Caspases function in autophagic programmed cell death in Drosophila

Self-digestion of cytoplasmic components is the hallmark of autophagic programmed cell death. This auto-degradation appears to be distinct from what occurs in apoptotic cells that are engulfed and digested by phagocytes. Although much is known about apoptosis, far less is known about the mechanisms that regulate autophagic cell death. Here we show that autophagic cell death is regulated by steroid activation of caspases in Drosophila salivary glands. Salivary glands exhibit some morphological changes that are similar to apoptotic cells, including fragmentation of the cytoplasm, but do not appear to use phagocytes in their degradation. Changes in the levels and localization of filamentous Actin, alpha-Tubulin, alpha-Spectrin and nuclear Lamins precede salivary gland destruction, and coincide with increased levels of active Caspase 3 and a cleaved form of nuclear Lamin. Mutations in the steroid-regulated genes beta FTZ-F1, E93, BR-C and E74A that prevent salivary gland cell death possess altered levels and localization of filamentous Actin, alpha-Tubulin, alpha-Spectrin, nuclear Lamins and active Caspase 3. Inhibition of caspases, by expression of either the caspase inhibitor p35 or a dominant-negative form of the initiator caspase Dronc, is sufficient to inhibit salivary gland cell death, and prevent changes in nuclear Lamins and alpha-Tubulin, but not to prevent the reorganization of filamentous Actin. These studies suggest that aspects of the cytoskeleton may be required for changes in dying salivary glands. Furthermore, caspases are not only used during apoptosis, but also function in the regulation of autophagic cell death.     

Warts is required for PI3K-regulated growth arrest, autophagy, and autophagic cell death in Drosophila

BACKGROUND: Cell growth arrest and autophagy are required for autophagic cell death in Drosophila. Maintenance of growth by expression of either activated Ras, Dp110, or Akt is sufficient to inhibit autophagy and cell death in Drosophila salivary glands, but the mechanism that controls growth arrest is unknown. Although the Warts (Wts) tumor suppressor is a critical regulator of tissue growth in animals, it is not clear how this signaling pathway controls cell growth. RESULTS: Here, we show that genes in the Wts pathway are required for salivary gland degradation and that wts mutants have defects in cell growth arrest, caspase activity, and autophagy. Expression of Atg1, a regulator of autophagy, in salivary glands is sufficient to rescue wts mutant salivary gland destruction. Surprisingly, expression of Yorkie (Yki) and Scalloped (Sd) in salivary glands fails to phenocopy wts mutants. By contrast, misexpression of the Yki target bantam was able to inhibit salivary gland cell death, even though mutations in bantam fail to suppress the wts mutant salivary gland-persistence phenotype. Significantly, wts mutant salivary glands possess altered phosphoinositide signaling, and decreased function of the class I PI3K-pathway genes chico and TOR suppressed wts defects in cell death. CONCLUSIONS: Although we have previously shown that salivary gland degradation requires genes in the Wts pathway, this study provides the first evidence that Wts influences autophagy. Our data indicate that the Wts-pathway components Yki, Sd, and bantam fail to function in salivary glands and that Wts regulates salivary gland cell death in a PI3K-dependent manner.     

Steroid regulation of autophagic programmed cell death during development

Apoptosis and autophagy are morphologically distinct forms of programmed cell death. While autophagy occurs during the development of diverse organisms and has been implicated in tumorigenesis, little is known about the molecular mechanisms that regulate this type of cell death. Here we show that steroid-activated programmed cell death of Drosophila salivary glands occurs by autophagy. Expression of p35 prevents DNA fragmentation and partially inhibits changes in the cytosol and plasma membranes of dying salivary glands, suggesting that caspases are involved in autophagy. The steroid-regulated BR-C, E74A and E93 genes are required for salivary gland cell death. BR-C and E74A mutant salivary glands exhibit vacuole and plasma membrane breakdown, but E93 mutant salivary glands fail to exhibit these changes, indicating that E93 regulates early autophagic events. Expression of E93 in embryos is sufficient to induce cell death with many characteristics of apoptosis, but requires the H99 genetic interval that contains the rpr, hid and grim proapoptotic genes to induce nuclear changes diagnostic of apoptosis. In contrast, E93 expression is sufficient to induce the removal of cells by phagocytes in the absence of the H99 genes. These studies indicate that apoptosis and autophagy utilize some common regulatory mechanisms.     

Real-time observation of autophagic programmed cell death of<Emphasis Type="Italic"> Drosophila</Emphasis> salivary glands in vitro

Autophagy, a form of programmed cell death (PCD) that is morphologically distinguished from apoptosis, is thought to be as prevalent as apoptosis, at least during development. In insect metamorphosis, the steroid hormone 20-hydroxyecdysone (ecdysone) activates autophagic PCD to eliminate larval structures that are no longer needed. However, in comparison with apoptosis, there are not many studies on the regulation mechanisms of autophagy. To provide a useful model for studying autophagic PCD, I established an in vitro culture system that enables real-time observation of the autophagic cell destruction of Drosophila salivary glands. The new system revealed that de novo gene expression was still required for the destruction of salivary glands dissected from phanerocephalic pupae. This indicates the usefulness of the system for exploring genes that participate in the last processes of autophagic PCD.Edited by N. Satoh     

Autophagy and apoptosis coordinate physiological cell death in larval salivary glands of Apis mellifera (Hymenoptera: Apidae)

Larval salivary glands of bees provide a good model for the study of hormone-induced programmed cell death in Hymenoptera because they have a well-defined secretory cycle with a peak of secretory activity phase, prior to cocoon spinning, and a degenerative phase, after the cocoon spinning. Our findings demonstrate that there is a relationship between apoptosis and autophagy during physiological cell death in these larval salivary glands, that adds evidence to the hypothesis of overlap in the regulation pathways of both types of programmed cell death. Features of autophagy include cytoplasm vacuolation, acid phosphatase activity, presence of autophagic vacuoles and multi-lamellar structures, as well as a delay in the collapse of many nuclei. Features of apoptosis include bleb formation in the cytoplasm and nuclei, with release of parts of the cytoplasm into the lumen, chromatin compaction, and DNA and nucleolar fragmentation. We propose a model for programmed cell death in larval salivary glands of Apis mellifera where autophagy and apoptosis function cooperatively for a more efficient degeneration of the gland secretory cells.     

Autophagy functions in programmed cell death

Autophagic cell death is a prominent morphological form of cell death that occurs in diverse animals. Autophagosomes are abundant during autophagic cell death, yet the functional role of autophagy in cell death has been enigmatic. We find that autophagy and the Atg genes are required for autophagic cell death of Drosophila salivary glands. Although caspases are present in dying salivary glands, autophagy is required for complete cell degradation. Further, induction of high levels of autophagy results in caspase-independent autophagic cell death. Our results provide the first in vivo evidence that autophagy and the Atg genes are required for autophagic cell death and confirm that autophagic cell death is a physiological death program that occurs during development.

Addendum to: Berry DL, Baehrecke EH. Growth arrest and autophagy are required for programmed salivary gland cell degradation in Drosophila. Cell 2007; 131:1137-48.     

Mechanisms of programmed cell death in the midgut and salivary glands from Bradysia hygida (Diptera: Sciaridae) during pupal–adult metamorphosis

Programmed cell death is involved with the degeneration/remodeling of larval tissues and organs during holometabolous development. The midgut is a model to study the types of programmed cell death associated with metamorphosis because its structure while degenerating is a substrate for the formation of the adult organ. Another model is the salivary glands from dipteran because their elimination involves different cell death modes. This study aimed to investigate the models of programmed cell death operating during midgut replacement and salivary gland histolysis in Bradysia hygida. We carried out experiments of real‐time observations, morphological analysis, glycogen detection, filamentous‐actin localization, and nuclear acridine orange staining. Our findings allow us to establish that an intact actin cytoskeleton is required for midgut replacement in B. hygida and nuclear condensation and acridine orange staining precede the death of the larval cells. Salivary glands in histolysis present cytoplasmic blebbing, nuclear retraction, and acridine orange staining. This process can be partially reproduced in vitro. We propose that the larval midgut death involves autophagic and apoptotic features and apoptosis is a mechanism involved with salivary gland histolysis.     

Autophagy and Apoptosis Coordinate Physiological Cell Death in Larval Salivary Glands of Apis mellifera (Hymenoptera: Apidae)

Larval salivary glands of bees provide a good model for the study of hormone-induced programmed cell death in Hymenoptera because they have a well-defined secretory cycle with a peak of secretory activity phase, prior to cocoon spinning, and a degenerative phase, after the cocoon spinning. Our findings demonstrate that there is a relationship between apoptosis and autophagy during physiological cell death in these larval salivary glands, that adds evidence to the hypothesis of overlap in the regulation pathways of both types of programmed cell death. Features of authophagy include cytoplasm vacuolation, acid phosphatase activity, presence of autophagic vacuoles and multi-lamellar structures, as well as a delay in the collapse of many nuclei. Features of apoptosis include bleb formation in the cytoplasm and nuclei, with release of parts of the cytoplasm into the lumen, chromatin compaction, and DNA and nucleolar fragmentation. We propose a model for programmed cell death in larval salivary glands of Apis mellifera where autophagy and apoptosis function cooperatively for a more efficient degeneration of the gland secretory cells.

Addendum to:

Programmed Cell Death in the Larval Salivary Glands of Apis mellifera (Hymenoptera, Apidae)

E.C.M. Silva-Zacarin, G.A. Tomaino, M.R. Brochetto-Braga, S.R. Taboga, R.L.M. Silva de Moraes

J Biosci 2007; 32:309-28     

Autophagy functions in programmed cell death

Autophagic cell death is a prominent morphological form of cell death that occurs in diverse animals. Autophagosomes are abundant during autophagic cell death, yet the functional role of autophagy in cell death has been enigmatic. We find that autophagy and the Atg genes are required for autophagic cell death of Drosophila salivary glands. Although caspases are present in dying salivary glands, autophagy is required for complete cell degradation. Further, induction of high levels of autophagy results in caspase-independent autophagic cell death. Our results provide the first in vivo evidence that autophagy and the Atg genes are required for autophagic cell death and confirm that autophagic cell death is a physiological death program that occurs during development.     

Rearrangement of the tubulin and actin cytoskeleton during programmed cell death in Drosophila salivary glands

During larva-to-pupa metamorphosis Drosophila salivary glands undergo programmed cell death by autophagocytosis. Although ultrastructure of Drosophila salivary glands has been extensively studied in the past, little is known about mechanism of programmed cell death, especially the role of the cytoskeleton. In this paper we describe changes in microtubule and actin filament network compared to the progress of DNA fragmentation and redistribution of acid phosphatase. In feeding and wandering larvae microtubules and actin filaments form regular networks localized mostly along the plasma membrane. The first major rearrangement of microtubules and actin filaments occurred when larvae everted spiracles and the glands shifted their secretion from saliva to mucoprotein glue (stage L1). Microtubule cytoskeleton became denser and actin filaments concentrated along cell boundaries. At the same time nuclei flattened and migrated into the microtubule-rich layer near the basal membrane. In late prepupae (8-10 h after P1) the microtubule network became fainter, and actin filaments appeared frequently deeper in cytoplasm, gradually concentrating around nuclei. Simultaneously large patches of acid phosphatase activity surrounded nuclei and shortly thereafter chromosomal DNA began to fragment. During the final collapse of the gland (early pupae, 13.5 h after formation of white puparium) cellular fragments and autophagic vacuoles contained a continuous F-actin lining and the microtubule network displayed signs of extensive degradation. The results are consistent with the hypothesis that, in Drosophila salivary glands, extensive autophagic activities target nuclei for degradation; that this process occurs late in the course of programmed cell death; and that it directly involves cytoskeletal structures which are altered far earlier during the course of cell death.     

Morphological evidence that salivary gland degeneration in the American dog tick,Dermacentor variabilis (Say), involves programmed cell death

During the preoviposition and oviposition periods of ixodid ticks, the salivary glands degenerate. It is unclear whether this is a necrotic or a programmed cell death event. We used an in situ TUNEL technique to determine if salivary gland degeneration involves apoptosis. Salivary glands were dissected from replete females at days 3, 5, 8, 11, 13, and 33 post-detachment. There were no differences in tick weight at detachment, suggesting that changes were not due to engorgement abnormalities. The onset of apoptosis began at day 5 and continued through oviposition at day 33. The greatest amount of nuclei containing fragmented DNA was observed on day 8 post-detachment, suggesting this was the peak occurrence of programmed cell death. Further, the temporal organization of programmed cell death suggests that the granule-secreting acini undergo apoptosis first, and that during the first week of oviposition the type I acini do not exhibit programmed cell death. These data suggest that the type I acini may still function in maintaining off-host hydration state of ovipositing females. These data provide morphological evidence that salivary gland degeneration involves a temporal programmed cell death event.     

Some autophagic and apoptotic features of programmed cell death in the anterior silk glands of the silkworm, Bombyx mori

Programmed cell death has been subdivided into two major groups: apoptosis and autophagic cell death. The anterior silk gland of Bombyx mori degenerates during larval-pupal metamorphosis. Our findings indicate that two types of programmed cell death features are observed during this physiological process. During the prepupal period, pyknosis of the nucleus, cell detachment,and membrane blebbing occur and they are the first signs of programmed cell death in the anterior silk glands. According to previous studies, all of these morphological appearances are common for both cell-death types. Autophagy features are also exhibited during the prepupal period. Levels of one of the lysosomal marker enzymes-acid phosphatase-are high during this period then decrease gradually. Vacuole formation begins to appear first at the basal surface of the cell, then expands to the apical surface just before the larval pupal ecdysis. After larval-pupal ecdysis, DNA fragmentation, which is the obvious biochemical marker of apoptosis, is detected in agarose gel electrophoresis, which also shows that caspase-like enzyme activities occur during the programmed cell death process of the anterior silk glands. Apoptosis and autophagic cell death interact with each other during the degeneration process of the anterior silk gland in Bombyx mori and this interaction occurs at a late phase of cell death. We suggest that apoptotic cell death only is not enough for whole gland degeneration and that more effective degeneration occurs with this cooperation.     

Identification of factors that function in Drosophila salivary gland cell death during development using proteomics

Proteasome inhibitors induce cell death and are used in cancer therapy, but little is known about the relationship between proteasome impairment and cell death under normal physiological conditions. Here, we investigate the relationship between proteasome function and larval salivary gland cell death during development in Drosophila. Drosophila larval salivary gland cells undergo synchronized programmed cell death requiring both caspases and autophagy (Atg) genes during development. Here, we show that ubiquitin proteasome system (UPS) function is reduced during normal salivary gland cell death, and that ectopic proteasome impairment in salivary gland cells leads to early DNA fragmentation and salivary gland condensation in vivo. Shotgun proteomic analyses of purified dying salivary glands identified the UPS as the top category of proteins enriched, suggesting a possible compensatory induction of these factors to maintain proteolysis during cell death. We compared the proteome following ectopic proteasome impairment to the proteome during developmental cell death in salivary gland cells. Proteins that were enriched in both populations of cells were screened for their function in salivary gland degradation using RNAi knockdown. We identified several factors, including trol, a novel gene CG11880, and the cop9 signalsome component cop9 signalsome 6, as required for Drosophila larval salivary gland degradation.     

Some autophagic and apoptotic features of programmed cell death in the anterior silk glands of the silkworm,Bombyx mori

Programmed cell death has been subdivided into two major groups: apoptosis and autophagic cell death. The anterior silk gland of Bombyx mori degenerates during larval-pupal metamorphosis. Our findings indicate that two types of programmed cell death features are observed during this physiological process. During the prepupal period, pyknosis of the nucleus, cell detachment and membrane blebbing occur and they are the first signs of programmed cell death in the anterior silk glands. According to previous studies, all of these morphological appearences are common for both cell death types. Autophagy features are also exhibited during the prepupal period. One of the lysosomal marker enzymes, acid phosphatase, levels are high during this period then decrease gradually. Vacuole formation begins to appear first at the basal surface of the cell, then expands to the apical surface just before the larval pupal ecdysis. After larval-pupal ecdysis, DNA fragmentation, which is the obvious biochemical marker of apoptosis, is detected in agarose gel electrophoresis which also shows that caspase-like enzyme activities occur during the programmed cell death process of the anterior silk glands. Apoptosis and autophagic cell death interact with each other during the degeneration process of the anterior silk gland in Bombyx mori and this interaction occurs at a late phase of cell death. We suggest that only apoptotic cell death not enough for whole gland degeneration and that more effective degeneration occurs with this cooperation.

Addendum to: Goncu E, Parlak O. Morphological changes and patterns of ecdysone receptor B1 immunolocalization in the anterior silk gland undergoing programmed cell death in the silkworm, Bombyx mori. Acta Histochem 2008; In press.     

Role of Bcl-2 family proteins in a non-apoptotic programmed cell death dependent on autophagy genes

Programmed cell death can be divided into several categories including type I (apoptosis) and type II (autophagic death). The Bcl-2 family of proteins are well-characterized regulators of apoptosis, and the multidomain pro-apoptotic members of this family, such as Bax and Bak, act as a mitochondrial gateway where a variety of apoptotic signals converge. Although embryonic fibroblasts from Bax/Bak double knockout mice are resistant to apoptosis, we found that these cells still underwent a non-apoptotic death after death stimulation. Electron microscopic and biochemical studies revealed that double knockout cell death was associated with autophagosomes/autolysosomes. This non-apoptotic death of double knockout cells was suppressed by inhibitors of autophagy, including 3-methyl adenine, was dependent on autophagic proteins APG5 and Beclin 1 (capable of binding to Bcl-2/Bcl-x(L)), and was also modulated by Bcl-x(L). These results indicate that the Bcl-2 family of proteins not only regulates apoptosis, but also controls non-apoptotic programmed cell death that depends on the autophagy genes.     

Cell death in the salivary glands of metamorphosing calliphora vomitoria

The salivary gland cells of Calliphora vomitoria larvae initiate and complete their own destruction in a programmed manner at the onset of metamorphosis. On entering the post-feeding period the larvae come to rest and the polytene salivary gland cells show a significant increase in DNA synthesis followed closely by a surge of mRNA synthesis accompanied by increasing protein production. During this prelude to cell death the new mRNA gives rise to at least 10 new proteins. The first new proteins having a MWt between 30 and 100kD appear by day 8 of the life-cycle and a number persist until the advent of cell death on day 9. Other new proteins appear in a cascade of production during day 8 and in vitro translation of mRNA produced at this time shows a new 55kD protein appearing before cell destruction. Significantly no evidence of DNA degeneration or laddering associated with classical apoptosis was observed, on the contrary considerable DNA synthesis in the form of chromosomal endoduplication or "genomic amplification" was seen; selective gene expression being apparently controlled at translational level. Overall the results strongly suggest a synthetically mediated programmed cell death in the metamorphosing salivary glands of the blow-fly which is distinct from apoptosis.     

AP-1, but not NF-kappa B, is required for efficient steroid-triggered cell death in Drosophila

Extensive studies in vertebrate cells have assigned a central role to Rel/NF-kappa B and AP-1 family members in the control of apoptosis. We ask here whether parallel pathways might function in Drosophila by determining if Rel/NF-kappa B or AP-1 family members contribute to the steroid-triggered death of larval salivary glands during Drosophila metamorphosis. We show that two of the three Drosophila Rel/NF-kappa B genes are expressed in doomed salivary glands and that one family member, Dif, is induced in a stage-specific manner immediately before the onset of programmed cell death. Similarly, Djun is expressed for many hours before salivary gland cell death while Dfos is induced in a stage-specific manner, immediately before this tissue is destroyed. We show that null mutations in the three Drosophila Rel/NF-kappa B family members, either alone or in combination, have no apparent effect on this death response. In contrast, Dfos is required for the proper timing of larval salivary gland cell death as well as the proper induction of key death genes. This study demonstrates a role for AP-1 in the stage-specific steroid-triggered programmed cell death of larval tissues during Drosophila metamorphosis.