A 21-amino acid peptide from the cysteine cluster II of the family D DNA polymerase from Pyrococcus horikoshii stimulates its nuclease activity which is Mre11-like and prefers manganese ion as the cofactor

Family D DNA polymerase (PolD) is a new type of DNA polymerase possessing polymerization and 3′–5′ exonuclease activities. Here we report the characterization of the nuclease activity of PolD from Pyrococcus horikoshii. By site-directed mutagenesis, we verified that the putative Mre11-like nuclease domain in the small subunit (DP1), predicted according to computer analysis and structure inference reported previously, is the catalytic domain. We show that D363, H365 and H454 are the essential residues, while D407, N453, H500, H563 and H565 are critical residues for the activity. We provide experimental evidence demonstrating that manganese, rather than magnesium, is the preferable metal ion for the nuclease activity of PolD. We also show that DP1 alone is insufficient to perform full catalysis, which additionally requires the formation of the PolD complex and manganese ion. We found that a 21 amino acid, subunit-interacting peptide of the sequence from cysteine cluster II of the large subunit (DP2) stimulates the exonuclease activity of DP1 and the internal deletion mutants of PolD lacking the 21-aa sequence. This indicates that the putative zinc finger motif of the cysteine cluster II is deeply involved in the nucleolytic catalysis.     

Novel structure of an N-terminal domain that is crucial for the dimeric assembly and DNA-binding of an archaeal DNA polymerase D large subunit from Pyrococcus horikoshii

Archaea-specific D-family DNA polymerase forms a heterotetramer consisting of two large polymerase subunits and two small exonuclease subunits. The N-terminal (1–300) domain structure of the large subunit was determined by X-ray crystallography, although ∼50 N-terminal residues were disordered. The determined structure consists of nine alpha helices and three beta strands. We also identified the DNA-binding ability of the domain by SPR measurement. The N-terminal (1–100) region plays crucial roles in the folding of the large subunit dimer by connecting the ∼50 N-terminal residues with their own catalytic region (792–1163).

Structured summary

DP2binds to DP2 by molecular sieving(View interaction)DP2binds to DP2 by fluorescence technology(View interaction)DP2binds to DP2 by circular dichroism(View interaction)     

Characterisation of XlCdc1, a Xenopus homologue of the small (PolD2) subunit of DNA polymerase delta; identification of ten conserved regions I-X based on protein sequence comparisons across ten eukaryotic species

DNA polymerase delta (Pol delta), which plays keys roles in DNA replication, repair and recombination in eukaryotic cells, comprises at least two essential subunits - a large catalytic subunit (PolD1) possessing both DNA polymerase and 3'-5' exonuclease activities, and a smaller subunit (PolD2) whose function is not yet clear. Here we describe the cloning and sequencing of a Xenopus cDNA encoding a homologue of the PolD2 subunit. This protein (designated XlCdc1) is 69% identical to the human PolD2 protein and 34% identical to fission yeast Cdc1. Alignment of PolD2 protein sequences across ten eukaryotic species identifies 36 invariant amino-acid positions. These 36 residues are located within ten conserved regions (designated I-X) likely to have key functional roles. Consistent with this, the mutations in six previously identified yeast mutant PolD2 proteins map within conserved regions III, VI, VII and VIII. Several of the invariant amino acids are also conserved across the archaeal DNA polymerase II DP1 protein family.     

Subunit interaction and regulation of activity through terminal domains of the family D DNA polymerase from Pyrococcus horikoshii

Functions of the terminal domains of the family D DNA polymerase from Pyrococcus horikoshii (PolDPho) were analyzed by making and characterizing various truncated proteins. Based on a co-expression vector developed previously (Shen, Y., Musti, K., Hiramoto, M., Kikuchi, H., Kawabayashi, Y., and Matsui, I. (2001) J. Biol. Chem. 276, 27376-27383), 25 vectors for terminal truncated proteins were constructed. The expressed proteins were characterized in terms of thermostability, subunit interaction, and polymerization and 3'-5' exonuclease activities. The carboxyl-terminal (1255-1332) of the large subunit (DP2Pho) and two regions, the 201-260 and 599-622, of the small subunit (DP1Pho) were found to be critical for the complex formation, and probable subunit interaction of PolDPho. The amino-terminal (1-300) of DP2Pho is essential for the folding of PolDPho and is likely the oligomerization domain of PolDPho. A short region at the extreme C-terminal of DP2Pho (from 1385 to 1434) and the N-terminal of DP1Pho(1-200), which forms a stable protein, are not absolutely necessary for either polymerization or the 3'-5' exonuclease activity. We identified a possible regulatory role of DP1Pho(1-200) for the 3'-5' exonuclease. Deletion of DP1Pho(1-200) increased the exonuclease and DNA binding activities of PolDPho. Adding DP1Pho(1-200) to the truncated protein suppressed the elevated exonuclease activity. We also constructed and analyzed three internal deletion mutants and two site-directed mutants in the region of the putative zinc finger motif (cysteine cluster II) of DP2Pho at the COOH-terminal. We found that the internal region of the zinc finger motif is critical for the 3'-5' exonuclease, but is dispensable for the DNA polymerization.     

Specific interaction between DNA polymerase II (PolD) and RadB, a Rad51/Dmc1 homolog, in Pyrococcus furiosus

Pyrococcus furiosus has an operon containing the DNA polymerase II (PolD) gene and three other genes. Using a two-hybrid screening to examine the interactions of the proteins encoded by the operon, we identified a specific interaction between the second subunit of PolD (DP1) and a Rad51/Dmc1 homologous protein (RadB). To ensure the specific interaction between these two proteins, each gene in the operon was expressed in Escherichia coli or insect cells separately and the products were purified. The in vitro analyses using the purified proteins also showed the interaction between DP1 and RadB. The deletion mutant analysis of DP1 revealed that a region important for binding with RadB is located in the central part of the sequence (amino acid residues 206-498). This region has an overlap to the C-terminal half (amino acids 334-613), which is highly conserved among euryarchaeal DP1s and is essential for the activity of PolD. Our results suggest that, although RadB does not noticeably affect the primer extension ability of PolD in vitro, PolD may utilize the RadB protein in DNA synthesis under certain conditions.     

Family D DNA polymerase interacts with GINS to promote CMG-helicase in the archaeal replisome

Genomic DNA replication requires replisome assembly. We show here the molecular mechanism by which CMG (GAN–MCM–GINS)-like helicase cooperates with the family D DNA polymerase (PolD) in Thermococcus kodakarensis. The archaeal GINS contains two Gins51 subunits, the C-terminal domain of which (Gins51C) interacts with GAN. We discovered that Gins51C also interacts with the N-terminal domain of PolD’s DP1 subunit (DP1N) to connect two PolDs in GINS. The two replicases in the replisome should be responsible for leading- and lagging-strand synthesis, respectively. Crystal structure analysis of the DP1N–Gins51C–GAN ternary complex was provided to understand the structural basis of the connection between the helicase and DNA polymerase. Site-directed mutagenesis analysis supported the interaction mode obtained from the crystal structure. Furthermore, the assembly of helicase and replicase identified in this study is also conserved in Eukarya. PolD enhances the parental strand unwinding via stimulation of ATPase activity of the CMG-complex. This is the first evidence of the functional connection between replicase and helicase in Archaea. These results suggest that the direct interaction of PolD with CMG-helicase is critical for synchronizing strand unwinding and nascent strand synthesis and possibly provide a functional machinery for the effective progression of the replication fork.     

DNA polymerase D temporarily connects primase to the CMG-like helicase before interacting with proliferating cell nuclear antigen

The eukaryotic replisome is comprised of three family-B DNA polymerases (Polα, δ and ϵ). Polα forms a stable complex with primase to synthesize short RNA-DNA primers, which are subsequently elongated by Polδ and Polϵ in concert with proliferating cell nuclear antigen (PCNA). In some species of archaea, family-D DNA polymerase (PolD) is the only DNA polymerase essential for cell viability, raising the question of how it alone conducts the bulk of DNA synthesis. We used a hyperthermophilic archaeon, Thermococcus kodakarensis, to demonstrate that PolD connects primase to the archaeal replisome before interacting with PCNA. Whereas PolD stably connects primase to GINS, a component of CMG helicase, cryo-EM analysis indicated a highly flexible PolD–primase complex. A conserved hydrophobic motif at the C-terminus of the DP2 subunit of PolD, a PIP (PCNA-Interacting Peptide) motif, was critical for the interaction with primase. The dissociation of primase was induced by DNA-dependent binding of PCNA to PolD. Point mutations in the alternative PIP-motif of DP2 abrogated the molecular switching that converts the archaeal replicase from de novo to processive synthesis mode.     

Characterization of the 3' exonuclease subunit DP1 of Methanococcus jannaschii replicative DNA polymerase D

The B-subunits associated with the replicative DNA polymerases are conserved from Archaea to humans, whereas the corresponding catalytic subunits are not related. The latter belong to the B and D DNA polymerase families in eukaryotes and archaea, respectively. Sequence analysis places the B-subunits within the calcineurin-like phosphoesterase superfamily. Since residues implicated in metal binding and catalysis are well conserved in archaeal family D DNA polymerases, it has been hypothesized that the B-subunit could be responsible for the 3′-5′ proofreading exonuclease activity of these enzymes. To test this hypothesis we expressed Methanococcus jannaschii DP1 (MjaDP1), the B-subunit of DNA polymerase D, in Escherichia coli, and demonstrate that MjaDP1 functions alone as a moderately active, thermostable, Mn²⁺-dependent 3′-5′ exonuclease. The putative polymerase subunit DP2 is not required. The nuclease activity is strongly reduced by single amino acid mutations in the phosphoesterase domain indicating the requirement of this domain for the activity. MjaDP1 acts as a unidirectional, non-processive exonuclease preferring mispaired nucleotides and single-stranded DNA, suggesting that MjaDP1 functions as the proofreading exonuclease of archaeal family D DNA polymerase.     

Distinct domain functions regulating de novo DNA synthesis of thermostable DNA primase from hyperthermophile Pyrococcus horikoshii

DNA primases are essential components of the DNA replication apparatus in every organism. Reported here are the biochemical characteristics of a thermostable DNA primase from the thermophilic archaeon Pyrococcus horikoshii, which formed the oligomeric unit L(1)S(1) and synthesized long DNA primers 10 times more effectively than RNA primers. The N-terminal (25KL) and C-terminal halves (20KL) of the large subunit (L) play distinct roles in regulating de novo DNA synthesis of the small catalytic subunit (S). The 25KL domain has a dual function. One function is to depress the large affinity of the intrasubunit domain 20KL for the template DNA until complex (L(1)S(1) unit) formation. The other function is to tether the L subunit tightly to the S subunit, probably to promote effective interaction between the intrasubunit domain 20KL and the active center of the S subunit. The 20KL domain is a central factor to enhance the de novo DNA synthesis activity of the catalytic S subunit since the total affinity of the L(1)S(1) unit is mainly derived from the affinity of 20KL, which is elevated more than 10 times by the heterodimer formation, presumably due to the cancellation of the inhibitory activity of 25KL through tight binding to the S subunit.     

Ku heterodimer binds to both ends of the Werner protein and functional interaction occurs at the Werner N-terminus

The human Werner syndrome protein, WRN, is a member of the RecQ helicase family and contains 3′→5′ helicase and 3′→5′ exonuclease activities. Recently, we showed that the exonuclease activity of WRN is greatly stimulated by the human Ku heterodimer protein. We have now mapped this interaction physically and functionally. The Ku70 subunit specifically interacts with the N-terminus (amino acids 1–368) of WRN, while the Ku80 subunit interacts with its C-terminus (amino acids 940– 1432). Binding between Ku70 and the N-terminus of WRN (amino acids 1–368) is sufficient for stimulation of WRN exonuclease activity. A mutant Ku heterodimer of full-length Ku80 and truncated Ku70 (amino acids 430–542) interacts with C-WRN but not with N-WRN and cannot stimulate WRN exonuclease activity. This emphasizes the functional significance of the interaction between the N-terminus of WRN and Ku70. The interaction between Ku80 and the C-terminus of WRN may modulate some other, as yet unknown, function. The strong interaction between Ku and WRN suggests that these two proteins function together in one or more pathways of DNA metabolism.     

Molecular basis for interaction between Icap1 alpha PTB domain and beta 1 integrin.

Icap1 alpha is a 200-amino acid protein that binds to the COOH-terminal 13 amino acids ((786)AVTTVVNPKYEGK(798)) of the integrin beta(1) subunit. Alanine scanning mutagenesis of this region revealed that Val(787), Val(790), and (792)NPKY(795) are critical for Icap1 alpha binding. The NPXY motif is a known binding substrate for phosphotyrosine binding (PTB) domain proteins. The sequences of Icap1 alpha, residues 58--200, and the beta(1) integrin, residues 786-797, were aligned to the available PTB-peptide structures to generate a high quality structural model. Site-directed mutagenesis showed that Leu(135), Ile(138), and Ile(139) of Icap1 alpha, residues predicted by the model to be in close proximity to (792)NPKY(795), and Leu(82) and Tyr(144), residues expected to form a hydrophobic pocket near Val(787), are required for the Icap1 alpha-beta(1) integrin interaction. These findings indicate that Icap1 alpha is a PTB domain protein, which recognizes the NPXY motif of beta(1) integrin. Furthermore, our date suggest that an interaction between Val(787) and the hydrophobic pocket created by Leu(82) and Tyr(144) of Icap1 alpha forms the basis for the specificity of Icap1 alpha for the beta(1) integrin subunit.     

The screening of expression and purification conditions for replicative DNA polymerase associated B-subunits, assignment of the exonuclease activity to the C-terminus of archaeal pol D DP1 subunit

The B-subunits of replicative DNA polymerases belong to the superfamily of calcineurin-like phosphoesterases and are conserved from Archaea to humans. Recently we and others have shown that the B-subunit (DP1) of the archaeal family D DNA polymerase is responsible for proofreading 3'-5' exonuclease activity. The similarity of B-subunit sequences implies a common fold, but since the key catalytic and metal binding residues of the phosphoesterase domain are disrupted in the eukaryotic B-subunits, their common function has not been identified. To study the structure and activities of B-subunits in more detail, we expressed 13 different recombinant B-subunits in Escherichia coli. We found that the solubility of a protein could be predicted from the calculated GRAVY score. These scores were useful for the selection of proteins for successful expression. We optimized the expression and purification of Methanocaldococcus (Methanococcus) jannaschii DP1 of DNA polymerase D (MjaDP1) and show that the protein co-purifies with a thermostable nuclease activity. Truncation of the protein indicates that the N-terminus (aa 1-134) is not needed for catalysis. The C-terminal part of the protein containing both the calcineurin-like phosphoesterase domain and the OB-fold is sufficient for the nuclease activity.     

Functional interaction between MutL and 3′-5′ Exonuclease X in Escherichia coli

Exonuclease X is a 3′-5′ distributive exonuclease that functions in DNA recombination and repair. It undergoes multiple rounds of binding, hydrolysis, and release to degrade long substrate molecules and thus is very inefficient. In order to identify a cofactor that elevates the excision activity of ExoX, we screened many proteins involved in repair and recombination. We observed that MutL greatly promoted the exonuclease activity of ExoX, and then verified the interaction between MutL and ExoX using SPR and Far-Western analysis. This promotion is independent of ATP and the DNA-binding activity of MutL. We constructed two deletion mutants to analyze this interaction and its regulation of ExoX activity, and found that this functional interaction with ExoX is mainly due to ionic interactions with the N-terminus of MutL. This adds a new role to MutL and gives a clue to MutL’s possible regulation on other DnaQ family exonuclease members.     

Characterization and mutational analysis of the RecQ core of the bloom syndrome protein

Bloom syndrome protein forms an oligomeric ring structure and belongs to a group of DNA helicases showing extensive homology to the Escherichia coli DNA helicase RecQ, a suppressor of illegitimate recombination. After over-production in E.coli, we have purified the RecQ core of BLM consisting of the DEAH, RecQ-Ct and HRDC domains (amino acid residues 642-1290). The BLM(642-1290) fragment could function as a DNA-stimulated ATPase and as a DNA helicase, displaying the same substrate specificity as the full-size protein. Gel-filtration experiments revealed that BLM(642-1290) exists as a monomer both in solution and in its single-stranded DNA-bound form, even in the presence of Mg(2+) and ATPgammaS. Rates of ATP hydrolysis and DNA unwinding by BLM(642-1290) showed a hyperbolic dependence on ATP concentration, excluding a co-operative interaction between ATP-binding sites. Using a lambda Spi(-) assay, we have found that the BLM(642-1290) fragment is able to partially substitute for the RecQ helicase in suppressing illegitimate recombination in E.coli. A deletion of 182 C-terminal amino acid residues of BLM(642-1290), including the HRDC domain, resulted in helicase and single-stranded DNA-binding defects, whereas kinetic parameters for ATP hydrolysis of this mutant were close to the BLM(642-1290) values. This confirms the prediction that the HRDC domain serves as an auxiliary DNA-binding domain. Mutations at several conserved residues within the RecQ-Ct domain of BLM reduced ATPase and helicase activities severely as well as single-stranded DNA-binding of the enzyme. Together, these data define a minimal helicase domain of BLM and demonstrate its ability to act as a suppressor of illegitimate recombination.     

DNA polymerases BI and D from the hyperthermophilic archaeon Pyrococcus furiosus both bind to proliferating cell nuclear antigen with their C-terminal PIP-box motifs

Proliferating cell nuclear antigen (PCNA) is the sliding clamp that is essential for the high processivity of DNA synthesis during DNA replication. Pyrococcus furiosus, a hyperthermophilic archaeon, has at least two DNA polymerases, polymerase BI (PolBI) and PolD. Both of the two DNA polymerases interact with the archaeal P. furiosus PCNA (PfuPCNA) and perform processive DNA synthesis in vitro. This phenomenon, in addition to the fact that both enzymes display 3'-5' exonuclease activity, suggests that both DNA polymerases work in replication fork progression. We demonstrated here that both PolBI and PolD functionally interact with PfuPCNA at their C-terminal PIP boxes. The mutant PolBI and PolD enzymes lacking the PIP-box sequence do not respond to the PfuPCNA at all in an in vitro primer extension reaction. This is the first experimental evidence that the PIP-box motif, located at the C termini of the archaeal DNA polymerases, is actually critical for PCNA binding to form a processive DNA-synthesizing complex.     

人Calpain1与心脏结构蛋白的相互作用

为探讨人calpain1与心脏结构蛋白之间的相互作用 ,采用酵母双杂交体系筛选与人calpain1大亚基相互作用的蛋白质 ,通过DNA序列测定及BLAST分析同源性 ,获得了阳性克隆 12 (pACT2 12 ) ,16 (pACT2 16 ) ,2 2 (pACT2 2 2 )和 37(pACT2 37)等 .12和 2 2分别与人心脏α肌动蛋白 (humancardiacmusclealpha actin ,ACTC)有 99%和 10 0 %同源性 .16和 37分别与人心脏的肌球蛋白结合蛋白C(humancardiacmyosin bindingproteinC ,MYBPC3)和人α2 辅肌动蛋白 (humancardiacalpha 2actinin ,ACTN2 )有 10 0 %同源性 .这些阳性克隆均属于心脏中心肌细胞的结构蛋白 ,参与心肌细胞的收缩运动 .为鉴定calpain1大亚基的哪些结构域可能参与这些相互作用 ,阳性克隆再分别与含有人calpain1大亚基结构域Ⅱ、Ⅲ、Ⅳ的诱饵质粒共同转化AH10 9进行酵母双杂交 ,发现pACT2 12(ACTC)和pACT2 16 (MYBPC3)均能与全长人calpain1大亚基的结构域Ⅱ和Ⅲ相互作用 ;pACT2 16(MYBPC3)还能与大亚基的结构域Ⅳ作用 ;而pACT2 37(ACTN)虽能与全长人calpain1大亚基作用 ,却不与其单独的结构域Ⅱ、Ⅲ或Ⅳ发生作用 .定量分析阳性克隆与人calpain1大亚基作用的强弱的结果显示 ,pACT2 12、16或 37分别与诱饵质粒pGBKT7 CANP共同转化AH10 9后     

NMR study of short β(1-3)-glucans provides insights into the structure and interaction with Dectin-1

β(1-3)-Glucans, abundant in fungi, have the potential to activate the innate immune response against various pathogens. Although part of the action is exerted through the C-type lectin-like receptor Dectin-1, details of the interaction mechanism with respect to glucan chain-length remain unclear. In this study, we investigated a set of short β(1-3)-glucans with varying degree of polymerization (DP); 3, 6, 7, 16, and laminarin (average DP; 25), analyzing the relationship between the structure and interaction with the C-type lectin-like domain (CTLD) of Dectin-1. The interaction of short β(1-3)-glucans (DP6, DP16, and laminarin) with the CTLD of Dectin-1 was systematically analyzed by ¹H-NMR titration as well as by saturation transfer difference (STD)-NMR. The domain interacted weakly with DP6, moderately with DP16 and strongly with laminarin, the latter plausibly forming oligomeric protein-laminarin complexes. To obtain structural insights of short β(1-3)-glucans, the exchange rates of hydroxy protons were analyzed by deuterium induced ¹³C-NMR isotope shifts. The hydroxy proton at C4 of laminarin has slower exchange with the solvent than those of DP7 and DP16, suggesting that laminarin has a secondary structure. Diffusion ordered spectroscopy revealed that none of the short β(1-3)-glucans including laminarin forms a double or triple helix in water. Insights into the interaction of the short β(1-3)-glucans with Dectin-1 CTLD provide a basis to understand the molecular mechanisms of β-glucan recognition and cellular activation by Dectin-1.     

The solution structure of the amino-terminal domain of human DNA polymerase epsilon subunit B is homologous to C-domains of AAA+ proteins

DNA polymerases α, δ and ε are large multisubunit complexes that replicate the bulk of the DNA in the eukaryotic cell. In addition to the homologous catalytic subunits, these enzymes possess structurally related B subunits, characterized by a carboxyterminal calcineurin-like and an aminoproximal oligonucleotide/oligosaccharide binding-fold domain. The B subunits also share homology with the exonuclease subunit of archaeal DNA polymerases D. Here, we describe a novel domain specific to the N-terminus of the B subunit of eukaryotic DNA polymerases ε. The N-terminal domain of human DNA polymerases ε (Dpoe2NT) expressed in Escherichia coli was characterized. Circular dichroism studies demonstrated that Dpoe2NT forms a stable, predominantly α-helical structure. The solution structure of Dpoe2NT revealed a domain that consists of a left-handed superhelical bundle. Four helices are arranged in two hairpins and the connecting loops contain short β-strand segments that form a short parallel sheet. DALI searches demonstrated a striking structural similarity of the Dpoe2NT with the α-helical subdomains of ATPase associated with various cellular activity (AAA+) proteins (the C-domain). Like C-domains, Dpoe2NT is rich in charged amino acids. The biased distribution of the charged residues is reflected by a polarization and a considerable dipole moment across the Dpoe2NT. Dpoe2NT represents the first C-domain fold not associated with an AAA+ protein.     

Detection of an epitope, not required for polymerization, that is conserved between E.coli DNA polymerases I and III and bacteriophage T4 DNA polymerase.

Monoclonal antibodies directed against the alpha subunit of the DNA polymerase III holoenzyme (1) of E. coli were tested for cross-reactivity with a variety of polymerases. We found that one monoclonal antibody bound to E. coli DNA polymerase I as well as to DNA polymerase III. A weaker, but specific, interaction was also detected with T4 DNA polymerase. We exploited the proteolysis procedure developed by Setlow, Brutlag and Kornberg (2) to determine which domain of DNA polymerase I contained the conserved epitope. Contrary to expectations, it was not found in the polymerase domain, but in the 5'----3' exonuclease domain. This reveals a sequence or structure, sufficiently important to be conserved among these polymerases, that is not directly involved in the polymerization reaction.     

Characterization of physical interaction between replication initiator protein DnaA and replicative helicase from <Emphasis Type="Italic">Mycobacterium tuberculosis</Emphasis> H37Rv

In the pathogenic Mycobacterium tuberculosis H37Rv, the causative agent of tuberculosis, the genetic and biochemical mechanisms for initiation of DNA replication are largely unknown. In the present study, we have characterized the physical interactions between M. tuberculosis DnaA and DnaB using both in vivo methods, such as bacterial two-hybrid assays, and in vitro techniques, such as surface plasmon resonance (SPR) and Pull-down/Western blotting. The full-length N-terminus (1–206 residues) of DnaB was found to interact with DnaA, while the shorter N-terminal domain of DnaB (1–125 residues), which lacked the linker region, did not. Further SPR and electrophoretic mobility shift assays indicated that the N-terminus (1–206 residues) of DnaB also had a critical role in regulating DnaA complex formation at the origin of replication (OriC). This regulatory effect was not obviously observed for DNA substrates containing only two DnaA-boxes. This is the first report showing a physical interaction between DnaA and replicative helicase DnaB from M. tuberculosis and the role in subsequent DnaA-OriC interactions. The findings reported here further the understanding of the regulatory mechanisms for initiation of DNA replication in this important human pathogen.