Abstract
One hallmark of apoptosis is DNA degradation that first appears as high molecular weight fragments followed by extensive internucleosomal fragmentation. During apoptosis, the DNA-dependent protein kinase (DNA-PK) is activated. DNA-PK is involved in the repair of DNA double-strand breaks (DSB) and its catalytic subunit is associated with the nuclease ARTEMIS. Here, we report that, on initiation of apoptosis in human cells by agents causing DNA DSB or by staurosporine or other agents, ARTEMIS binds to apoptotic chromatin together with DNA-PK and other DSB repair proteins. ARTEMIS recruitment to chromatin showed a time and dose dependency. It required DNA-PK protein kinase activity and was blocked by antagonizing the onset of apoptosis with a pan-caspase inhibitor or on overexpression of the antiapoptotic BCL2 protein. In the absence of ARTEMIS, no defect in caspase-3, poly(ADP-ribose) polymerase-1, and XRCC4 cleavage or in H2AX phosphorylation was observed and DNA-PK catalytic subunit was still phosphorylated on S2056 in response to staurosporine. However, DNA fragmentation including high molecular weight fragmentation was delayed in ARTEMIS-deficient cells compared with cells expressing ARTEMIS. In addition, ARTEMIS enhanced the kinetics of MLL gene cleavage at a breakage cluster breakpoint that is frequently translocated in acute or therapy-related leukemias. These results show a facilitating role for ARTEMIS at least in early, site-specific chromosome breakage during apoptosis.
Highlights
Apoptosis is one of the pathways of programmed cell death [1, 2]
A significant defect in the initial kinetics of the site-specific cleavage in the mixed-lineage leukemia breakage cluster region (MLLbcr) was observed in the absence of ARTEMIS, supporting a role for ARTEMIS in site-specific high molecular weight (HMW) DNA fragmentation during apoptosis
In human cells, ARTEMIS is an example of DNA repair enzyme that plays a role in DNA fragmentation during apoptosis
Summary
Apoptosis is one of the pathways of programmed cell death [1, 2] During this process, a family of cysteine proteases called caspases is activated that degrades a large number of proteins leading to cell destruction [3]. DNA is cut by a two-step process in which it is first cleaved into 50- to 300-kb fragments, termed high molecular weight (HMW) DNA [4] and into fragments of low molecular weight. Caspaseactivated DNase activity is a key player in DNA fragmentation, more than 20 other nucleases can operate depending on the organism or tissue [5]. Because apoptosis produces DNA double-strand breaks (DSB), it is not surprising to find connections between this process and cellular pathways that repair damaged DNA.
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