Biotin tagging deletion analysis of domain limits involved in protein-macromolecular interactions. Mapping the tau binding domain of the DNA polymerase III alpha subunit

Clamp Loader Processing Is Important during DNA Replication Stress

The DNA clamp loader is critical to the processivity of the DNA polymerase and coordinating synthesis on the leading and lagging strands. In bacteria, the major subunit of the clamp loader, DnaX, has two forms: the essential full-length τ form and shorter γ form. These are conserved across bacterial species, and three distinct mechanisms have been found to create them: ribosomal frameshift, transcriptional slippage, and, in Caulobacter crescentus, partial proteolysis. This conservation suggests that DnaX processing is evolutionarily important, but its role remains unknown. Here we find a bias against switching from expression of a wild-type dnaX to a nonprocessable τ-only allele in Caulobacter. Despite this bias, cells are able to adapt to the τ-only allele with little effect on growth or morphology and only minor defects during DNA damage. Motivated by transposon sequencing, we find that loss of the gene sidA in the τ-only strain slows growth and increases filamentation. Even in the absence of exogenous DNA damage treatment, the ΔsidA τ-only double mutant shows induction of and dependence on recA, likely due to a defect in resolution of DNA damage or replication fork stalling. We find that some of the phenotypes of the ΔsidA τ-only mutant can be complemented by expression of γ but that an overabundance of τ-only dnaX is also detrimental. The data presented here suggest that DnaX processing is important during resolution of DNA damage events during DNA replication stress. Although the presence of DnaX τ and γ forms is conserved across bacteria, different species have developed different mechanisms to make these forms. This conservation and independent evolution of mechanisms suggest that having two forms of DnaX is important. Despite having been discovered more than 30 years ago, the purpose of expressing both τ and γ is still unclear. Here, we present evidence that expressing two forms of DnaX and controlling the abundance and/or ratio of the forms are important during the resolution of DNA replication stress. IMPORTANCE Though the presence of DnaX τ and γ forms is conserved across bacteria, different species have developed different mechanisms to make these forms. This conservation and independent evolution of mechanisms suggest that having two forms of DnaX is important. Despite having been discovered more than 30 years ago, the purpose of expressing both τ and γ is still unclear. Here, we present evidence that expressing two forms of DnaX and controlling the abundance and/or ratio of the forms is important during the resolution of DNA replication stress.

The Macromolecular Machines that Duplicate the Escherichia coli Chromosome as Targets for Drug Discovery

DNA replication is an essential process. Although the fundamental strategies to duplicate chromosomes are similar in all free-living organisms, the enzymes of the three domains of life that perform similar functions in DNA replication differ in amino acid sequence and their three-dimensional structures. Moreover, the respective proteins generally utilize different enzymatic mechanisms. Hence, the replication proteins that are highly conserved among bacterial species are attractive targets to develop novel antibiotics as the compounds are unlikely to demonstrate off-target effects. For those proteins that differ among bacteria, compounds that are species-specific may be found. Escherichia coli has been developed as a model system to study DNA replication, serving as a benchmark for comparison. This review summarizes the functions of individual E. coli proteins, and the compounds that inhibit them.

DNA Polymerase III, but Not Polymerase IV, Must Be Bound to a τ-Containing DnaX Complex to Enable Exchange into Replication Forks

Examples of dynamic polymerase exchange have been previously characterized in model systems provided by coliphages T4 and T7. Using a dominant negative D403E polymerase (Pol) III α that can form initiation complexes and sequester primer termini but not elongate, we investigated the possibility of exchange at the Escherichia coli replication fork on a rolling circle template. Unlike other systems, addition of polymerase alone did not lead to exchange. Only when D403E Pol III was bound to a τ-containing DnaX complex did exchange occur. In contrast, addition of Pol IV led to rapid exchange in the absence of bound DnaX complex. Examination of Pol III* with varying composition of τ or the alternative shorter dnaX translation product γ showed that τ-, τ2-, or τ3-DnaX complexes supported equivalent levels of synthesis, identical Okazaki fragment size, and gaps between fragments, possessed the ability to challenge pre-established replication forks, and displayed equivalent susceptibility to challenge by exogenous D403E Pol III*. These findings reveal that redundant interactions at the replication fork must stabilize complexes containing only one τ. Previously, it was thought that at least two τs in the trimeric DnaX complex were required to couple the leading and lagging strand polymerases at the replication fork. Possible mechanisms of exchange are discussed.

The DNA polymerase III holoenzyme contains γ and is not a trimeric polymerase

There is widespread agreement that the clamp loader of the Escherichia coli replicase has the composition DnaX₃δδ’χψ. Two DnaX proteins exist in E. coli, full length τ and a truncated γ that is created by ribosomal frameshifting. τ binds DNA polymerase III tightly; γ does not. There is a controversy as to whether or not DNA polymerase III holoenzyme (Pol III HE) contains γ. A three-τ form of Pol III HE would contain three Pol IIIs. Proponents of the three-τ hypothesis have claimed that γ found in Pol III HE might be a proteolysis product of τ. To resolve this controversy, we constructed a strain that expressed only τ from a mutated chromosomal dnaX. γ containing a C-terminal biotinylation tag (γ-C_tag) was provided in trans at physiological levels from a plasmid. A 2000-fold purification of Pol III* (all Pol III HE subunits except β) from this strain contained one molecule of γ-C_tag per Pol III* assembly, indicating that the dominant form of Pol III* in cells is Pol III₂τ₂ γδδ’χψ. Revealing a role for γ in cells, mutants that express only τ display sensitivity to ultraviolet light and reduction in DNA Pol IV-dependent mutagenesis associated with double-strand-break repair, and impaired maintenance of an F’ episome.

Replisome Dynamics during Chromosome Duplication

This review describes the components of the Escherichia coli replisome and the dynamic process in which they function and interact under normal conditions. It also briefly describes the behavior of the replisome during situations in which normal replication fork movement is disturbed, such as when the replication fork collides with sites of DNA damage. E. coli DNA Pol III was isolated first from a polA mutant E. coli strain that lacked the relatively abundant DNA Pol I activity. Further biochemical studies, and the use of double mutant strains, revealed Pol III to be the replicative DNA polymerase essential to cell viability. In a replisome, DnaG primase must interact with DnaB for activity, and this constraint ensures that new RNA primers localize to the replication fork. The leading strand polymerase continually synthesizes DNA in the direction of the replication fork, whereas the lagging-strand polymerase synthesizes short, discontinuous Okazaki fragments in the opposite direction. Discontinuous lagging-strand synthesis requires that the polymerase rapidly dissociate from each new completed Okazaki fragment in order to begin the extension of a new RNA primer. Lesion bypass can be thought of as a two-step reaction that starts with the incorporation of a nucleotide opposite the lesion, followed by the extension of the resulting distorted primer terminus. A remarkable property of E. coli, and many other eubacterial organisms, is the speed at which it propagates. Rapid cell division requires the presence of an extremely efficient replication machinery for the rapid and faithful duplication of the genome.

DNA Polymerase α Subunit Residues and Interactions Required for Efficient Initiation Complex Formation Identified by a Genetic Selection

Biophysical and structural studies have defined many of the interactions that occur between individual components or subassemblies of the bacterial replicase, DNA polymerase III holoenzyme (Pol III HE). Here, we extended our knowledge of residues and interactions that are important for the first step of the replicase reaction: the ATP-dependent formation of an initiation complex between the Pol III HE and primed DNA. We exploited a genetic selection using a dominant negative variant of the polymerase catalytic subunit that can effectively compete with wild-type Pol III α and form initiation complexes, but cannot elongate. Suppression of the dominant negative phenotype was achieved by secondary mutations that were ineffective in initiation complex formation. The corresponding proteins were purified and characterized. One class of mutant mapped to the PHP domain of Pol III α, ablating interaction with the ϵ proofreading subunit and distorting the polymerase active site in the adjacent polymerase domain. Another class of mutation, found near the C terminus, interfered with τ binding. A third class mapped within the known β-binding domain, decreasing interaction with the β2 processivity factor. Surprisingly, mutations within the β binding domain also ablated interaction with τ, suggesting a larger τ binding site than previously recognized.

Long-Range PCR Amplification of DNA by DNA Polymerase III Holoenzyme from Thermus thermophilus

DNA replication in bacteria is accomplished by a multicomponent replicase, the DNA polymerase III holoenzyme (pol III HE). The three essential components of the pol III HE are the α polymerase, the β sliding clamp processivity factor, and the DnaX clamp-loader complex. We report here the assembly of the functional holoenzyme from Thermus thermophilus (Tth), an extreme thermophile. The minimal holoenzyme capable of DNA synthesis consists of α, β and DnaX (τ and γ), δ and δ′ components of the clamp-loader complex. The proteins were each cloned and expressed in a native form. Each component of the system was purified extensively. The minimum holoenzyme from these five purified subunits reassembled is sufficient for rapid and processive DNA synthesis. In an isolated form the α polymerase was found to be unstable at temperatures above 65°C. We were able to increase the thermostability of the pol III HE to 98°C by addition and optimization of various buffers and cosolvents. In the optimized buffer system we show that a replicative polymerase apparatus, Tth pol III HE, is capable of rapid amplification of regions of DNA up to 15,000 base pairs in PCR reactions.

Cycling of the E. coli lagging strand polymerase is triggered exclusively by the availability of a new primer at the replication fork

Two models have been proposed for triggering release of the lagging strand polymerase at the replication fork, enabling cycling to the primer for the next Okazaki fragment—either collision with the 5′-end of the preceding fragment (collision model) or synthesis of a new primer by primase (signaling model). Specific perturbation of lagging strand elongation on minicircles with a highly asymmetric G:C distribution with ddGTP or dGDPNP yielded results that confirmed the signaling model and ruled out the collision model. We demonstrated that the presence of a primer, not primase per se, provides the signal that triggers cycling. Lagging strand synthesis proceeds much faster than leading strand synthesis, explaining why gaps between Okazaki fragments are not found under physiological conditions.

Comprehensive analysis of DNA polymerase III α subunits and their homologs in bacterial genomes

The analysis of ∼2000 bacterial genomes revealed that they all, without a single exception, encode one or more DNA polymerase III α-subunit (PolIIIα) homologs. Classified into C-family of DNA polymerases they come in two major forms, PolC and DnaE, related by ancient duplication. While PolC represents an evolutionary compact group, DnaE can be further subdivided into at least three groups (DnaE1-3). We performed an extensive analysis of various sequence, structure and surface properties of all four polymerase groups. Our analysis suggests a specific evolutionary pathway leading to PolC and DnaE from the last common ancestor and reveals important differences between extant polymerase groups. Among them, DnaE1 and PolC show the highest conservation of the analyzed properties. DnaE3 polymerases apparently represent an ‘impaired’ version of DnaE1. Nonessential DnaE2 polymerases, typical for oxygen-using bacteria with large GC-rich genomes, have a number of features in common with DnaE3 polymerases. The analysis of polymerase distribution in genomes revealed three major combinations: DnaE1 either alone or accompanied by one or more DnaE2s, PolC + DnaE3 and PolC + DnaE1. The first two combinations are present in Escherichia coli and Bacillus subtilis, respectively. The third one (PolC + DnaE1), found in Clostridia, represents a novel, so far experimentally uncharacterized, set.

Polymerase manager protein UmuD directly regulates Escherichia coli DNA polymerase III α binding to ssDNA

Replication by Escherichia coli DNA polymerase III is disrupted on encountering DNA damage. Consequently, specialized Y-family DNA polymerases are used to bypass DNA damage. The protein UmuD is extensively involved in modulating cellular responses to DNA damage and may play a role in DNA polymerase exchange for damage tolerance. In the absence of DNA, UmuD interacts with the α subunit of DNA polymerase III at two distinct binding sites, one of which is adjacent to the single-stranded DNA-binding site of α. Here, we use single molecule DNA stretching experiments to demonstrate that UmuD specifically inhibits binding of α to ssDNA. We predict using molecular modeling that UmuD residues D91 and G92 are involved in this interaction and demonstrate that mutation of these residues disrupts the interaction. Our results suggest that competition between UmuD and ssDNA for α binding is a new mechanism for polymerase exchange.

DNA replicases from a bacterial perspective

Bacterial replicases are complex, tripartite replicative machines. They contain a polymerase, polymerase III (Pol III), a β₂ processivity factor, and a DnaX complex ATPase that loads β₂ onto DNA and chaperones Pol III onto the newly loaded β₂. Bacterial replicases are highly processive, yet cycle rapidly during Okazaki fragment synthesis in a regulated way. Many bacteria encode both a full-length τ and a shorter γ form of DnaX by a variety of mechanisms. γ appears to be uniquely placed in a single position relative to two τ protomers in a pentameric ring. The polymerase catalytic subunit of Pol III, α, contains a PHP domain that not only binds to a prototypical ε Mg²⁺-dependent exonuclease, but also contains a second Zn²⁺-dependent proofreading exonuclease, at least in some bacteria. This review focuses on a critical evaluation of recent literature and concepts pertaining to the above issues and suggests specific areas that require further investigation.

Polymerase chaperoning and multiple ATPase sites enable the E. coli DNA polymerase III holoenzyme to rapidly form initiation complexes

Cellular replicases include three subassemblies: a DNA polymerase, a sliding clamp processivity factor, and a clamp loader complex. The Escherichia coli clamp loader is the DnaX complex (DnaX(3)δδ'χψ), where DnaX occurs either as τ or as the shorter γ that arises by translational frameshifting. Complexes composed of either form of DnaX are fully active clamp loaders, but τ confers important replicase functions including chaperoning the polymerase to the newly loaded clamp to form an initiation complex for processive replication. The kinetics of initiation complex formation were explored for DnaX complexes reconstituted with varying τ and γ stoichiometries, revealing that τ-mediated polymerase chaperoning accelerates initiation complex formation by 100-fold. Analyzing DnaX complexes containing one or more K51E variant DnaX subunits demonstrated that only one active ATP binding site is required to form initiation complexes, but the two additional sites increase the rate by ca 1000-fold. For τ-containing complexes, the ATP analogue ATPγS was found to support initiation complex formation at 1/1000th the rate with ATP. In contrast to previous models that proposed ATPγS drives hydrolysis-independent initiation complex formation by τ-containing complexes, the rate and stoichiometry of ATPγS hydrolysis coincide with those for initiation complex formation. These results show that although one ATPase site is sufficient for initiation complex formation, the combination of polymerase chaperoning and the binding and hydrolysis of three ATPs dramatically accelerates initiation complex formation to a rate constant (25-50 s(-1)) compatible with double-stranded DNA replication.

Breaking the rules: bacteria that use several DNA polymerase IIIs

Studies using Escherichia coli DNA polymerase (Pol) III as the prototype for bacterial DNA replication have suggested that--in contrast to eukaryotes--one replicase performs all of the main functions at the replication fork. However, recent studies have revealed that replication in other bacteria requires two forms of Pol III, one of which seems to extend RNA primers by only a few nucleotides before transferring the product to the other polymerase--an arrangement analogous to that in eukaryotes. Yet another group of bacteria encode a second Pol III (ImuC), which apparently replaces a Pol Y-type polymerase (Pol V) that is required for induced mutagenesis in E. coli. A complete understanding of complex bacterial replicases will allow the simultaneous biochemical screening of all their components and, thus, the identification of new antibacterial compounds.

Essential roles for imuA'- and imuB-encoded accessory factors in DnaE2-dependent mutagenesis in Mycobacterium tuberculosis

In Mycobacterium tuberculosis (Mtb), damage-induced mutagenesis is dependent on the C-family DNA polymerase, DnaE2. Included with dnaE2 in the Mtb SOS regulon is a putative operon comprising Rv3395c, which encodes a protein of unknown function restricted primarily to actinomycetes, and Rv3394c, which is predicted to encode a Y-family DNA polymerase. These genes were previously identified as components of an imuA-imuB-dnaE2-type mutagenic cassette widespread among bacterial genomes. Here, we confirm that Rv3395c (designated imuA') and Rv3394c (imuB) are individually essential for induced mutagenesis and damage tolerance. Yeast two-hybrid analyses indicate that ImuB interacts with both ImuA' and DnaE2, as well as with the beta-clamp. Moreover, disruption of the ImuB-beta clamp interaction significantly reduces induced mutagenesis and damage tolerance, phenocopying imuA', imuB, and dnaE2 gene deletion mutants. Despite retaining structural features characteristic of Y-family members, ImuB homologs lack conserved active-site amino acids required for polymerase activity. In contrast, replacement of DnaE2 catalytic residues reproduces the dnaE2 gene deletion phenotype, strongly implying a direct role for the alpha-subunit in mutagenic lesion bypass. These data implicate differential protein interactions in specialist polymerase function and identify the split imuA'-imuB/dnaE2 cassette as a compelling target for compounds designed to limit mutagenesis in a pathogen increasingly associated with drug resistance.

Parallel multiplicative target screening against divergent bacterial replicases: identification of specific inhibitors with broad spectrum potential

Typically, biochemical screens that employ pure macromolecular components focus on single targets or a small number of interacting components. Researches rely on whole cell screens for more complex systems. Bacterial DNA replicases contain multiple subunits that change interactions with each stage of a complex reaction. Thus, the actual number of targets is a multiple of the proteins involved. It is estimated that the overall replication reaction includes up to 100 essential targets, many suitable for discovery of antibacterial inhibitors. We have developed an assay, using purified protein components, in which inhibitors of any of the essential targets can be detected through a common readout. Use of purified components allows each protein to be set within the linear range where the readout is proportional to the extent of inhibition of the target. By performing assays against replicases from model Gram-negative and Gram-positive bacteria in parallel, we show that it is possible to distinguish compounds that inhibit only a single bacterial replicase from those that exhibit broad spectrum potential.

Chaperoning of a replicative polymerase onto a newly assembled DNA-bound sliding clamp by the clamp loader

Cellular replicases contain multiprotein ATPases that load sliding clamp processivity factors onto DNA. We reveal an additional role for the DnaX clamp loader: chaperoning of the replicative polymerase onto a clamp newly bound to DNA. We show that chaperoning confers distinct advantages, including marked acceleration of initiation complex formation. We reveal a requirement for the tau form of DnaX complex to relieve inhibition by single-stranded DNA binding protein during initiation complex formation. We propose that, after loading beta(2), DnaX complex preserves an SSB-free segment of DNA immediately downstream of the primer terminus and chaperones Pol III into that position, preventing competition by SSB. The C-terminal tail of SSB stimulates reactions catalyzed by tau-containing DnaX complexes through a contact distinct from the contact involving the chi subunit. Chaperoning of Pol III by the DnaX complex provides a molecular explanation for how initiation complexes form when supported by the nonhydrolyzed analog ATPgammaS.

Strand displacement by DNA polymerase III occurs through a tau-psi-chi link to single-stranded DNA-binding protein coating the lagging strand template

In addition to the well characterized processive replication reaction catalyzed by the DNA polymerase III holoenzyme on single-stranded DNA templates, the enzyme possesses an intrinsic strand displacement activity on flapped templates. The strand displacement activity is distinguished from the single-stranded DNA-templated reaction by a high dependence upon single-stranded DNA binding protein and an inability of gamma-complex to support the reaction in the absence of tau. However, if gamma-complex is present to load beta(2), a truncated tau protein containing only domains III-V will suffice. This truncated protein is sufficient to bind both the alpha subunit of DNA polymerase (Pol) III and chipsi. This is reminiscent of the minimal requirements for Pol III to replicate short single-stranded DNA-binding protein (SSB)-coated templates where tau is only required to serve as a scaffold to hold Pol III and chi in the same complex (Glover, B., and McHenry, C. (1998) J. Biol. Chem. 273, 23476-23484). We propose a model in which strand displacement by DNA polymerase III holoenzyme depends upon a Pol III-tau-psi-chi-SSB binding network, where SSB is bound to the displaced strand, stabilizing the Pol III-template interaction. The same interaction network is probably important for stabilizing the leading strand polymerase interactions with authentic replication forks. The specificity constant (k(cat)/K(m)) for the strand displacement reaction is approximately 300-fold less favorable than reactions on single-stranded templates and proceeds with a slower rate (150 nucleotides/s) and only moderate processivity (approximately 300 nucleotides). PriA, the initiator of replication restart on collapsed or misassembled replication forks, blocks the strand displacement reaction, even if added to an ongoing reaction.

Mechanism of polymerase collision release from sliding clamps on the lagging strand

Replicative polymerases are tethered to DNA by sliding clamps for processive DNA synthesis. Despite attachment to a sliding clamp, the polymerase on the lagging strand must cycle on and off DNA for each Okazaki fragment. In the 'collision release' model, the lagging strand polymerase collides with the 5' terminus of an earlier completed fragment, which triggers it to release from DNA and from the clamp. This report examines the mechanism of collision release by the Escherichia coli Pol III polymerase. We find that collision with a 5' terminus does not trigger polymerase release. Instead, the loss of ssDNA on filling in a fragment triggers polymerase to release from the clamp and DNA. Two ssDNA-binding elements are involved, the tau subunit of the clamp loader complex and an OB domain within the DNA polymerase itself. The tau subunit acts as a switch to enhance polymerase binding at a primed site but not at a nick. The OB domain acts as a sensor that regulates the affinity of Pol III to the clamp in the presence of ssDNA.

Allosteric regulation of the primase (DnaG) activity by the clamp-loader (tau) in vitro

During DNA replication the helicase (DnaB) recruits the primase (DnaG) in the replisome to initiate the polymerization of new DNA strands. DnaB is attached to the tau subunit of the clamp-loader that loads the beta clamp and interconnects the core polymerases on the leading and lagging strands. The tau-DnaB-DnaG ternary complex is at the heart of the replisome and its function is likely to be modulated by a complex network of allosteric interactions. Using a stable ternary complex comprising the primase and helicase from Geobacillus stearothermophilus and the tau subunit of the clamp-loader from Bacillus subtilis we show that changes in the DnaB-tau interaction can stimulate allosterically primer synthesis by DnaG in vitro. The A550V tau mutant stimulates the primase activity more efficiently than the native protein. Truncation of the last 18 C-terminal residues of tau elicits a DnaG-stimulatory effect in vitro that appears to be suppressed in the native tau protein. Thus changes in the tau-DnaB interaction allosterically affect primer synthesis. Although these C-terminal residues of tau are not involved directly in the interaction with DnaB, they may act as a functional gateway for regulation of primer synthesis by tau-interacting components of the replisome through the tau-DnaB-DnaG pathway.

Modulation of RAG/DNA complex by HSP70 in V(D)J recombination

V(D)J recombination, a site-specific gene rearrangement process, requires two RAG1 and RAG2 proteins specifically recognizing recombination signal sequences and forming DNA double-strand breaks. The broken DNA ends tightly bound to RAG proteins are joined by repair proteins. Here, we found that heat shock protein 70 was associated with RAG2 following two-step affinity chromatography purification. It was also co-immunoprecipitated with RAG2 in pro-B cells. Purified HSP70 protein disrupted RAG/DNA complexes assembled in vitro and also inhibited the V(D)J cleavage (both nick and hairpin formation) in a dose-dependent manner. This HSP70 action required ATP energy. These data suggest that HSP70 might play a crucial role in disassembling RAG/DNA complexes stably formed during V(D)J recombination.

Differential binding of Escherichia coli DNA polymerases to the beta-sliding clamp

Escherichia coli strains expressing the mutant beta159-sliding clamp protein (containing both a G66E and a G174A substitution) are temperature sensitive for growth and display altered DNA polymerase (pol) usage. We selected for suppressors of the dnaN159 allele able to grow at 42 degrees C, and identified four intragenic suppressor alleles. One of these alleles (dnaN780) contained only the G66E substitution, while a second (dnaN781) contained only the G174A substitution. Genetic characterization of isogenic E. coli strains expressing these alleles indicated that certain phenotypes were dependent upon only the G174A substitution, while others required both the G66E and G174A substitutions. In order to understand the individual contributions of the G66E and the G174A substitution to the dnaN159 phenotypes, we utilized biochemical approaches to characterize the purified mutant beta159 (G66E and G174A), beta780 (G66E) and beta781 (G174A) clamp proteins. The G66E substitution conferred a more pronounced effect on pol IV replication than it did pol II or pol III, while the G174A substitution conferred a greater effect on pol III and pol IV than it did pol II. Taken together, these findings indicate that pol II, pol III and pol IV interact with distinct, albeit overlapping surfaces of the beta clamp.

The unstructured C-terminus of the tau subunit of Escherichia coli DNA polymerase III holoenzyme is the site of interaction with the alpha subunit

The τ subunit of Escherichia coli DNA polymerase III holoenzyme interacts with the α subunit through its C-terminal Domain V, τ_C16. We show that the extreme C-terminal region of τ_C16 constitutes the site of interaction with α. The τ_C16 domain, but not a derivative of it with a C-terminal deletion of seven residues (τ_C16Δ7), forms an isolable complex with α. Surface plasmon resonance measurements were used to determine the dissociation constant (K_D) of the α−τ_C16 complex to be ∼260 pM. Competition with immobilized τ_C16 by τ_C16 derivatives for binding to α gave values of K_D of 7 μM for the α−τ_C16Δ7 complex. Low-level expression of the genes encoding τ_C16 and τ_C16▵7, but not τ_C16Δ11, is lethal to E. coli. Suppression of this lethal phenotype enabled selection of mutations in the 3′ end of the τ_C16 gene, that led to defects in α binding. The data suggest that the unstructured C-terminus of τ becomes folded into a helix–loop–helix in its complex with α. An N-terminally extended construct, τ_C24, was found to bind DNA in a salt-sensitive manner while no binding was observed for τ_C16, suggesting that the processivity switch of the replisome functionally involves Domain IV of τ.

A versatile system for site-specific enzymatic biotinylation and regulated expression of proteins in cultured mammalian cells

We have developed a system for producing biotinylated recombinant proteins in mammalian cells. The expression construct consists of an inducible tetracycline response element (TRE) that drives expression of a bicistronic cassette comprising a biotin acceptor peptide (BioTag) fused to either terminus of the target protein, the gene for Escherichia coli biotin ligase (BirA), and an intervening internal ribosome entry site (IRES). By either transient or stable transfection of Chinese hamster ovary (CHO) Tet-On cells, we successfully expressed, detected, and immobilized biotinylated human Itch, a pleiotropic multi-domain ubiquitin-protein ligase, as well as Gla-RTK, a putative vitamin K-dependent receptor tyrosine kinase. The biotinylation of recombinant Itch in transiently transfected CHO Tet-On cells required biotin supplementation and coexpression of BirA, occurred quantitatively and specifically on the lysine residue of the BioTag, and enabled detection of Itch by Western blot in as little as 10ng of total lysate protein. Stably selected clones were rapidly pre-screened for doxycycline (dox)-inducible BirA expression by ELISA, and subsequently screened for dox-inducible expression of biotinylated Itch. Biotinylated Gla-RTK was detectable in as little as 5ng of total lysate protein from transiently transfected CHO Tet-On cells, and exhibited pronounced tyrosine phosphorylation. In stable clones however, constitutive phosphorylation was prevented by reducing the expression level of Gla-RTK through the titration of dox. These results demonstrate the utility of this system for the expression of 'difficult' proteins, particularly those that are cytotoxic or those that may require lower expression levels to ensure appropriate post-translational modification.

Metabolic biotinylation provides a unique platform for the purification and targeting of multiple AAV vector serotypes

The development of rationally designed targeted gene delivery vectors is an important focus for gene therapy. While genetic modification of AAV can produce vectors with modified tropism, incorporation of targeting peptides into the structural context of the AAV virion often results in loss of function or loss of virion integrity. To address this issue, we have developed a targeting system using metabolically biotinylated AAV. We generated serotype 1, 2, 3, 4, and 5 AAV capsids with small peptide insertions that are metabolically biotinylated in packaging cells during vector production by coexpression of the Escherichia coli BirA, biotin ligase, gene. Biotin moieties are exposed on the surface of assembled AAV particles and can interact with avidin. Metabolically biotinylated AAV vectors produced in this manner maintained endogenous titer and tissue tropism, could be purified on monomeric avidin resin, and could be retargeted to cells engineered to express an artificial avidin-biotin receptor. This technology provides not only a single platform for the purification of multiple AAV vector serotypes, but also a means for the development of multiple targeted AAV vectors utilizing a single capsid modification via straightforward avidin-biotin ligand coupling.

The NH2-terminal php domain of the alpha subunit of the Escherichia coli replicase binds the epsilon proofreading subunit

The alpha subunit of the replicase of all bacteria contains a php domain, initially identified by its similarity to histidinol phosphatase but of otherwise unknown function (Aravind, L., and Koonin, E. V. (1998) Nucleic Acids Res. 26, 3746-3752). Deletion of 60 residues from the NH2 terminus of the alpha php domain destroys epsilon binding. The minimal 255-residue php domain, estimated by sequence alignment with homolog YcdX, is insufficient for epsilon binding. However, a 320-residue segment including sequences that immediately precede the polymerase domain binds epsilon with the same affinity as the 1160-residue full-length alpha subunit. A subset of mutations of a conserved acidic residue (Asp43 in Escherichia coli alpha) present in the php domain of all bacterial replicases resulted in defects in epsilon binding. Using sequence alignments, we show that the prototypical gram+ Pol C, which contains the polymerase and proofreading activities within the same polypeptide chain, has an epsilon-like sequence inserted in a surface loop near the center of the homologous YcdX protein. These findings suggest that the php domain serves as a platform to enable coordination of proofreading and polymerase activities during chromosomal replication.

Mutator mutants of Escherichia coli carrying a defect in the DNA polymerase III tau subunit

To investigate the possible role of accessory subunits of Escherichia coli DNA polymerase III holoenzyme (HE) in determining chromosomal replication fidelity, we have investigated the role of the dnaX gene. This gene encodes both the tau and gamma subunits of HE, which play a central role in the organization and functioning of HE at the replication fork. We find that a classical, temperature-sensitive dnaX allele, dnaX36, displays a pronounced mutator effect, characterized by an unusual specificity: preferential enhancement of transversions and -1 frameshifts. The latter occur predominantly at non-run sequences. The dnaX36 defect does not affect the gamma subunit, but produces a tau subunit carrying a missense substitution (E601K) in its C-terminal domain (domain V) that is involved in interaction with the Pol III alpha subunit. A search for new mutators in the dnaX region of the chromosome yielded six additional dnaX mutators, all carrying a specific tau subunit defect. The new mutators displayed phenotypes similar to dnaX36: strong enhancement of transversions and frameshifts and only weak enhancement for transitions. The combined findings suggest that the tau subunit of HE plays an important role in determining the fidelity of the chromosomal replication, specifically in the avoidance of transversions and frameshift mutations.

RshA mimetic peptides inhibiting the transcription driven by a Mycobacterium tuberculosis sigma factor SigH

SigH, an alternative sigma factor in Mycobacterium tuberculosis, is a central regulator in responses to the oxidative and heat stress. This SigH activity is specifically controlled by an anti-sigma factor RshA during expression of stress-related genes. Thus, the specific interaction (k(on)=1.15x10(5) (M(-1) s(-1)), k(off)=1.7x10(-3) (s(-1)), KD=15 nM, determined in this study) between SigH and RshA is crucial for the survival and pathogenesis of M. tuberculosis. Using phage-display peptide library, we defined three specific regions on RshA responsible for SigH binding. Three RshA mimetic peptides (DAHADHD, AEVWTLL, and CTPETRE) specifically inhibited the transcription initiated by SigH in vitro. One of them (DAHADHD) diminished the extent of binding of RshA to SigH in a dose-dependent manner. The binding affinity (KD) of this peptide to SigH was about 1.2 microM. These findings might provide some insights into the development of new peptide-based drugs for TB.

Discovery and characterization of the cryptic psi subunit of the pseudomonad DNA replicase

We previously reconstituted a minimal DNA replicase from Pseudomonas aeruginosa consisting of alpha and epsilon (polymerase and editing nuclease), beta (processivity factor), and the essential tau, delta, and delta' components of the clamp loader complex (Jarvis, T., Beaudry, A., Bullard, J., Janjic, N., and McHenry, C. (2005) J. Biol. Chem. 280, 7890-7900). In Escherichia coli DNA polymerase III holoenzyme, chi and Psi are tightly associated clamp loader accessory subunits. The addition of E. coli chiPsi to the minimal P. aeruginosa replicase stimulated its activity, suggesting the existence of chi and Psi counterparts in P. aeruginosa. The P. aeruginosa chi subunit was recognizable from sequence similarity, but Psi was not. Here we report purification of an endogenous replication complex from P. aeruginosa. Identification of the components led to the discovery of the cryptic Psi subunit, encoded by holD. P. aeruginosa chi and Psi were co-expressed and purified as a 1:1 complex. P. aeruginosa chiPsi increased the specific activity of tau(3)deltadelta' 25-fold and enabled the holoenzyme to function under physiological salt conditions. A synergistic effect between chiPsi and single-stranded DNA binding protein was observed. Sequence similarity to P. aeruginosa Psi allowed us to identify Psi subunits from several other Pseudomonads and to predict probable translational start sites for this protein family. This represents the first identification of a highly divergent branch of the Psi family and confirms the existence of Psi in several organisms in which Psi was not identifiable based on sequence similarity alone.

Cellular DNA replicases: components and dynamics at the replication fork

DNA replicases are multicomponent machines that have evolved clever strategies to perform their function. Although the structure of DNA is elegant in its simplicity, the job of duplicating it is far from simple. At the heart of the replicase machinery is a heteropentameric AAA+ clamp-loading machine that couples ATP hydrolysis to load circular clamp proteins onto DNA. The clamps encircle DNA and hold polymerases to the template for processive action. Clamp-loader and sliding clamp structures have been solved in both prokaryotic and eukaryotic systems. The heteropentameric clamp loaders are circular oligomers, reflecting the circular shape of their respective clamp substrates. Clamps and clamp loaders also function in other DNA metabolic processes, including repair, checkpoint mechanisms, and cell cycle progression. Twin polymerases and clamps coordinate their actions with a clamp loader and yet other proteins to form a replisome machine that advances the replication fork.

A bipartite polymerase-processivity factor interaction: only the internal beta binding site of the alpha subunit is required for processive replication by the DNA polymerase III holoenzyme

Previously, we localized the beta2 interacting portion of the catalytic subunit (alpha) of DNA polymerase III to the C-terminal half, downstream of the polymerase active site. Since then, two different beta2 binding sites within this region have been proposed. An internal site includes amino acid residues 920-924 (QADMF) and an extreme C-terminal site includes amino acid residues 1154-1159 (QVELEF). To permit determination of their relative contributions, we made mutations in both sites and evaluated the biochemical, genetic, and protein binding properties of the mutant alpha subunits. All purified mutant alpha subunits retained near wild-type polymerase function, which was measured in non-processive gap-filling assays. Mutations in the internal site abolished the ability of mutant alpha subunits to participate in processive synthesis. Replacement of the five-residue internal sequence with AAAKK eliminated detectable binding to beta2. In addition, mutation of residues required for beta2 binding abolished the ability of the resulting polymerase to participate in chromosomal replication in vivo. In contrast, mutations in the C-terminal site exhibited near wild-type phenotypes. alpha Subunits with the C-terminal site completely removed could participate in processive DNA replication, could bind beta2, and, if induced to high level expression, could complement a temperature-sensitive conditional lethal dnaE mutation. C-terminal defects that only partially complemented correlated with a defect in binding to tau, not beta2. A C-terminal deletion only reduced beta2 binding fourfold; tau binding was decreased ca 400-fold. The context in which the beta2 binding site was presented made an enormous difference. Replacement of the internal site with a consensus beta2 binding sequence increased the affinity of the resulting alpha for beta2 over 100-fold, whereas the same modification at the C-terminal site did not significantly increase binding. The implications of multiple interactions between a replicase and its processivity factor, including applications to polymerase cycling and interchange with other polymerases and factors at the replication fork, are discussed.

Mapping subunit location on the Saccharomyces cerevisiae origin recognition complex free and bound to DNA using a novel nanoscale biopointer

The Saccharomyces cerevisiae origin recognition complex (ORC) is composed of six subunits and is an essential component in the assembly of the replication apparatus. To probe the organization of this multiprotein complex by electron microscopy, each subunit was tagged on either its C or N terminus with biotin and assembled into a complex with the five other unmodified subunits. A nanoscale biopointer consisting of a short DNA duplex with streptavidin at one end was used to map the location of the N and C termini of each subunit. These observations were made using ORC free in solution and bound to the ARS1 origin of replication. This mapping confirms and extends previous studies mapping the sites of subunit interaction with origin DNA. In particular, we provide new information concerning the stoichiometry of the ORC-ARS1 complex and the changes in conformation that are associated with DNA binding by ORC. This versatile, new approach to mapping protein structure has potential for many applications.

A temperature-sensitive mutation in the dnaE gene of Caulobacter crescentus that prevents initiation of DNA replication but not ongoing elongation of DNA

A genetic screen for cell division cycle mutants of Caulobacter crescentus identified a temperature-sensitive DNA replication mutant. Genetic complementation experiments revealed a mutation within the dnaE gene, encoding the alpha-catalytic subunit of DNA polymerase III holoenzyme. Sequencing of the temperature-sensitive dnaE allele indicated a single base pair substitution resulting in a change from valine to glutamic acid within the C-terminal portion of the protein. This mutation lies in a region of the DnaE protein shown in Escherichia coli, to be important in interactions with other essential DNA replication proteins. Using DNA replication assays and fluorescence flow cytometry, we show that the observed block in DNA synthesis in the Caulobacter dnaE mutant strain occurs at the initiation stage of replication and that there is also a partial block of DNA elongation.

A peptide switch regulates DNA polymerase processivity

Chromosomal DNA polymerases are tethered to DNA by a circular sliding clamp for high processivity. However, lagging strand synthesis requires the polymerase to rapidly dissociate on finishing each Okazaki fragment. The Escherichia coli replicase contains a subunit (tau) that promotes separation of polymerase from its clamp on finishing DNA segments. This report reveals the mechanism of this process. We find that tau binds the C-terminal residues of the DNA polymerase. Surprisingly, this same C-terminal "tail" of the polymerase interacts with the beta clamp, and tau competes with beta for this sequence. Moreover, tau acts as a DNA sensor. On binding primed DNA, tau releases the polymerase tail, allowing polymerase to bind beta for processive synthesis. But on sensing the DNA is complete (duplex), tau sequesters the polymerase tail from beta, disengaging polymerase from DNA. Therefore, DNA sensing by tau switches the polymerase peptide tail on and off the clamp and coordinates the dynamic turnover of polymerase during lagging strand synthesis.

Clamp-loader-helicase interaction in Bacillus. Leucine 381 is critical for pentamerization and helicase binding of the Bacillus tau protein

Recently, we revealed the architecture of the clamp-loader-helicase (tau-DnaB) complex in Bacillus by atomic force microscopy imaging and constructed a structural model, whereby a pentameric clamp-loader interacts with the hexameric helicase. Crucial to this model is the assumption that the clamp-loader forms a pentamer in the absence of other components of the clamp-loader complex such as deltadelta'. Here, we show that the Bacillus subtilis tau protein, even in the absence of deltadelta', interacts as a pentamer with the hexameric DnaB and that the L381 of tau is critical for the integrity of the tau oligomer and interaction with DnaB. The effects of the L381A mutation were confirmed by gel filtration, ultracentrifugation, circular dichroism, cross-linking studies, and genetic replacement of the dnaX gene with a mutant L381A dnaX gene in vivo. The L381A protein is able to support growth in vivo only when expressed in high quantities. Finally, despite the fact that a mutation at P465 has been reported to result in a thermosensitive gene in vivo, a P465L mutant protein interacts with DnaB in vitro suggesting that this defect is not a result of a defective tau-DnaB interaction.

DNA polymerase III holoenzyme from Thermus thermophilus identification, expression, purification of components, and use to reconstitute a processive replicase

DNA replication in bacteria is performed by a specialized multicomponent replicase, the DNA polymerase III holoenzyme, that consist of three essential components: a polymerase, the beta sliding clamp processivity factor, and the DnaX complex clamp-loader. We report here the assembly of the minimal functional holoenzyme from Thermus thermophilus (Tth), an extreme thermophile. The minimal holoenzyme consists of alpha (pol III catalytic subunit), beta (sliding clamp processivity factor), and the essential DnaX (tau/gamma), delta and delta' components of the DnaX complex. We show with purified recombinant proteins that these five components are required for rapid and processive DNA synthesis on long single-stranded DNA templates. Subunit interactions known to occur in DNA polymerase III holoenzyme from mesophilic bacteria including delta-delta' interaction, deltadelta'-tau/gamma complex formation, and alpha-tau interaction, also occur within the Tth enzyme. As in mesophilic holoenzymes, in the presence of a primed DNA template, these subunits assemble into a stable initiation complex in an ATP-dependent manner. However, in contrast to replicative polymerases from mesophilic bacteria, Tth holoenzyme is efficient only at temperatures above 50 degrees C, both with regard to initiation complex formation and processive DNA synthesis. The minimal Tth DNA polymerase III holoenzyme displays an elongation rate of 350 bp/s at 72 degrees C and a processivity of greater than 8.6 kilobases, the length of the template that is fully replicated after a single association event.

A three-domain structure for the delta subunit of the DNA polymerase III holoenzyme delta domain III binds delta' and assembles into the DnaX complex

Using psi-BLAST, we have developed a method for identifying the poorly conserved delta subunit of the DNA polymerase III holoenzyme from all sequenced bacteria. This approach, starting with Escherichia coli delta, leads not only to the identification of delta but also to the DnaX and delta' subunits of the DnaX complex and other AAA(+)-class ATPases. This suggests that, although not an ATPase, delta is related structurally to the other subunits of the DnaX complex that loads the beta sliding clamp processivity factor onto DNA. To test this prediction, we aligned delta sequences with those of delta' and, using the start of delta' Domain III established from its x-ray crystal structure, predicted the juncture between Domains II and III of delta. This putative delta Domain III could be expressed to high levels, consistent with the prediction that it folds independently. delta Domain III, like Domain III of DnaX and delta', assembles by itself into a complex with the other DnaX complex components. Cross-linking studies indicated a contact of delta with the DnaX subunits. These observations are consistent with a model where two tau subunits and one each of the gamma, delta', and delta subunits mutually interact to form a pentameric functional core for the DnaX complex.

Carboxyl-terminal domain III of the delta' subunit of the DNA polymerase III holoenzyme binds delta

The delta and delta' subunits are essential components of the DNA polymerase III holoenzyme, required for assembly and function of the DnaX-complex clamp loader (tau2gammadeltadelta'chipsi). The x-ray crystal structure of delta' contains three structural domains (Guenther, B., Onrust, R., Sali, A., O'Donnell, M., and Kuriyan, J. (1997) Cell 91, 335-345). In this study, we localize the delta-binding domain of delta' to a carboxyl-terminal domain III by quantifying the interaction of delta with a series of delta' fusion proteins lacking specific domains. Purification and immobilization of the fusion proteins were facilitated by the inclusion of a tag containing hexahistidine and a short biotinylation sequence. Both NH2- and COOH-terminal-tagged full-length delta' were soluble and had specific activities comparable with that of native delta'. delta and delta' form a 1:1 heterodimer with a dissociation constant (K(D)) of 5 x 10(-7) m determined by equilibrium sedimentation. The K(D) determined by surface plasmon resonance was comparable. Domain III alone bound delta at an affinity comparable to that of wild type delta', whereas proteins lacking domain III did not bind delta. Using a panel of domain-specific anti-delta' monoclonal antibodies, we found that two of the domain III-specific monoclonal antibodies interfered with delta-delta' interaction and abolished the replication activity of DNA polymerase-III holoenzyme.

tau binds and organizes Escherichia coli replication proteins through distinct domains. Domain IV, located within the unique C terminus of tau, binds the replication fork, helicase, DnaB

Interaction between the tau subunit of the DNA polymerase III holoenzyme and the DnaB helicase is critical for coupling the replicase and the primosomal apparatus at the replication fork (Kim, S., Dallmann, H. G., McHenry, C. S., and Marians, K. J. (1996) Cell 84, 643-650). In the preceding manuscript, we reported the identification of five putative structural domains within the tau subunit (Gao, D., and McHenry, C. (2000) J. Biol. Chem. 275, 4433-4440). As part of our systematic effort to assign functions to each of these domains, we expressed a series of truncated, biotin-tagged tau fusion proteins and determined their ability to bind DnaB by surface plasmon resonance on streptavidin-coated surfaces. Only tau fusion proteins containing domain IV bound DnaB. The DnaB-binding region was further limited to a highly basic 66-amino acid residue stretch within domain IV. Unlike the binding of immobilized tau(4) to the DnaB hexamer, the binding of monomeric domain IV to DnaB(6) was dependent upon the density of immobilized domain IV, indicating that DnaB(6) is bound by more than one tau protomer. This observation implies that both the leading and lagging strand polymerases are tethered to the DnaB helicase via dimeric tau. These double tethers of the leading and lagging strand polymerases proceeding through the tau-tau link and an additional tau-DnaB link are likely important for the dynamic activities of the replication fork.

tau binds and organizes Escherichia coli replication through distinct domains. Partial proteolysis of terminally tagged tau to determine candidate domains and to assign domain V as the alpha binding domain

The tau subunit dimerizes Escherichia coli DNA polymerase III core through interactions with the alpha subunit. In addition to playing critical roles in the structural organization of the holoenzyme, tau mediates intersubunit communications required for efficient replication fork function. We identified potential structural domains of this multifunctional subunit by limited proteolysis of C-terminal biotin-tagged tau proteins. The cleavage sites of each of eight different proteases were found to be clustered within four regions of the tau subunit. The second susceptible region corresponds to the hinge between domain II and III of the highly homologous delta' subunit, and the third region is near the C-terminal end of the tau-delta' alignment (Guenther, B., Onrust, R., Sali, A., O'Donnell, M., and Kuriyan, J. (1997) Cell 91, 335-345). We propose a five-domain structure for the tau protein. Domains I and II are based on the crystallographic structure of delta' by Guenther and colleagues. Domains III-V are based on our protease cleavage results. Using this information, we expressed biotin-tagged tau proteins lacking specific protease-resistant domains and analyzed their binding to the alpha subunit by surface plasmon resonance. Results from these studies indicated that the alpha binding site of tau lies within its C-terminal 147 residues (domain V).

Tau binds and organizes Escherichia coli replication proteins through distinct domains. Domain III, shared by gamma and tau, binds delta delta ' and chi psi

The DnaX complex of the DNA polymerase holoenzyme assembles the beta(2) processivity factor onto the primed template enabling highly processive replication. The key ATPases within this complex are tau and gamma, alternative frameshift products of the dnaX gene. Of the five domains of tau, I-III are shared with gamma In vivo, gamma binds the auxiliary subunits deltadelta' and chipsi (Glover, B. P., and McHenry, C. S. (2000) J. Biol. Chem. 275, 3017-3020). To localize deltadelta' and chipsi binding domains within gamma domains I-III, we measured the binding of purified biotin-tagged DnaX proteins lacking specific domains to deltadelta' and chipsi by surface plasmon resonance. Fusion proteins containing either DnaX domains I-III or domains III-V bound deltadelta' and chipsi subunits. A DnaX protein only containing domains I and II did not bind deltadelta' or chipsi. The binding affinity of chipsi for DnaX domains I-III and domains III-V was the same as that of chipsi for full-length tau, indicating that domain III contained all structural elements required for chipsi binding. Domain III of tau also contained deltadelta' binding sites, although the interaction between deltadelta' and domains III-V of tau was 10-fold weaker than the interaction between deltadelta' and full length tau. The presence of both delta and chipsi strengthened the delta'-C(0)tau interaction by at least 15-fold. Domain III was the only domain common to all of tau fusion proteins whose interaction with delta' was enhanced in the presence of delta and chipsi. Thus, domain III of the DnaX proteins not only contains the deltadelta' and chipsi binding sites but also contains the elements required for the positive cooperative assembly of the DnaX complex.

A novel assembly mechanism for the DNA polymerase III holoenzyme DnaX complex: association of deltadelta' with DnaX(4) forms DnaX(3)deltadelta'

We have constructed a plasmid-borne artificial operon that expresses the six subunits of the DnaX complex of Escherichia coli DNA polymerase III holoenzyme: tau, gamma, delta, delta', chi and psi. Induction of this operon followed by assembly in vivo produced two taugamma mixed DnaX complexes with stoichiometries of tau(1)gamma(2)deltadelta'chipsi and tau(2)gamma(1)deltadelta'chipsi rather than the expected gamma(2)tau(2)deltadelta'chipsi. We observed the same heterogeneity when taugamma mixed DnaX complexes were reconstituted in vitro. Re-examination of homomeric DnaX tau and gamma complexes assembled either in vitro or in vivo also revealed a stoichiometry of DnaX(3)deltadelta'chipsi. Equilibrium sedimentation analysis showed that free DnaX is a tetramer in equilibrium with a free monomer. An assembly mechanism, in which the association of heterologous subunits with a homomeric complex alters the stoichiometry of the homomeric assembly, is without precedent. The significance of our findings to the architecture of the holoenzyme and the clamp-assembly apparatus of all other organisms is discussed.

Escherichia coli DNA polymerase III tau- and gamma-subunit conserved residues required for activity in vivo and in vitro

The Escherichia coli DNA polymerase III tau and gamma subunits are single-strand DNA-dependent ATPases (the latter requires the delta and delta' subunits for significant ATPase activity) involved in loading processivity clamp beta. They are homologous to clamp-loading proteins of many organisms from phages to humans. Alignment of 27 prokaryotic tau/gamma homologs and 1 eukaryotic tau/gamma homolog has refined the sequences of nine previously defined identity and functional motifs. Mutational analysis has defined highly conserved residues required for activity in vivo and in vitro. Specifically, mutations introduced into highly conserved residues within three of those motifs, the P loop, the DExx region, and the SRC region, inactivated complementing activity in vivo and clamp loading in vitro and reduced ATPase catalytic efficiency in vitro. Mutation of a highly conserved residue within a fourth motif, VIc, inactivated clamp-loading activity and reduced ATPase activity in vitro, but the mutant gene, on a multicopy plasmid, retained complementing activity in vivo and the mutant gene also supported apparently normal replication and growth as a haploid, chromosomal allele.

Suppression of a DnaX temperature-sensitive polymerization defect by mutation in the initiation gene, dnaA, requires functional oriC

Temperature sensitivity of DNA polymerization and growth, resulting from mutation of the tau and gamma subunits of Escherichia coli DNA polymerase III, are suppressed by Cs,Sx mutations of the initiator gene, dnaA. These mutations simultaneously cause defective initiation at 20 degrees C. Efficient suppression, defined as restoration of normal growth rate at 39 degrees C to essentially all the cells, depends on functional oriC. Increasing DnaA activity in a strain capable of suppression, by introducing a copy of the wild-type allele, increasing the suppressor gene dosage or introducing a seqA mutation, reversed the suppression. This suggests that the suppression mechanism depends on reduced activity of DnaACs, Sx. Models that assume that suppression results from an initiation defect or from DnaACs,Sx interaction with polymerization proteins during nascent strand synthesis are proposed.

Mutations of acidic residues in RAG1 define the active site of the V(D)J recombinase

The RAG1 and RAG2 proteins collaborate to initiate V(D)J recombination by binding recombination signal sequences (RSSs) and making a double-strand break between the RSS and adjacent coding DNA. Like the reactions of their biochemical cousins, the bacterial transposases and retroviral integrases, cleavage by the RAG proteins requires a divalent metal ion but does not involve a covalent protein/DNA intermediate. In the transposase/integrase family, a triplet of acidic residues, commonly called a DDE motif, is often found to coordinate the metal ion used for catalysis. We show here that mutations in each of three acidic residues in RAG1 result in mutant derivatives that can bind the RSS but whose ability to catalyze either of the two chemical steps of V(D)J cleavage (nicking and hairpin formation) is severely impaired. Because both chemical steps are affected by the same mutations, a single active site appears responsible for both reactions. Two independent lines of evidence demonstrate that at least two of these acidic residues are directly involved in coordinating a divalent metal ion: The substitution of Cys for Asp allows rescue of some catalytic function, whereas an alanine substitution is no longer subject to iron-induced hydroxyl radical cleavage. Our results support a model in which the RAG1 protein contains the active site of the V(D)J recombinase and are interpreted in light of predictions about the structure of RAG1.

The Escherichia coli SOS mutagenesis proteins UmuD and UmuD' interact physically with the replicative DNA polymerase

The Escherichia coli umuDC operon is induced in response to replication-blocking DNA lesions as part of the SOS response. UmuD protein then undergoes an RecA-facilitated self-cleavage reaction that removes its N-terminal 24 residues to yield UmuD'. UmuD', UmuC, RecA, and some form of the E. coli replicative DNA polymerase, DNA polymerase III holoenzyme, function in translesion synthesis, the potentially mutagenic process of replication over otherwise blocking lesions. Furthermore, it has been proposed that, before cleavage, UmuD together with UmuC acts as a DNA damage checkpoint system that regulates the rate of DNA synthesis in response to DNA damage, thereby allowing time for accurate repair to take place. Here we provide direct evidence that both uncleaved UmuD and UmuD' interact physically with the catalytic, proofreading, and processivity subunits of the E. coli replicative polymerase. Consistent with our model proposing that uncleaved UmuD and UmuD' promote different events, UmuD and UmuD' interact differently with DNA polymerase III: whereas uncleaved UmuD interacts more strongly with beta than it does with alpha, UmuD' interacts more strongly with alpha than it does with beta. We propose that the protein-protein interactions we have characterized are part of a higher-order regulatory system of replication fork management that controls when the umuDC gene products can gain access to the replication fork.