p53-dependent programmed necrosis controls germ cell homeostasis during spermatogenesis.

The importance of regulated necrosis in pathologies such as cerebral stroke and myocardial infarction is now fully recognized. However, the physiological relevance of regulated necrosis remains unclear. Here, we report a conserved role for p53 in regulating necrosis in Drosophila and mammalian spermatogenesis. We found that Drosophila p53 is required for the programmed necrosis that occurs spontaneously in mitotic germ cells during spermatogenesis. This form of necrosis involved an atypical function of the initiator caspase Dronc/Caspase 9, independent of its catalytic activity. Prevention of p53-dependent necrosis resulted in testicular hyperplasia, which was reversed by restoring necrosis in spermatogonia. In mouse testes, p53 was required for heat-induced germ cell necrosis, indicating that regulation of necrosis is a primordial function of p53 conserved from invertebrates to vertebrates. Drosophila and mouse spermatogenesis will thus be useful models to identify inducers of necrosis to treat cancers that are refractory to apoptosis.

The Initiator Caspase Dronc Drives Compensatory Proliferation of Apoptosis-Resistant Cells During Epithelial Tissue Regeneration After Ionizing Radiation.

Caspases, well-known for their role in executing apoptosis, also participate in various non-apoptotic processes. Despite this, their involvement in promoting compensatory proliferation - a key aspect of tissue regeneration following extensive cell death - has been a subject of ongoing ambiguity. In our study, we investigate compensatory proliferation in the Drosophila wing imaginal disc following ionizing radiation, a model epithelial tissue that has been a pioneering system for studying this regenerative response. Using a delayed genetic reporter to monitor the activity of the initiator caspase-2/9 ortholog, Dronc, we identified two populations of apoptosis-resistant epithelial cells involved in compensatory proliferation: those that activate Dronc (termed DARE cells) and those that do not (NARE cells). We show that DARE cells pass their apoptosis-resistance trait to their daughter cells, suggesting a molecular memory. We demonstrate that Dronc in DARE cells, but not the apoptosome adapter Dark and the effector caspases, promotes compensatory proliferation both within these cells and in NARE cells through a non-cell-autonomous mechanism. We found that Myo1D, an unconventional myosin interacting with Dronc, is essential for the survival of DARE cells by preventing the lethal activation of effector caspases and subsequent apoptosis. In contrast, Myo7A/Crinkled, another unconventional myosin that interacts with Dronc, promotes effector caspase activation in DARE cells. We demonstrate that the TNFR>JNK signaling pathway in DARE cells directly regulates their proliferation, which in turn influences NARE cell proliferation. Consequently, we show that maintaining proliferative homeostasis between DARE and NARE cells is vital for balanced tissue regeneration. Given the widespread use of ionizing irradiation in cancer treatment and prevention, our findings have potential implications for understanding treatment-resistant cells and cancer recurrence.

Egg multivesicular bodies elicit an LC3-associated phagocytosis-like pathway to degrade paternal mitochondria after fertilization.

Mitochondria are maternally inherited, but the mechanisms underlying paternal mitochondrial elimination after fertilization are far less clear. Using Drosophila, we show that special egg-derived multivesicular body vesicles promote paternal mitochondrial elimination by activating an LC3-associated phagocytosis-like pathway, a cellular defense pathway commonly employed against invading microbes. Upon fertilization, these egg-derived vesicles form extended vesicular sheaths around the sperm flagellum, promoting degradation of the sperm mitochondrial derivative and plasma membrane. LC3-associated phagocytosis cascade of events, including recruitment of a Rubicon-based class III PI(3)K complex to the flagellum vesicular sheaths, its activation, and consequent recruitment of Atg8/LC3, are all required for paternal mitochondrial elimination. Finally, lysosomes fuse with strings of large vesicles derived from the flagellum vesicular sheaths and contain degrading fragments of the paternal mitochondrial derivative. Given reports showing that in some mammals, the paternal mitochondria are also decorated with Atg8/LC3 and surrounded by multivesicular bodies upon fertilization, our findings suggest that a similar pathway also mediates paternal mitochondrial elimination in other flagellated sperm-producing organisms.

DNase II mediates a parthanatos-like developmental cell death pathway in Drosophila primordial germ cells.

During Drosophila embryonic development, cell death eliminates 30% of the primordial germ cells (PGCs). Inhibiting apoptosis does not prevent PGC death, suggesting a divergence from the conventional apoptotic program. Here, we demonstrate that PGCs normally activate an intrinsic alternative cell death (ACD) pathway mediated by DNase II release from lysosomes, leading to nuclear translocation and subsequent DNA double-strand breaks (DSBs). DSBs activate the DNA damage-sensing enzyme, Poly(ADP-ribose) (PAR) polymerase-1 (PARP-1) and the ATR/Chk1 branch of the DNA damage response. PARP-1 and DNase II engage in a positive feedback amplification loop mediated by the release of PAR polymers from the nucleus and the nuclear accumulation of DNase II in an AIF- and CypA-dependent manner, ultimately resulting in PGC death. Given the anatomical and molecular similarities with an ACD pathway called parthanatos, these findings reveal a parthanatos-like cell death pathway active during Drosophila development.

Caspases maintain tissue integrity by an apoptosis-independent inhibition of cell migration and invasion.

Maintenance of tissue integrity during development and homeostasis requires the precise coordination of several cell-based processes, including cell death. In animals, the majority of such cell death occurs by apoptosis, a process mediated by caspase proteases. To elucidate the role of caspases in tissue integrity, we investigated the behavior of Drosophila epithelial cells that are severely compromised for caspase activity. We show that these cells acquire migratory and invasive capacities, either within 1-2 days following irradiation or spontaneously during development. Importantly, low levels of effector caspase activity, which are far below the threshold required to induce apoptosis, can potently inhibit this process, as well as a distinct, developmental paradigm of primordial germ cell migration. These findings may have implications for radiation therapy in cancer treatment. Furthermore, given the presence of caspases throughout metazoa, our results could imply that preventing unwanted cell migration constitutes an ancient non-apoptotic function of these proteases.

Alternative germ cell death pathway in Drosophila involves HtrA2/Omi, lysosomes, and a caspase-9 counterpart.

In both flies and mammals, almost one-third of the newly emerging male germ cells are spontaneously eliminated before entering meiosis. Here, we show that in Drosophila, germ cell death (GCD) involves the initiator caspase Dronc independently of the apoptosome and the main executioner caspases. Electron microscopy of dying germ cells revealed mixed morphologies of apoptosis and necrosis. We further show that the lysosomes and their catabolic enzymes, but not macroautophagy, are involved in the execution of GCD. We then identified, in a screen, the Parkinson's disease-associated mitochondrial protease, HtrA2/Omi, as an important mediator of GCD, acting mainly through its catalytic activity rather than by antagonizing inhibitor of apoptosis proteins. Concomitantly, other mitochondrial-associated factors were also implicated in GCD, including Pink1 (but not Parkin), the Bcl-2-related proteins, and endonuclease G, which establish the mitochondria as central mediators of GCD. These findings uncover an alternative developmental cell death pathway in metazoans.