Abstract
DNA polymerases of the Y-family are involved in translesion DNA synthesis past different types of DNA damage. Previous work has shown that DNA polymerases eta and iota are localised in replication factories during S phase, where they colocalise one-to-one with PCNA. Cells with factories containing these polymerases accumulate after treatment with DNA damaging agents because replication forks are stalled at sites of damage. We now show that DNA polymerase kappa (pol(kappa)) has a different localisation pattern. Although, like the other Y-family polymerases, it is exclusively localised in the nucleus, pol(kappa) is found in replication foci in only a small proportion of S-phase cells. It does not colocalise in those foci with proliferating cell nuclear antigen (PCNA) in the majority of cells. This reduced number of cells with pol(kappa) foci, when compared with those containing pol(eta) foci, is observed both in untreated cells and in cells treated with hydroxyurea, UV irradiation or benzo[a]pyrene. The C-terminal 97 amino acids of pol(kappa)are sufficient for this limited localisation into nuclear foci, and include a C2HC zinc finger, bipartite nuclear localisation signal and putative PCNA binding site.
Highlights
All cells have evolved a variety of pathways for repairing different types of DNA damage
It does not colocalise in those foci with proliferating cell nuclear antigen (PCNA) in the majority of cells
The C-terminal 97 amino acids of polκ are sufficient for this limited localisation into nuclear foci, and include a C2HC zinc finger, bipartite nuclear localisation signal and putative PCNA binding site
Summary
All cells have evolved a variety of pathways for repairing different types of DNA damage. Despite the efficiency of these pathways, unrepaired lesions remain in the DNA during DNA replication, and most types of DNA damage block the progress of the replication machinery. The replicative DNA polymerases are very efficient and processive, and replicate DNA with high fidelity They are unable to accommodate damaged DNA bases in their active sites and such lesions block their progress. A major way in which mammalian cells overcome this barrier is to use specialised translesion synthesis (TLS) polymerases These polymerases have low efficiencies and fidelities, but are able to replicate DNA past different types of damage (reviewed by Lehmann, 2002; Prakash and Prakash, 2002). Polι is a paralog of polη (Tissier et al, 2000), but despite extensive studies on its activities in vitro, its function in vivo remains unknown
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