Abstract
Programmed cell death (apoptosis) is a homeostasis program of animal tissues designed to remove cells that are unwanted or are damaged by physiological insults. To assess the functional role of apoptosis, we have studied the consequences of subjecting Drosophila epithelial cells defective in apoptosis to stress or genetic perturbations that normally cause massive cell death. We find that many of those cells acquire persistent activity of the JNK pathway, which drives them into senescent status, characterized by arrest of cell division, cell hypertrophy, Senescent Associated ß-gal activity (SA-ß-gal), reactive oxygen species (ROS) production, Senescent Associated Secretory Phenotype (SASP) and migratory behaviour. We have identified two classes of senescent cells in the wing disc: 1) those that localize to the appendage part of the disc, express the upd, wg and dpp signalling genes and generate tumour overgrowths, and 2) those located in the thoracic region do not express wg and dpp nor they induce tumour overgrowths. Whether to become tumorigenic or non-tumorigenic depends on the original identity of the cell prior to the transformation. We also find that the p53 gene contributes to senescence by enhancing the activity of JNK.
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Introduction
Programmed cell death (apoptosis) is a response mechanism to eliminate cells that are unwanted during development [1,2,3] or are damaged by different stressors such as ionizing radiation (IR), heat shock (HS) or drug treatments [4]. The key molecules involved are cysteine proteases (caspases) that dismantle protein substrates and cause death of the affected cells. Caspases are present in all animal cells as inactive zymogens, which may become activated by various factors [5, 6]. The role of caspases as apoptosis executors is conserved in Metazoans [7], although the mechanisms of caspase activation vary among species.
Lack of apoptosis is known to have deleterious effects; it predisposes to the formation of tumours and also causes developmental anomalies [8]. It has been proposed that one of the hallmarks of cancer cells is that they avoid apoptosis [9], thus emphasizing the anti-tumour function of apoptosis. Work in Drosophila by us and others [10,11,12,13] has also shown that compromising apoptosis often results in tumorous overgrowths.
Because of its sophisticated genetics and readiness for experimental in vivo manipulation, Drosophila is a convenient system to analyse the consequences of the lack of apoptosis. The apoptosis program is well characterized, especially the response to IR (reviewed in [14, 15]). An outline of the program is shown in Fig. 1. After IR a number of upstream factors become active, which in turn lead to the activation of p53 and of the Jun N-Terminal Kinase (JNK) pathway. These two factors are the major contributors to IR-induced apoptosis; they can elicit apoptosis response independently [16,17,18,19], but also stimulate each other [20], what reinforces the apoptotic response. The cellular/genetic events initiated by p53 and JNK to cause cell death are well known: induction of pro-apoptotic genes like head involution defective (hid) or reaper (rpr), which in turn suppress the activity of the Drosophila inhibitor of apoptosis1 (Diap1) protein, thus allowing activation of the apical caspase Dronc and subsequently of the effector caspases Drice and Dcp1 (Fig. 1) (reviewed in [15]).
However, and importantly, JNK also has other non-apoptotic roles (Fig. 1, see review in [14]); it has a paracrine function that stimulates the proliferation of cells close to those expressing JNK. This pro-proliferation activity is likely due to secreted growth factors, like Decapentaplegic (Dpp) and Wingless (Wg), known targets of JNK and responsible for the overgrowths caused by “undead” cells, in which cell death is blocked by the effector caspases inhibitor P35 [11,12,13]. This paracrine function also plays a role in regeneration processes in which dying JNK-expressing cells stimulate the growth of surrounding tissue [21].
Another property associated with JNK activity is that it promotes cell migration, both in vertebrates [22, 23] and in Drosophila [13, 24, 25], which may lead to JNK-expressing cells invading neighbour compartments.
Thus, there are at least three distinct functions of JNK that have been characterized in imaginal cells: two endogenous (autocrine) activities - pro-apoptosis and pro-migration- and an exogenous (paracrine) one - pro-proliferation. After IR the pro-apoptotic function is predominant: the high apoptotic levels brought about by JNK activity kill the cells shortly after induction thus obliterating the pro-proliferation and pro-migration functions [19]. Previous work has shown that, upon IR or HS, tissues in which cell death is prevented develop overgrowths that require JNK activity [10, 11, 13].
As pointed out above, p53 induction by IR can cause apoptosis independently of JNK, but since both JNK and p53 stimulate each other [20] and both converge at the level of rpr and hid [15, 17, 19, 26], the overall apoptosis after IR is the result of joint activities of JNK and p53. However, the consequences of the activation of p53 in Apoptosis-Deficient cells (here thereafter referred to as AD cells) have not been investigated.
We have made use of various genetic conditions to study the outcome of subjecting AD tissues to IR. We find that many AD cells acquire high JNK levels and also attain typical features of senescent cells [27]: cellular hypertrophy, cell cycle arrest, oxidative stress, Senescent-Associated (SA) ß-gal activity and Senescent-Associated Secretory Phenotype (SASP). The latter is manifest by the secretion of the signalling molecules Unpaired (Upd), Dpp and Wg, which induce tumorous overgrowth of the surrounding tissue. The acquisition of all these features is completely dependent on JNK activity, for on its absence there is no sign of senescence.
We obtain similar results driving p53 activity in AD tissue, suggesting that the effects caused by IR are mediated by p53 activity. Furthermore, we have analysed the response to IR of AD tissue that is defective in p53 function. The lack of p53 significantly reduces senescence and the magnitude of the overgrowths caused by JNK, indicating that p53 is a major contributor to the senescence induced by JNK.
Results
Cells refractory to apoptosis become senescent after irradiation (IR)
We have assembled several genetic conditions in which cells cannot execute the apoptosis program: 1) dronc mutant cells cannot activate the effector caspases [28]. Larvae mutant for dronc develop to late third instar, thus allowing the isolation and manipulation of imaginal discs unable to execute the apoptosis pathway. 2) In discs of genotype hedgehog-Gal4, tub-Gal80ts (hhGal80 > ) UAS-miRHG (see full genetic notation in the Methods section) the activity of the three major pro-apoptotic genes rpr, hid and grim is prevented in posterior compartments by the expression of miRNAs that suppress the function of these genes [29]. 3) In discs of genotype hhGal80 > UAS-p35 the presence of the pan caspase inhibitor P35 blocks the activity of the effector caspases in the posterior compartment [30]. Those cells become “undead” and remain alive indefinitely after IR or HS [11, 13].
The activation of the apoptosis program in irradiated AD tissue permits the study of the consequences of unrestrained activity of JNK or p53. We previously reported that IR treatments (4000 R) to AD imaginal discs or compartments cause permanent JNK activity, which in turn produces large overgrowths [10]. We have confirmed this observation in discs of genotype hhGal80 > UAS-miRHG, TREred in which apoptosis is inhibited in the posterior compartment and JNK activity is monitored by the TREred construct, a reporter of overall JNK activity [31]. After IR, the posterior compartments develop large overgrowths, associated with ectopic and persistent activity of JNK (Supplementary Fig. 1a, b and e). The overgrowth of the posterior compartments is strictly dependent on JNK function because forcing expression of bskDN, which encodes a dominant negative form of the Jun Kinase Basket suppresses it [32] (Supplementary Fig. 1c, d, e).
Given the critical role of JNK in the process, we have paid special attention to the JNK-expressing TREred cells. These cells are generally grouped in patches of variable size distributed all over the AD tissue, although they tend to accumulate in the pouch region. On average, the TREred patches fill about 20–25% of the compartment (Supplementary Fig. 1b).
The TREred cells also exhibit a number of features, which are essentially like those described for senescent cells (SCs) in Drosophila and in vertebrates [27, 33, 34]. 1) Staining with Phalloidin to visualize F-actin shows that TREred cells are bigger than surrounding cells (Fig. 2a, b). 2) TREred cells do not divide, as indicated by the lack of incorporation of cell proliferation markers like EdU (5-ethynyl-2'-deoxyuridine) or the down regulation of the G2/M inducer String (Stg) (Fig. 2c, d). Staining with the Fly-Fucci cell cycle indicator [35] reveals that TREred cells are arrested at the G2 phase of the division cycle (Fig. 2e). 3) TREred cells show high levels of ß-gal activity indicating augmented lysosomal function (Fig. 2f), a typical feature of SCs, referred to as SA-ß-gal activity [27]. 4) They produce Reactive Oxygen Species (ROS) as observed by the activation of the oxidative stress response gene GstD (Fig. 2g) [36], another distinctive feature of senescent cells [27]. Moreover, as shown in Fig. 2f, g, the gain of ß-gal activity and of ROS production by the TREred cells is strictly dependent on JNK activity.
We also find a feature not normally associated with senescence, and that is that the TREred cells are able to transgress the antero-posterior (A/P) border and to invade neighbour compartments (Fig. 2h). In the case of the hhGal80 > UAS-miRHG, TREred experiment we find that in 84% of the discs (n = 37) TREred cells, which originate in the posterior compartment, can be found in the anterior one. We have quantified the fraction of the anterior compartment occupied by senescent cells of posterior origin and find it to be around 10%. This indicates a significant contribution to the anterior compartment.
A key feature of senescent cells is the Senescent Associated Secretory Phenotype (SASP); these cells secrete a number of factors, including cytokines, chemokines and metalloproteinases (reviewed in [33]), some of which are associated with inflammation and tumour development in mammalian tissues [37,38,39,40]. In our experiments we have analysed whether the TREred cells exhibit secretory phenotype by examining the expression of the genes upd, dpp and wg, which encode for the secreted ligands of the JAK/STAT, Dpp and Wg pathways respectively. These pathways are known to control growth in imaginal discs [41,42,43]. As shown in Fig. 3a–c, the three genes become ectopically activated in many TREred cells, although not in all. We also found many instances in which there is an increase of the proliferation of cells close to the TREred ones. This effect appeared to be restricted to the central region of the disc (Fig. 3d).
The “undead” cells are senescent
We have also analysed the response to IR and to HS of cells of the posterior compartment of discs of genotype hhGal80 > UAS-p35, UAS-GFP, TREred in which the presence of baculovirus protein P35 impedes the activity of effector caspases [30] and prevents cell death. This is the same type of experiment in which “undead” cells were described [11, 13]. As illustrated in Supplementary Fig. 2 these undead cells also express senescence biomarkers: they are bigger than surrounding cells, do not divide and produce ROS (Supplementary Fig. 2a–d). Moreover, these cells often invade neighbour compartment (Supplementary Fig. 2e), a feature we have reported previously [13, 21]. Previous work by us and others showed that these cells secrete the Dpp and Wg ligands [11,12,13]. We find similar results by generating TREred cells by heat shock (Supplementary Fig. 2f–i). All together, these results demonstrate the senescence nature of undead cells.
Diversity of SCs cells within the wing disc
In the hhGal80 > UAS-miRHG, TREred experiments above we observed (Fig. 3) that although some senescence biomarkers like size increase or ROS production were present in all TREred cells, there were some TREred cells that did not express the signalling genes upd, wg and dpp. This finding suggested an in vivo variability of SCs within the disc, which we have explored in detail. To this effect we irradiated discs of genotype dronc-; TREred, in which the entire disc is deficient in apoptosis, and examined the expression of senescence biomarkers in TREred patches in the different regions of the disc.
Confirming the preliminary observation, we find two types of TREred patches. One group expresses all the regular senescent biomarkers, e.g. cellular hypertrophy, cell division arrest, SA-ß-gal activity, ROS production (Fig. 4 and Supplementary Fig. 3), but do not show expression of the signalling genes upd, dpp and wg. The second group expresses the latter genes in addition to the rest of senescent markers (Fig. 4 and Supplementary Fig. 3).
Moreover, the two groups tend to appear in different regions of the disc. As illustrated in Fig. 4a–c, the TREred cells containing upd, wg and dpp expression appear preferentially in the pouch region of the disc, which contains the precursor cells of the appendage (the wing proper). This is more evident in the case of wg expression where its activation is restricted to the appendage domain. In contrast, those that do not express wg and dpp localize mostly to the thoracic domain of the disc, that includes the notum, and the peripheral region of the disc, which gives rise to the pleura, the ventral part of the thorax [44].
Another significant difference between the two groups of SCs is that those in the wing pouch appear associated with over proliferation of neighbour non-SCs, whereas those in the thoracic regions are not (Fig. 4d). We refer to those in the pouch as tumorigenic senescent cells (tSCs), and those in the thorax as non-tumorigenic (ntSCs). We note that the tumorigenic region corresponds very precisely with the appendage part of the disc, whereas the non-tumorigenic region (pleura and notum) corresponds to the thoracic part of the body (Fig. 4e).
We have tested separately the tumorigenic potential of the thoracic and appendage regions of the disc using the pannier-Gal4 (pnr > ) and the rotund-Gal4 (rn > ) lines, which drive expression in the proximal part of the notum and the wing region respectively [45, 46].
In IR-treated discs of genotype pnr > UAS-miRHG, UAS-GFP, TREred we observe in the Pnr domain the presence of numerous patches of TREred cells, which show typical senescence features like cellular hypertrophy, lack of cell division, cell motility or SA ß-gal activity (Supplementary Fig. 3e–g). However, there is no overgrowth of the Pnr domain, which remains of the same size as the control (Fig. 4g, h). In contrast, rn > UAS-miRHG, UAS-GFP, TREred IR-treated discs show a large overgrowth of the Rn domain (Fig. 4i, j)
The different kind of senescent cells in the thorax and the appendage was intriguing; one possibility was that the different local microenvironments of the two regions may influence the type, tSC or ntSC, of the cells, a position-derived effect. Alternatively, it could be determined by the original identity of the cells, thoracic versus appendage, prior to the transformation. To resolve this question, we performed an experiment to change the identity of appendage cells toward thoracic without modifying the position.
It is known that driving expression of the pnr gene in wing cells changes their identity from wing to notum [46]. We first confirmed this transformation in adult flies of genotype rn > UAS-pnr, which show a clear wing to notum transformation, as indicated by the presence of thoracic bristles and the typical notum pigmentation (Fig. 4f).
Next, we tested whether the change of identity driven by pnr in wing cells is reflected in the production of overgrowth, and hence on the type of senescent cell. The result (Fig. 4i, j) was that unlike the control rn > UAS-miRHG, UAS-GFP, TREred discs, which show a clear overgrowth, irradiation of discs of genotype rn > UAS-miRHG, UAS-GFP, TREred, UAS-pnr does not cause overgrowth (Fig. 4i). This result suggests that the original identity of the cell is a major factor that determines the type of senescence.
The preceding results demonstrate the existence of at least two classes of SCs in the wing disc, those that secrete the Upd, Dpp and Wg ligands and cause overgrowth in surrounding territory and those that do not. The transformation into tSC or ntSCs appears to be determined by the original identity of the cells, prior to the transformation.
Tumorous overgrowths induced by senescent cells; contribution of the JAK/STAT, Wg and Dpp pathways
The presence of SCs in the disc induce the formation of tumorous overgrowths (Supplementary Fig. 1), but detailed examination of division rates indicates that the SCs do not divide, but may stimulate proliferation of non-SCs in their vicinity (Fig. 2c), suggesting that the overgrowths are generated by over proliferating non-SCs.
Moreover, the observation that tSCs generate the Upd, Dpp and Wg growth signals suggests that they induce the activation of the JAK/STAT, Dpp and Wg pathways, which would presumably be responsible for the tissue overgrowth. We have checked this hypothesis in experiments in which the activity of each of those pathways is abolished or reduced in the posterior compartment by specific UAS-RNAi lines. The JAK/STAT pathway is compromised by suppressing the Stat92E transcription factor [41], the Dpp pathway by inactivating the Dpp ligand [47] and Wg by suppressing the function of the receptor Frizzled (Fz) [48].
Suppression of function of each of the pathways prevents the overgrowth of the posterior compartment, clearly demonstrating they are needed for the tumorigenic process (Fig. 5a–d).
We also find that in the absence of JAK/STAT, Dpp or Wg activity, the amount of TREred cells is significantly reduced (Fig. 5a–d), suggesting a correlation between the number of JNK-expressing cells and the overgrowth of the tissue. It also raises the possibility that the pathways above are required for the maintenance of JNK activity in AD cells. We also note that in spite of the diminution of the number of TREred patches, these can still migrate across compartment borders (Fig. 5). Thus, the lack of signalling does not affect the migratory property of SCs cells.
A principal conclusion from this section is that the JAK/STAT, Dpp and Wg pathways are critically required for the development of tumorigenic overgrowths. The specific contributions of each of them to the process and their functional interactions remain to be examined.
Induction of senescence by p53. Interactions with JNK
Acute activation of p53 after cellular stress has been shown to be implicated in the acquisition of senescence in mammalian cells [49, 50], and also in Drosophila [34], but the mechanism by which p53 contributes to senescence in Drosophila has not been studied.
It is known that in Drosophila p53 is activated after IR, in turn, it induces JNK activity and causes an immediate apoptotic response [15, 19]. Thus, the analysis of the non-apoptotic roles of p53 and of its implication in senescence requires the suppression of the apoptotic program in p53-expressing cells.
We have tested whether driving expression of p53 in AD tissue is able to generate senescent cells. To do this, we temporarily expressed p53 and the miRHG construct in the posterior compartment (hhGal80 > UAS-miRHG, UAS-p53). Posterior cells show strong JNK induction and overgrowth of the compartment (Fig. 6a, b). As in the IR experiments above, TREred positive cells acquire senescence characteristics, including morphology changes as visualized by F-Actin and Topro staining, cell cycle arrest at G2, SA-ß-gal activity, response to ROS and secretory phenotype, as shown by up regulation of upd, dpp and wg (Fig. 6c–i). We also find senescent cells of posterior origin that penetrate in the anterior compartment. These cells contain expression of dpp and wg (Fig. 6j), what suggests that they affect the growth of the surrounding tissue.
Importantly, many of these senescent features brought about by p53, including the ectopic activation of upd, dpp and wg and tissue overgrowth, are suppressed by blocking JNK activity with bskDN (Fig. 6a, b, g–i), indicating a functional interaction between p53 and JNK in the induction of senescence.
To analyse the contribution of p53 to the JNK-driven senescence we compared the levels of senescence, measured by the amount of TREred tissue and the size of the overgrown posterior compartments, of irradiated discs of genotypes hhGal80 > UAS-miRHG, TREred, UAS-p53-RNAi, in which p53 function is abolished and those of genotype hhGal80 > UAS-miRHG, TREred, which contain normal p53 activity and serves as a control.
The results are shown in Fig. 7. The lack of p53 function results in a large reduction of the overgrowth of the posterior compartment, as illustrated in Fig. 7a. The size of the posterior compartment with respect to that of the total in irradiated discs decreases from 53% to 42%, while in non-irradiated discs is 38% (Fig. 7b). Furthermore, there is also a large reduction in the amount of TREred tissue in the compartment, from 25 to 8% (Fig. 7c). In non-irradiated controls the amount of TREred tissue is negligible (Fig. 7a). These results clearly demonstrate that much of the cellular senescence caused by JNK is mediated by p53.
However, it was possible that p53 could be also involved in the mechanism maintaining the permanent JNK activity observed in AD cells after its initial activation. To check on this possibility we performed experiments to suppress p53 after JNK activity is established (Fig. 7d). In irradiated discs of genotype hhGal80 > UAS-p53-RNAi, UAS-GFP, dronc- we inactivated p53 in the posterior compartment 72 h after IR, well after the initial JNK activation (Fig. 7d, e). Then, we examined the effect of the suppression of p53 by comparing the size of the posterior compartments with or without p53 function (Fig. 7e, f). The result is that the suppression of p53 activity after JNK function has been established has no detectable effect on the size of the posterior compartment (Fig. 7f), nor on JNK activity, as measured by the expression of the JNK target gene puckered (puc) [51] (Fig. 7g). These findings indicate that p53 only contributes to senescence by enhancing the initial activation of JNK.
Discussion
Acquisition of senescence by Drosophila Apoptosis-Deficient (AD) cells after IR or p53 induction
We have performed several experiments subjecting Drosophila AD cells, which cannot execute the apoptosis program, to treatments that would normally result in massive cell death: a high IR dose (4000 R) or induction of the p53 gene, which triggers apoptosis. In those experiments, a fraction of the AD cells acquires high and persistent levels of JNK activity, visualized by the TREred reporter. In addition, they exhibit the typical attributes of senescence, such as cellular hypertrophy, cell cycle arrest, SA ß-gal expression, ROS production and the secretory phenotype (SASP) (see reviews in [33, 37, 52]). Our conclusion is that cells in which the apoptosis program is inhibited are prone to become senescent after stress.
In addition to the biomarkers described above, we have also observed that SCs possess migratory behaviour, that can be visualized by invasion of neighbour compartments, which may extend to long distance from the A/P border. This behaviour is observed in irradiated hhGal80 > UAS-miRHG, TREred (Fig. 2h) and hhGal80 > UAS-GFP, UAS-p35, TREred discs (Supplementary Fig. 2e), as well as after overexpressing p53 in hhGal80 > UAS-GFP, UAS-miRHG, UAS-p53 (Fig. 6j). This invasiveness property has also been reported for Apoptosis-Deficient aneuploid cells [24], which become senescent [53]. The ability to migrate is dependent on the activation of the JNK transcription program and can be reversed by suppressing JNK [24]. Although in the latter report the authors associate invasiveness to aneuploidy, our experiments suggest that invasiveness does not depend specifically on aneuploidy but it is a general property of SCs, which express one of the non-apoptotic roles of JNK activity, the stimulus of cell migration. This property has also been reported in mammalian cells expressing JNK [22, 23] and during the normal development of Drosophila [25, 54]. In our experiments this property is common to tumorigenic and non-tumorigenic SCs. The ability to invade neighbour tissues may also be a general biomarker of senescence and one that might have implications in tumorigenesis. Regarding tumorigenesis, it is of interest that the migratory property of senescent cells has already been shown to be associated with metastasis in thyroid cancer in humans [55].
Our results also bear on one feature, resistance to apoptosis, generally considered diagnostic of SCs (see [27]). Our experiments suggest that, at least in Drosophila, resistance to apoptosis may not be a consequence of senescence but a prerequisite to become senescent. In tissues sensitive apoptosis, IR treatments or p53 expression do not induce cells to become senescent; these are rapidly eliminated by the pro-apoptotic function of JNK and p53. In contrast, in tissues resistant to apoptosis, those treatments result in permanent expression of JNK, which drives cells into acquiring the typical attributes of senescence. We propose that it is not that senescent cells avoid apoptosis but that cells refractory to apoptosis are prone to become senescent.
There have been several previous reports describing senescence in Drosophila imaginal cells. Nakamura et al. 2014, showed that mitochondrial dysfunction associated with Ras activation causes senescence in eye imaginal cells, with features like those described above [34]. The induction of senescence appears to be mediated by production of ROS by the affected cells. This results in p53 and JNK activity, which appear to be responsible for the senescent phenotype.
We note, however, that in our experiments SCs are arrested in G2, whereas in Nakamura et al. 2014 the up regulation of the p21 ortholog dacapo indicates cell cycle arrest at the G1 stage [34]. Whether this difference is significant regarding senescence is not clear, but it indicates that Drosophila imaginal SCs may use different mechanisms to arrest cell divisions.
Another example of senescence in Drosophila has been provided by Joy et al. 2021 [53]. These authors induce chromosomal instability by inactivating the spindle assembly checkpoint gene rod, what causes aneuploidy. To circumvent the poor viability of aneuploid cells, they are generated in an Apoptosis-Deficient background, using the miRHG construct, which inactivates the rpr, hid and grim pro-apoptotic genes [29]. Under these genetic conditions aneuploid cells survive and display typical senescence biomarkers. Importantly, the acquisition of senescence is dependent on JNK activity.
p53 in cellular senescence
The implication of p53 in the acquisition of senescence in mammalian cells is well established (reviewed in [49, 50]). Cellular stress like IR leads to p53 activation and the transcriptional induction of many target genes, some of which, p21 for example, are effectors of senescence biomarkers like cell cycle arrest.
In the imaginal discs of Drosophila, p53 activation by IR induces the pro-apoptotic genes, which results in cell death in a p53-dependent manner [17, 18] (reviewed in [15]). However, here we show that in absence of apoptosis, p53 function drives cells into senescence (Fig. 6). The involvement of p53 has also been demonstrated in senescence induction by Ras overexpression in eye imaginal discs [34].
In comparing the roles of JNK and p53 as effectors of senescence, the key observation is that there is no senescence in the absence of JNK (Figs. 2 and 6), while in the absence of p53 senescence is reduced but not abolished (Fig. 7a). Thus, the pro-senescence role of p53 requires JNK function, suggesting that p53 exerts a subsidiary role, likely enhancing JNK activity. Furthermore, this enhancing function of p53 appears to act only during the initial activation of JNK, for once it is established the loss of p53 activity does not affect the levels of senescence (Fig. 7d–g).
A model of cellular senescence in Drosophila
Based on previous work and on our own results we propose that there are two critical prerequisites for Drosophila imaginal cells to become senescent. 1) inhibition of apoptosis, 2) a trigger of JNK activity (IR, p53 and likely other stressors). Under these conditions the pro-apoptotic function of JNK is suppressed, the AD cells remain alive and manifest the non-apoptotic roles of JNK. The initial triggering of JNK is resolved into permanent activity due to a maintenance loop involving moladietz and ROS [10, 56].
This proposal provides a frame to integrate the published results about senescence in Drosophila. The aneuploid Apoptosis-Deficient cells reported by Joy et al. 2021 produce ROS and subsequent activation of JNK, which becomes permanent; in our view the key issue is that the process producing aneuploidy also activates the JNK pathway, which is responsible for the senescence.
In the experiments by Nakamura et al. 2014 we believe that a primary reason for the transformation is that the elevated levels of Ras activity make the cells refractory to apoptosis [10, 57, 58]. Then the stress induced by the mitochondrial dysfunction activates JNK, which becomes permanent in the absence of apoptosis. We have previously shown [10] that a simple IR stress administered to cells expressing RasV12 causes ectopic long-term JNK activity associated with wg induction and massive overgrowths; a senescence scenario.
The migratory property of SCs described in this report and in previous work [12, 13, 24] is also consistent with the proposal, since one the cellular functions associated with JNK is the induction of cell motility [22, 23, 25].
Induction of tumorigenesis: the tSC and ntSC senescent cells. Role of identity
The secretory phenotype is of special interest because it is responsible for paracrine effects of senescence like tumorigenesis. We have identified three secreted signals, Upd, Wg and Dpp, although surely there will be others. Interestingly, unlike other senescence biomarkers, the Upd, Wg and Dpp ligands are not expressed in all the SCs cells, but only in a fraction of about 50%. Moreover, only the SCs expressing those ligands induce non-autonomous overgrowths (Fig. 3d, Fig. 4d).
This reveals a genetic diversity within the wing disc (Fig. 4a–e): after IR there are two classes of SCs: tSCs, which produce and secrete proliferative signals and generate overgrowths and ntSCs, which do not. Although genetic variability has been described for senescent cells in culture [59], to our knowledge this is the first case reporting this kind of variability of SCs in in vivo tissues.
Of special interest is that the tSC and ntSCs localize to different regions of the disc (Fig. 4a–c, e). The former appears preferentially in the appendage region while the ntSCs appear in the trunk region (notum and the pleura). The implication is that, regarding senescence, the wing disc is subdivided into a tumorigenic and a non-tumorigenic region. Strong support for this view is our finding that generating SCs exclusively in the thorax domain does not cause tumorigenic overgrowth (Fig. 4g, h). In contrast, induced SCs in the wing pouch produce large overgrowths (Fig. 4i, j).
An important question is about the mechanism behind this position-related diversity. Our experiments suggest that a critical factor is the original identity of the cells prior to the transformation towards senescence. Cells with appendage (wing pouch) identity can generate overgrowths after IR (Fig. 4i), but those with thoracic (notum and pleura) identity do not (Fig. 4g). This idea is strongly reinforced by the experiment in which cells of the wing pouch are transformed into notum cells and consequently lose to ability to generate overgrowth (Fig. 4f–j).
Since JNK is the key factor inducing senescence, the implication is that it functions differently in cells of thoracic and appendage identity. In fact, there is previous evidence of the differential activity of JNK in the two regions: driving a constitutive active form of hemipterous (hepCA), the effector of JNK [32] in the wing pouch induces overgrowth, while it does not in the notum region [21]. A finding likely to be related with the inability of thoracic structures to regenerate after massive damage [21]. The distinct behaviour of SCs in the thorax and the appendage may well be a reflection of the very different patterning and genetic mechanisms operating in the body trunk and the appendages [60].
The genetic diversity of SCs we find in Drosophila impinge on a classical paradox of the role of senescence: its anti-tumour and pro-tumour properties, and associate them with the identity of the cells prior to the acquisition of the senescence. The anti-tumour role is expressed by the senescent cells of thoracic identity (ntSCs); they stop dividing and do not activate the Wg and Dpp pathways. In contrast, the senescent cells of appendage identity (tSCs, located in the wing) produce the Upd, Dpp and Wg ligands that induce activity of these pathways, known to stimulate growth and proliferation of neighbour cells. The persistent activity of those pathways causes excess of growth: a pro-tumour role.
Methods
Drosophila strains
The different Drosophila strains were maintained on standard medium at 25 °C (except for the temperature shift experiments, see below). The strains used in this study were the following:
Gal4 lines: hh-Gal4 ([61]), pnr-Gal4 ([62]), rn-Gal4 ([45]), tub-Gal80ts ([63]) and en-gal4 (Flybase ID: FBti0003572).
UAS lines: UAS-miRHG ([29]), UAS-y+ ([62]), UAS-bskDN (Bloomington Drosophila Stock Center, BDSC#6409), UAS-GFP (BDSC), UAS-Stat92ERNAi (BDSC#33637), UAS-p53RNAi (BDSC#29351), UAS-pnr ([64]), UAS-p53-A ([65]), UAS-dppRNAi ([66]), UAS-fz1RNAi (VDRC#105493).
Mutants: dronci29, dronci24 (a gift from A. Bergmann, MD Anderson Center, Houston, TX, USA)
Reporter lines: TREred ([31]), stg-GFP (BDSC#50879), ubi-GFP-E2f11-230, ubi-mRFP1-NLS-CycB1-266 (Fly-Fucci, BSDC#55099), GstD-LacZ ([36]), upd1-LacZ (a gift from T. Igaki), dpp-LacZ (p10638, BDSC#12379), puc-LacZ (pucE69) ([51]).
Imaginal discs staining
Third instar larvae were dissected in PBS and fixed with 4% paraformaldehyde, 0.1% deoxycholate (DOC) and 0.3% Triton X-100 in PBS for 27 min at room temperature. They were blocked in PBS, 1% BSA, and 0.3% Triton, incubated with the primary antibody over night at 4 °C, washed in PBS, 0.3% Triton and incubated with the corresponding fluorescent secondary antibodies for at least 2 h at room temperature in the dark. They were then washed and mounted in Vectashield mounting medium (Vector Laboratories).
The following primary antibodies were used: rat anti-Ci (DSHB 2A1) 1:50; mouse anti-Mmp1 (DSHB, a combination, 1:1:1, of 3B8D12, 3A6B4 and 5H7B11) 1:50; mouse anti-β-galactosidase (DSHB 40-1a) 1:50; rabbit anti-β-galactosidase (ICN Biomedicals) 1:2000; mouse anti-Wingless (DSHB 4D4) 1:50; rabbit anti-Dpp ([67]) 1:200; rabbit and mouse anti-PH3 (MERCK and Cell Signal Technology) 1:500, rat anti-RFP (Chromotek, 5F8) 1:2000.
Fluorescently labelled secondary antibodies (Molecular Probes Alexa-488, Alexa-555, Alexa-647, ThermoFisher Scientific) were used in a 1:200 dilution. Phalloidin TRITC (Sigma Aldrich) and Phalloidin-Alexa-647 (ThermoFisher Scientific) were used in a 1:200 dilution to label the actin cytoskeleton. TO-PRO3 (Invitrogen) and DAPI (MERCK) was used in a 1:500 dilution to label the nuclei.
EdU incorporation
Dissected wing discs were cultured in 1 mL of EdU labelling solution for 20 min at room temperature and subsequently fixed in 4% paraformaldehyde for 30 min at room temperature. Rat anti-RFP (Invitrogen) 1:200 antibody was used overnight at 4 °C before EdU detection to protect RFP fluorescence. EdU detection was performed according to the manufacturer instructions (Click-iT EdU Alexa Fluor 647 Imaging Kit, ThermoFisher Scientific), and wing discs were incubated during 30–40 min at room temperature in the dark.
β-galactosidase activity assay
To assess the levels of β-galactosidase activity in senescent cells a CellEventTM Senescence Green Detection Kit (Invitrogen) was used. Larvae were fixed in 4% paraformaldehyde for 20 min and, after washing with PBS, 1% BSA, incubated with the Green Probe (1:1000 dilution) for 2 h at 37ªC in the dark. Larvae were washed with PBS and then wing imaginal discs were mounted in Vectashield. Images were taken shortly after the protocol to avoid loss of fluorescence.
IR treatments
Larvae were irradiated in an X-ray machine Phillips MG102 at the standard dose of 4000Rads (R) at different times after the egg laying and dissected at the indicated times depending on the experiment (see “Temperature shift experiments”).
Temperature shift experiments
Generation of senescent cells in posterior compartments: larvae of the genotype hh-Gal4, tub-Gal80ts (hhGal80 > ); TREred, UAS-miRHG were raised at 17 °C for 3-4 days and then transferred to 29 °C 1 day before irradiation to activate the corresponding transgene. After irradiation, larvae were kept at 29ªC for 3-4 days to allow tumor growth before being dissected. This standard protocol was used to analyse all senescent markers as well as the contribution of JNK, p53, JAK/STAT, Dpp and Wg pathways to senescence and size of the compartment. This protocol was also used for larvae of the genotypes hh-Gal4, tub-Gal80ts; TREred; UAS-p35.
Induction of p53-A and miRHG in the posterior compartment: larvae of the genotype hh-Gal4, tub-Gal80ts; TREred, UAS-miRHG; UAS-p53-A were raised at 17 °C for 5–7 days and then transferred to 29 °C for 3 days before dissection to activate the corresponding transgene. This standard protocol was used to analyse all senescent markers as well as to study the contribution of JNK. For the Fly-Fucci and Stg-GFP experiments, the en-Gal4 line was used and the larvae were kept at 25 °C before dissection.
Generation of senescent cells in dronc mutant discs: larvae of the genotype TREred; dronci24/dronci29 were raised at 25 °C and changed to 29 °C 1 day before irradiation. After IR treatment, larvae were kept at 25 °C for 3-4 days before dissection.
Generation of senescent cells in the Pnr and Rn domains: larvae of the genotype 1) TREred, UAS-miRHG/UAS-GFP; pnr-Gal4, 2) TREred, UAS-miRHG/UAS-GFP; rn-Gal4 were raised at 25 °C and changed to 29 °C 1 day before irradiation. After IR treatment, larvae were kept at 25 °C for 3-4 days before dissection.
Generation of pnr-expressing cells in the Rn domain: Larvae of genotype TREred, UAS-miRHG/UAS-GFP; rn-Gal4/UAS-pnr were raised at 25 °C and changed to 29 °C 1 day before irradiation. After IR treatment, larvae were kept at 25 °C for 3-4 days before dissection.
Experiment to analyse the contribution of p53 on the JNK-induced senescence: Larvae of the genotypes 1) UAS-GFP, tub-Gal80ts; hh-Gal4 dronci29/dronci24, puc-LacZ and 2) UAS-GFP, tub-Gal80ts/UAS-p53RNAi; hh-Gal4 dronci29/dronci24, puc-LacZ were subjected to two different experimental treatments. The first one was the same as described above for the generation of senescent cells in posterior compartments; in the second one, larvae were raised at 17 °C for 2-3 days, irradiated and kept at 17 °C for 3 days to allow normal JNK activation. After this, larvae were changed to 29 °C for 3 days to allow expression of the construct UAS-p53-RNAi and then dissected. An illustrative scheme of the two experimental treatments is presented in Fig. 7d.
Image acquisition, quantifications and statistical analysis
Stack images were captured with a Leica (Solms, Germany) LSM510, LSM710, DB550 B vertical confocal microscope and a Nikon A1R. Multiple focal planes were obtained for each imaginal disc. Quantifications and image processing were performed using the Fiji/ImageJ (https://fji.sc) and Adobe Photoshop software. Schemes in Fig. 1, Fig. 4 and Fig. 7 were made with BioRender (https://www.biorender.com/).
For quantification of the percentage of the posterior compartment/domain, a Z-maximal intensity projection was made for each image. Then, the area of the compartment/domain (labelled with GFP or the absence of Ci staining in each case) was measured by using the “Area” tool and normalized dividing between the total disc area (labelled by TOPRO-3 or DAPI staining). For JNK activation, quantification (%TREred), TREred positive area was measured using the “Threshold” tool and then normalized dividing between the area of the compartment. pucLacZ ratio (P/A) is calculated as the %pucLacZ in the posterior compartment divided between the %pucLacZ in the anterior compartment. Cell size was measured as the mean of the area of 10 TREred positive cells (labelled by phalloidin staining) and the mean of the area of 10 TREred negative cells per imaginal disc.
For the Fly-FuccI cell quantification, third instar larvae of the en-Gal4; UAS-p53-A, UAS-miRHG; UAS-GFP-E2F11-230, UAS-mRFP1-NLS-CycB1-266 genotype were raised at 25 °C and stained for Mmp1 and the Fly-Fucci markers. Red, green, or yellow cells were manually quantified. For each experiment, at least five wing imaginal discs were used to count at least 50 Mmp1 positive group of cells.
Statistical analysis was performed using the GraphPad Prism software (https://www.graphpad.com). To compare between two groups, a non-parametric Student’s t-test test was used. To compare between more than two groups, a non-parametric, one-way ANOVA Dunnett’s test was used. Sample size was indicated in each Figure legend.
Data availability
All data generated or analysed during this study are included in this published article and its supplementary information files.
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Acknowledgements
We thank Brian Calvi, Marco Milán, the Bloomington Stock Center, the Vienna Drosophila Resource Center, and the Developmental Studies Hybridoma Bank for fly stocks and reagents. Thanks also to the Confocal Microscopy Service at CBMSO for their help. We especially thank Ernesto Sanchez-Herrero, Antonio Baonza, Mireya Ruiz-Losada and the members of the Morata lab for fruitful discussions throughout the period of this work. This study was supported by grants from: FEDER/Ministerio de Ciencia e Innovación-Agencia Estatal de Investigación-Consejo Superior de Investigaciones Científicas [No. PGC2018-095151-B-I00, PID2021-125377NB-100, PIE Intramural 202020E255 to GM and No. PGC2018-095144-B-I00, PID2021-127114NB-100 to CE).
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GM and CE designed the project. GM wrote the manuscript with help from CE. JMG-A, NP, SC-V and CE performed all experiments. GM, CE and JMG-A analyzed the data and discussed the results. All authors approved the manuscript.
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Garcia-Arias, J.M., Pinal, N., Cristobal-Vargas, S. et al. Lack of apoptosis leads to cellular senescence and tumorigenesis in Drosophila epithelial cells. Cell Death Discov. 9, 281 (2023). https://doi.org/10.1038/s41420-023-01583-y
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DOI: https://doi.org/10.1038/s41420-023-01583-y
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