Abstract
DNA-dependent protein kinase (DNA-PK) is involved in joining DNA double-strand breaks induced by ionizing radiation or V(D)J recombination. The kinase is activated by DNA ends and composed of a DNA binding subunit, Ku, and a catalytic subunit, DNA-PK(CS). To define the DNA structure required for kinase activation, we synthesized a series of DNA molecules and tested their interactions with purified DNA-PK(CS). The addition of unpaired single strands to blunt DNA ends increased binding and activation of the kinase. When single-stranded loops were added to the DNA ends, binding was preserved, but kinase activation was severely reduced. Obstruction of DNA ends by streptavidin reduced both binding and activation of the kinase. Significantly, short single-stranded oligonucleotides of 3-10 bases were capable of activating DNA-PK(CS). Taken together, these data indicate that kinase activation involves a specific interaction with free single-stranded DNA ends. The structure of DNA-PK(CS) contains an open channel large enough for double-stranded DNA and an adjacent enclosed cavity with the dimensions of single-stranded DNA. The data presented here support a model in which duplex DNA binds to the open channel, and a single-stranded DNA end is inserted into the enclosed cavity to activate the kinase.
Highlights
Cells recognize and respond to a multitude of different DNA lesions by activating pathways for apoptosis, cell cycle arrest, or DNA repair
Unpaired Single-stranded DNA Ends Increase the Vmax for DNA-PKCS Activation—We previously reported that a 12-bp DNA fragment failed to activate the kinase significantly, but when 5 bases of unpaired single strands were added to both ends of each strand, the kinase was strongly activated (27)
Binding of DNA-PKCS to DNA Ends Occurs at a Transition Fork between Double-stranded DNA and Two Single Strands—To define the structure in double-strand breaks (DSBs) that activates DNAPKCS, we synthesized a series of DNA fragments with different end structures
Summary
Cells recognize and respond to a multitude of different DNA lesions by activating pathways for apoptosis, cell cycle arrest, or DNA repair. Ionizing radiation activates the ATM kinase and DNA-dependent protein kinase (DNA-PK), which have homologous kinase domains. DNA-PK is required for the repair of DSBs produced by ionizing radiation and V(D)J recombination, the process that generates immunological diversity in antibodies and T cell receptors (4). The catalytic domain of DNA-PKCS is mutated in the severe combined immunodeficiency mouse (17, 18), which is defective in the repair of DSBs (19 –21). Supercoiled plasmid DNA fails to activate DNA-PK, but supercoiled plasmid DNA containing the NRE1 sequence from mouse mammary tumor virus was reported to activate the kinase (25, 26). Based on these studies, it was not clear what specific DNA structure was critical for the activation of DNA-PK
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