Abstract
The POLQ gene encodes DNA polymerase θ, a 2590 amino acid protein product harboring DNA-dependent ATPase, template-dependent DNA polymerase, dNTP-dependent endonuclease, and 5′–dRP lyase functions. Polymerase θ participates at an essential step of a DNA double-strand break repair pathway able to join 5′-resected substrates by locating and pairing microhomologies present in 3′-overhanging single-stranded tails, cleaving the extraneous 3′-DNA by dNTP-dependent end-processing, before extending the nascent 3′ end from the microhomology annealing site. Metazoans require polymerase θ for full resistance to DNA double-strand break inducing agents but can survive knockout of the POLQ gene. Cancer cells with compromised homologous recombination, or other DNA repair defects, over-utilize end-joining by polymerase θ and often over-express the POLQ gene. This dependency points to polymerase θ as an ideal drug target candidate and multiple drug-development programs are now preparing to enter clinical trials with small-molecule inhibitors. Specific inhibitors of polymerase θ would not only be predicted to treat BRCA-mutant cancers, but could thwart accumulated resistance to current standard-of-care cancer therapies and overcome PARP-inhibitor resistance in patients. This article will discuss synthetic lethal strategies targeting polymerase θ in DNA damage-response-deficient cancers and summarize data, describing molecular structures and enzymatic functions.
Highlights
Faithful segregation of chromosomes by equal sharing of genetic material between daughter cells is critical for genomic stability
Checkpoint activation is an essential component of the DNA damage response (DDR), ensuring that DNA repair machinery has time to restore DNA before chromosomes are subjected to the physical stresses of cell division
Animals with defects in genes coding for DNA repair enzymes or other DDR proteins may survive with elevated rates of genomic instability
Summary
Faithful segregation of chromosomes by equal sharing of genetic material between daughter cells is critical for genomic stability. Signaling cascades known as checkpoints evolved to arrest the cell cycle in response to DNA lesions capable of skewing the distribution of inherited genetic material [1]. Checkpoint activation is an essential component of the DNA damage response (DDR), ensuring that DNA repair machinery has time to restore DNA before chromosomes are subjected to the physical stresses of cell division. The field of precision oncology looks to exploit weaknesses inherent in cancer cells by testing the hypothesis that specific genetic backgrounds underpin cancer predisposition or fortify the tumor microenvironment, and are treatable by likewise specific and targeted therapies [2,3].
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