Substrate-dependent millisecond domain motions in DNA polymerase β

DNA polymerase β (Pol β) is a 39-kDa enzyme that performs the vital cellular function of repairing damaged DNA. Mutations in Pol β have been linked to various cancers, and these mutations are further correlated with altered Pol β enzymatic activity. The fidelity of correct nucleotide incorporation into damaged DNA is essential for Pol β repair function, and several studies have implicated conformational changes in Pol β as a determinant of this repair fidelity. In this work, the rate constants for domain motions in Pol β have been determined by solution NMR relaxation dispersion for the apo and substrate-bound, binary forms of Pol β. In apo Pol β, molecular motions, primarily isolated to the DNA lyase domain, are observed to occur at 1400 s(-1). Additional analysis suggests that these motions allow apo Pol β to sample a conformation similar to the gapped DNA-substrate-bound form. Upon binding DNA, these lyase domain motions are significantly quenched, whereas evidence for conformational motions in the polymerase domain becomes apparent. These NMR studies suggest an alteration in the dynamic landscape of Pol β due to substrate binding. Moreover, a number of the flexible residues identified in this work are also the location of residues, which upon mutation lead to cancer phenotypes in vivo, which may be due to the intimate role of protein motions in Pol β fidelity.     

Social complexity in bees is not sufficient to explain lack of reversions to solitary living over long time scales

Background  

The major lineages of eusocial insects, the ants, termites, stingless bees, honeybees and vespid wasps, all have ancient origins (≥ 65 mya) with no reversions to solitary behaviour. This has prompted the notion of a 'point of no return' whereby the evolutionary elaboration and integration of behavioural, genetic and morphological traits over a very long period of time leads to a situation where reversion to solitary living is no longer an evolutionary option.     

Mammalian DNA polymerase beta can substitute for DNA polymerase I during DNA replication in Escherichia coli.

Mammalian DNA polymerase beta is the smallest known eukaryotic polymerase and is expressed as an active protein in Escherichia coli harboring a plasmid containing its cDNA. Since some catalytic functions of DNA polymerase beta and E. coli DNA polymerase I are similar, we wished to determine if DNA polymerase beta could substitute for DNA polymerase I in bacteria. We found that the expression of mammalian DNA polymerase beta in E. coli restored growth in a DNA polymerase I-defective bacterial mutant. Sucrose density gradient analysis revealed that DNA polymerase beta complements the replication defect in the mutant by increasing the rate of joining of Okazaki fragments. These findings demonstrate that DNA polymerase beta, believed to function in DNA repair in mammalian cells, can also function in DNA replication. Moreover, this complementation system will permit study of the in vivo function of altered species of DNA polymerase beta, an analysis currently precluded by the difficulty in isolating mutants in mammalian cells.     

The Asp285 variant of DNA polymerase beta extends mispaired primer termini via increased nucleotide binding

Endogenous DNA damage occurs at a rate of at least 20,000 lesions per cell per day. Base excision repair (BER) is a key pathway for maintaining genome stability. Several pol beta variants were identified as conferring resistance to 3'-azido-3'-deoxythymidine (AZT) in Escherichia coli (Kosa et al. (1999) J. Biol. Chem. 274, 3851-3858). Detailed biochemical studies on one of these AZT-resistant variants, His285 to Asp, have shown that the H285D variant of pol beta possesses pre-steady-state kinetics that are similar to the wild-type polymerase. In gap filling assays with 5-bp gapped DNA, H285D showed a slight mutator phenotype. In depth single turnover kinetic analysis revealed that H285D is much more efficient than wild-type pol beta at extending mispaired primer termini. This mispair extension property of H285D is attributed to a greatly increased binding to the next correct nucleotide in the presence of a mispair. This change in K d(dNTP),app is not accompanied by a change in k pol; values for k pol are the same for both H285D and wild-type. Close examination of available structural data, as well as molecular modeling, has shown that residue 285 is able to make several stabilizing contacts in the fingers domain of the polymerase, and the introduction of a negatively charged side chain could have important effects on the enzyme. It is postulated that the loss of the contact between His285, Lys289, and Ile323 is responsible for the ability of H285D to extend mispairs through disruption of contacts near the C-terminal end of pol beta and propagation into the nucleotide binding pocket.     

The Leu22Pro tumor-associated variant of DNA polymerase beta is dRP lyase deficient

Approximately 30% of human tumors characterized to date express DNA polymerase beta (pol β) variant proteins. Two of the polymerase beta cancer-associated variants are sequence-specific mutators, and one of them binds to DNA but has no polymerase activity. The Leu22Pro (L22P) DNA polymerase beta variant was identified in a gastric carcinoma. Leu22 resides within the 8 kDa amino terminal domain of DNA polymerase beta, which exhibits dRP lyase activity. This domain catalyzes the removal of deoxyribose phosphate during short patch base excision repair. We show that this cancer-associated variant has very little dRP lyase activity but retains its polymerase activity. Although residue 22 has no direct contact with the DNA, we report here that the L22P variant has reduced DNA-binding affinity. The L22P variant protein is deficient in base excision repair. Molecular dynamics calculations suggest that alteration of Leu22 to Pro changes the local packing, the loop connecting helices 1 and 2 and the overall juxtaposition of the helices within the N-terminal domain. This in turn affects the shape of the binding pocket that is required for efficient dRP lyase catalysis.