Abstract
DNA repair pathways are essential for maintaining genome stability. DNA polymerase beta plays a critical role in base-excision repair in vivo. DNA polymerase lambda, a recently identified X-family homolog of DNA polymerase beta, is hypothesized to be a second polymerase involved in base-excision repair. The full-length DNA polymerase lambda is comprised of three domains: a C-terminal DNA polymerase beta-like domain, an N-terminal BRCA1 C-terminal domain, and a previously uncharacterized proline-rich domain. Strikingly, pre-steady-state kinetic analyses reveal that, although human DNA polymerase lambda has almost identical fidelity to human DNA polymerase beta, the C-terminal DNA polymerase beta-like domain alone displays a dramatic, up to 100-fold loss in fidelity. We further demonstrate that the non-enzymatic proline-rich domain confers the increase in fidelity of DNA polymerase lambda by significantly lowering incorporation rate constants of incorrect nucleotides. Our studies illustrate a novel mechanism, in which the DNA polymerase fidelity is controlled not by an accessory protein or a proofreading exonuclease domain but by an internal regulatory domain.
Highlights
DNA repair mechanisms and cell-cycle checkpoint regulation upon DNA damage [5]
The biological role of pol is unknown. pol has been suggested to play a role in DNA repair synthesis associated with meiosis [1], in “short-patch” base excision repair (BER) [15, 16], in the proliferating cell nuclear antigen-dependent BER pathway [15, 17], and in the repair of double-stranded breaks through non-homologous end-joining pathways [15, 18, 19]
We expect the full-length pol to have similar polymerase activity as tpol and follow the same minimal mechanism shown in Scheme 1
Summary
DNA repair mechanisms and cell-cycle checkpoint regulation upon DNA damage [5]. The proline-rich domain, which contains multiple serine, threonine, and proline residues, is found to functionally suppress the polymerase activity of pol [6] and limit strand-displacement synthesis [7]. Pol has been suggested to play a role in DNA repair synthesis associated with meiosis [1], in “short-patch” BER [15, 16], in the proliferating cell nuclear antigen-dependent BER pathway [15, 17], and in the repair of double-stranded breaks through non-homologous end-joining pathways [15, 18, 19]. All these potential physiological functions require pol to possess gap-filling polymerase activity. Our kinetic results strongly support a role for pol as the second polymerase in BER
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