Multiple domains of DFF45 bind synergistically to DFF40: roles of caspase cleavage and sequestration of activator domain of DFF40.

CAD/DFF40, the nuclease responsible for DNA fragmentation during apoptosis, exists as a heterodimeric complex with DFF45/ICAD. The study presented here augments the accompanying inhibition and chaperone study with an analysis of specific binding strengths and locations of DFF45 binding sites within DFF40. This allows us to show that DFF40/45 interaction is mediated by binding of three functional domains (D1, D2, and D3) of DFF45 to two domains (activator and catalytic) of DFF40. D1 binds exclusively to the activator domain and D2 binds to the catalytic domain of DFF40. Inhibition of DFF40 nuclease activity arises independently from D1 functional sequestration of the activator domain and D2 blockage of the catalytic domain of DFF40. The mechanism of caspase activation of DFF40 is the disruption of the synergistic binding activity of DFF45 domains to DFF40 after caspase recognition and cleavage of DFF45 in the context of a DFF45/40 complex.     

Functional interaction of DFF35 and DFF45 with caspase-activated DNA fragmentation nuclease DFF40.

DNA fragmentation factor (DFF) functions downstream of caspase-3 and directly triggers DNA fragmentation during apoptosis. Here we described the identification and characterization of DFF35, an isoform of DFF45 comprised of 268 amino acids. Functional assays have shown that only DFF45, not DFF35, can assist in the synthesis of highly active DFF40. Using the deletion mutants, we mapped the function domains of DFF35/45 and demonstrated that the intact structure/conformation of DFF45 is essential for it to function as a chaperone and assist in the synthesis of active DFF40. Whereas the amino acid residues 101-180 of DFF35/45 mediate its binding to DFF40, the amino acid residues 23-100, which is homologous between DFF35/45 and DFF40, may function to inhibit the activity of DFF40. In contrast to DFF45, DFF35 cannot work as a chaperone, but it can bind to DFF40 more strongly than DFF45 and can inhibit its nuclease activity. These findings suggest that DFF35 may function in vivo as an important alternative mechanism to inhibit the activity of DFF40 and further, that the inhibitory effects of both DFF35 and DFF45 on DFF40 can put the death machinery under strict control.     

Activation of the apoptotic endonuclease DFF40 (caspase-activated DNase or nuclease). Oligomerization and direct interaction with histone H1.

DNA fragmentation factor (DFF) is a heterodimeric protein composed of 45-kDa (DFF45) and 40-kDa (DFF40) subunits, a protein that mediates regulated DNA fragmentation and chromatin condensation in response to apoptotic signals. DFF45 is a specific molecular chaperone and an inhibitor for the nuclease activity of DFF40. Previous studies have shown that upon cleavage of DFF45 by caspase-3, the nuclease activity of DFF40 is relieved of inhibition. Here we further investigate the mechanism of DFF40 activation. We demonstrate that DFF45 can also be cleaved and inactivated by caspase-7 but not by caspase-6 and caspase-8. The cleaved DFF45 fragments dissociate from DFF40, allowing DFF40 to oligomerize to form a large functional complex that cleaves DNA by introducing double strand breaks. Histone H1 directly interacts with DFF, confers DNA binding ability to DFF, and stimulates the nuclease activity of DFF40 by increasing its Kcat and decreasing its Km.     

Solution structure of the DFF-C domain of DFF45/ICAD. A structural basis for the regulation of apoptotic DNA fragmentation

DFF45/ICAD has dual functions in the final stage of apoptosis, by acting as both a folding chaperone and a DNase inhibitor of DFF40/CAD. Here, we present the solution structure of the C-terminal domain of DFF45, which is essential for its chaperone-like activity. The structure of this domain (DFF-C) consists of four alpha helices, which are folded in a novel helix-packing arrangement. The 3D structure reveals a large cluster of negatively charged residues on the molecular surface of DFF-C. This observation suggests that charge complementation plays an important role in the interaction of DFF-C with the positively charged catalytic domain of DFF40, and thus for the chaperone activity of DFF45. The structure of DFF-C also provides a rationale for the loss of the chaperone activity in DFF35, a short isoform of DFF45. Indeed, in DFF35, the amino acid sequence is truncated in the middle of the second alpha helix constituting the structure of DFF-C, and thus both the hydrophobic core and the cluster of negative charges are disrupted.     

Discovery, regulation, and action of the major apoptotic nucleases DFF40/CAD and endonuclease G

Toward the end of the 20th and beginning of the 21st centuries, clever in vitro biochemical complementation experiments and genetic screens from the laboratories of Xiaodong Wang, Shigekazu Nagata, and Ding Xue led to the discovery of two major apoptotic nucleases, termed DNA fragmentation factor (DFF) or caspase-activated DNase (CAD) and endonuclease G (Endo G). Both endonucleases attack chromatin to yield 3'-hydroxyl groups and 5'-phosphate residues, first at the level of 50-300 kb cleavage products and next at the level of internucleosomal DNA fragmentation, but these nucleases possess completely different cellular locations in normal cells and are regulated in vastly different ways. In non-apoptotic cells, DFF exists in the nucleus as a heterodimer, composed of a 45 kD chaperone and inhibitor subunit (DFF45) [also called inhibitor of CAD (ICAD-L)] and a 40 kD latent nuclease subunit (DFF40/CAD). Apoptotic activation of caspase-3 or -7 results in the cleavage of DFF45/ICAD and release of active DFF40/CAD nuclease. DFF40's nuclease activity is further activated by specific chromosomal proteins, such as histone H1, HMGB1/2, and topoisomerase II. DFF is regulated by multiple pre- and post-activation fail-safe steps, which include the requirements for DFF45/ICAD, Hsp70, and Hsp40 proteins to mediate appropriate folding during translation to generate a potentially activatable nuclease, and the synthesis in stoichiometric excess of the inhibitors (DFF45/35; ICAD-S/L). By contrast, Endo G resides in the mitochondrial intermembrane space in normal cells, and is released into the nucleus upon apoptotic disruption of mitochondrial membrane permeability in association with co-activators such as apoptosis-inducing factor (AIF). Understanding further regulatory check-points involved in safeguarding non-apoptotic cells against accidental activation of these nucleases remain as future challenges, as well as designing ways to selectively activate these nucleases in tumor cells.     

Histone H1 subtype preferences of DFF40 and possible nuclear localization of DFF40/45 in normal and trichostatin A-treated NB4 leukemic cells

A major hallmark of the terminal stages of apoptosis is the internucleosomal DNA fragmentation. The endonuclease responsible for this type of DNA degradation is the DNA fragmentation factor (DFF). DFF is a complex of the endonuclease DFF40 and its chaperone/inhibitor, DFF45. In vitro work has shown that histone H1 and HMGB1/2 recruit/target DFF40 to the internucleosomal linker regions of chromatin and that histone H1 directly interacts with DFF40 conferring DNA binding ability and enhancing its nuclease activity. The histone H1 family is comprised of many subtypes, which recent work has shown may have distinct roles in chromatin function. Thus we studied the binding association of DFF40 with specific H1 subtypes and whether these binding associations are altered after the induction of apoptosis in an in vivo cellular context. The apoptotic agent used in this study is the histone deacetylase inhibitor, trichostatin A (TSA). We separated the insoluble chromatin-enriched fraction from the soluble nuclear fraction of the NB4 leukemic cell line. Using MNase digestion, we provide evidence which strongly suggests that the heterodimer, DFF40-DFF45, is localized to the chromatin fraction under apoptotic as well as non-apoptotic conditions. Moreover, we present results that show that DFF40 interacts with the all H1 subtypes used in this study, but preferentially interacts with specific H1 subtypes after the induction of apoptosis by TSA. These results illustrate for the first time the association of DFF40 with individual H1 subtypes, under a specific apoptotic stimulus in an in vivo cellular context.     

The DFF40/CAD endonuclease and its role in apoptosis

The sequential generation of large-scale DNA fragments followed by internucleosomal chromatin fragmentation is a biochemical hallmark of apoptosis. One of the nucleases primarily responsible for genomic DNA fragmentation during apoptosis is called DNA Fragmentation Factor 40 (DFF40) or Caspase-activated DNase (CAD). DFF40/CAD is a magnesium-dependent endonuclease specific for double stranded DNA that generates double strand breaks with 3'-hydroxyl ends. DFF40/CAD is activated by caspase-3 that cuts the nuclease's inhibitor DFF45/ICAD. The nuclease preferentially attacks chromatin in the internucleosomal linker DNA. However, the nuclease hypersensitive sites can be detected and DFF40/CAD is potentially involved in large-scale DNA fragmentation as well. DFF40/CAD-mediated DNA fragmentation triggers chromatin condensation that is another hallmark of apoptosis.     

Crystallization of the N-terminal domain of DFF45: the mutual chaperone mechanism is challenged

DNA fragmentation factor 45 (DFF45) regulates DNase DFF40 as its inhibitor and chaperone. It was reported that the N-terminal domain (NTD) of DFF45 alone is disordered and DFF40 is necessary as a mutual chaperone for the folding of NTD. However, here we reported the crystallization of DFF45 NTD. These crystals diffract to 9A using a synchrotron radiation source. In spite of the low resolution, the demonstration of crystal formation indicates that DFF45 NTD itself is not unstructured, which strongly questions the mutual chaperone speculation about DFF45 and DFF40.     

Interaction of DNA fragmentation factor (DFF) with DNA reveals an unprecedented mechanism for nuclease inhibition and suggests that DFF can be activated in a DNA-bound state

DNA fragmentation factor (DFF) is a complex of the DNase DFF40 (CAD) and its chaperone/inhibitor DFF45 (ICAD-L) that can be activated during apoptosis to induce DNA fragmentation. Here, we demonstrate that DFF directly binds to DNA in vitro without promoting DNA cleavage. DNA binding by DFF is mediated by the nuclease subunit, which can also form stable DNA complexes after release from DFF. Recombinant and reconstituted DFF is catalytically inactive yet proficient in DNA binding, demonstrating that the nuclease subunit in DFF is inhibited in DNA cleavage but not in DNA binding, revealing an unprecedented mode of nuclease inhibition. Activation of DFF in the presence of naked DNA or isolated nuclei stimulates DNA degradation by released DFF40 (CAD). In transfected HeLa cells transiently expressed DFF associates with chromatin, suggesting that DFF could be activated during apoptosis in a DNA-bound state.     

Molecular basis of apoptotic DNA fragmentation by DFF40

Although the functions of CIDE domain-containing proteins, including DFF40, DFF45, CIDE-A, CIDE-B, and FSP27, in apoptotic DNA fragmentation and lipid homeostasis have been studied extensively in mammals, the functions of four CIDE domain-containing proteins identified in the fly, namely DREP1, 2, 3, and 4, have not been explored much. Recent structural study of DREP4, a fly orthologue of mammalian DFF40 (an endonuclease involved in apoptotic DNA fragmentation), showed that the CIDE domain of DREP4 (and DFF40) forms filament-like assembly, which is critical for the corresponding function. The current study aimed to investigate the mechanism of filament formation of DREP4 CIDE and to characterize the same. DREP4 CIDE was shown to specifically bind to histones H1 and H2, an event important for the nuclease activity of DREP4. Based on the current experimental results, we proposed the mechanism underlying the process of apoptotic DNA fragmentation.Subject terms: Proteins, Enzymes, X-ray crystallography     

Structural mechanism for inactivation and activation of CAD/DFF40 in the apoptotic pathway

CAD/DFF40 is responsible for the degradation of chromosomal DNA into nucleosomal fragments and subsequent chromatin condensation during apoptosis. It exists as an inactive complex with its inhibitor ICAD/DFF45 in proliferating cells but becomes activated upon cleavage of ICAD/DFF45 into three domains by caspases in dying cells. The molecular mechanism underlying the control and activation of CAD/DFF40 was unknown. Here, the crystal structure of activated CAD/DFF40 reveals that it is a pair of molecular scissors with a deep active-site crevice that appears ideal for distinguishing internucleosomal DNA from nucleosomal DNA. Ensuing studies show that ICAD/DFF45 sequesters the nonfunctional CAD/DFF40 monomer and is also able to disassemble the functional CAD/DFF40 dimer. This capacity requires the involvement of the middle domain of ICAD/DFF45, which by itself cannot remain bound to CAD/DFF40 due to low binding affinity for the enzyme. Thus, the consequence of the caspase-cleavage of ICAD/DFF45 is a self-assembly of CAD/DFF40 into the active dimer.     

The histone H1 C-terminal domain binds to the apoptotic nuclease, DNA fragmentation factor (DFF40/CAD) and stimulates DNA cleavage

The apoptotic nuclease, DNA fragmentation factor (DFF40/CAD), is primarily responsible for internucleosomal DNA cleavage during the terminal stages of programmed cell death. Previously, we demonstrated that histone H1 greatly stimulates naked DNA cleavage by this nuclease. Here, we investigate the mechanism of this stimulation with native and recombinant mouse and human histone H1 species. Using a series of truncation mutants of recombinant histone H1-0, we demonstrate that the H1 C-terminal domain (CTD) is responsible for activation of DFF40/CAD. We show further that the intact histone H1-0 CTD and certain synthetic CTD fragments bind to DFF40/CAD and confer upon it an increased ability to bind to DNA. Interestingly, we find that each of the six somatic cell histone H1 isoforms, whose CTDs differ significantly in primary sequence but not amino acid composition, equally activate DFF40/CAD. We conclude that the interactions identified here between the histone H1 CTD and DFF40/CAD target and activate linker DNA cleavage during the terminal stages of apoptosis.     

Subunit structures and stoichiometries of human DNA fragmentation factor proteins before and after induction of apoptosis

DNA fragmentation factor (DFF) is one of the major endonucleases responsible for internucleosomal DNA cleavage during apoptosis. Understanding the regulatory checkpoints involved in safeguarding non-apoptotic cells against accidental activation of this nuclease is as important as elucidating its activation mechanisms during apoptosis. Here we address these issues by determining DFF native subunit structures and stoichiometries in human cells before and after induction of apoptosis using the technique of native pore-exclusion limit electrophoresis in combination with Western analyses. For comparison, we employed similar techniques with recombinant proteins in conjunction with atomic force microscopy. Before induction of apoptosis, the expression of DFF subunits varied widely among the cell types studied, and the chaperone/inhibitor subunits DFF45 and DFF35 unexpectedly existed primarily as monomers in vast excess of the latent nuclease subunit, DFF40, which was stoichiometrically associated with DFF45 to form heterodimers. DFF35 was exclusively cytoplasmic as a monomer. Nuclease activation upon caspase-3 cleavage of DFF45/DFF35 was accompanied by DFF40 homo-oligomer formation, with a tetramer being the smallest unit. Interestingly, intact DFF45 can inhibit nuclease activity by associating with these homo-oligomers without mediating their disassembly. We conclude that DFF nuclease is regulated by multiple pre- and post-activation fail-safe steps.     

BAPTA blocks DNA fragmentation and chromatin condensation downstream of caspase-3 and DFF activation in HT-induced apoptosis in HL-60 cells

DFF ((DNA Fragmentation Factor) is a heterodimer composed of 40 kDa (DFF40, CAD) and 45 kDa (DFF45, ICAD) subunits. During apoptosis, activated caspase-3 cleaves DFF45 and activates DFF40, a DNase that targets nucleosomal linker region and cleaves chromatin DNA into nucleosomal fragments. We have previously reported that HT induced apoptosis in HL-60 cells, and intracellular Ca²⁺ chelator BAPTA blocked apoptosis-associated DNA fragmentation induced by HT. We report here that HT also induced activation of caspase-3 and cleavage of DFF45. BAPTA prevented neither the caspase-3 activation nor the cleavage of DFF45. Mitochondrial membrane potential was disrupted in BAPTA-AM treated cells. However, BAPTA did prevent DNA fragmentation and chromatin condensation in HT-treated cells. These data suggest a novel role for intracellular calcium in regulating apoptotic nuclease that causes DNA fragmentation and chromatin condensation.     

Generation of aberrant forms of DFF40 concurrent with caspase-3 activation during acute and chronic liver injury in rats

DNA fragmentation factors (DFF) form protein complexes consisting of nuclease DFF40/CAD and inhibitory chaperon DFF45/ICAD. Although activated caspase-3 has been shown to cleave DFF complexes with the release of active DFF40 and DNA fragmentation, the organ-specific mechanisms of DFF turnover during liver injury accompanied by massive apoptosis are unclear. In this study, we investigated hepatic profile of DFF40-immunopositive proteins in two models of liver injury in rats: acute ischemia/reperfusion (I/R) and chronic alcohol administration. We show that DFF40-like proteins occur in intact rat liver mainly as a 52kDa protein. Hepatic I/R-induced caspase-3 activation and a time-dependent accumulation of DFF40-positive protein fragments (40 and 20kDa), most likely via specific caspase-3 cleavage as evidenced by in vitro digestion of intact liver tissue with recombinant caspase-3. In addition, immunoprecipitation with DFF40 followed by Western blot with active caspase-3 antibody revealed the presence of active caspase-3 in DFF40-immunopositive 20kDa proteins. Chronic alcohol administration in rats also resulted in a dose-dependent fragmentation of DFF40 proteins similar to I/R injury. Collectively, these data demonstrate that DFF40 immunopositive proteins exist in the liver as distinct, tissue-specific molecular forms that may be processed by caspase-3 during both acute and chronic liver injury.     

Regional and Temporal Alterations in DNA Fragmentation Factor (DFF)-Like Proteins Following Experimental Brain Trauma in the Rat

DNA fragmentation, an early event in neuronal death following traumatic brain injury, may be triggered by the 40-kDa subunit of DNA fragmentation factor (DFF40). DFF40 is typically bound to the 45-kDa subunit of DFF (DFF45), and activation of DFF40 may occur as a result of caspase-3-mediated cleavage of DFF45 into 30- and 11-kDa fragments. In this study, the intracellular distribution of DFF45 and DFF40 was examined following lateral fluid percussion brain injury of moderate severity (2.4-2.7 atm) in male Sprague-Dawley rats. In the cytosolic fraction (S1) of the injured cortex at 2 and 24 h postinjury, significant decreases in the intensities of DFF45-like proteins at 45- and 32-kDa bands and a concomitant increase in the 11-kDa bands were observed (p < 0.05 vs. uninjured controls). A significant decrease in the intensities of the 32-kDa band in the nuclear (P1) fraction of the injured cortex was observed at 30 min and 2 h postinjury (p < 0.01). Concomitantly, a decrease in DFF40 was observed in the cortical S1 fraction at 2 and 24 h (p < 0.05) and in the P1 fraction at 30 min and 2 h postinjury (p < 0.01). In the hippocampus, DFF45 decreased at 30 min in the P1 and 2 h in the S1 fraction (p < 0.05) and recovered by 24 h postinjury, whereas DFF40 was significantly decreased in the S1 and increased in the P1 fraction at both 2 and 24 h (p < 0.01), which indicated a translocation of DFF40 from cytosol to nucleus. These data are the first to demonstrate that changes in DFF proteins occur after brain trauma and suggest that these changes may play a role in apoptotic cell death via caspase-3-DFF45/DFF40-DNA cleavage observed following traumatic brain injury.     

Dual apoptotic DNA fragmentation system in the fly: Drep2 is a novel nuclease of which activity is inhibited by Drep3

DNA fragmentation is the hallmark of apoptotic cells and mainly mediated by the DNA fragmentation factor DFF40(CAD)/DFF45(ICAD). DFF40 is a novel nuclease, whereas DFF45 is an inhibitor that can suppress the nuclease activity. Apoptotic DNA fragmentation in the fly is controlled by four DFF-related proteins, known as Drep1, 2, 3 and 4. However, the functions of Drep2 and Drep3 are totally unknown. Here, we found that Drep2 is a novel nuclease whose activity is inhibited by Drep3 through a tight interaction with the CIDE domain. Our results suggest that the fly has dual apoptotic DNA fragmentation systems: Drep1: Drep4 and Drep2: Drep3 complexes.Structured summary of protein interactionsDrep2 CIDE and Drep-3 CIDE bind by blue native page (View interaction)Drep2 CIDE and Drep-3 CIDE bind by molecular sieving (View interaction)     

A putative role of Drep1 in apoptotic DNA fragmentation system in fly is mediated by direct interaction with Drep2 and Drep4

DNA fragmentation is common phenomenon for apoptotic cell death. DNA fragmentation factor, called DFF40 (CAD: mouse homologue), is a main nuclease for apoptotic DNA fragmentation. Nuclease activity of DFF40 is normally inhibited by DFF45 by tight interaction via CIDE domain without apoptotic stimuli. Once effector caspase is activated during apoptosis signaling, it cleave DFF45, allowing DFF40 to enter the nucleus and cleave chromosomal DNA. Unlike mammalian system, apoptotic DNA fragmentation in the fly might be controlled by four DFF-related proteins, known as Drep1, Drep2, Drep3 and Drep4. Although the function of Drep1 and Drep4 is well known as DFF45 and DFF40 homologues, respectively, the function of Drep2 and Drep3 is still unclear. DFF-related proteins contain a conserved CIDE domain of ~90 amino acid residues that is involved in protein–protein interaction. Here, we showed that Drep1 directly bind to Drep2 as well as Drep4 via CIDE domain. In addition, we found that the interaction of Drep2 and Drep4 to Drep1 was not competitive indicating that Drep2 and Drep4 bind different place of Drep1. All together, we suggest that Drep1 might be involved in apoptotic DNA fragmentation of fly system by direct interaction with Drep2 as well as Drep4.     

Oligomerization state of the DNA fragmentation factor in normal and apoptotic cells

The caspase-activated DNase (CAD) is the primary nuclease responsible for oligonucleosomal DNA fragmentation during apoptosis. The DNA fragmentation factor (DFF) is composed of the 40-kDa CAD (DFF40) in complex with its cognate 45-kDa inhibitor (inhibitor of CAD: ICAD or DFF45). The association of ICAD with CAD not only inhibits the DNase activity but is also essential for the co-translational folding of CAD. Activation of CAD requires caspase-3-dependent proteolysis of ICAD. The tertiary structures of neither the inactive nor the activated DFF have been conclusively established. Whereas the inactive DFF is thought to consist of the CAD/ICAD heterodimer, activated CAD has been isolated as a large (>MDa) multimer, as well as a monomer. To establish the subunit stoichiometry of DFF and some of its structural determinants in normal and apoptotic cells, we utilized size-exclusion chromatography in combination with co-immunoprecipitation and mutagenesis techniques. Both endogenous and heterologously expressed DFF have an apparent molecular mass of 160-190 kDa and contain 2 CAD and 2 ICAD molecules (CAD/ICAD)2 in HeLa cells. Although the N-terminal (CIDE-N) domain of CAD is not required for ICAD binding, it is necessary but not sufficient for ICAD homodimerization in the DFF. In contrast, the CIDE-N domain of ICAD is required for CAD/ICAD association. Using bioluminescence resonance energy transfer (BRET), dimerization of ICAD in DFF was confirmed in live cells. In apoptotic cells, endogenous and exogenous CAD forms limited oligomers, representing the active nuclease. A model is proposed for the rearrangement of the DFF subunit stoichiometry in cells undergoing programmed cell death.     

Roles of DNA fragmentation factor and poly(ADP-ribose) polymerase in an amplification phase of tumor necrosis factor-induced apoptosis.

During apoptosis, endonucleases cleave DNA into 50-300-kb fragments and subsequently into internucleosomal fragments. DNA fragmentation factor (DFF) is implicated in apoptotic DNA cleavage; this factor comprises DFF45 and DFF40 subunits, the former of which acts as a chaperone and inhibitor of the catalytic subunit and whose cleavage by caspase-3 results in DFF activation. Disruption of the DFF45 gene blocks internucleosomal DNA fragmentation and confers resistance to apoptosis in primary thymocytes. The role of DFF-mediated DNA fragmentation in apoptosis was investigated in primary fibroblasts from DFF45(-/-) and control (DFF45(+/+)) mice. DFF45 deficiency rendered fibroblasts resistant to apoptosis induced by tumor necrosis factor (TNF). TNF induced rapid cleavage of DNA into approximately 50-kb fragments in DFF45(+/+) fibroblasts but not in DFF45(-/-) cells, indicating that DFF mediates this initial step in DNA processing. The TNF-induced activation of poly(ADP-ribose) polymerase (PARP), which requires PARP binding to DNA strand breaks, and the consequent depletion of the PARP substrate NAD were markedly delayed in DFF45(-/-) cells, suggesting a role for DFF in PARP activation. The activation of caspase-3 and mitochondrial events important in apoptotic signaling, including the loss of mitochondrial membrane potential and the release of cytochrome c, induced by TNF were similarly delayed in DFF45(-/-) fibroblasts. DFF45(-/-) and DFF45(+/+) cells were equally sensitive to the DNA-damaging agent and PARP activator N-methyl-N'-nitro-N-nitrosoguanidine. Inhibition of PARP by 3-aminobenzamide partially protected DFF45(+/+) cells against TNF-induced death and inhibited the associated release of cytochrome c and activation of caspase-3. These results suggest that the generation of 50-kb DNA fragments by DFF, together with the activation of PARP, mitochondrial dysfunction, and caspase-3 activation, contributes to an amplification loop in the death process.