ROS-Induced JNK and p38 Signaling Is Required for Unpaired Cytokine Activation during Regeneration
Regenerative biology pursues to unveil the genetic networks triggered by tissue damage. Regeneration can occur after damage by cell death or by injury. We used the imaginal disc of Drosophila in which we genetically activated apoptosis or physically removed some parts and monitored the capacity to repair the damage. We found that dying cells generate a burst of reactive oxygen species (ROS) necessary to activate JNK and p38 signaling pathways in the surrounding living cells. The action of these pathways is necessary for the activation of the cytokines Unpaired (Upd). Eventually, Upd will turn on the JAK/STAT signaling pathway to induce regenerative growth. Thus, we present here a module of signals that depends on oxidative stress and that, through the p38-JNK interplay, will activate cytokine-dependent regeneration.
Published in the journal:
ROS-Induced JNK and p38 Signaling Is Required for Unpaired Cytokine Activation during Regeneration. PLoS Genet 11(10): e32767. doi:10.1371/journal.pgen.1005595
Category:
Research Article
doi:
https://doi.org/10.1371/journal.pgen.1005595
Summary
Regenerative biology pursues to unveil the genetic networks triggered by tissue damage. Regeneration can occur after damage by cell death or by injury. We used the imaginal disc of Drosophila in which we genetically activated apoptosis or physically removed some parts and monitored the capacity to repair the damage. We found that dying cells generate a burst of reactive oxygen species (ROS) necessary to activate JNK and p38 signaling pathways in the surrounding living cells. The action of these pathways is necessary for the activation of the cytokines Unpaired (Upd). Eventually, Upd will turn on the JAK/STAT signaling pathway to induce regenerative growth. Thus, we present here a module of signals that depends on oxidative stress and that, through the p38-JNK interplay, will activate cytokine-dependent regeneration.
Introduction
Tissues and organs need to function reliably regardless of adverse environmental conditions. Injuries, disease, infection and environmental insults are stressors causing cell damage that can be repaired via homeostatic machinery. Thus, optimal health is largely dependent upon tissue homeostasis, which involves cell replacement and tissue repair. Although many signaling pathways have been proposed to respond to environmental insults, the early activation of those signals is poorly understood.
Response to damage can involve oxidative stress and, subsequently, the stimulation of stress-activated protein kinases. The production of reactive oxygen species (ROS) by various redox metabolic reactions, which has generally been considered to be deleterious, is now emerging as an active participant in cell signaling events [1,2]. ROS are byproducts of aerobic metabolism that include superoxide O2-, peroxide H2O2 and hydroxyl radicals OH·. ROS, and in particular H2O2 are required for inflammatory cell recruitment [3,4]. Amphibian and zebrafish injuries produce the ROS necessary to promote proliferation and regeneration [5–8]. In mammalian cells, ROS are known to act as second messengers to activate diverse redox-sensitive signaling transduction cascades, including the stress-activated MAP kinases p38 and the Jun-N Terminal kinase (JNK) [9–11]. ROS-mediated p38 activation occurs during the inflammatory response in rats [12] and during the loss of self-renewal and differentiation in glioma-initiating cells [13]. It has also been found that p38 and JNK are differentially required during repair. In endothelial cells, TNF-α stimulates repair through the positive action of JNK and negative regulation of p38 [14], whereas in corneal repair, p38, and not JNK, is required for epithelial migration [15]. In Drosophila both MAPK have been associated with stress responses [16]. Drosophila p38 pathway responds to different environmental stimuli and stressors [17,18]. Moreover, increasing ROS beyond basal level triggers precocious differentiation of Drosophila hematopoietic progenitors through JNK signaling [19].
The JNK signaling pathway has emerged as an early response to cell death and physical damage and appears to play a critical role in compensatory proliferation, regeneration and wound healing [20–28]. Moreover, upon apoptotic stimulus p53 and JNK are activated by the caspase Dronc and function upstream of pro-apoptotic genes, creating an amplifying loop that ensures cell death [29–33]. One of the early known responses to cell death is the transcriptional activation of the phosphatase puckered (puc), a downstream effector of the JNK pathway and a powerful negative regulator of the same pathway. Interestingly puc has been found in surviving cells of nearby tissue after cell death [23,27] and after physical injury [22,34]. JNK activation of the cytokines unpaired (upd), a family of cytokines linked to the human interleukin-6, is necessary for hyperproliferation in Drosophila tumors and for wound healing [34–36]. Thus, we hypothesize here that the activation of JNK, which is amplified in dying cells, is in some way propagated to nearby surviving tissue where beneficial low levels of JNK promote upd expression.
Apoptotic cells have been observed in the early regeneration of different animals and are thought to provide signals that regulate wound healing and regeneration [37–39]. As apoptosis has been associated with oxidative stress and cytokines act as a functional link between oxidative stress and compensatory proliferation in mammals [40], we decided to investigate whether ROS occur upstream from the stress-activated protein kinases p38 and JNK and cytokines during tissue repair. We took advantage of the regeneration capacity of Drosophila imaginal disc epithelium (reviewed in [41,42]) to address these questions. Imaginal discs are larval epithelial sacs that possess a robust ability for homeostatic cell renewal to overcome the effect of stressors. We report here that, either by inflicting a physical lesion or after inducing cell death, imaginal disc cells produce ROS that are linked to the activation of p38 and JNK stress MAP kinases. In addition, JNK and p38 activity in the living tissue triggers transcription of the cytokine unpaired (upd), which acts as a ligand of the JAK/STAT signaling pathway and promotes regeneration of the missing part.
Results
ROS are produced after tissue damage
To monitor ROS after tissue damage we used CellROX Green, a cell-permeant fluorogenic probe that is non-fluorescent in the reduced state and exhibits bright fluorescence upon oxidation. We found high levels of CellROX Green near the wound edges of physically cut wing imaginal discs. Only a few of the CellROX Green positive cells were TO-PRO-3 positive cells (dying cells), indicating that most ROS-producing cells were alive (Fig 1A). We examined the production and propagation of ROS over time. Few minutes after cut (0–5’) some cells at the wound edges were CellROX Green positive, indicating that the oxidative burst is rapidly occurring after damage (Figs 1B and 1C and S1). Ex vivo imaging showed that fluorescence propagates to the neighboring cells during the first 30’ after damage (Figs 1B and S1).
We next monitored ROS production after controlled induction of cell death (also known as genetic ablation), which can be used as a type of insult to study cellular responses. Apoptosis was induced using patched (ptc)-Gal4 to drive expression of the pro-apoptotic gene reaper (rpr) under the control of a UAS (henceforth ptc>rpr); the Gal4/UAS system was controlled by the temperature-sensitive form of Gal80 (Gal80TS), which inhibits Gal4 and enables examination of regeneration after cell death [23,24]. As previously described, ptc>rpr discs show a stripe of apoptotic cells that eventually extrudes basally and is replaced apically by living cells (Fig 1D) [23]. CellROX Green was strongly incorporated into the ptc>rpr apoptotic cells (TO-PRO-3 positive) (Fig 1E). Strikingly, living cells adjacent to the apoptotic zone also showed ROS, albeit at much lower levels than in dead cells (Fig 1E and 1F). Similar observations were obtained using 2',7'-dichlorodihydrofluorescein diacetate (H2DCFDA) which upon oxidation is converted to the highly fluorescent DCF. Indeed, cut or rpr-ablated discs, showed high levels of fluorescence on the wound edges, in the apoptotic cells and also in the living cells near the apoptotic (S1B, S1C and S1D Fig).
Thus, these results showed that both physical injury and genetically induced apoptosis are insults that result in the production of ROS.
ROS are required for tissue repair
Oxidative burst following death or damage could propagate from dying to living cells in sub-toxic doses and initiate repair. To explore this issue, we decided to deplete ROS production and examine adult wings after cell death. We first checked whether antioxidants (vitamin C, Trolox or N-acetyl cysteine [NAC]) are capable of blocking ROS production. We incubated cut discs in Schneider’s medium containing antioxidants, and found strong reduction of CellROX Green fluorescence (S2 Fig).
Next, we studied the effects of ROS scavenging on regeneration. We used a Gal4 construct under the control of a wing-specific enhancer (salE/Pv-Gal4), which allows analysis in adult wings while not affecting the rest of the organism, to activate UAS-rpr (henceforth salE/Pv>rpr). To deplete intracellular ROS, salE/Pv>rpr larvae were fed with food supplemented with antioxidants (Fig 2A). ROS scavengers in salE/Pv>rpr controls kept at 17°C to prevent cell death did not show any alteration of wing morphology (S2B Fig). Conversely, a salE/Pv>rpr control group without scavengers moved to 29°C for 11 h showed complete wing regeneration (Fig 2B). However, the salE/Pv>rpr experimental group with ROS scavengers and induced cell death showed incomplete regeneration in about 50% of the cases (Fig 2B and 2C). We considered incomplete regeneration when some veins or intervein sectors were missing. To discard that these effects could be caused by differences in survival or developmental delay, we checked whether proliferation is impaired after ROS depletion. We counted the number of mitoses after cell death induction in discs from NAC-fed larvae and found a significant decrease compared to discs from larvae fed in the absence of antioxidants (Fig 2D). The number of mitoses in controls fed with or without antioxidants and kept at 17°C to block cell death did not vary (Fig 2D).
In addition, we used enzymatic manipulation of ROS. Superoxide dismutase (Sod) catalyzes the dismutation of superoxide anion into oxygen and hydrogen peroxide. In the presence of hydrogen peroxide, Catalase (Cat) catalyzes its breakdown into water and oxygen. Thus, overexpression of Sod or Cat will remove their respective ROS substrates, whereas simultaneous activation of Sod and Cat will enhance the depletion of both O2- and H2O2. UAS-Sod, UAS-Cat or UAS-Sod:UAS-Cat were ectopically expressed under the nub-Gal4 driver, which operates throughout the wing pouch (Fig 2E). To induce cell death, we used an independent transactivator based on the LexA/lexO binary system. We generated a salE/Pv-LHG transgene, which includes a Gal80 suppressible form of LexA [43], to conditionally express lexO-rpr in the salE/Pv domain. This combination permits control of the temporary expression of two binary systems (salE/Pv-LHG lexO-rpr and nub-Gal4 UAS-transgene) by tubGal80TS (Fig 2E). This design has the advantage of simultaneously activating two wing-specific transgenes (nub-Gal4 and salE/Pv-LHG) in overlapping domains, therefore hindering early ROS. After salE/Pv-LHG lexO-rpr genetic ablation and nub-Gal4 UAS-transgene expression we allowed the larvae to develop to adulthood and found a drop in the number of regenerated wings (Figs 2F and 2G and S2C and S2D). Together, these results indicate that chemical and enzymatic ROS scavengers interfere with regeneration.
ROS control JNK activity
To determine whether ROS act on JNK during wing disc repair, we first monitored the activity of this pathway in wing discs after cell death. We used two different reporters to monitor JNK activity: puc-lacZ, which marks puc-expressing cells [44], and the TRE-DsRed.T4 reporter, which monitors the JNK substrate AP1 transcription factor (hereafter TRE-red reporter) (Fig 3A and S3A Fig) [45]. In ptc>rpr discs, we found high levels of TRE-red reporter in the basal apoptotic zone and, to a lesser extent, in the apical living cells (Fig 3A and 3B). In contrast, puc-lacZ positive cells were found in the apical zone, as described previously [23], and rarely in the apoptotic zone. Some puc positive cells incorporated EdU, supporting that JNK is also induced in living cells (Fig 3C).
As NAC is an excellent source of sulfhydryl SH- groups and efficiently promotes scavenging of free radicals [46], it was the most suitable antioxidant to determine the relationship between ROS and JNK in stressed imaginal discs. To test NAC effects on JNK, we used the TRE-red reporter because is more rapidly and extensively expressed than puc-lacZ (Figs 3A and S3B) and because its activity is blocked in JNK mutants [45] or after chemical JNK inhibitors (S3C Fig). We found that the mean pixel intensity of the TRE-red reporter in ptc>rpr wing discs from animals grown in NAC-supplemented food was lower than in the same zone of individuals fed with standard food (Fig 3D and 3E). Moreover, discs cultured ex vivo in which NAC was added into the medium resulted in a drop of TRE-red activity after physical injury (Fig 3F and 3G). These observations indicate that activation of JNK is ROS dependent.
ROS stimulates p38 phosphorylation
Another potential response to ROS increase is the activation of the p38 signaling cascade [10,17,18]. Active p-38 signaling can be monitored using anti-phosphorylated p38 (P-p38). We found that discs fixed and incubated with anti-P-p38 a few minutes after physical injury showed P-p38 staining around the wound. P-p38 localization was variable and depended on the severity of the injury. In contrast, intact discs immediately stained after fixing did not show P-p38 (Fig 4A). However, discs cultured for 3 to 8 hours with or without injury showed P-p38 staining throughout the disc. This general staining is likely due to the stress generated by culturing, and contrasts with the fast local P-p38 response around the damaged zone. We next wondered whether the boost in ROS that propagates to the surviving tissue triggers p38 activation. We observed that the early P-p38 staining was blocked in discs cut and cultured ex vivo in medium containing NAC (Fig 4B and 4C).
We also analyzed p38 activation after inducing cell death and found P-p38 only in living cells but never in the basal apoptotic zone (Fig 4D). In the absence of cell death, no P-p38 was detected. Blocking of ROS production with NAC resulted in a significant drop in P-p38-labeled cells (Fig 4D and 4E). In addition, we used the double transcriptional trans-activator system consisting of the salE/Pv-LHG lexO-rpr to induce apoptosis and simultaneously interfere with ROS production by inducing UAS-Sod:UAS-Cat in the anterior (ci-Gal4) compartment (Fig 4G). The results showed a strong reduction of P-p38 in the anterior (ci-Gal4 UAS-Sod:UAS-Cat) compartment in comparison to the posterior.
To test whether an independent source of ROS could activate P-p38 in discs, we fed larvae for 2h with food supplemented with 1% H2O2 and checked for P-p38. Intact discs (no cut, no cell death) from these larvae resulted in high levels of P-p38 as well as high CellROX Green fluorescence (S4 Fig).
Together, these observations show that chemical (NAC) or genetic (UAS-Sod:UAS-Cat) ROS scavengers inhibit P-p38 and therefore indicate that oxidative stress is required for p38 activation.
p38 signaling is required for tissue repair
We next scored wing regeneration after salE/Pv>rpr induction of cell death in different mutant backgrounds of the p38 pathway. As most of the alleles are lethal or semilethal in homozygosis [47], we tested them in heterozygosis. Alleles of two Drosophila p38 genes, p38a and p38b, were used in this work. We found that heterozygous p38bd27 animals regenerated entire wings (Fig 5A). However, a severe effect was observed with p38a1 as the resulting wings lacked some sectors and presented notches in the margin. Drosophila p38 signaling is activated by MKK3/licorne (lic)-mediated phosphorylation [48]. Heterozygous licd13 showed all wing sectors albeit wings were smaller than controls. However, double heterozygotes for licd13 and p38bd27 were unable to regenerate some wing sectors. We also tested Atf2PB, a hypomorphic allele of the ATF2 transcription factor downstream of p38 [49], either in homozygosis or in double heterozygous combinations (licd13 Atf2PB or p38bd27 Atf2PB). We found defects in size and pattern after salE/Pv>rpr induction. Regeneration was severely impaired in double heterozygotes for p38a1 (MAPK) and Atf2PB (Fig 5A).
We also blocked the pathway with UAS-RNAi constructs for lic, p38b, p38a and Atf2 and analyzed the adult wings. These transgenes were activated in the anterior compartment (ci>RNAi) and cell death was induced in the salE/Pv domain (salE/Pv-LHG lexO-rpr). We found a reduction of individuals capable to fully regenerate wings for those RNAi’s (S5A Fig).
To gain further insight into the requirement for p38, we chemically blocked the pathway using the imidazole drug SB202190, a specific cell permeable p38 MAP kinase inhibitor that has been reported to do not interfere JNK or ERK kinases and is known to prevent phosphorylation of Atf2 in Drosophila S2 cells [50]. We first tested the specificity of the SB202190 on P-p38 in rpr-ablated discs and found significant differences between individuals fed with the drug and controls. In contrast, the differences on TRE-red reporter were not significant (S5C Fig). This indicates that SB202190 strongly blocked P-p38 and weakly the TRE-red. SalE/Pv>rpr larvae grown at 17°C to prevent cell death and fed with food containing SB202190 (0.12, 1.0 or 5.0 μM) emerged into normal adults (S5B Fig). However, salE/Pv>rpr-induced larvae fed with SB202190 developed wings lacking some sectors. The highest percentage of aberrant wings was found using 5 μM SB202190 (Fig 5B). This observation confirms that activation of p38 is required for wing repair.
p38 and JNK act independently
To assess the relationship between JNK and p38, we tested p38 activation in wounded null hemizygous JNKK hemipterous (hepr75) discs. P-p38 was localized near the wound after physical injury (Fig 6A). This contrasts with the decrease in P-p38 when the MAPK kinase lic, which is the p38 activating kinase, was interfered with RNAi in injured discs (S6A Fig).
Moreover, P-p38 staining was localized in hepr75 discs after ptc>rpr induction, as in the wild type (Fig 6B, compare with Fig 4), indicating that JNK and p38 act independently. In addition, we fed animals with the JNK Inhibitor IX, which abolishes TRE-red reporter expression and inhibits regeneration (S3C and S3D Fig), and found that P-p38 after rpr-ablation was not affected (S6B Fig).
To confirm that JNK and p38 act independently, we blocked the p38 pathway and checked for TRE-red reporter activity. As the p38a1 allele in heterozygosis strongly affects regeneration (Fig 5), we used this null allele in homozygosis and tested TRE-red activity after physical injury. Our results showed that TRE-red is induced at the wound edges of p38a1-/- mutant discs (Fig 6C and 6D). Together, these results demonstrate that p38 and JNK stress responses act independently in damaged imaginal discs.
Upd expression is triggered by ROS
The evidence that JNK is active in the living tissue located near damaged zones arises from the expression of puc and TRE-red reporters (Fig 3A and 3B), and also because inhibition of JNK results in defects in repair [21,23,25,26,51]. Moreover, JNK activation promotes upd expression in different contexts [28,52]. We wondered whether those low non-deleterious JNK levels are capable of triggering tissue repair through upd expression. Upd cytokines are ligands that associate with the receptor domeless (dome) to stimulate the kinase activity of the receptor associated protein kinase hopscotch (hop), which in turn phosphorylates dimers of the transcription factor STAT92E [53]. We found upd and upd3 expression near the wound after both physical injury and cell death (Fig 7A, 7B, 7F and 7G). This injury-induced upd expression was blocked in JNKK hepr75 mutants (Fig 7C and 7D) and by JNK Inhibitor IX (S3C Fig), which is consistent with previous observations [28,35].
To study the requirement for JAK/STAT for regeneration, we used the salE/Pv-LHG lexO-rpr to induce apoptosis and simultaneously interfered with the receptor dome using the dominant negative form UAS-domeDN driven by ci-Gal4. These wings lacked most of the tissue where cell death was induced and dome was blocked (Fig 7J and 7K), indicating that JAK/STAT signaling is needed for tissue recovery. Moreover, heterozygous alleles for the JAK/STAT pathway resulted in partial disruption of adult wing recovery after cell death (S7 Fig).
We next analyzed if JAK/STAT signaling requires ROS in this context. Two different reporters (10XSTAT92E-GFP and upd-Gal4 UAS-myrtomato) were used in physically injured discs and showed reduced expression after NAC feeding (Fig 7E). In addition, ptc>rpr induced discs from NAC fed larvae showed a reduction of upd expression (Fig 7H and 7I). Thus, this expression is ROS dependent after both physical injury and cell death. We speculated that if ROS operate upstream upd, the impairment of regeneration resulting from NAC feeding should be rescued by activating Upd. To this aim, we used the double transactivation system to induce cell death in NAC-fed individuals and concomitantly activate upd expression (Fig 7L). Analysis of the resulting wings showed that upd ectopic expression rescued the NAC inhibition phenotype (Fig 7M and 7N). These observations demonstrate that ROS function upstream of JAK/STAT during repair.
We wondered whether p38 is also required for upd expression in damaged discs. Expression of upd or upd3 was severely reduced in p38a1-/- wound edges (Figs 8A–8C and S8). This suggests that in addition to JNK, p38 is essential for upd expression upon stress. Finally, we argued that if p38 is required for repair through upd, its ectopic expression should rescue the impaired regeneration after inhibition of p38. We, again, used the double transactivation system to induce cell death in SB202190-fed individuals, to block p38 phosphorylation and alongside activate upd expression (Fig 8D). Indeed, we found that the number of wings that regenerated after p38 inhibition increased (Fig 8E and 8F). Altogether these results position Upd cytokines downstream from the ROS/p38/JNK module.
Discussion
In this work, we demonstrate a stress-responsive module activated upon cell death or physical damage. This module consists of ROS dependent stimulation of non-deleterious levels of JNK and p38 MAP kinases necessary for the expression of Upd and JAK/STAT signaling which drives regeneration. Non-lethal levels of JNK may have multiple functions, among them cytoskeleton organization [44,54], healing and initiation of regenerative growth [21,23–26,51,55,56]. Thus, this early responsive module is crucial to maintain tissue in a healthy condition, trigger tissue repair and restore homeostasis.
In an apoptotic context, Rpr dimerizes and, through direct binding, brings the Drosophila inhibitor of apoptosis protein-1 (DIAP1) to mitochondria, concomitantly promoting DIAP1 auto-ubiquitination and destruction [57,58]. Rpr action on the mitochondria results in alteration of cytochrome C driven by caspases [59] and in mitochondrial disruption [60]. The ROS dyes used here detect a wide range of ROS, and therefore we cannot discriminate between membrane oxidases or mitochondrial origin. However, since Rpr acts on mitochondria, mitochondrial alterations could cause the burst of ROS in apoptotic cells. Of note, we observed that high ROS levels are associated with high levels of JNK in apoptotic cells. It has been proposed that ROS can mediate the activation of JNK [61] by quenching the MAP kinase phosphatases [62]. Conversely, low levels of ROS detected in nearby surviving tissue correlate with low non-deleterious levels of JNK and activation of MAP kinase phosphatases. Thus, puc MAP kinase phosphatase could protect the living cells close to the damage from the noxious effects of high JNK. Indeed, living cells near the wound retain low levels of JNK, not sufficient to kill but necessary for tissue recovery.
Additionally, the caspase Dronc, which acts downstream from Rpr, has functions beyond apoptosis [63]. Dronc is involved in the activation of JNK and p53, which activate the pro-apoptotic genes, creating an amplification loop that ensures apoptosis [27,29–31,64]. The JNK/p53 driven apoptosis stimulates proliferation of the nearby tissues [29–31,65]. Although still unclear, it has been proposed that apoptotic cells can release the products of mitogenic genes such as wingless (wg) and decapentaplegic (dpp) [33,66,67][31,68]. Alternatively, we show here that ROS operate as signals responding to insults (apoptosis, mechanical stress) that turn on the homeostatic machinery to compensate the epithelial damage. This fits with a scenario in which ROS are able to either diffuse from cell to cell or perhaps to propagate their production to several rows of cells. Indeed, ROS have been proven to cross cell membranes, to spread through gap junctions [69–71] and to enter into the cell through specific membrane aquaporin channels [71,72]. Therefore, ROS behave as an efficient paracrine signal that ultimately will result in Upd activation.
In addition to JNK, ROS are stressors involved in p38 activation [73]. ROS may activate the p38 pathway through the oxidative modification of intracellular kinases such as redox-sensitive activating protein-1 ASK1 [74]. We showed here that not only JNK but also p38 is required for regeneration. Moreover, the p38a1 allele seems to particularly affect upd expression and regeneration. This concurs with the finding that Drosophila p38a is more susceptible to environmental stressors, such as oxidative stress [18]. However, other p38 kinases could contribute to tissue regeneration. Indeed, heterozygous alleles of the p38 activating kinase lic, which normally do not show patterning defects after rpr-mediated ablation, can result in incomplete regeneration when a dose of p38b is missing (Fig 5A). Moreover, RNAi of p38b also can show defective regeneration individuals (S2 Fig). In addition, we cannot discard that p38c, which has been recently found involved in intestinal immune homeostasis [75], may also function in imaginal disc regeneration.
We have found that both hepr75 and p38a1 inhibit upd expression. But hepr75 mutants, which block JNK signaling, do not affect p38 phosphorylation and viceversa, p38a1 mutants, which block at least the p38a branch of the p38 kinase, do not interfere with the TRE-red reporter expression. This suggests that ROS activate p38 and JNK independently and that both MAP kinases act on upd expression to drive tissue repair. Thus, ROS signaling operates through these two MAP kinase pathways that in turn will converge to stimulate the transcriptional expression of the cytokines (Fig 9).
JNK and p38 are not only activated after cell death but also after physical injury. Beneficial ROS production is an ubiquitous reaction associated with inflammatory responses to wounding [4,6,76]. Recent findings show that ROS produced in dynamic epithelia operate as a tuning mechanism for reorganization of epithelia [77]. Therefore, it could be that changes in mechanical stress generated during wounding and epithelial disruption (mechanical stretching) results in ROS production. Some dead cells were also found after physical injury. Thus, a partial contribution of dead cells in addition to the stress due to epithelial disruption can account for the oxidative burst generated after physical injury.
In summary, an early boost of oxidative stress is required to activate p38 and JNK in apoptotic cells or near the wound. Moreover, upd is turned on downstream JNK and p38. Thus, downstream of the stress response module, cytokines operate to control tissue growth during regeneration.
Materials and Methods
Drosophila strains
The Drosophila melanogaster strains used were ptc-Gal4 [78], tubGal80TS [79], UAS-rpr [80], ci-Gal4 [81], nub-Gal4 [82] sal-Gal4 and salE/Pv-Gal4 [83], p38bd27, licd13 [47], dATF2PB [49], p38a1, [17], LexO-rCD2::GFP [43], TRE-DsRed.T4 [45] as AP1 reporter, puc-lacZ [44], pucE69-A-Gal4 [84], UAS-upd [85], upd-Gal4 (from D. Harrison), 10XSTAT92E-GFP [86], en-Gal4, UAS-GFP, UAS-myrtomato, UAS-Sod.A (sod1), UAS-Cat.A, UAS-domeDN, hop2, hop27, stat92e06346 (Bloomington Stock center), stat92e397 [87], and hepr75 [88]. Transgenic Drosophila shRNAi lines were obtained from the Vienna Drosophila RNAi Center (VDRC). Canton S was used as the wild type control.
Imaginal disc culture and physical injury
Wing discs were dissected from third instar larvae in Schneider’s insect medium (Sigma-Aldrich) and a small fragment was removed with tungsten needles. Discs were cultured in Schneider’s insect medium supplemented with 2% heat activated fetal calf serum, 2.5% fly extract and 5 μg/ml insulin, for different periods of time (from 1 to 10 hours) at 25°C. Ex vivo images were taken using a Leica SPE confocal microscope and processed with Fiji software.
Generation of LexA/lexO strains for genetic ablation
The salE/Pv-LHG construct was created cutting the wing specific enhancer of spalt, salE/Pv [83] from pC4LacZ-Spalt PE EcoRI/BamHI and cloning this fragment into the plasmid attB-LHG containing a Gal80-suppressible form of LexA transcriptional activator (LHG) [43]. LHG contains both the binding domain of LexA and the activator domain of Gal4, which is recognized by the inhibitor Gal80TS.The LexO-rpr strain was obtained subcloning the pro-apoptotic gene reaper (rpr) from pOT2-rpr (IP02529) EcoRI/XhoI in the pLOTattB plasmid [89] carrying the lexA operator LexO. Transgenic flies were performed with standard protocols.
Genetic ablation and dual Gal4/LexA transactivator system
Cell death was genetically induced as previously described [23,90]. We used two different drivers to induce cell death. The first, ptc-Gal4 which is expressed in a narrow stripe in the center of the disc. This strain was used to induce cell death in imaginal discs (UAS-rpr), because the dead domain can be easily discerned from the neighboring living domain. The second, salE/Pv-Gal4 strain, which consists of sal wing enhancer with expression confined to the wing [83] has been used in this work to score adult wing parameters.
The UAS line used to promote cell death was UAS-rpr, and the system was controlled by the thermo sensitive repressor tubGal80TS. We also used the salE/Pv-LHG and LexO-rpr strains for genetic ablation using the same design as for Gal4/UAS.
Embryos were kept at 17°C until the 8th day/192 h after egg laying (equivalent to 96 hours at 25°C) to prevent rpr expression. They were subsequently moved to 29°C for 11 hours and then back to 17°C until adulthood. Controls without rpr expression were always treated in parallel.
In dual transactivation experiments, we used the salE/Pv-LHG LexO-rpr to ablate the salE/Pv domain, whereas Gal4 was used to express different transgenes under the control of nub-Gal4 or ci-Gal4.
In the experiments on antioxidants (Fig 2) and upd (Figs 7 and 8) overexpression, larvae were transferred to NAC- (100 μg/ml) or SB202190- (5 μM) supplemented food 24 h before cell death induction.
ROS detection ex vivo
All experiments for ROS detection were done in living conditions. To detect the presence of ROS we used CellROX Green Reagent (Life Technologies), which is an indicator of oxidative stress in living cells. For both genetic ablation and physical injury experiments, third instar discs were dissected in Schneider´s medium immediately after cell death or injury and incubated for 15 minutes in medium containing 5 μM CellROX Green Reagent, followed by three washes. Samples were protected from light throughout. Then they were mounted using culture medium supplemented with 1 μM TO-PRO-3 (Life Technologies) nucleic acid stain. As TO-PRO-3 only enters dead cells, we used it to distinguish dead cells from living cells in the ex vivo experiments. Images were taken using a Leica SPE and SPII confocal microscope. Grey values of regions of interest (ROI) were measured using Fiji software. ROIs were established at the wound edges of injured discs (examples in S2 Fig), or in rectangles as indicated in Fig 1E. Pixel intensities were collected and analyzed from raw images taken under the same laser confocal conditions. Thermal LUT images were rendered from slices taken from the confocal using the Interactive 3D Surface Plot tool of the Fiji software (ImageJ). We also used the cell-permeant 2',7'-dichlorodihydrofluorescein diacetate (H2DCFDA 5μM, Life Technologies) which upon oxidation is converted to the highly fluorescent 2',7'-dichlorofluorescein (DCF).
To visualize the ROS images in Fig 1 after genetic ablation, the whole stacks were subject to the Enhance Contrast tool at 0.4 pixel saturation in whole stack normalization. For physical injury images, thermal LUT images were obtained from raw stacks.
ROS scavenging
To prevent ROS production, we used two protocols. The first was mainly used for rpr-ablation discs. It consisted in that antioxidants were supplemented into standard fly food. As antioxidants we used vitamin C (250 μg/ml), Trolox (an analog of vitamin E; 20 μg/ml) and N-acetyl cysteine (NAC) (100 μg/ml), all from Sigma-Aldrich. To score adult wings, larvae were transferred from vials containing standard food to vials containing food with the desired antioxidant concentration. Antioxidant treatment was administered at 168 h of development at 17°C (equivalent to 84 h AEL at 25°C). After 24 hours, experimental larvae were moved to 29°C for 11 hours to promote rpr apoptosis. Meanwhile one control consisted of larvae maintained at 17°C and another control consisted of larvae transferred to a vial with standard food and moved to 29°C for the same period as in the experimental group. After rpr induction temperature was returned to 17°C to allow tissue recovery. This protocol was applied for Figs 2A–2D, 3D, 3E, 4E, 4F and 7E.
The second was used for ex vivo cultured discs. Wing imaginal discs were incubated for 30 minutes in Schneider’s insect medium supplemented with NAC 100 μg/ml. Then, they were transferred to Schneider’s containing CellROX Green (S2 Fig). NAC incubated discs were used for monitoring TRE-red (Fig 3F and 3G) or for P-p38 antibody staining (Fig 4B and 4C). In S2 Fig medium was supplemented with NAC, Trolox or Vit C.
Chemical inhibition of p38 and JNK pathway
The imidazole drug SB202190 (Sigma-Aldrich) was added to standard fly food to prevent p38 activation. We used three different concentrations (0.12 μM, 1 μM and 5 μM), and DMSO as the control. To inhibit chemically JNK we used the JNK Inhibitor IX (5 μM, Selleckchem) which is a thienylnaphthamide compound that is a selective and potent inhibitor of the ATP binding site of JNK. The timing and protocol followed to inhibit both pathways was the same as that to scavenge ROS.
Oxidative stress induction
Third instar larvae were transferred to vials containing 1% H2O2, 1,3% low melting agarose and 5% sucrose. To avoid loss of oxidative capacity, H2O2 was added at a temperature under 45°C. Larvae were fed for 2h in this medium prior dissection and fixation of the discs. Controls without H2O2 were done in parallel.
Test for regenerated adult wings and statistics
For testing the capacity to regenerate we used adult wings emerged from salE/Pv>rpr individuals, in which patterning defects can be easily scored. Flies were fixed in glycerol:ethanol (1:2) for 24 h. Wings were dissected on water and then washed with ethanol. Then they were mounted on 6:5 lactic acid:ethanol and analyzed and imaged under a microscope.
Definition of regenerated/non-regenerated wings: when veins or interveins were missing, we considered them as defective in their capacity to restore the normal pattern. Therefore, the % of regenerated wings (Figs 2, 5, 7, 8, S2, S3, S5 and S7) was calculated after the number of wings with the complete set of veins and interveins. For each sample of “regenerated wings” we scored the percentage of individuals that belong to the “regenerated wings” class and calculated the standard error of sample proportion based on binomial distribution (regenerate complete wing or not) SE = √p (1-p)/n, where p is the proportion of successes in the population.
Ratios between wing areas (Fig 5) were used as an indication of the size achieved after cell death for each genetic background, and consisted of a comparison between wing size with and without rpr induction.
Immunochemistry and fluorescence in situ hybridization (FISH)
Immunostaining and FISH were performed using standard protocols. Primary antibodies used in this work were P-p38 (rabbit 1:50, Cell Signaling Technology), phospho-Histone-H3 (rabbit 1:1000, Millipore), ß-galactosidase (rabbit 1:1000, ICN Biomedicals), Upd (rabbit 1:800, gift from D. Harrison) and cleaved caspase-3 (rabbit 1:100, Cappel).
Fluorescently labeled secondary antibodies were from Life Technologies and Jackson Immunochemicals. Discs were mounted in SlowFade (Life Technologies) supplemented with 1 μM TO-PRO-3 (Life Technologies) to label nuclei. Note that in fixed tissues all nuclei are TO-PRO-3 labeled, whereas in ex-vivo culture only nuclei of dead or dying cells are TO-PRO-3 labeled.
The number of mitosis after analyzing the stacks of confocal images was calculated using Fiji software (Cell counter plug-in). Mitosis were counted for the entire anterior compartment of the wing pouch for each disc.
For apoptotic cell detection, we used both anti cleaved caspase 3 or TUNEL assay. For TUNEL we used the fluorescently labeled dUTP ChromaTide BODIPY FL-14-dUTP (Life Technologies) and incorporated using terminal deoxynucleotidyl transferase (Roche).
EdU was incorporated using the Click-iT EdU Imaging Kit (Life Technologies). Wing discs were dissected after cell death induction and incubated in Schneider’s insect medium supplemented with 1 mg/ml EdU for 5 minutes. Following EdU incorporation, discs were fixed and immunostained.
Riboprobes for upd and upd3 were synthesized using cDNA clones from DGRC AT1366 and FI03911.
Genotypes
Fig 1
A, B. Wild type
D, E, F. ptc>rpr: UAS-rpr/+; ptc-Gal4/+; tubGal80TS/+
Fig 2
A, B, C. salE/Pv>rpr: UAS-rpr/+; salE/Pv-Gal4/+; tubGal80TS/+
D. ptc>rpr: UAS-rpr/+; ptc-Gal4:tubGal80TS/+
E, F, G. salE/Pv>rpr nub>GFP: w; nub-Gal4/UAS-GFP; salE/Pv-LHG:tubGal80TS/lexO-rpr
salE/Pv>rpr nub>Cat: w; nub-Gal4/UAS-Cat; salE/Pv-LHG:tubGal80TS/lexO-rpr
salE/Pv>rpr nub>Sod: w; nub-Gal4/UAS-Sod; salE/Pv-LHG:tubGal80TS/lexO-rpr
salE/Pv>rpr nub>Sod:Cat: w; nub-Gal4/UAS-Sod:Cat; salE/Pv-LHG:tubGal80TS/lexO-rpr
Fig 3
A, B. ptc>rpr: UAS-rpr/+; ptc-Gal4:tubGal80TS/TRE-DsRed.T4; puc-LacZ/+
C. ptc>rpr: UAS-rpr/+; ptc-Gal4:tubGal80TS/+; puc-LacZ/+
D, E. ptc>rpr: UAS-rpr/+; ptc-Gal4:tubGal80TS/TRE-DsRed.T4
F, G. w; TRE-DsRed.T4
Fig 4
A, B, C. Wild type.
D, E, F. ptc>rpr: UAS-rpr/+; ptc-Gal4/+; tubGal80TS/+
G. w; ci-Gal4/UAS-Sod:Cat; salE/Pv-LHG:tubGal80TS/lexO-rpr
Fig 5
A. Control: w; +; salE/Pv-LHG:tubGal80TS/lexO-rpr (control for lexO-rpr on the third chromosome) and w; lexO-rpr/+; salE/Pv-LHG:tubGal80TS/+ (control for lexO-rpr on the second chromosome)
licd13/+: licd13/+; +; salE/Pv-LHG:tubGal80TS/lexO-rpr
p38bd27/+: w; p38bd27/+; salE/Pv-LHG:tubGal80TS/lexO-rpr
p38a1/+: w; lexO-rpr/+; p38a1/salEPv-LHG:tubGal80TS
licd13/+p38bd27/+: licd13/+; p38bd27/+; salEPv-LHG:tubGal80TS/lexO-rpr
dATF2PB/+: w; Atf2PB/+; salE/Pv-LHG:tubGal80TS/lexO-rpr
dATF2PB-/-: w; Atf2PB/Atf2PB; salE/Pv-LHG:tubGal80TS/lexO-rpr
licd13/+ dATF2PB/+: licd13/+; Atf2PB/+; salE/Pv-LHG:tubGal80TS/lexO-rpr
p38bd27/+ dATF2PB/+: w; p38bd27/Atf2PB; salE/Pv-LHG:tubGal80TS/lexO-rpr
dATF2PB/+p38a1/+: w; Atf2PB/lexO-rpr; p38a1/salEPv-LHG:tubGal80TS
B. salE/Pv>rpr: UAS-rpr/+; salE/Pv-Gal4/+; tubGal80TS/+
Fig 6
A. hepr75: hepr75/Y
B. ptc>rpr hepr75: hepr75/Y; ptc-Gal4:tubGal80TS/+; UAS-rpr/+
C. wt: w; TRE-DsRed.T4
p38a-/-: w; TRE-DsRed.T4; p38a1/p38a1
Fig 7
A, B. Wild type.
C, D. hepr75: hepr75/Y
E. upd-Gal4/+; UAS-myrtomato/10XSTAT92E-GFP
F, G, H, I. ptc>rpr: UAS-rpr/+; ptc-Gal4/+; tubGal80TS/+
salE/Pv>rpr: UAS-rpr/+; sal-Gal4/+; tubGal80TS/+
J, K. salE/Pv>rpr ci>GFP: w; ci-Gal4/lexO-rpr; salE/Pv-LHG:tubGal80TS/UAS-GFP
ci>domeDN salE/Pv>GFP: w; ci-Gal4/lexO-rCD2::GFP; salE/Pv-LHG:tubGal80TS/UAS-domeDN
salE/Pv>rpr ci> domeDN: w; ci-Gal4/lexO-rpr; salE/Pv-LHG:tubGal80TS/UAS-domeDN
L, M, N. ci-Gal4 UAS-upd: w; ci-Gal4/UAS-upd; salE/Pv-LHG:tubGal80TS/lexO-rCD2::GFP
salE/Pv-LHG lexO-rpr: w; ci-Gal4/UAS-GFP; salE/Pv-LHG:tubGal80TS/lexO-rpr
ci-Gal4 UAS-upd salE/Pv-LHG lexO-rpr: w; ci-Gal4/UAS-upd; salE/Pv-LHG:tubGal80TS/lexO-rpr
Fig 8
A, B, C. Wild type.
p38a-/-: w; +; p38a1/p38a1
D, E, F. ci-Gal4 UAS-upd: w; ci-Gal4/UAS-upd; salE/Pv-LHG:tubGal80TS/lexO-rCD2::GFP
salE/Pv-LHG lexO-rpr: w; ci-Gal4/UAS-GFP; salE/Pv-LHG:tubGal80TS/lexO-rpr
ci-Gal4 UAS-upd salE/Pv-LHG lexO-rpr: w; ci-Gal4/UAS-upd; salE/Pv-LHG:tubGal80TS/lexO-rpr
S1 Fig
A, C, D. Wild type.
B. ptc>rpr: UAS-rpr/+; ptc-Gal4:tubGal80TS/+
S2 Fig
A. wt
B. salE/Pv>rpr: UAS-rpr/+; salE/Pv-Gal4/+; tubGal80TS/+
C. salE/Pv>rpr nub>GFP: w; nub-Gal4/UAS-GFP; salE/Pv-LHG:tubGal80TS/lexO-rpr
salE/Pv>rpr nub>Cat: w; nub-Gal4/UAS-Cat; salE/Pv-LHG:tubGal80TS/lexO-rpr
salE/Pv>rpr nub>Sod: w; nub-Gal4/UAS-Sod; salE/Pv-LHG:tubGal80TS/lexO-rpr
salE/Pv>rpr nub>Sod:Cat: w; nub-Gal4/UAS-Sod:Cat; salE/Pv-LHG:tubGal80TS/lexO-rpr
D. salE/Pv>rpr nub>GFP: w; nub-Gal4/UAS-GFP; salE/Pv-LHG:tubGal80TS/lexO-rpr
salE/Pv>rpr nub>Cat: w; nub-Gal4/UAS-Cat; salE/Pv-LHG:tubGal80TS/lexO-rpr
nub>Cat: w; nub-Gal4/UAS-Cat; salE/Pv-LHG:tubGal80TS/lexO-GFP
salE/Pv>rpr nub>Sod: w; nub-Gal4/UAS-Sod; salE/Pv-LHG:tubGal80TS/lexO-rpr
nub>Sod: w; nub-Gal4/UAS-Sod; salE/Pv-LHG:tubGal80TS/lexO-GFP
salE/Pv>rpr nub>Sod:Cat: w; nub-Gal4/UAS-Sod:Cat; salE/Pv-LHG:tubGal80TS/lexO-rpr
nub>Sod:Cat: w; nub-Gal4/UAS-Sod:Cat; salE/Pv-LHG:tubGal80TS/lexO-GFP
S3 Fig
A. Wild type.
B. w; TRE-DsRed.T4/+; puc-Gal4:UAS-GFP/+
C. ptc>rpr: UAS-rpr/+; ptc-Gal4:tubGal80TS/TRE-DsRed.T4
D. salE/Pv>rpr: UAS-rpr/+; salE/Pv-Gal4/+; tubGal80TS/+
S4 Fig
Wild type
S5 Fig
A. salE/Pv>rpr: w; ci-Gal4/UAS-GFP; salE/Pv-LHG:tubGal80TS/lexO-rpr
ci>RNAi p38a: w; ci-Gal4/UAS-RNAi p38a; salE/Pv-LHG:tubGal80TS/lexO-GFP
salE/Pv>rpr ci>RNAi p38a: w; ci-Gal4/UAS-RNAi p38a; salE/Pv-LHG:tubGal80TS/lexO-rpr
ci>RNAi p38b: w; ci-Gal4/UAS-RNAi p38b; salE/Pv-LHG:tubGal80TS/lexO-GFP
salE/Pv>rpr ci>RNAi p38b: w; ci-Gal4/UAS-RNAi p38b; salE/Pv-LHG:tubGal80TS/lexO-rpr
ci>RNAi Atf2: w; ci-Gal4/UAS-RNAi Atf2; salE/Pv-LHG:tubGal80TS/lexO-GFP
salE/Pv>rpr ci>RNAi Atf2: w; ci-Gal4/UAS-RNAi Atf2; salE/Pv-LHG:tubGal80TS/lexO-rpr
ci>RNAi lic: w; ci-Gal4/UAS-RNAi lic; salE/Pv-LHG:tubGal80TS/lexO-GFP
salE/Pv>rpr ci>RNAi lic: w; ci-Gal4/UAS-RNAi lic; salE/Pv-LHG:tubGal80TS/lexO-rpr
B. salE/Pv>rpr: UAS-rpr/+; salE/Pv-Gal4/+; tubGal80TS/+
C. salE/Pv>rpr: UAS-rpr/+; salE/Pv-Gal4/+; tubGal80TS/+
ptc>rpr: UAS-rpr/+; ptc-Gal4:tubGal80TS/TRE-DsRed.T4
S6 Fig
en>RNAi lic: w; en-Gal4:UAS-GFP/UAS-RNAi lic
S7 Fig
Control: UAS-rpr/+; salE/Pv-Gal4/+; tubGal80TS/+
hop2/+: UAS-rpr/hop2; salE/Pv-Gal4/+; tubGal80TS/+
hop27/+: UAS-rpr/hop27; salE/Pv-Gal4/+; tubGal80TS/+
stat92e397/+: UAS-rpr/+; salE/Pv-Gal4/+; tubGal80TS/stat92e397
stat92e06346/+: UAS-rpr/+; salE/Pv-Gal4/+; tubGal80TS/stat92e06346
S8 Fig
Wild type.
p38a-/-: w; +; p38a1/p38a1
Supporting Information
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Genetika Reprodukčná medicínaČlánok vyšiel v časopise
PLOS Genetics
2015 Číslo 10
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