Inside an enigma: do mitochondria contribute to cell death in Drosophila?

Mitochondria have been shown to play an important role in cell death in mammalian cells. However, the importance of mitochondria in Drosophila apoptosis is still under investigation. Many proteins involved in the regulation of apoptosis in mammals act at mitochondria or are released from mitochondria, resulting in caspase activation. In addition, these organelles undergo significant ultrastructural changes during apoptosis. This review highlights similarities and differences in the roles of mitochondria and mitochondrial factors in apoptosis between Drosophila and mammals. In Drosophila, many key regulators of apoptosis also appear to localize to this organelle, which also undergoes ultrastructural changes during apoptosis. Although many of the proteins important for the control of apoptosis in mammalian cells are conserved in Drosophila, the role that mitochondria play in apoptosis in this model system remains an area of controversy and active research.

The Drosophila homolog of the putative phosphatidylserine receptor functions to inhibit apoptosis.

Exposure of phosphatidylserine is a conserved feature of apoptotic cells and is thought to act as a signal for engulfment of the cell corpse. A putative receptor for phosphatidylserine (PSR) was previously identified in mammalian systems. This receptor is proposed to function in engulfment of apoptotic cells, although gene ablation of PSR has resulted in a variety of phenotypes. We examined the role of the predicted Drosophila homolog of PSR (dPSR) in apoptotic cell engulfment and found no obvious role for dPSR in apoptotic cell engulfment by phagocytes in the embryo. In addition, dPSR is localized to the nucleus, inconsistent with a role in apoptotic cell recognition. However, we were surprised to find that overexpression of dPSR protects from apoptosis, while loss of dPSR enhances apoptosis in the developing eye. The increased apoptosis is mediated by the head involution defective (Wrinkled) gene product. In addition, our data suggest that dPSR acts through the c-Jun-NH(2) terminal kinase pathway to alter the sensitivity to cell death.

Mitochondrial disruption in Drosophila apoptosis.

Mitochondrial disruption is a conserved aspect of apoptosis, seen in many species from mammals to nematodes. Despite significant conservation of other elements of the apoptotic pathway in Drosophila, a broad role for mitochondrial changes in apoptosis in flies remains unconfirmed. Here, we show that Drosophila mitochondria become permeable in response to the expression of Reaper and Hid, endogenous regulators of developmental apoptosis. Caspase activation in the absence of Reaper and Hid is not sufficient to permeabilize mitochondria, but caspases play a role in Reaper- and Hid-induced mitochondrial changes. Reaper and Hid rapidly localize to mitochondria, resulting in changes in mitochondrial ultrastructure. The dynamin-related protein, Drp1, is important for Reaper- and DNA-damage-induced mitochondrial disruption. Significantly, we show that inhibition of Reaper or Hid mitochondrial localization or inhibition of Drp1 significantly inhibits apoptosis, indicating a role for mitochondrial disruption in fly apoptosis.

Deoxyribonuclease II is a lysosomal barrier to transfection.

DNA delivered in nonviral vectors or as naked DNA must overcome a number of extracellular and intracellular barriers to transfection. Since many vectors deliver DNA into cells by the endocytic route, DNA degradation by lysosomal nucleases has been proposed as a significant barrier to transfection, despite the fact that this has not yet been formally demonstrated to occur. To test this hypothesis, we have investigated the role of deoxyribonuclease II (DNase II), the primary acidic endonuclease active in the lysosome, in transfection. Two genetic systems were engineered in which mammalian cells either overexpressed DNase II or were knocked out for the enzyme. In both models, higher levels of DNase II correlated with decreased transfection efficiency by nonviral DNA delivery vectors. These data provide direct evidence implicating lysosomal DNase II as a barrier to transfection.

A family history of deoxyribonuclease II: surprises from Trichinella spiralis and Burkholderia pseudomallei.

Deoxyribonuclease IIalpha (DNase IIalpha) is an acidic endonuclease found in lysosomes and nuclei, and it is also secreted. Though its Caenorhabditis elegans homolog, NUC-1, is required for digesting DNA of apoptotic cell corpses and dietary DNA, it is not required for viability. However, DNase IIalpha is required in mice for correct development and viability, because undigested cell corpses lead to lesions throughout the body. Recently, we showed that, in contrast to previous reports, active DNase IIalpha consists of one contiguous polypeptide. To better analyze DNase II protein structure and determine residues important for activity, extensive database searches were conducted to find distantly related family members. We report 29 new partial or complete homologs from 21 species. Four homologs with differences at the purported active site histidine residue were detected in the parasitic nematodes Trichinella spiralis and Trichinella pseudospiralis. When these mutations were reconstructed in human DNase IIalpha, the expressed proteins were inactive. DNase II homologs were also identified in non-metazoan species. In particular, the slime-mold Dictyostelium, the protozoan Trichomonas vaginalis, and the bacterium Burkholderia pseudomallei all contain sequences with significant similarity and identity to previously cloned DNase II family members. We report an analysis of their sequences and implications for DNase II protein structure and evolution.

Structural requirements of human DNase II alpha for formation of the active enzyme: the role of the signal peptide, N-glycosylation, and disulphide bridging.

DNase II alpha (EC 3.1.22.1) is an endonuclease, which is active at low pH, that cleaves double-stranded DNA to short 3'-phosphoryl oligonucleotides. Although its biochemistry is well understood, its structure-activity relationship has been largely unexamined. Recently, we demonstrated that active DNase II alpha consists of one contiguous polypeptide, heavily glycosylated, and containing at least one intrachain disulphide linkage [MacLea, Krieser and Eastman (2002) Biochem. Biophys. Res. Commun. 292, 415-421]. The present paper describes further work to examine the elements of DNase II alpha protein required for activity. Truncated forms and site-specific mutants were expressed in DNase II alpha-null mouse cells. Results indicate that the signal-peptide leader sequence is required for correct glycosylation and that N-glycosylation is important for formation of the active enzyme. Despite this, enzymic deglycosylation of wild-type protein with peptide N-glycosidase F reveals that glycosylation is not intrinsically required for DNase activity. DNase II alpha contains six evolutionarily conserved cysteine residues, and mutations in any one of these cysteines completely ablated enzymic activity, consistent with the importance of disulphide bridging in maintaining correct protein structure. We also demonstrate that a mutant form of DNase II alpha that lacks the purported active-site His(295) can still bind DNA, indicating that this histidine residue is not simply involved in DNA binding, but may have a direct role in catalysis. These results provide a more complete model of the DNase II alpha protein structure, which is important for three-dimensional structural analysis and for production of DNase II alpha as a potential protein therapeutic for cystic fibrosis or other disorders.

Engulfment mechanism of apoptotic cells.

Apoptotic cells are engulfed and removed by phagocytes. This ensures proper development of the organism and can modulate immune responses. Recent studies have examined molecules on apoptotic cells, such as phosphatidylserine, which may signal for engulfment through multiple receptors. Apoptotic recognition mechanisms may vary with the apoptotic and engulfing cell type, and even with the age of the corpse.

Revised structure of the active form of human deoxyribonuclease IIalpha.

Deoxyribonuclease IIalpha (DNase IIalpha) is an acid endonuclease found in lysosomes, nuclei, and various secretions. Murine DNase IIalpha is required for digesting the DNA of apoptotic cells after phagocytosis and for correct development and viability. DNase IIalpha purified from porcine spleen was previously shown to contain three peptides, two of which were thiol crosslinked, all derived by processing of a single polypeptide. Commercial bovine protein is consistent with this structure. However, screening of 18 human cell lines failed to demonstrate this processing, rather a 45 kDa protein was consistently observed. Incubation of cells with the N-glycosylation inhibitor tunicamycin resulted in a 37 kDa protein, which is close to the predicted formula weight. The protein also contains at least one thiol crosslink. Similar results were obtained with overexpressed DNase IIalpha. These results suggest that active DNase IIalpha consists of one contiguous polypeptide. We suggest the previous structure reflects proteolysis during protein purification.