Abstract
Apoptosis is an ancient and evolutionarily conserved cell suicide program. During apoptosis, executioner caspase enzyme activation has been considered a point of no return. However, emerging evidence suggests that some cells can survive caspase activation following exposure to apoptosis-inducing stresses, raising questions as to the physiological significance and underlying molecular mechanisms of this unexpected phenomenon. Here, we show that, following severe tissue injury, Drosophila wing disc cells that survive executioner caspase activation contribute to tissue regeneration. Through RNAi screening, we identify akt1 and a previously uncharacterized Drosophila gene CG8108, which is homologous to the human gene CIZ1, as essential for survival from the executioner caspase activation. We also show that cells expressing activated oncogenes experience apoptotic caspase activation, and that Akt1 and dCIZ1 are required for their survival and overgrowth. Thus, survival following executioner caspase activation is a normal tissue repair mechanism usurped to promote oncogene-driven overgrowth.
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Introduction
Precise control of cell death and survival is critical for tissue homeostasis. Apoptosis is an important form of programmed cell death executed by proteolytic enzymes called caspases. While physiological apoptosis promotes normal development and homeostasis, inappropriate apoptosis causes tissue damage, degenerative diseases, and immune system dysfunction1.
In the process of apoptosis, activation of executioner caspases results in cleavage of hundreds of proteins, thereby dismantling the cell. Executioner caspase activation has thus been considered a point of no return2. However, recent studies show that some cells can survive apoptosis-inducing stresses even after executioner caspase activation3,4,5,6,7,8. Cultured mammalian cells can recover from executioner caspase activation induced by transient exposure to apoptotic inducers like ethanol, staurosporine, and TNFα, through a process called anastasis3,4,6. Similar events have been described in tumors cells after tBid overexpression5 or treatment with chemotherapeutic drugs like paclitaxel8. Survival after stress-induced executioner caspase activation has also been reported in cardiomyocytes after ischemia-reperfusion9 and in neurons expressing pathogenic tau10 in mice. These studies suggest that, in addition to the established competition between pro-death and pro-survival signals upstream of caspases, there is another layer of regulation after executioner caspases activation (Fig. 1a). Deciphering these regulatory mechanisms could therefore identify new therapeutic targets for a variety of diseases caused by improper cell death versus survival decisions.
To identify cells that survive executioner caspase activation in vivo, we previously developed a biosensor, CasExpress, which labels cells that have experienced transient caspase activation in Drosophila (Fig. 1b)11. We discovered widespread survival after executioner caspase activation during normal development of Drosophila larval and adult tissues including rapidly proliferating larval imaginal discs11. A similar sensor exhibits similar activation in adult tissues12. Here, we use the CasExpress sensor to decipher the physiological importance of, and molecular mechanisms enabling, survival from stress-induced executioner caspase activation in vivo. We show that although executioner caspase activation induced by heat shock, X-ray irradiation, or transient pro-apoptotic gene overexpression causes extensive cell death in wing imaginal discs, many epithelial cells survive and participate in tissue regeneration. We also report that wing disc epithelial cells experience transient apoptosis-inducing stresses even during normal development. To investigate the molecular mechanisms enabling cell survival from transient caspase activation, we developed a second-generation CasExpress sensor compatible with RNAi screening. We identified Akt1 and a new gene, CG8108 (dCIZ1), as essential for survival from executioner caspase activation. Finally, we show that cells expressing activated oncogenes experience homeostatic apoptotic stress and exploit Akt1 and dCIZ1 to survive. Thus, survival from executioner caspase activation is a normal cellular response to tissue injury that promotes repair and can be hijacked to drive tumor growth.
Results
Survival from heat shock- or X-irradiation-induced executioner caspase activation contributes to tissue regeneration
The observations that a variety of cells can survive executioner caspase activation in response to diverse stresses (Fig. 1a) raises the question as to the physiological significance of this unexpected cellular resilience. We hypothesized that it might represent an injury repair mechanism. To test whether cells can survive executioner caspase activation after tissue damage in vivo, we exposed Drosophila larvae to heat shock and radiation, which are known to cause massive apoptosis in wing imaginal discs13. To assess whether any cells survived executioner caspase activation, we took advantage of the CasExpress biosensor11. CasExpress is a fusion protein composed of the extracellular and transmembrane domains of mCD8, 200 amino acids from an endogenous executioner caspase target protein containing the proteolytic cleavage site (DQVD), and the transcription factor Gal4 (Fig. 1b). Upon caspase cleavage, Gal4 is released and translocates to the nucleus where, in combination with the G-trace lineage tracing system14, it catalyzes DNA recombination that results in permanent GFP expression in that cell and all of its progeny11. In the presence of Gal80ts, Gal4 activity is repressed at 18 °C. We grew animals at 18 °C to the mid-third instar larval stage to silence reporter activity during normal development. Larvae were then exposed to 2 hrs heat shock at 37 °C or 10 Gy X-ray and transferred to 29 °C to allow Gal4 to function (Fig. 1c). After 24 h at 29 °C, we stained for cleaved Dcp-1 to detect dead cells. We note that cleaved Dcp-1 (cDcp1), which is an active form of the executioner caspase Dcp-1, accumulates detectably only in dead cells. In living/recovering cells, active caspase turns over rapidly and does not accumulate15. Moreover, dead/dying cells shrink, further concentrating the signal in small, intense clusters. Dead cells are also extruded and thus are primarily located in a different focal plane from the living epithelium. We confirmed that extensive apoptotic cell death occurs in the discs of irradiated or heat-shocked larvae13 (Supplementary Figure S1a–c).
To determine whether any cells that activated executioner caspase survived, we examined CasExpress flies for GFP expression. One day after stress, ~20% of cells in discs from heat-shocked larvae and ~30% of cells in the discs from irradiated animals were GFP+ (CasExpress+), compared to 0.9% in the mock-treated controls (Fig. 1d–f, m). Discs expressing a caspase-insensitive control sensor, in which the executioner caspase cleavage site DQVD is mutated to DQVA, showed no GFP+ cells after stress (Supplementary Figure S1d–f). The stress-induced CasExpress activation was blocked in discs that lacked the initiator caspase Dronc (Supplementary Figure S1g–i). We then tested whether caspase activation in the GFP+ cells required the pro-apoptotic proteins Reaper (Rpr), Head involution defective (Hid), and Grim (Fig. 1a). Drosophila lacking rpr, hid, and grim die as embryos16, precluding analysis of triple mutant larvae. Animals homozygous for rpr and grim and heterozygous for hid are viable to larval stages and exhibited a significant reduction in the percentage of GFP+ cells after stress (Fig. 1g–i, m), indicating that CasExpress activation depends on these initiators of apoptosis.
To determine whether the GFP+ cells in the stressed discs ultimately contributed to the regenerated discs, after stress and one day at 29 °C, we transferred the larvae back to 18 °C for an additional 3 days recovery (Fig. 1c). At the time of dissection, all GFP+ cells should be the progeny of cells that activated executioner caspase during the one day at 29 °C. Four days after stress, the discs exhibited normal morphology (Supplementary Figures S1j–l), and the cDcp1+ dead cells in the discs were diminished (compare Supplementary Figures S1m–o to Supplementary Figures S1a–c), indicating the discs had regenerated. Importantly, a large proportion of the regenerated discs were GFP+ (Fig. 1j–m), and some of the GFP+ cells were proliferating, demonstrated by co-localization of GFP and phospho-histone H3 (PH3) staining (Supplementary Figure S1p). Therefore, we conclude that cells that survived stress-induced executioner caspase activation contributed to tissue regeneration following injury.
To determine whether cells that survived stress-induced executioner caspase activation were capable of differentiating, we examined regenerated eye discs after radiation. In early larval stages, like wing discs, eye disc cells are proliferative. At the beginning of the third instar, cells begin to differentiate into multiple cell types including photoreceptor neurons. We irradiated larvae carrying CasExpress, G-trace, and Gal80ts, and transferred them to 29 °C for 1day to allow Gal4 to function prior to the initiation of differentiation, and then returned them to 18 °C (Supplementary Figure S1q). After 4 days at 18 °C, we found a large proportion of differentiated neurons (elav+) were GFP+ cells (Supplementary Figure S1s), indicating that cells that survived X-ray-induced executioner caspase activation can differentiate normally.
Cells can survive rpr-induced executioner caspase activation
To test whether cells can recover from more direct activation of the apoptotic pathway caused by overexpression of the pro-apoptotic protein Rpr, we used the LexA/lexO transcription system to drive rpr specifically in the central spalt (sal) domain of the wing pouch (Fig. 2a). We used a Gal80-regulatable version of LexA, LHG, and Gal80ts, to control the timing of rpr overexpression17,18 (Fig. 2a). As expected, discs overexpressing rpr for one day exhibited intense executioner caspase activation and cell death, as shown by accumulation of cells with cDcp1 and pyknotic nuclei (Fig. 2b–b”’). To test if any rpr-overexpressing cells survived, we used L-trace (Fig. 2c) which, similar to G-trace, permanently labels cells that originate from the sal-LHG-expressing region with GFP. After rpr overexpression for one day at 29 °C, larvae were transferred back to 18 °C for recovery. Three days later, the dead cells had been mostly eliminated and normal disc morphology restored (Fig. 2e-e”). A large fraction of the rpr-overexpressing cells died and were eliminated from the epithelium (compare Fig. 2e to d). However, the presence of GFP+ cells in the restored epithelium (Fig. 2e) indicated that a fraction of cells can survive transient rpr overexpression.
To assess whether these survivors had experienced executioner caspase activation or had simply escaped either rpr expression or caspase activation, we used CasExpress and G-trace to monitor survival from executioner caspase activation following rpr overexpression (Fig. 2f). Compared to controls in which rpr was not overexpressed (Fig. 2g), we found increased CasExpress+ (GFP+) cells in the recovered epithelium after one day of rpr overexpression at 29 °C (Fig. 2i). After 3 days regeneration at 18 °C, few CasExpress+ cells were present in the control without rpr overexpression (Fig. 2h), compared to the regenerated epithelium (Fig. 2j). The CasExpress+ cells in the regenerated epithelium were at the same location (middle of the pouch) and abundance as those that survived transient rpr overexpression (compare Fig. 2j to e), indicating that most, if not all, rpr-overexpressing cells experienced executioner caspase activation. While many cells died, some survived and remained in the regenerated discs. After 2 days of regeneration, phospho-histone H3 (PH3) staining showed actively proliferating CasExpress+ cells (Fig. 2k-k”’).
Developmental CasExpress activation depends on apoptosis-inducing signals
We previously showed that ~1% of cells in a growing disc activate CasExpress during any given 24-h period of normal disc development (Fig. 1d, m)11. Activation of CasExpress during normal development is dependent on the upstream caspase Dronc (Supplementary Figure S1g)11, and is thus distinct from the more recently described phenomenon of “basal” caspase activation in discs, which is Dronc-independent19. To gain further insight into the cellular and molecular mechanisms driving CasExpress activation, we set out to knockdown or overexpress genes and assess their effects on CasExpress. However, the original CasExpress employs Gal4/UAS and FLP/FRT, precluding Gal4/UAS-mediated RNAi or overexpression. To circumvent this limitation, we redesigned the CasExpress sensor. We replaced Gal4 with LexA and G-trace with L-trace, which is the LexA-responsive version of G-trace (Fig. 3a). Similar to the Gal4/UAS version, the LexA construct (henceforth referred to as L-CasExpress) showed a large fraction of GFP+ (CasExpress+) cells in third larval instar wing discs (Fig. 3b, b’). Although ~50% of disc cells are GFP+ by this stage, it is important to note that this reflects the sum of all cells that activate the sensor at any point in development and all of their progeny. Within any given 24 h period, only ~0.9% cells activate CasExpress (Fig. 1d, m).
To test L-CasExpress activation for Dronc dependence and establish a quantitative RNAi screening assay, we used engrailed-Gal4 (en-Gal4) to express UAS-dronc RNAi specifically in the posterior compartment of the wing disc. The anterior compartment thus serves as an internal control. Compared to the white (w) RNAi control (Fig. 3c, c’), knocking down dronc blocked L-CasExpress activation (Fig. 3d, d’) indicating that L-CasExpress, like the original CasExpress, is Dronc-dependent. To quantify the effect of dronc RNAi (or any UAS transgene) on L-CasExpress activation, we calculated the ratio of the percentage of cells that were GFP+ in the posterior compartment to that in the anterior compartment (CasExpress P/A) (Fig. 3e, j).
Using this assay, we found overexpression of P35, a baculovirus protein that specifically binds and inhibits the executioner caspases, virtually abolished L-CasExpress activation (Supplementary Figure S2a, b). We further tested which of the two Drosophila executioner caspases, Drice and Dcp-1, is required for CasExpress activation. We found that drice RNAi reduced CasExpress activation (Fig. 3f, f’ and j), whereas loss of dcp-1 had no measurable effect (Supplementary Figure S2c–e). This is notable because apoptosis induction in wing discs requires Drice but not Dcp-120,21, whereas basal caspase activation depends on both19. Thus, CasExpress activation, like apoptotic induction20, reflects Drice activation during wing disc development.
Expression of miRGH, a microRNA that targets three pro-apoptotic genes rpr, hid, and grim22,23 also reduced CasExpress activation (Fig. 3g, g’, j). Animals homozygous for rpr and grim, and heterozygous for hid, exhibited a nearly 20-fold reduction in GFP+ imaginal disc cells (from 54 to 3%, Supplementary Figure S2f–h). Therefore, developmental CasExpress activation, like apoptosis—but unlike basal caspase activity19—depends on Rpr, Hid, and Grim, Dronc, and Drice, but not Dcp-1. Although some cell types, such as sperm, require the upstream apoptotic cascade and caspase activation for normal differentiation24,25, the patterns of L-CasExpress and such non-apoptotic caspase activation are different: Caspase is activated in every sperm cell at precisely the same stage of development25; whereas activation of CasExpress in the wing disc occurs in a subset of cells and is sporadic over time (ref. 11 and this study). Together, the data, therefore, suggest that CasExpress+ cells are cells that survive apoptotic executioner caspase activation during normal development.
These findings suggest that some cells sporadically experience endogenous, apoptosis-inducing stress during normal wing disc development, which is consistent with the fact that apoptotic cell death occurs in wing discs without any externally imposed stress26. To test this hypothesis, we inhibited Jun N-terminal kinase (JNK), a well-established stress-activated kinase27. Overexpression of the JNK inhibitor puckered (puc) (Fig. 3h, h’) or knockdown of the Drosophila JNK, called basket (bsk) (Fig. 3i, i’) reduced L-CasExpress activation (Fig. 3j). Using a JNK activity reporter, TRE:DsRed28, we found that active JNK was present in the scutellum region but barely detectable in the pouch or hinge regions of normal wing discs (Fig. 3k, k’). Overexpression of p35, which blocks the execution of apoptosis and thereby leads to the abnormal accumulation of stressed cells, caused an increase in the number of cells with activated JNK (Fig. 3l, l’), suggesting activated JNK normally eliminates stressed cells by apoptosis. These data together suggest that during development, transient apoptotic stresses activate JNK signaling, which in turn initiates executioner caspase activation. Cells that die are rapidly removed from the epithelium, while others survive as L-CasExpress+ cells.
Identification of genes that regulate survival from stress-induced caspase activation
A key unanswered question is what molecular mechanisms rescue cells from stress-induced executioner caspase activation. To address this question, we crossed en-Gal4 and UAS-RNAi lines, together with the newly developed L-CasExpress sensor and L-trace, to screen for genes that enhanced or suppressed survival from stress-induced executioner caspase activation during development (Fig. 4a). We reasoned that genes associated with stress responses, growth, survival, and regeneration29 would be good candidates.
We measured the percentage of cells with CasExpress activation in the RNAi-expressing compartment compared to the percentage in the control compartment (CasExpress P/A) (Fig. 3e). By taking the percentage, we normalized for general effects on growth and survival since these should equally affect GFP+ and GFP− cells. The percentage of GFP+ cells measures the frequency of survival from executioner caspase activation. A change in CasExpress activation could in principle result either from a change in the fraction of cells that activate executioner caspase and/or a change in the capacity to survive executioner caspase activation. To distinguish between these two possibilities, we used cDcp1 staining to assess cell death. If a gene is required for cell survival from executioner caspase activation, we expect RNAi to cause an increase in the percentage of cDcp1+ dead cells (cells that die after executioner caspase activation) at the expense of CasExpress+ cells (cells that live after executioner caspase activation). By contrast, if knocking down a gene affects apoptosis initiation and/or caspase activity but not the capacity to survive executioner caspase activation, we expect the percentages of CasExpress+ cells and of cDcp1+ dead cells to change in the same direction (Fig. 4a). However, due to the very low level of cDcp1+ cells in control tissues, it is difficult to detect a significant reduction of cDcp1+ cells. Thus, in discs with decreased CasExpress activation, if the percentage of cDcp1+ cells did not increase, we considered that the knockdown more likely affected caspase activation.
We screened 102 RNAi lines targeting 84 different genes which, when combined with en-Gal4, survived to late third instar (Supplementary data set 1). RNAi against the w gene served as a negative control (Fig. 4b, b’). We found 13 genes that, when knocked down, increased both the percentage of CasExpress+ cells and the percentage of cDcp1+ dead cells, indicating that knocking down these genes led to executioner caspase activation in more cells (Fig. 4a, Supplementary data set 1). (Note that any given cell is typically either CasExpress+ and alive, or cDcp1+ and dead). Some known, general pro-survival and proliferation genes like thickveins (tkv), STAT92E, jub, Notch (n), appeared in this category (Supplementary Figure S3a–c, Supplementary data set 1). We found knockdown of any of 7 genes reduced the percentage of CasExpress+ cells without elevating the percentage of cDcp1+ cells (Supplementary data set 1), suggesting knocking down these genes reduced executioner caspase activation frequency within the compartment. One gene in this category is expanded (ex), a known tumor suppressor. Knocking down ex abolished CasExpress+ cells but did not induce extra cDcp1+ cells (Figure S3d–f), consistent with the known effects of ex on expression of apoptosis inhibitors like Diap1 and bantam30. Interestingly, we identified 3 genes, akt1, bip2, and CG8108 for which RNAi resulted in a reduced percentage of CasExpress+ cells (Figs. 4c–d, 5a–c, Supplementary Figure S3g–h) and increased percentage of cDcp1+ dead cells (Figs. 4f, g, 5d–f, Supplementary Figure S3i), indicating these genes are required for survival from executioner caspase activation.
Akt1 is required for survival from stress-induced executioner caspase activation
To test directly whether Akt1 is required for survival following an imposed apoptosis-inducing stress, we heat-shocked enGal4; UAS-akt1RNAi larvae and evaluated the effect on L-CasExpress activation one day later. In this genotype, developmental L-CasExpress activation is not blocked before stress, so even unstressed (mock-treated) animals exhibit L-CasExpress activity. Nevertheless, heat shock-induced a significant increase in L-CasExpress activation in the anterior compartment of the wing discs, where akt1 RNAi was not expressed (Fig. 4h, h’, i). In contrast, no significant heat-shock-induced increase in L-CasExpress activation was detected in the akt1 RNAi-expressing compartments (Fig. 4h, h’, i).
CG8108, a Drosophila homolog of CIZ1, is essential for survival from executioner caspase activation
Of the 102 RNAi lines we tested for effects on CasExpress activation, two (BL#36665 and BL#28329) were supposed to target the gene chico. When expressed with en-Gal4, both reduced CasExpress activation (Fig. 5a, a’, c, Supplementary Figure S4a, b). However, expression of BL#28329 dramatically increased the number of cDcp1+ cells (Fig. 5d, d’, f) whereas BL#36665 did not (Supplementary Figure S4a”). We thought that BL#28329 might provide a stronger knockdown than BL#36665, so we used qPCR to compare their effects on chico mRNA levels. Surprisingly, BL#36665 reduced chico mRNA level to one-fourth, whereas BL#28329 had no measurable effect (Figure S4c), indicating BL#28329 did not target chico.
To identify the likely target of this RNAi line, we sequenced the hairpin and found that BL#28329 targeted CG8108, rather than chico, indicating that it was mislabeled in the stock center. We confirmed with qPCR that expression of BL#28329 reduced the mRNA level of CG8108 by half (Figure S4d).
CG8108 is an uncharacterized gene encoding a protein homologous to human CDKN1A-interacting zinc finger protein 1 (CIZ1). A second RNAi line against dCIZ1 (CG8108) (BL#27562) caused similar phenotypes as BL#28329, including reduced CasExpress activation (Fig. 5b, b’, c) and increased cDcp1+ cells (Fig. 5e, e’, f). These phenotypes were rescued by overexpression of dCIZ1 (Fig. 5g–j). Furthermore, dCIZ1 knockdown prevented heat-shock- or radiation-induced L-CasExpress activation (Fig. 5k–m). These data together suggest dCIZ1 is essential for survival from executioner caspase activation.
Overexpression of dCIZ1 was not sufficient to protect against rpr-induced apoptotic cell death (Supplementary Figure S5a–c). There was no cleaved form of dCIZ1 specific to apoptotic cells (Supplementary Figure S5d). Nor was there a detectable physical interaction between dCIZ1 and Drice or cleaved Drice (Supplementary Figure S5e), suggesting dCIZ1 may not promote survival through direct interaction with Drice.
dCIZ1 required for survival from executioner caspase activation in tissues with activated PI3K/Akt signaling
The phosphinositide-3-kinase (PI3K) pathway (Supplementary Figure S6a) is associated with cell proliferation and survival in many contexts31. RNAi screening revealed potent effects—some expected and others not—of multiple components of PI3K pathway on cell death and on CasExpress activation (Supplementary Figure S6b–g, Supplementary data set 1). For example, the phosphatase and tensin homolog (PTEN) is a negative regulator of PI3K signaling and an established tumor suppressor31. RNAi against pten resulted, unsurprisingly, in compartment overgrowth (Fig. 6a, a’, f). However, pten RNAi also resulted in increased apoptotic cell death detected with anti-cDcp1 staining (Fig. 6a, a’), suggesting that tissue overgrowth due to hyperactive PI3K signaling might cause stress and induce apoptosis. Increased CasExpress activation in the pten RNAi-expressing compartment (Fig. 6b, c) shows not only increased death but also increased survival following apoptotic caspase activation.
The pattern of increased cDcp1 and CasExpress indicates that pten loss increased apoptotic induction of caspase activity (Fig. 4a). To test this idea, we inhibited rpr/hid/grim expression in cells expressing pten RNAi. Overexpressing miRGH in the wing disc compartment expressing pten RNAi reduced CasExpress activation by two-thirds (Fig. 6d, e) and virtually eliminated cDcp1+ dead cells (Fig. 6d”). Thus, the executioner caspase activation and cell death within the pten RNAi compartment required pro-apoptotic genes. The observation that miRGH expression in the pten RNAi domain further increased the compartment size by 15% (Fig. 6f), suggests that apoptosis restrained tissue overgrowth to some extent.
To test which effects of pten RNAi were consequences of activation of PI3K pathway, we manipulated PI3K signaling in the pten RNAi compartment. Knocking down the catalytic subunit of the PI3K complex, pi3k92e, together with pten RNAi suppressed CasExpress activation, cDcp1+ dead cells (Fig. 6g, h), and overgrowth (Fig. 6i). Furthermore, overexpression of pi3k92e elevated both cell death (Fig. 6j) and CasExpress activation (Fig. 6k, l). Similar to pten RNAi, pi3k92e-induced CasExpress activation and cell death was inhibited by overexpression of miRGH (Fig. 6m, n). Constitutively activated akt1 (myr:akt1) caused similar effects (Fig. 6o–s). These data suggest that activation of PI3K-Akt1 signaling promotes tissue overgrowth, which results in apoptotic stress in the overgrown compartment, possibly due to overgrowth-induced cell crowding32 and/or competition for nutrients or survival factors33,34. However, activated Akt1 also promotes survival from executioner caspase activation, which contributes to tissue overgrowth (Fig. 7i). These results underscore the multifaceted effects of PI3K/Akt signaling on multicellular tissues.
The discovery of dCIZ1 as an important regulator of cell survival from caspase activation during normal development raised the question as to whether survival from executioner caspase activation generally requires dCIZ1. We found that CasExpress activation in pi3k92e-overexpressing discs (Fig. 7a-a”) was eliminated by dCIZ1 knockdown (b-b” and f), indicating an essential role of dCIZ1 in promoting survival in the context of activated PI3K. Next, we tested the effect of dCIZ1 RNAi on myr:akt1-induced CasExpress activation. Knocking down dCIZ1 significantly suppressed myr:akt1-induced CasExpress activation (Fig. 7c–e, g). Because both UAS-myr:akt1 and the two Bloomington dCIZ1 RNAi are on the third chromosome, we used another dCIZ1 RNAi from Vienna Drosophila Resource Center, vdrc35344, in this experiment. Similar to BL#28329 and BL#27562, expression of vdrc35344 increased the fraction of cDcp+ dead cells (Supplementary Figure S7a). The increased cell death in vdrc35344-expressing discs was rescued by co-expressing dCIZ1 (Supplementary Figure S7b), suggesting vdrc35344 targets on dCIZ1.
It has been reported that knocking down CIZ1 in human prostate cancer cells reduced Akt expression35. However, neither the Akt level (Fig. 7h) nor the PI3K-induced Akt phosphorylation was affected in dCIZ1 RNAi discs (compare Fig. 7a”, b”). These data together are consistent with a function for dCIZ1 downstream of or in parallel to Akt1 (Fig. 7i), although we cannot formally exclude the possibility that dCIZ1 may act upstream of Akt1.
Akt1 and dCIZ1 promote survival of cells with oncogenic RasV12-induced executioner caspase activation
Hyperactivation of PI3K-Akt1 signaling occurs in a large variety of human cancers. The human PIK3CA gene, which encodes the catalytic subunit of the PI3K complex, is the second most frequently mutated oncogene, and PTEN is one of the most frequently mutated tumor suppressor genes31. The discovery of induced apoptotic stress and survival from executioner caspase activation in tissues with activated PI3K-Akt signals led us to test whether expression of another common oncogenic mutation, RasV12, would also induce autonomous apoptotic stress and subsequent survival from executioner caspase activation. Expression of rasV12 with en-Gal4 was lethal, so we used Gal80ts to limit the expression to three days. Expression of oncogenic rasV12 in the posterior compartment led to a more than two-fold increase in the fraction of cells with CasExpress activation (Fig. 8a, b). Strikingly, few if any cDcp1+ cells were detectable (Fig. 8c), indicating that most cells that activated executioner caspases survived. Co-expressing miRGH to inhibit apoptosis induction in the rasV12-expressing compartment suppressed the elevated CasExpress (Fig. 8b, d). We conclude that rasV12-induced CasExpress activation requires apoptosis induction.
Mild activation of executioner caspases in scrib− rasV12 clones in eye discs can promote neoplastic growth36. However, in rasV12-expressing disc cells, overexpression of miRGH caused a small increase rather than reduction in the compartment size (Fig. 8e). Therefore, apoptosis restrains the overgrowth of tissues with oncogenic mutations including both rasV12 and, as shown above, PI3K. Counteracting this growth-inhibiting apoptosis, RasV12 also promotes survival from executioner caspase activation, which eventually contributes to tissue overgrowth. Promoting survival from caspase activation due to apoptotic stress represents a previously unknown function for activated Ras.
Consistent with a previous report that PI3K signaling is activated in rasV12-expressing cells37, we detected increased active Akt1 (phospho-Akt1) in the rasV12-expressing compartment (Fig. 8f). Knocking down akt1 in the rasV12-expressing compartment blocked the induced CasExpress activation (Fig. 8g–h), suggesting RasV12 promotes survival from executioner caspase activation through Akt1. Knocking down dCIZ1 in rasV12-overexpressing discs also suppressed CasExpress activation (Fig. 8i, j), induced apoptotic cell death (Fig. 8k, l), and suppressed RasV12-induced tissue overgrowth (Fig. 8m). Compartments co-expressing dCIZ1 RNAi and rasV12 showed high Akt1 activity (Fig. 8n), again indicating dCIZ1 may function downstream of or in parallel to Akt1.
Based on these data, we propose that during RasV12-induced oncogenic transformation, competing death and survival signals are activated. Apoptosis is initiated and executioner caspases are activated, either as a homeostatic mechanism or as a consequence of nutrient-deprivation, hypoxia, or mechanical stress. In any case, dCIZ1 and activated Akt1 in the transformed cells promote survival of stressed cells, thereby contributing to oncogenic overgrowth (Fig. 8o).
Discussion
Here we show that cells can survive executioner caspase activation induced by apoptotic signals during normal development, following imposed apoptosis-inducing stresses such as heat shock, radiation, and rpr overexpression, and in response to oncogene activation. We show that cells can survive executioner caspase activation and contribute to tissue regeneration following severe imposed stresses. The wing disc is a highly regenerative tissue. It can regenerate even after half of the cells die38. A widely-acknowledged mechanism underlying wing disc regeneration is apoptosis-induced proliferation, in which apoptotic cells emit mitogenic signals to promote proliferation of surrounding healthy cells18,39,40,41. The initiator caspase Dronc is required for mitogenic signal production in apoptotic cells42. Apoptosis and executioner caspases also play indispensable roles in regeneration in other model organisms like planaria, hydra, and mice43,44,45,46,47. For example, loss of either caspase-3 or -7 impairs skin wound repair and liver regeneration in mice44. In the classic apoptosis-induced regeneration model, cells initiate apoptosis, activate executioner caspases, and die; the regenerated epithelium originates from healthy cells that never activate executioner caspase. Here we report that even cells that activate executioner caspases can survive and participate in regeneration.
The fraction of the regenerated epithelium that originates from cells that survive apoptotic caspase activation varies depending on the conditions. In irradiated larvae, the majority of cells in the recovered disc are progeny of cells that have experienced executioner caspase activation (Fig. 1). In contrast, when discs regenerate after local and transient rpr overexpression, fewer CasExpress+ cells contribute to recovery (Fig. 2). The difference could be due to different rates or levels of caspase activation20 and/or to competition from unstressed cells48,49. In the radiation experiments, all cells were stressed whereas rpr overexpression was limited to a small fraction of the disc, so there was a large pool of unstressed cells nearby. These findings suggest that salvaging cells from executioner caspase activation may be particularly important for recovery from a transient apoptosis-inducing stress that affects an entire organ or organism, such as systemic chemotherapy.
One hallmark of cancer is the capacity to evade cell death. An apparent paradox is that caspase activity is prevalent in gastric and breast cancers, melanoma, and lymphoma50,51,52, amongst others. In recent years, apoptosis and caspases have been shown to promote tumor growth, recurrence, and metastasis both autonomously and non-autonomously36,53,54,55,56,57. After radiation or chemotherapeutic drug treatment, caspase 3-dependent secretion of growth factors in apoptotic tumor cells can trigger repopulation of non-apoptotic tumor cells and angiogenesis54,55,56,58. Apoptotic lymphoma cells can modify the tumor microenvironment and activate tumor-associated macrophages to promote tumor progression57.
In addition to these paracrine effects on tumor progression, executioner caspase activity can also autonomously drive tumor growth and metastasis in Drosophila36 and mouse models53. In this study, we found that PI3K activation and oncogenic RasV12 mutation, two of the most frequent molecular alterations in tumors, can promote cell survival from apoptotic executioner caspase activation. Our observation that inhibition of survival from executioner caspase activation in rasV12-expressing tissues suppressed overgrowth demonstrates that recovery from apoptotic caspase activation represents a previously unrecognized mechanism by which RasV12 promotes survival.
We identified Akt1 as an essential driver for survival from executioner caspase activation. As a pro-survival protein, Akt is well known to inhibit apoptosis upstream of caspase activation and mitochondrial permeabilization59,60. Our work reveals the capacity of Akt1 to promote cell survival after executioner caspase activation in response to apoptotic stresses, consistent with one study that shows that Akt can inhibit apoptosis even after mitochondrial outer membrane permeabilization, at least in one cell type61. Khalil et al.62 found that exposure of multiple cell types and tissues to apoptosis-inducing radiation or chemicals results in stress-induced Akt activation that is dependent upon caspase 3 induction of apoptosis and necessary for tissue repair and animal survival. Though they did not show Akt was activated in the very same cells that activated caspase 3, since they did not have a CasExpress-like reporter, it seems likely that they detected Akt-mediated survival after executioner caspase activation. These, together with our data, suggest the regulation of survival from executioner caspase activation may be conserved from flies to mammals.
It is exciting then, that in addition to Ras and PI3K/Akt1, the fly screen revealed the importance of CG8108 (dCIZ1). Though there are no published functional studies on dCIZ1, it was identified in the interactome of stress-activated MAP kinases63. Remarkably, it also emerged in a PI3K interactome64. The human homolog of dCIZ1 has many attributes consistent with a determinant that promotes survival in the face of tissue damage. For example, CIZ1 binds and inactivates the senescence-promoting protein p21Cip1/Waf165, thus antagonizing DNA-damage-induced proliferation arrest. It has reported roles in DNA replication66, cell cycle progression67, transcription68,69,70, and epigenetic regulation71. CIZ1 can promote tumor growth and metastasis70,72,73,74 and protect cells from radiation-induced DNA damage and apoptosis75. ciz1−/− mice develop neurodegenerative phenotypes during aging75; whereas overexpression of CIZ1 in cardiomyocytes protects the heart from ischemia-reperfusion injury76, a physiological condition in which cells survive caspase-3 activation9. CIZ1 is also overexpressed in many solid tumors67,77. All these studies suggest the role of CIZ1 in promoting survival from stress-induced executioner caspase activation may be conserved from Drosophila to mammals. Activation of PI3K-Akt signaling and oncogenic Ras are common in tumors. The fact that loss of dCIZ1 blocked survival in tissues with high level of PI3K-Akt1 activity or RasV12, suggests it would be an excellent therapeutic target for cancer treatment. The discovery of dCIZ1 as a general regulator of survival from executioner caspase activation in development, regeneration, and oncogene-driven proliferation thus represents a significant advance.
Methods
Fly stocks
To construct the L-CasExpress sensor, DNA encoding mCD8, and amino acids 2-147 of Diap1 (mCD8-DQVD) was cloned from the previously reported CasExpress sensor11. DNA encoding lexA::p65 fusion protein was cloned from pBPLexA::p65Uw (Addgene#26231). The mCD8-DQVD and lexA::p65 fragments were then ligated into pattB-Ubi vector11 using In-Fusion Cloning Kit (Clontech). The construct was injected into attP2 site by BestGene Inc.
To make UAS-dCIZ1:3Xflag transgenic flies, we cloned the cDNA of dCIZ1 using clone LD27033 (Drosophila Genomics Resource Center) as the template and put it into the pJFRC7-20XUAS vector (made from Addgene#26220). The construct was injected into attP40 site by BestGene Inc.
All the RNAi stocks used in the RNAi screening are listed in Supplementary data set 1. The other fly stocks used in this study are listed in Supplementary Table S1. The L-trace flies were made through recombination of lexO-flp (II) and FRT-STOP-FRT-GFP (II).
The genotypes of the samples shown in the figures are listed in Supplementary Table S2.
Stress and recovery assays
For all stress and recovery experiments including heat shock, radiation, and transient rpr overexpression, embryos were collected in an 8 h window at 25 °C, and the embryo collection plates were then transferred to 18 °C. 2 days after embryo collection, larvae were collected into food vials with additional dry yeast at 50 larvae per vial. For heat shock and radiation, larvae were heat shock at 37 °C for 2h or irradiated with 10 Gy X-ray at 0.3069 Gy/min on day 7 after egg-laying, then transferred to 29 °C for 1d, followed by dissection or an additional 3 days at 18 °C. For transient rpr overexpression, on day 7 after egg-laying, larvae were shifted to 29 °C for 1d, then the larvae were either dissected or shifted back to 18 °C for recovery.
RNAi screening
CasExpress is activated in sperm due to the essential role of executioner caspase in sperm differentiation25. Thus CasExpress and L-trace need to be kept in separate stocks. We first made en-Gal4 UAS-RFP/CyOGFP; L-CasExpress/TM6B stock and en-Gal4 UAS-RFP L-trace/CyO stock for RNAi screening. Each UAS-RNAi on the third chromosome was crossed into L-trace background, and the L-trace/CyOGFP; UAS-RNAi/TM6B flies were then crossed to en-Gal4 UAS-RFP/CyOGFP; L-CasExpress/TM6B flies to get the en-Gal4 UAS-RFP/L-trace; L-CasExpress/UAS-RNAi larvae. Each UAS-RNAi on the second chromosome was crossed into L-CasExpress background, and the UAS-RNAi/CyOGFP; L-CasExpress/TM6B flies were then crossed to en-Gal4 UAS-RFP L-trace/CyO flies to get en-Gal4 UAS-RFP L-trace/UAS-RNAi; L-CasExpress/+ larvae. For genes like akt1, which when knocked down at 25 °C causes lethality, we used Gal80ts to limit the knock-down to 3 days. The wing disc dissection, imaging, and quantification procedures are described in detail in the following sections. RNAi that caused a statistically significant change higher than 20% on CasExpress P/A were considered as candidates for regulators. Among the candidates, only those with cDcp1+ cells changed in the direction opposite to change in CasExpress P/A were considered as regulators for survival from executioner caspase activation.
Immunostaining and imaging
Larvae at mid or late third instar were dissected and fixed in 4% paraformaldehyde (Electron Microscope Sciences) for 20 min at room temperature. After fixation, samples were rinsed with PBS twice and washed with PBS + 0.2% Trition X-100 (Sigma) (0.2% PBT) for 20 min. Samples were then blocked with 5% goat serum in 0.2% PBT for 30 min, followed by overnight incubation with primary antibody solution at 4 °C. Next day, the samples were washed with 0.2% PBT three times, and incubated with secondary antibody and Hoechst solution (Molecular Probes) for 1 h at room temperature. Samples were then washed three times with 0.2% PBT and mounted on slides using Vectashield mounting medium (Vector Laboratories). The primary and secondary antibodies used in the immunostaining are listed in Supplementary Table S3. Images were taken using Zeiss LSM 780 confocal microscope and Zeiss LSM 880 confocal microscope. The software used in image capture is Zen Black (version 14.0, Zeiss).
Image analysis and quantification
All the image analysis and quantification were done using ImageJ (version 2.0). To evaluate the effect of transgene on CasExpress activation, the GFP+ nuclei area and total nuclei area in both the posterior compartment (P) and the anterior compartment (A) was measured. Then the percentage of GFP+ nuclei in each compartment was calculated, and CasExpress P/A ratio was calculated. To quantify cell death, cDcp1+ area and RFP area were measured and the ratio between them was calculated.
RNA extraction, reverse transcription, and qPCR
For each genotype, about 50 late third instar wing discs were dissected in PBS, and immediately transferred to TRIZOL (ThermoFisher Scientific). The total RNA was extracted using standard TRIZOL RNA extraction protocol. Turbo DNase (ThermoFisher Scientific) was used to remove genomic DNA contamination. Reverse transcription was done using SuperScript III First-Strand Synthesis System (ThermoFisher Scientific). qPCR was done using SsoAdvanced Universal SYBR Green Supermix (Bio-rad) on Bio-rad CFX96 real-time PCR detection system. The data were collected using Bio-rad CFX Manager software (version 3.1, Bio-rad). The primers used for qPCR were listed in Supplementary Table S4.
Transfection, protein sample preparation, co-immunoprecipitation, and western blotting
Drosophila S2 cells (Thermo Fisher Scientific) were cultured in Schneider’s Drosophila medium (Thermo Fisher Scientific) supplemented with 10% fetal bovine serum (Sigma) and 100U/ml Penicillin-Streptomycin (Thermo Fisher Scientific). One day before transfection, S2 cells were seeded in 6-well plates. pMT-Gal4 plasmid and pJFRC-20XUAS-dCIZ1:3Xflag plasmid were transfected into S2 cells using Effectene Transfection Reagent (Qiagen) following the manual. Next day, 500 μM CuSO4 was added to the cells to induce Gal4 expression. After one-day induction, cells were collected and lysed in RIPA buffer (for western blotting) or TBS with 1% Trition X-100 (for co-immunoprecipitation) supplemented with 1 mM PMSF. Co-immunoprecipitation was done using anti-FLAG M2 magnetic beads (Sigma). The protein samples were applied to 10% SDS-PAGE. The primary antibodies used in western blotting are listed in Supplementary Table S3. The original scans of all blots were in Source Data file.
Statistics and reproducibility
All the statistical analyses were done using Prism 6 software (GraphPad). Statistical significance was determined after logarithm transformation using unpaired two-tailed t-test for two-sample comparison or one-way ANOVA for multiple-sample comparison. The Tukey test was used to derive adjusted P-value for multiple comparisons. All experiments were independently repeated at least three times to ensure reproducibility, and the representative images are shown in the figures.
Reporting summary
Further information on research design is available in the Nature Research Reporting Summary linked to this article.
Data availability
All the raw data supporting the findings of this study are available from the corresponding authors upon request. Source data are provided with this paper.
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Acknowledgments
We thank Dr. David Bilder, Dr. Florenci Serras, Dr. Kristin White, Dr. Alfonso Martinez-Arias, Dr. Rachel K. Smith-Bolton, Bloomington Stock Center, and Vienna Drosophila Research Center for providing fly stocks. We thank James Mondo for the FIJI macro used for cDcp1 staining quantification. We thank Rebecca Cheng, Marni Nashimoto, Yufeng Wang, Xiaojiao Li, and Advanced Medical Research Institute, Shandong University for technical support. This work was supported by NIH grant DP1OD019313 to D.J.M.
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G.S. and D.J.M. designed the experiments. G.S., A.X.D., Y.A., and X.G. carried out the experiments. G.S. and D.J.M. prepared the manuscript.
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Sun, G., Ding, X.A., Argaw, Y. et al. Akt1 and dCIZ1 promote cell survival from apoptotic caspase activation during regeneration and oncogenic overgrowth. Nat Commun 11, 5726 (2020). https://doi.org/10.1038/s41467-020-19068-2
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DOI: https://doi.org/10.1038/s41467-020-19068-2
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