Project description:Processive chromosomal replication relies on sliding DNA clamps, which are loaded onto DNA by pentameric clamp loader complexes belonging to the AAA+ family of adenosine triphosphatases (ATPases). We present structures for the ATP-bound state of the clamp loader complex from bacteriophage T4, bound to an open clamp and primer-template DNA. The clamp loader traps a spiral conformation of the open clamp so that both the loader and the clamp match the helical symmetry of DNA. One structure reveals that ATP has been hydrolyzed in one subunit and suggests that clamp closure and ejection of the loader involves disruption of the ATP-dependent match in symmetry. The structures explain how synergy among the loader, the clamp, and DNA can trigger ATP hydrolysis and release of the closed clamp on DNA.

Project description:Transcription activation of bacteriophage T4 late genes is accomplished by a transcription activation complex containing RNA polymerase (RNAP), the promoter specificity factor gp55, the coactivator gp33, and a universal component of cellular DNA replication, the sliding clamp gp45. Although genetic and biochemical studies have elucidated many aspects of T4 late gene transcription, no precise structure of the transcription machinery in the process is available. Here, we report the cryo-EM structures of a gp55-dependent RNAP-promoter open complex and an intact gp45-dependent transcription activation complex. The structures reveal the interactions between gp55 and the promoter DNA that mediate the recognition of T4 late promoters. In addition to the ?R2 homology domain, gp55 has a helix-loop-helix motif that chaperons the template-strand single-stranded DNA of the transcription bubble. Gp33 contacts both RNAP and the upstream double-stranded DNA. Gp45 encircles the DNA and tethers RNAP to it, supporting the idea that gp45 switches the promoter search from three-dimensional diffusion mode to one-dimensional scanning mode.

Project description:Sliding DNA clamps are loaded at a ss/dsDNA junction by a clamp loader that depends on ATP binding for clamp opening. Sequential ATP hydrolysis results in closure of the clamp so that it completely encircles and diffuses on dsDNA. We followed events during loading of an E.?coli ??clamp in real time by using single-molecule FRET (smFRET). Three successive FRET states were retained for 0.3?s, 0.7?s, and 9?min: Hydrolysis of the first ATP molecule by the ? clamp loader resulted in closure of the clamp in 0.3?s, and after 0.7?s in the closed conformation, the clamp was released to diffuse on the dsDNA for at least 9?min. An additional single-molecule polarization study revealed that the interfacial domain of the clamp rotated in plane by approximately 8° during clamp closure. The single-molecule polarization and FRET studies thus revealed the real-time dynamics of the ATP-hydrolysis-dependent 3D conformational change of the ??clamp during loading at a ss/dsDNA junction.

Project description:The structure of the E. coli beta clamp polymerase processivity factor has been solved in complex with primed DNA. Interestingly, the clamp directly binds the DNA duplex and also forms a crystal contact with the ssDNA template strand, which binds into the protein-binding pocket of the clamp. We demonstrate that these clamp-DNA interactions function in clamp loading, perhaps by inducing the ring to close around DNA. Clamp binding to template ssDNA may also serve to hold the clamp at a primed site after loading or during switching of multiple factors on the clamp. Remarkably, the DNA is highly tilted as it passes through the beta ring. The pronounced 22 degrees angle of DNA through beta may enable DNA to switch between multiple factors bound to a single clamp simply by alternating from one protomer of the ring to the other.

Project description:Clamp loaders load ring-shaped sliding clamps onto DNA. Once loaded onto DNA, sliding clamps bind to DNA polymerases to increase the processivity of DNA synthesis. To load clamps onto DNA, an open clamp loader-clamp complex must form. An unresolved question is whether clamp loaders capture clamps that have transiently opened or whether clamp loaders bind closed clamps and actively open clamps. A simple fluorescence-based clamp opening assay was developed to address this question and to determine how ATP binding contributes to clamp opening. A direct comparison of real time binding and opening reactions revealed that the Escherichia coli ? complex binds ? first and then opens the clamp. Mutation of conserved "arginine fingers" in the ? complex that interact with bound ATP decreased clamp opening activity showing that arginine fingers make an important contribution to the ATP-induced conformational changes that allow the clamp loader to pry open the clamp.

Project description:The clamp protein (gp45) of the DNA polymerase III of the bacteriophage T4 is known to bind to DNA and stay attached to it in order to facilitate the process of DNA copying by the polymerase. As part of a project aimed at developing new biomimetic data-encoding systems we have investigated the binding of gp45 to synthetic polymers, that is, rigid, helical polyisocyanopeptides. Molecular modelling studies suggest that the clamp protein may interact with the latter polymers. Experiments aimed at verifying these interactions are presented and discussed.

Project description:Interaction between pairs of Staphylococcus aureus replication proteins was detected in an Escherichia coli based two-hybrid analysis. A reverse two-hybrid system was constructed for selection of compounds that hindered interaction between interacting protein pairs. A number of cyclic peptides, from a library generated by the split intein-mediated circular ligation of peptides and proteins technology, were found to interfere with dimerization of the ?-sliding clamp of the replisome. Two 8-mer peptides were analyzed in more detail. Both inhibited DNA replication, led to SOS induction, altered cell morphology and cell death. The peptides were active when added to bacterial cultures indicating that they could traverse the bacterial membrane to find their intracellular target. Peptide specificity was confirmed by overproduction of the putative target (DnaN) which resulted in resistance. The minimum inhibitory concentration was ?50 ?g/ml for S. aureus cells. These compounds may serve as lead candidates for future development into novel classes of antibiotics as well as provide information on the function of the S. aureus replication process.

Project description:Mismatch repair corrects errors that have escaped polymerase proofreading enhancing replication fidelity by at least two orders of magnitude. The ? and PCNA sliding clamps increase the polymerase processivity during DNA replication and are important at several stages of mismatch repair. Both MutS and MutL, the two proteins that initiate the mismatch repair response, interact with ?. Binding of MutS to ? is important to recruit MutS and MutL to foci. Moreover, the endonuclease activity of human and yeast MutL? is stimulated by PCNA. However, the concrete functions of the processivity clamp in the repair steps preceding DNA resynthesis remain obscure. Here, we demonstrate that the C-terminal domain of MutL encompasses a bona fide ?-binding motif that mediates a weak, yet specific, interaction between the two proteins. Mutation of this conserved motif correlates with defects in mismatch repair, demonstrating that the direct interaction with ? is important for MutL function. The interaction between the C-terminal domain of MutL and ? is conserved in both Bacillus subtilis and Escherichia coli, but the repair defects associated with mutation of this ?-binding motif are more severe in the former, suggesting that this interaction may have a more prominent role in methyl-independent than methyl-directed mismatch repair systems. Together with previously published data, our work strongly suggests that ? may stimulate the endonuclease activity of MutL through its direct interaction with the C-terminal domain of MutL.

Project description:The homodimeric Escherichia coli beta sliding clamp contains two hydrophobic clefts with which proteins involved in DNA replication, repair and damage tolerance interact. Deletion of the C-terminal five residues of beta (beta(C)) disrupted both clefts, severely impairing interactions of the clamp with the DnaX clamp loader, as well as the replicative DNA polymerase, Pol III. In order to determine whether both clefts were required for loading clamp onto DNA, stimulation of Pol III replication and removal of clamp from DNA after replication was complete, we developed a method for purification of heterodimeric clamp proteins comprised of one wild-type subunit (beta(+)), and one beta(C) subunit (beta(+)/beta(C)). The beta(+)/beta(C) heterodimer interacted normally with the DnaX clamp loader, and was loaded onto DNA slightly more efficiently than was beta(+). Moreover, beta(+)/beta(C) interacted normally with Pol III, and stimulated replication to the same extent as did beta(+). Finally, beta(+)/beta(C) was severely impaired for unloading from DNA using either DnaX or the delta subunit of DnaX. Taken together, these findings indicate that a single cleft in the beta clamp is sufficient for both loading and stimulation of Pol III replication, but both clefts are required for unloading clamp from DNA after replication is completed.

Project description: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.