Inhibition of both the extrinsic and intrinsic death pathways through nonhomotypic death-fold interactions.

Death-fold domains constitute an evolutionarily conserved superfamily that mediates apoptotic signaling. These motifs, including CARD (caspase recruitment domain), DD (death domain), and DED (death effector domain), are believed to exert their effects solely through homotypic interactions. Herein we demonstrate that the CARD-containing protein ARC engages in nontraditional death-fold interactions to suppress both extrinsic and intrinsic death pathways. The extrinsic pathway is disrupted by heterotypic interactions between ARC's CARD and the DDs of Fas and FADD, which inhibit Fas-FADD binding and assembly of the death-inducing signaling complex (DISC). The intrinsic pathway is antagonized by ARC-Bax binding, involving ARC's CARD and the Bax C terminus. This inhibits Bax activation and translocation to the mitochondria. Knockdown of endogenous ARC facilitates DISC assembly and triggers spontaneous Bax activation and apoptosis. Conversely, physiological levels of ARC suppress these events. These studies establish a critical role for nonhomotypic death-fold interactions in the regulation of apoptosis.

Inhibition of cardiac myocyte apoptosis improves cardiac function and abolishes mortality in the peripartum cardiomyopathy of Galpha(q) transgenic mice.

BACKGROUND: Although the occurrence of cardiac myocyte apoptosis during heart failure has been documented, its importance in pathogenesis is unknown. Transgenic mice with cardiac-restricted overexpression of Galpha(q) exhibit a lethal, peripartum cardiomyopathy accompanied by apoptosis. To test whether apoptosis is causally linked to heart failure, we assessed whether inhibiting this cell death would improve left ventricular function and survival in the Galpha(q) peripartum cardiomyopathy model. METHODS AND RESULTS: The potent polycaspase inhibitor IDN-1965 or vehicle was administered subcutaneously to Galpha(q) mice by osmotic minipump beginning on day 12 of pregnancy and continuing through euthanasia at day 14 postpartum. As expected, IDN-1965 markedly suppressed cardiac caspase-3-like activity (86.5%; P<0.01), accompanied by reduction in the frequency of cardiac myocyte apoptosis from 1.9+/-0.3% to 0.2+/-0.1% (P<0.01). Animals receiving IDN-1965 exhibited significant improvements in left ventricular end-diastolic dimension (vehicle, 4.7+/-0.1 mm; IDN-1965, 4.2+/-0.1 mm; P<0.01), fractional shortening (vehicle, 30.7+/-1.2%; IDN-1965, 38.9+/-1.0%; P<0.01), positive (vehicle, 3972+/-412; IDN-1965, 5870+/-295; P<0.01) and negative (vehicle, 2365+/-213; IDN-1965, 3413+/-201; P<0.01) dP/dt, and complete suppression of mortality (vehicle, 6 of 20 died; IDN-1965, 0 of 14 died; P<0.05). CONCLUSIONS: Reduction in cardiac myocyte apoptosis by caspase inhibition improved left ventricular function and survival in pregnant Galpha(q) mice. These data indicate that cardiac myocyte apoptosis plays a causal role in the pathogenesis of cardiomyopathy in this model. Caspase inhibition may provide a novel therapeutic target for heart failure.

Myocytes die by multiple mechanisms in failing human hearts.

We tested the hypothesis that myocyte loss in failing human hearts occurs by different mechanisms: apoptosis, oncosis, and autophagic cell death. Explanted hearts from 19 patients with idiopathic dilated cardiomyopathy (EF< or =20%) and 7 control hearts were analyzed. Myocyte apoptosis revealed by caspase-3 activation and TUNEL staining occurred at a rate of 0.002+/-0.0005% (P<0.05 versus control) and oncosis assessed by complement 9 labeling at 0.06+/-0.001% (P<0.05). Cellular degeneration including appearance of ubiquitin containing autophagic vacuoles and nuclear disintegration was present at the ultrastructural level. Nuclear and cytosolic ubiquitin/protein accumulations occurred at 0.08+/-0.004% (P<0.05). The ubiquitin-activating enzyme E1 and the ligase E3 were not different from control. In contrast, ubiquitin mRNA levels were 1.8-fold (P<0.02) elevated, and the conjugating enzyme E2 was 2.3-fold upregulated (P<0.005). The most important finding, however, is the 2.3-fold downregulation of the deubiquitination enzyme isopeptidase-T and the 1.5-fold reduction of the ubiquitin-fusion degradation system-1, which in conjunction with unchanged proteasomal subunit levels and proteasomal activity results in massive storage of ubiquitin/protein complexes and in autophagic cell death. A 2-fold decrease of cathepsin D might be an additional factor responsible for the accumulation of ubiquitin/protein conjugates. It is concluded that in human failing hearts apoptosis, oncosis, and autophagy act in parallel to varying degrees. A disturbed balance between a high rate of ubiquitination and inadequate degradation of ubiquitin/protein conjugates may contribute to autophagic cell death. Together, these different types of cell death play a significant role for myocyte disappearance and the development of contractile dysfunction in failing hearts.