enables the DnaK and DnaJ heat shock proteins to mediate a partial disassembly of the fourth-stage complex. These protein disassembly reactions activate the intrinsic helicase activity of DnaB and result in localized unwinding of the ori lambda template. The protein disassembly reactions are described in the accompanying articles.

Heat shock protein-mediated disassembly of nucleoprotein structures is required for the initiation of bacteriophage lambda DNA replication.

Three Escherichia coli heat shock proteins, DnaJ, DnaK, and GrpE, are required for replication of the bacteriophage lambda chromosome in vivo. We show that the GrpE heat shock protein is not required for initiation of lambda DNA replication in vitro when the concentration of DnaK is sufficiently high. GrpE does, however, greatly potentiate the action of DnaK in the initiation process when the DnaK concentration is reduced to a subsaturating level. We demonstrate in the accompanying articles (Alfano, C. and McMacken, R. (1989) J. Biol. Chem. 264, 10699-10708; Dodson, M., McMacken, R., and Echols, H. (1989) J. Biol. Chem. 264, 10719-10725) that DnaJ and DnaK bind to prepriming nucleoprotein structures that are assembled at the lambda replication origin (ori lambda). Binding of DnaJ and DnaK completes the ordered assembly of an ori lambda initiation complex that also contains the lambda O and P initiators and the E. coli DnaB helicase. With the addition of ATP, the DnaJ and DnaK heat shock proteins mediate the partial disassembly of the initiation complex, and the P and DnaJ proteins are largely removed from the template. Concomitantly, on supercoiled ori lambda plasmid templates, the intrinsic helicase activity of DnaB is activated and DnaB initiates localized unwinding of the DNA duplex, thereby preparing the template for priming and DNA chain elongation. We infer from our results that DnaK and DnaJ function in normal E. coli metabolism to promote ATP-dependent protein unfolding and disassembly reactions. We also provide evidence that neither the lambda O and P initiators nor the E. coli DnaJ and DnaK heat shock proteins play a direct role in the propagation of lambda replication forks in vitro.

The Escherichia coli dnaB replication protein is a DNA helicase.

Genetic and biochemical analyses indicate that the Escherichia coli dnaB replication protein functions in the propagation of replication forks in the bacterial chromosome. We have found that the dnaB protein is a DNA helicase that is capable of unwinding extensive stretches of double-stranded DNA. We constructed a partially duplex DNA substrate, containing two preformed forks of single-stranded DNA, which was used to characterize this helicase activity. The dnaB helicase depends on the presence of a hydrolyzable ribonucleoside triphosphate, is maximally stimulated by a combination of E. coli single-stranded DNA-binding protein and E. coli primase, is inhibited by antibody directed against dnaB protein, and is inhibited by prior coating of the single-stranded regions of the helicase substrate with the E. coli single-stranded DNA-binding protein. It was determined that the dnaB protein moves 5' to 3' along single-stranded DNA, apparently in a processive fashion. To invade the duplex portion of the helicase substrate, the dnaB protein requires a 3'-terminal extension of single-stranded DNA in the strand to which it is not bound. Under optimal conditions at 30 degrees C, greater than 1 kilobase pair of duplex DNA can be unwound within 30 s. Based on these findings and other available data, we propose that the dnaB protein is the primary replicative helicase of E. coli and that it actively and processively migrates along the lagging strand template, serving both to unwind the DNA duplex in advance of the leading strand and to potentiate synthesis by the bacterial primase of RNA primers for the nascent (Okazaki) fragments of the lagging strand.

A bipartite signaling mechanism involved in DnaJ-mediated activation of the Escherichia coli DnaK protein.

The DnaK and DnaJ heat shock proteins function as the primary Hsp70 and Hsp40 homologues, respectively, of Escherichia coli. Intensive studies of various Hsp70 and DnaJ-like proteins over the past decade have led to the suggestion that interactions between specific pairs of these two types of proteins permit them to serve as molecular chaperones in a diverse array of protein metabolic events, including protein folding, protein trafficking, and assembly and disassembly of multisubunit protein complexes. To further our understanding of the nature of Hsp70-DnaJ interactions, we have sought to define the minimal sequence elements of DnaJ required for stimulation of the intrinsic ATPase activity of DnaK. As judged by proteolysis sensitivity, DnaJ is composed of three separate regions, a 9-kDa NH2-terminal domain, a 30-kDa COOH-terminal domain, and a protease-sensitive glycine- and phenylalanine-rich (G/F-rich) segment of 30 amino acids that serves as a flexible linker between the two domains. The stable 9-kDa proteolytic fragment was identified as the highly conserved J-region found in all DnaJ homologues. Using this structural information as a guide, we constructed, expressed, purified, and characterized several mutant DnaJ proteins that contained either NH2-terminal or COOH-terminal deletions. At variance with current models of DnaJ action, DnaJ1-75, a polypeptide containing an intact J-region, was found to be incapable of stimulating ATP hydrolysis by DnaK protein. We found, instead, that two sequence elements of DnaJ, the J-region and the G/F-rich linker segment, are each required for activation of DnaK-mediated ATP hydrolysis and for minimal DnaJ function in the initiation of bacteriophage lambda DNA replication. Further analysis indicated that maximal activation of ATP hydrolysis by DnaK requires two independent but simultaneous protein-protein interactions: (i) interaction of DnaK with the J-region of DnaJ and (ii) binding of a peptide or polypeptide to the polypeptide-binding site associated with the COOH-terminal domain of DnaK. This dual signaling process required for activation of DnaK function has mechanistic implications for those protein metabolic events, such as polypeptide translocation into the endoplasmic reticulum in eukaryotic cells, that are dependent on interactions between Hsp70-like and DnaJ-like proteins.

Kinetic characterization of the ATPase cycle of the DnaK molecular chaperone.

DnaK, the prototype Hsp70 protein of Escherichia coli, functions as a molecular chaperone in protein folding and protein disassembly reactions through cycles of polypeptide binding and release that are coupled to its intrinsic ATPase activity. To further our understanding of these processes, we sought to obtain a quantitative description of the basic ATPase cycle of DnaK. To this end, we have performed steady-state and pre-steady-state kinetics experiments and have determined rate constants corresponding to individual steps in the DnaK ATPase cycle at 25 degrees C. Hydrolysis of ATP proceeds very slowly with a rate constant (khyd approximately 0.02 min-1) at least 10-fold smaller than the rate constant for any other first-order step in the forward reaction pathway. The ATP hydrolysis step has an activation energy of 26.2 +/- 0.4 kcal/mol and is rate limiting in the steady-state under typical in vitro conditions. ATP binds with unusual strength to DnaK, with a measured KD approximately 1 nM. ADP binds considerably less tightly than ATP and dissociates from DnaK with a koff of approximately 0.4 min-1 (compared with a koff of approximately 0.008 min-1 for ATP). However, in the presence of physiologically relevant concentrations of inorganic phosphate (Pi), the release of ADP from DnaK is greatly slowed, approximately to the rate of ATP hydrolysis. Under these conditions, the ADP-bound form of DnaK, the form that binds substrate polypeptides most tightly, was found to represent a significant fraction of the DnaK population. The slowing of ADP release by exogenous Pi is due to thermodynamic coupling of the binding of the two ligands, which produces a coupling energy of approximately 1.6 kcal/mol. This result implies that product release is not strictly ordered. In the absence of exogenous inorganic phosphate, Pi product, by virtue of its higher koff, is released prior to ADP. However, at physiological concentrations of inorganic phosphate, the alternate product release pathway, whereby ADP dissociates from a ternary DnaK.ADP.Pi complex, becomes more prominent.

Regulation of expression of the Escherichia coli dnaG gene and amplification of the dnaG primase.

We have isolated lambda transducing phages carrying the Escherichia coli primase gene (dnaG) and mapped restriction sites in the cloned bacterial DNA segments. Several different DNA fragments containing the dnaG gene were inserted into multicopy plasmids. An analysis of the primase levels in cells harboring such plasmids indicates that sequences far upstream from the dnaG gene are required for optimal primase expression. Using this knowledge, we constructed a plasmid with a thermoinducible copy-number, pRLM61, which was employed to amplify intracellular primase levels approximately 100-fold. The dnaG gene is transcribed clockwise with respect to the E. coli genetic map, and a HindIII site located 180 base pairs upstream from the dnaG gene separates the gene from its primary promoter. An apparent transcription termination signal is positioned 30-70 base pairs in front of the primase gene. Transcription proceeds past this strong terminator only when RNA polymerase has first transcribed the bacterial DNA segment proximal to the HindIII site. We suggest that primase expression in E. coli is positively regulated by a mechanism of transcription antitermination mediated by a bacterial factor. We propose, furthermore, that the neighboring structural genes for primase and for the sigma subunit of RNA polymerase are coordinately regulated as part of an operon. This arrangement may enable the bacterial cell to readily control the level of initiation of DNA and RNA synthesis and thus to respond quickly and efficiently to changing conditions.

The bacteriophage lambda O replication protein: isolation and characterization of the amplified initiator.

The bacteriophage lambda O protein participates in the initiation of lambda DNA replication. The lambda O gene was cloned into plasmid pKC30 such that its expression was controlled by the lambda PL promoter. A lambda prophage-coded thermosensitive cI repressor was used to regulate transcription of the cloned O gene. Thermal inactivation of the lambda cI repressor resulted in overproduction of the O protein until it constituted approximately 20% of the total cellular protein of Escherichia coli. A simple three-step purification protocol was developed that yields several milligrams of homogeneous O protein per gram of cell paste. The precise position of the O gene in the known lambda DNA sequence was identified from the amino-terminal sequence of the isolated O protein. Purified O protein stimulated the replication of plasmid lambda dv DNA in vitro and specifically bound to duplex DNA fragments carrying the lambda replication origin.

Specialized nucleoprotein structures at the origin of replication of bacteriophage lambda. Protein association and disassociation reactions responsible for localized initiation of replication.

Binding of the O protein of phage lambda to the replication origin (ori lambda) results in the formation of an organized nucleoprotein structure termed the O-some. The O-some serves to localize and initiate a six-protein sequential reaction that provides for localized unwinding of the origin region, the critical prepriming step for precise initiation of DNA replication. By the use of electron microscopy of gold-tagged antibody complexes, we have defined four stages of protein association and dissociation reactions that are involved in the prepriming pathway. First, as defined previously, O protein binds to multiple DNA sites and self-associates to form the O-some. Second, lambda P and host DnaB proteins add to the O-some to generate an O.P.DnaB.ori lambda complex. Addition of the DnaK and DnaJ proteins yields a third stage complex containing DnaK, DnaJ, O, P, and DnaB. With the addition of ATP and single-strand binding protein (SSB), the P protein is largely removed, and the DnaB acts as a helicase to generate locally unwound, SSB-coated single strand DNA. Thus, the initiation of lambda DNA replication requires ordered assembly and partial disassembly of specialized nucleoprotein structures. The disassembly activity of DnaK and DnaJ may be their general role in the heat shock response.

Migration of Escherichia coli dnaB protein on the template DNA strand as a mechanism in initiating DNA replication.

The first step in conversion of varphiX174 singlestranded DNA to the duplex replicative form in vitro is the synthesis of a nucleoprotein intermediate [Weiner, J. H., McMacken, R. & Kornberg, A. (1976) Proc. Natl. Acad. Sci. USA 73, 752-756]. We now demonstrate that dnaB protein (approximately one molecule per DNA circle) is an essential component of the intermediate and retains its ATPase activity. Synthesis of RNA primers, dependent on dnaG protein (primase), occurred only on DNA that had been converted to the intermediate form. In a coupled RNA priming-DNA replication reaction the first primer synthesized was extended by DNA polymerase III holoenzyme into full-length complementary strand DNA. In RNA priming uncoupled from replication, multiple RNA primers were initiated on a varphiX174 circle. The single dnaB protein molecule present on each DNA circle participated in initiation of each of the RNA primers, which appear to be aligned at regular intervals along the template strand. We propose that dnaB protein, once bound to the template, migrates in a processive fashion along the DNA strand, perhaps utilizing energy released by hydrolysis of ATP for propulsion; in this scheme the actively moving dnaB protein acts as a "mobile promoter" signal for dnaG protein (primase) to produce many RNA primers. Schemes are proposed for participation of dnaB protein both in the initiation of replication at the origin of the Escherichia coli chromosome and in the initiation of primers for nascent (Okazaki) fragments at a replication fork.

Functional properties of replication fork assemblies established by the bacteriophage lambda O and P replication proteins.

We have used a set of bacteriophage lambda and Escherichia coli replication proteins to establish rolling circle DNA replication in vitro to permit characterization of the functional properties of lambda replication forks. We demonstrate that the lambda replication fork assembly synthesizes leading strand DNA chains at a physiological rate of 650-750 nucleotides/s at 30 degrees C. This rate is identical to the fork movement rate we obtained using a minimal protein system, composed solely of E. coli DnaB helicase and DNA polymerase III holoenzyme. Our data are consistent with the conclusion that these two key bacterial replication proteins constitute the basic functional unit of a lambda replication fork. A comparison of rolling circle DNA replication in the minimal and lambda replication systems indicated that DNA synthesis proceeded for more extensive periods in the lambda system and produced longer DNA chains, which averaged nearly 200 kilobases in length. The higher potency of the lambda replication system is believed to result from its capacity to mediate efficient reloading of DnaB helicase onto rolling circle replication products, thereby permitting reinitiation of DNA chain elongation following spontaneous termination events. E. coli single-stranded DNA-binding protein and primase individually stimulated rolling circle DNA replication, but they apparently act indirectly by blocking accumulation of inhibitory free single-stranded DNA product. Finally, in the course of this work, we discovered that E. coli DNA polymerase III holoenzyme is itself capable of carrying out significant strand displacement DNA synthesis at about 50 nucleotides/s when it is supplemented with E. coli single-stranded DNA-binding protein.

The bacteriophage lambda O and P protein initiators promote the replication of single-stranded DNA.

A soluble enzyme system that specifically initiates lambda dv plasmid DNA replication at a bacteriophage lambda replication origin [Wold et al. (1982) Proc. Natl. Acad. Sci. USA 79, 6176-6180] is also capable of replicating the single-stranded circular chromosomes of phages M13 and phi X174 to a duplex form. This chain initiation on single-stranded templates is novel in that it is absolutely dependent on the lambda O and P protein chromosomal initiators and on several Escherichia coli proteins that are known to function in the replication of the lambda chromosome in vivo, including the host dnaB, dnaG (primase), dnaJ and dnaK replication proteins. Strand initiation occurs at multiple sites following an O and P protein-dependent pre-priming step in which the DNA is converted into an activated nucleoprotein complex containing the bacterial dnaB protein. We propose a scheme for the initiation of DNA synthesis on single-stranded templates in this enzyme system that may be relevant to strand initiation events that occur during replication of phage lambda in vivo.

Purification and properties of Escherichia coli protein i, a prepriming protein in phi X174 DNA replication.

Protein i, one of seven Escherichia coli proteins essential for primosome initiation of DNA chains in the in vitro conversion of single-stranded phi X174 DNA to duplex replicative form, has been purified approximately 15,000-fold to more than 98% purity. The protein is an oligomer of 22,000-dalton subunits migrating as a single electrophoretic band on native, as well as on denaturing polyacrylamide gels. Estimates of a Stokes radius of 41 A, a sedimentation coefficient of 3.5 S, a Mr = 61,000, and a frictional coefficient of 1.57 suggest that native protein i is a highly asymmetric oligomer composed of three identical subunits. About 50 such molecules are present/cell. Cross-linking the protein with dimethylsuberimidate or dimethyladipimidate produced three major bands corresponding to the monomer, dimer, and trimer, as well as two minor bands corresponding to the tetramer and pentamer. Incorporation of 3H-labeled "trimeric" protein i into the prepriming replication intermediate (primosome) occurs at a stage requiring participation of dnaB and dnaC proteins, and follows the actions of proteins n, n', and n". After extension of primers by DNA polymerase III holoenzyme, protein i is not retained in the isolated primosome complex. Thus, protein i is essential in the assembly of a functional primosome, but its precise physiologic role and genetic locus are still unknown.

Specialized nucleoprotein structures at the origin of replication of bacteriophage lambda: complexes with lambda O protein and with lambda O, lambda P, and Escherichia coli DnaB proteins.

The O protein of bacteriophage lambda is required for initiation of DNA replication at the lambda replicative origin designated ori lambda. The binding sites for O protein are four direct repeats, each of which is an inverted repeat. By means of electron microscopy, we have found that phage lambda O protein utilizes these multiple binding sites to form a specific nucleoprotein structure in which the origin DNA is inferred to be folded or wound. The phage lambda O and P proteins and host DnaB protein interact at ori lambda to generate a larger structure than that formed by O protein alone; P and DnaB proteins fail to form any observable complex when O protein is excluded from the reaction mixture. We conclude that the specialized nucleoprotein structure formed by phage lambda O protein and ori lambda provides for localized initiation of DNA replication by serving as the foundation for the assembly of the initial priming structure. Specialized nucleoprotein structures may be a general means to confer exceptional accuracy on DNA transactions requiring extraordinary precision.