Melanoma-Derived DNA Polymerase Theta Variants Exhibit Altered DNA Polymerase Activity.

DNA polymerase θ (Pol θ or POLQ) is primarily involved in repairing double-stranded breaks in DNA through an alternative pathway known as microhomology-mediated end joining (MMEJ) or theta-mediated end joining (TMEJ). Unlike other DNA repair polymerases, Pol θ is thought to be highly error-prone yet critical for cell survival. We have identified several POLQ gene variants from human melanoma tumors that experience altered DNA polymerase activity, including a propensity for incorrect nucleotide selection and reduced polymerization rates compared to WT Pol θ. Variants are 30-fold less efficient at incorporating a nucleotide during repair and up to 70-fold less accurate at selecting the correct nucleotide opposite a templating base. This suggests that aberrant Pol θ has reduced DNA repair capabilities and may also contribute to increased mutagenesis. Moreover, the variants were identified in established tumors, suggesting that cancer cells may use mutated polymerases to promote metastasis and drug resistance.

Melanoma-derived DNA polymerase theta variants exhibit altered DNA polymerase activity.

DNA Polymerase θ (Pol θ or POLQ) is primarily involved in repairing double-stranded breaks in DNA through the alternative pathway known as microhomology-mediated end joining (MMEJ) or theta-mediated end joining (TMEJ). Unlike other DNA repair polymerases, Pol θ is thought to be highly error prone, yet critical for cell survival. We have identified several mutations in the POLQ gene from human melanoma tumors. Through biochemical analysis, we have demonstrated that all three cancer-associated variants experienced altered DNA polymerase activity including a propensity for incorrect nucleotide selection and reduced polymerization rates compared to WT Pol θ. Moreover, the variants are 30 fold less efficient at incorporating a nucleotide during repair and up to 70 fold less accurate at selecting the correct nucleotide opposite a templating base. Taken together, this suggests that aberrant Pol θ has reduced DNA repair capabilities and may also contribute to increased mutagenesis. While this may be beneficial to normal cell survival, the variants were identified in established tumors suggesting that cancer cells may use this promiscuous polymerase to its advantage to promote metastasis and drug resistance.

Novel carbon skeletons activate human NicotinAMide Phosphoribosyl Transferase (NAMPT) enzyme in biochemical assay.

Nicotinamide adenine dinucleotide (NAD) is a central molecule in cellular metabolism that has been implicated in human health, the aging process, and an array of human diseases. NAD is well known as an electron storage molecule, cycling between NAD and the reduced NADH. In addition, NAD is cleaved into nicotinamide and Adenine diphosphate ribose by NAD-consuming enzymes such as sirtuins, PARPs and CD38. There are numerous pathways for the biosynthesis of NAD to maintain a baseline concentration and thus avoid cellular death. The NAD salvage pathway, a two-step process to regenerate NAD after cleavage, is the predominant pathway for humans. Nicotinamide PhosphribosylTransferase (NAMPT) is the rate-limiting enzyme within the salvage path. Exposure to pharmacological modulators of NAMPT has been reported to either deplete or increase NAD levels. This study used a curated set of virtual compounds coupled with biochemical assays to identify novel activators of NAMPT. Autodock Vina generated a ranking of the National Cancer Institute's Diversity Set III molecular library. The library contains a set of organic molecules with diverse functional groups and carbon skeletons that can be used to identify lead compounds. The target NAMPT surface encompassed a novel binding location that included the NAMPT dimerization plane, the openings to the two active site channels, and a portion of the known binding location for NAMPT substrate and product. Ranked molecules were evaluated in a biochemical assay using purified recombinant NAMPT enzyme. Two novel carbon skeletons were confirmed to stimulate NAMPT activity. Compound 20 (NSC9037) is a polyphenolic xanthene derivative in the fluorescein family, while compound 2 (NSC19803) is the polyphenolic myricitrin nature product. Micromolar quantities of compound 20 or compound 2 can double NAMPT's product formation. In addition, natural products that contain high concentrations of polyphenolic flavonoids, similar to myricitrin, also stimulate NAMPT activity. Confirmation of a novel binding site for these compounds will further our understanding of the cellular mechanism leading to NAD homeostasis and better human health outcomes.