The backbone NMR resonance assignments of the stabilized E. coli ß clamp.

The 81 kDa E. coli ß clamp is a ring-shaped head-to-tail homodimer that encircles DNA and plays a central role in bacterial DNA replication by serving as a processivity factor for DNA polymerases and a binding platform for other DNA replication and repair proteins. Here we report the backbone 1H, 15N, and 13C NMR resonance assignments of the stabilized T45R/S107R ß clamp variant obtained using standard TROSY-based triple-resonance experiments (BMRB 52548). The backbone assignments were aided by 13C and 15N edited NOESY experiments, allowing us to utilize our previously reported assignments of the ß clamp ILV side-chain methyl groups (BMRB 51430, 51431). The backbone assignments of the T45R/S107R ß clamp variant were transferred to the wild-type ß clamp using a minimal set of TROSY-based 15N edited NOESY, NHCO and NHCA experiments (BMRB 52549). The reported backbone and previous ILV side-chain resonance assignments will enable NMR studies of the ß clamp interactions and dynamics using amide and methyl groups as probes.

ILV methyl NMR resonance assignments of the 81 kDa E. coli ß-clamp.

The ring-shaped E. coli ß-clamp protein is an 81 kDa head-to-tail homodimer, which serves as a processivity factor anchoring the replicative polymerase to DNA, thereby increasing replication processivity and speed. In addition, it facilitates numerous protein transactions that take place on DNA during replication, repair, and damage response. We used a structure-based approach to obtain nearly complete Ile, Leu and Val side-chain methyl NMR resonance assignments of the wild-type ß-clamp and its stabilized T45R/S107R variant based on site directed mutagenesis and the analysis of methyl-methyl NOESY data. The obtained assignments will facilitate future studies of the ß-clamp interactions and dynamics.

Dynamics of the E. coli ß-Clamp Dimer Interface and Its Influence on DNA Loading.

The ring-shaped sliding clamp proteins have crucial roles in the regulation of DNA replication, recombination, and repair in all organisms. We previously showed that the Escherichia coli ß-clamp is dynamic in solution, transiently visiting conformational states in which Domain 1 at the dimer interface is more flexible and prone to unfolding. This work aims to understand how the stability of the dimer interface influences clamp-opening dynamics and clamp loading by designing and characterizing stabilizing and destabilizing mutations in the clamp. The variants with stabilizing mutations conferred similar or increased thermostability and had similar quaternary structure as compared to the wild type. These variants stimulated the ATPase function of the clamp loader, complemented cell growth of a temperature-sensitive strain, and were successfully loaded onto a DNA substrate. The L82D and L82E I272A variants with purported destabilizing mutations had decreased thermostability, did not complement the growth of a temperature-sensitive strain, and had weakened dimerization as determined by native trapped ion mobility spectrometry-mass spectrometry. The ß L82E variant had a reduced melting temperature but dimerized and complemented growth of a temperature-sensitive strain. All three clamps with destabilizing mutations had perturbed loading on DNA. Molecular dynamics simulations indicate altered hydrogen-bonding patterns at the dimer interface, and cross-correlation analysis showed the largest perturbations in the destabilized variants, consistent with the observed change in the conformations and functions of these clamps.

Structural Approach To Identify a Lead Scaffold That Targets the Translesion Synthesis Polymerase Rev1.

Translesion synthesis (TLS) is a mechanism of replication past damaged DNA through which multiple forms of human cancer survive and acquire resistance to first-line genotoxic chemotherapies. As such, TLS is emerging as a promising target for the development of a new class of anticancer agents. The C-terminal domain of the DNA polymerase Rev1 (Rev1-CT) mediates assembly of the functional TLS complex through protein-protein interactions (PPIs) with Rev1 interacting regions (RIRs) of several other TLS DNA polymerases. Utilizing structural knowledge of the Rev1-CT/RIR interface, we have identified the phenazopyridine scaffold as an inhibitor of this essential TLS PPI. We demonstrate direct binding of this scaffold to Rev1-CT, and the synthesis and evaluation of a small series of analogues have provided important structure-activity relationships for further development of this scaffold. Furthermore, we utilized the umbrella sampling method to predict the free energy of binding to Rev1-CT for each of our analogues. Binding energies calculated through umbrella sampling correlated well with experimentally determined IC50 values, validating this computational tool as a viable approach to predict the biological activity for inhibitors of the Rev1-CT/RIR PPI.