A Tumor-Specific Molecular Network Promotes Tumor Growth in Drosophila by Enforcing a Jun N-Terminal Kinase–Yorkie Feedforward Loop

Simple Summary Cancer genomics and transcriptomics have revealed genes and pathways altered in several cancers. These studies have provided valuable information about cancer cells, their origin, oncogenic processes, and signaling pathways. An emerging challenge is to further characterize activity levels and interactions of pathways to develop a deeper understanding of how specific alterations in these interactions promote tumor growth. Drosophila with its sophisticated genetics has proved valuable in studying cooperative oncogenesis. Using Drosophila tumor models, we report a tumor cell-specific network comprising four pathways. We show that Wingless and effector caspase Dronc direct a signal amplification loop involving JNK and Hippo-effector Yorkie (Yki). Our studies provide evidence from in vivo studies regarding the organization of tumor-promoting oncogenic pathways, which may be useful in developing precise and effective approaches for pathway inhibition. These pathways are evolutionarily conserved from flies to humans, suggesting that findings from flies can be extrapolated to mammalian cancers. Abstract Cancer cells expand rapidly in response to altered intercellular and signaling interactions to achieve the hallmarks of cancer. Impaired cell polarity combined with activated oncogenes is known to promote several hallmarks of cancer, e.g., activating invasion by increased activity of Jun N-terminal kinase (JNK) and sustained proliferative signaling by increased activity of Hippo effector Yorkie (Yki). Thus, JNK, Yki, and their downstream transcription factors have emerged as synergistic drivers of tumor growth through pro-tumor signaling and intercellular interactions like cell competition. However, little is known about the signals that converge onto JNK and Yki in tumor cells and enable tumor cells to achieve the hallmarks of cancer. Here, using mosaic models of cooperative oncogenesis (RasV12,scrib−) in Drosophila, we show that RasV12,scrib− tumor cells grow through the activation of a previously unidentified network comprising Wingless (Wg), Dronc, JNK, and Yki. We show that RasV12,scrib− cells show increased Wg, Dronc, JNK, and Yki signaling, and all these signals are required for the growth of RasV12,scrib− tumors. We report that Wg and Dronc converge onto a JNK–Yki self-reinforcing positive feedback signal-amplification loop that promotes tumor growth. We found that the Wg–Dronc–Yki–JNK molecular network is specifically activated in polarity-impaired tumor cells and not in normal cells, in which apical-basal polarity remains intact. Our findings suggest that the identification of molecular networks may provide significant insights into the key biologically meaningful changes in signaling pathways and paradoxical signals that promote tumorigenesis.


Introduction
Over the past decade, genomic, transcriptomic, and proteomic data from several cancers have revealed the genetic alterations and changes in gene expression and epigenetic modifications linked to several cancers [1][2][3][4].These approaches have revealed the extensive differences between normal and cancer cells, as well as the effects of cancer on multiple genes and signaling pathways [3].Although these studies have provided valuable information about cancer cells, their origin, oncogenic processes, and signaling pathways, efforts now need to be directed at further characterizing tumors.For example, which proteins are expressed in the same cancer cell and are likely to physically interact?Which signaling pathways play decisive roles in promoting cell proliferation, survival, and metastasis in the different stages of cancer?Does the intricate distribution or clustering of ligand receptors affect cell-cell interactions [5]?For this, complementary approaches with in vivo models that allow manipulation of multiple genes (that represent the key cancer driver mutations) are required.
Drosophila, the common fruit fly, represents an efficient model organism to modulate the expression of multiple genes to study the signaling crosstalk that promotes tumor growth and progression [6,7].Models of cooperative oncogenesis in Drosophila, such as clonal tumors induced by the activation of oncogenic Ras (Ras V12 ) in polarity-deficient scribble (scrib) [Ras V12 scrib − ], lethal giant larva (lgl), or discs large (dlg) mutant cells, show classic hallmarks of aggressive cancer growth exemplified by increased proliferation rate, reduced apoptosis and differentiation, and metastasis [8][9][10][11].These models have been instrumental in establishing the links between the deregulation of cell polarity and increased signaling from Jun N-terminal kinase (JNK) and Yorkie (Yki), effectors of two key signaling pathways that regulate cell proliferation and apoptosis [12][13][14][15][16].However, the upstream mechanisms by which JNK and Yki activation promote aggressive metastatic growth during oncogenic cooperation remain poorly defined.
We investigated the changes in signaling interactions to decipher how oncogenic cooperation [Ras V12 ,scrib − ] promotes tumor growth.Herein, we show that the Ras V12 ,scrib − tumors grow aggressively by upregulating a previously unidentified molecular network comprising the Wingless (Wg, the Drosophila homolog of mammalian Wnt1), the effector caspase Dronc (Drosophila homolog of mammalian Caspase 9), JNK, and Yki (Drosophila homolog of Hippo effectors YAP/TAZ in mammals).The upregulation of these signals promotes the growth of Ras V12 ,scrib − tumors, and the depletion of these signals reverses these phenotypes.These signals are well-known for their roles in patterning and growth control [17][18][19][20][21] and intercellular interactions like cell competition [22][23][24][25][26][27][28].We show that during oncogenic cooperation, these signals act together in a tumor cell-specific signaling network, in which Wg acts upstream of Dronc and regulates JNK and Yki.JNK activity changes from pro-apoptosis to pro-proliferation due to a paradoxical signaling switch that ultimately promotes Yki activity.We demonstrate that in Ras V12 ,scrib − tumor cells, Yki, in turn, upregulates JNK activity, causing the robust activation of both JNK and Yki.This bidirectional regulatory interaction results in the formation of a self-reinforcing JNK-Yki positive feedback signal-amplification loop downstream of Wg and Dronc.We show that this molecular network is sufficient to induce tumorigenesis in other contexts of oncogenic cooperation (such as en > Yki, scrib − , or Ras V12 //scrib − [interclonal tumor model [10]]).Taken together, our data strongly support the functional significance of molecular networks rather than individual signals in cancer cells and provide novel insights into the molecular pathways and paradoxical signals that play a key role in tumor growth and progression.

Fly Stocks
The studies described here are conducted on Drosophila melanogaster, the common fruit fly.All flies were reared in a standard cornmeal-agar-molasses medium containing Tegosept and propionic acid.All fly stocks used in this study are described in Flybase (http://flybase.bio.indiana.edu)accessed on 1 March 2024.

Immunohistochemistry and Image Acquisition
Immunohistochemistry was performed following our published protocol [37].Briefly, imaginal discs from wandering 3rd instar larvae were dissected in 1XPBS (phosphate buffered saline), fixed in 4% paraformaldehyde (PFA) for 20 min (min) at room temperature (RT), washed 3 × 10 min each in 1XPBST (1XPBS + 0.2% Triton X-100), and blocked in PBSTN (PBST+ 2% Normal donkey serum) for 1 h before incubation with primary antibody at 4 • C overnight.The samples were then washed 3 × 10 min each in 1XPBST, incubated in an appropriate secondary antibody for two hours at RT, washed in 1XPBST for 20 min, and mounted in Vectashield (Vector Laboratories Inc., Burlingame, CA, USA).
Image acquisition: We used an Olympus Fluoview 1000 confocal microscope to acquire projections of Z-stacks of confocal images.To enable comparison between samples, all images in an experimental group were acquired at identical magnification and similar imaging conditions.The final figures were made using Adobe Photoshop CS6.

Statistical Analyses
Statistical analyses were performed using Microsoft Excel 2013.The magnetic lasso tool was used for clone size comparison (Figures 1A and 2A Wild type n = 11, rest n = 25).Mean pixel values of clone area were obtained using the Histogram function in Photoshop CS6 and analyzed using the non-parametric Mann-Whitney test (two-tailed), assuming statistical significance at p < 0.05.Signal intensity levels for both inside (GFP-positive) and outside (GFP-negative), the clones were obtained using the histogram function in Adobe Photoshop CS6 (n = 5).The average wild-type values were used to find the normalization factor to determine and calculate differences in intensity levels between wild-type, scrib − , Ras V12 , and Ras V12 ; scrib − clones for all antibodies tested.Bar scatterplots were then generated to show fold-change in Dronc, Wg, dronc 1.7kb -lacZ, wg-lacZ, diap1-lacZ, pJNK levels (Figures 1 and S1), and DIAP1 (Figures 2F and S3).Similarly, the normalization factor was calculated using wild-type values (GFP-negative areas) to assess changes in the expression of Wg (Figure 3), Yki, pJNK, and Dronc (Figure 4).Statistical significance (p < 0.05) was tested using a non-parametric Mann-Whitney test (two-tailed), and all graphs were plotted using GraphPad Prism9.0.

qRT-PCR
RNA was extracted from eye imaginal discs from wandering third instar larvae.At least 40-50 discs were collected per genotype in TRIzol.The ZYMO RNA Clean and Concentrator Kit was used for RNA extraction.To prepare cDNA, 200 ng/µL RNA/sample was reverse transcribed using the cDNA synthesis kit (Cytiva, Danaher Corporation, Washington, DC, USA).qRT-PCRs were performed in triplicate per sample using the iQ SYBER Green Supermix (Bio-Rad Laboratories, Hercules, CA USA) on an iCycler iQ™ Real-Time PCR Detection System (Bio-Rad Laboratories, Hercules, CA USA).Three biological and three technical repeats were performed for each experiment, and data were analyzed using the ddCt method.

Ras V12 ,scrib − Cells Grow Robustly and Induce JNK, Yki, Dronc, and Wg
To investigate the changes in intercellular interactions that promote tumor growth, we made ey-FLPand Ubx-FLP-induced MARCM clones [GFP positive] in the eye (Figure 1A-C) and wing discs (Figure 1D,E) respectively and monitored clone size to assess tumor growth (Figure 1A).Compared to wild-type (Figure 1A), scrib − clones grew poorly (Figure S1A) [38].Given that scrib − clones are competed out due to cell competition-mediated apoptosis [12,38], we blocked apoptosis by overexpressing UASp35 (Figure S1B), a pan-Caspase inhibitor [39].The inhibition of apoptosis improved the growth of scribclones (scrib − , p35, Figures 1A and S1C); however, the discs remain monolayered, and clones did not form invasive tumors (Figure S1C,C' and YZ sections in Figure S1C").In contrast, the coexpression of oncogenic Ras (UASRas V12 ) in scrib − cells (Ras V12 ,scrib − ) resulted in robust aggressive and invasive tumors [8] that grew severalfold compared to wild-type, scrib − , or scrib − , p35 clones (Figure 1A).These data suggest that a paradoxical switch changes the ability of scrib − cells, and inter-cellular interactions may play a critical role in these observed effects.Next, to understand the nature of the intercellular interactions that may underlie the differences in clone sizes, we tested cell death by using an antibody against activated Caspase 3 [Casp3*].In comparison to wild-type clones (Figure 1B,B'), Ras V12 ,scrib − clones show cell death both inside and outside the clone, and interestingly, the bulk of the observed cell death was induced in wild-type cells surrounding the clone (Figures 1C,C' and S1B-B").Similarly in the wing discs, compared to wild-type (Figure 1D), Ras V12 ,scrib − clones grew into large invasive tumors (Figures 1E and S1D).Taken together, these data suggested that the Ras V12 ,scrib − clones grow robustly.Therefore, as a next step, we tested if JNK, Yki, Dronc, and Wg, markers that have previously been linked to cell survival and proliferation during cell competition [22][23][24]40] were also affected in the Ras V12 scrib − tumors.1D), Ras V12 ,scrib − clones grew into large invasive tumors (Figures 1E and S1D).Taken together, these data suggested that the Ras V12 ,scrib − clones grow robustly.Therefore, as a next step, we tested if JNK, Yki, Dronc, and Wg, markers that have previously been linked to cell survival and proliferation during cell competition [22][23][24]40] were also affected in the Ras V12 scrib − tumors.JNK and Yki are known to interact in a context-dependent manner [12][13][14]41], and increased JNK or Yki activity has been linked to tumor growth [12,[42][43][44][45].In contrast, the elimination of scrib − cells by cell competition involved JNK-dependent suppression of Yki activity [12,38,[46][47][48].To test Yki activity, we employed the Yki-reporter, diap1-lacZ, which is expressed ubiquitously in wild-type (Figure S1E) discs.Increased Yki activity due to Yki overexpression in "Flp-out" (AyGAL4 > Yki) clones showed the robust induction of diap1-lacZ (Figure S1F,F').In the Ras V12 ,scrib − clones, diap1-lacZ was strongly induced (Figure S1G,G').Interestingly, diap1-lacZ was also induced in peri-tumoral cells (non-cell autonomously in wild-type cells) abutting the Ras V12 ,scrib − tumors (Figure S1G').The normalized pixel intensity from the controls and experimental groups was quantified and showed a significant increase in Ras V12 ,scrib − clones (Figure S1H).Compared to wildtype (Figure S1I,I'), pJNK was robustly induced in the Ras V12 ,scrib − clones (Figure S1J,J', quantified in Figure S1K).Thus, consistent with previous data, JNK and Yki activities were simultaneously upregulated in the Ras V12 ,scrib − tumors.We then investigated the signals that converge onto Yki and JNK to promote the growth of Ras V12 ,scrib − tumors.
Previous studies have shown that Dronc (the initiator caspase that induces apoptosis through activation of caspase 3) and Wg (the secreted ligand of the Wingless/Wnt pathway that acts as a mitogen) play critical roles in intercellular interactions like cell competition and compensatory proliferation [27,[49][50][51].Yki also transcriptionally regulates dronc and wg [52,53].We tested levels of active Dronc using an antibody against Dronc CA , the activated form of Dronc [51], and Wg in the Ras V12 ,scrib − clones (Figure 1).Dronc is expressed ubiquitously in wild-type imaginal discs (Figure 1F,F', quantified in Figure 1H), and its levels remained unaffected in scrib − cells in the wild-type background (Figure 1H).Therefore, wild-type Dronc levels may be sufficient for the elimination of scrib − cells in the presence of elevated pJNK levels.In comparison, Dronc was strongly upregulated in Ras V12 ,scrib − cells (Figure 1G,G').Quantification showed that Dronc levels were significantly upregulated (1.7-fold) in Ras V12 ,scrib − cells compared to either wild-type or scrib − cells (Figure 1H).Taken together, these data suggested that Dronc plays a non-apoptotic role and promotes Ras V12 ,scrib − tumor growth.In wildtype eye discs, Wg is expressed at the lateral margins anterior to the morphogenetic furrow (Figure 1I,I', quantified in Figure 1K) [32].This pattern of Wg expression was unaltered in scrib − cells generated in the wild-type background (Figure 1K).In Ras V12 ,scrib − clones, Wg was robustly induced (Figure 1J,J').When compared to wild-type or scrib − cells, Wg expression was significantly upregulated (2.7-fold) in Ras V12 ,scrib − cells (Figure 1K), suggesting that the steep upregulation of Wg levels in Ras V12 ,scrib − may itself promote super-competition by promoting proliferation through its mitogenic functions.
Next, we checked if dronc and wg transcription was affected in Ras V12 ,scrib − cells using the dronc 1.7kb -lacZ (Figure 1L-M') and wg-lacZ (Figure 1O-P') reporters, quantified in Figure 1N,Q, respectively.We found that compared to the wild-type (Figure 1L), dronc 1.7kb -lacZ expression was robustly induced in the Ras V12 ,scrib − clones (Figure 1M,M').Similarly, the normal pattern of wg-lacZ expression in eye discs (Figure 1O) was disrupted due to ectopic induction of wg-lacZ in Ras V12 ,scrib − clones (Figure 1O').We confirmed the increased expression of dronc and wg in Ras V12 ,scrib − clones using qRT-PCR (Figure S2).The upregulation of dronc and wg in the tumor cells suggests that these genes promote tumor growth, possibly by co-opting compensatory mechanisms in which dronc plays a non-apoptotic role and wg plays a mitogenic role.Taken together, these data suggest that four signals associated with intercellular interactions (Yki, JNK, Wg, caspases) were upregulated in aggressively growing Ras V12 ,scrib − tumors.

Ras V12 ,scrib − Tumors Require JNK, Yki, Dronc, and Wg for Growth
To understand if some or all of these signals played a key role in the aggressive growth of Ras V12 ,scrib − tumors, we tested their requirement by independently downregulating these signals in Ras V12 ,scrib − clones (Figure 2).To achieve this, we used well-established transgenes, for example, RNAi, to knockdown Dronc, which impairs caspase-mediated signaling [UAS-Dronc RNAi ] [52], the dominant-negative form of Bsk, which is a potent suppressor of JNK signaling [UAS-Bsk DN ] [38], UAS-Sgg S9A , which dominantly blocks Wg signaling [54], and UAS-Yki N+CRNAi , which causes the inactivation of Yki-mediated signaling [34].lished transgenes, for example, RNAi, to knockdown Dronc, which impairs caspase-mediated signaling [UAS-Dronc RNAi ] [52], the dominant-negative form of Bsk, which is a potent suppressor of JNK signaling [UAS-Bsk DN ] [38], UAS-Sgg S9A , which dominantly blocks Wg signaling [54], and UAS-Yki N+CRNAi , which causes the inactivation of Yki-mediated signaling [34].A comparison of clone sizes revealed that individual downregulation of the four signaling pathways significantly decreased the growth of the Ras V12 ,scrib − cells (Figure 2A-E).These findings suggested that the four signals are independently required for the aggressive growth of Ras V12 ,scrib − tumors.Therefore, we next tested if loss of cellular fitness or interactions amongst these signals was an underlying cause for the change in tumor size.

Downregulation of JNK, Yki, Dronc, and Wg Impairs Cellular Fitness
We hypothesized that the reduction in clone size was due to altered fitness within Ras V12 ,scrib − cells.First, we tested changes in DIAP1 levels (Figure 2B-E red, grey) in conditions where at least one of these four signals was downregulated (Figure 2B-F).As DIAP1 inhibits caspase activation, it protects cells from caspase-mediated apoptosis [55].DIAP1 was ubiquitously expressed in wild-type cells (Figure S3A), downregulated in scrib − cells (Figure S3B, yellow arrowheads), and robustly induced in Ras V12 ,scrib − clones (Figure S3C).However, when Yki (Figure 2B), JNK (Figure 2C), Dronc (Figure 2D), or Wg (Figure 2E) were downregulated in Ras V12 ,scrib − clones (Figure 2C-E, yellow outline in grey channels), DIAP1 was downregulated (quantified in Figure 2F).This finding suggests that Ras V12 ,scrib − tumor cells had decreased survival and were susceptible to elimination by apoptosis (Figure 2B-E, blue, grey), when the tumor-promoting signals were downregulated.The downregulation of Yki (Figure 2B) or Wg (Figure 2E) resulted in apoptosis both inside (Figure 2B,E yellow arrowheads) and outside (Figure 2B,E, red arrowhead) the Ras V12 ,scrib − clones, suggesting that Wg and Yki protect Ras V12 ,scrib − tumors during competitive interactions.The downregulation of the JNK pathway (Figure 2C) or Dronc (Figure 2D) resulted in apoptosis at the clone boundary (Figure 2C,D, red arrowhead), but not within the clones, likely because these cell death regulators (JNK and Dronc) were suppressed in the clones.Taken together, these data suggested that the downregulation of the tumor-promoting signals impaired cellular fitness in Ras V12 ,scrib − cells.
These observations were further supported in control experiments, where we made MARCM clones in which we depleted each component of the molecular network in otherwise wild-type cells (Figure S4).Wg is a target of its own signaling [56][57][58].Therefore, we made UAS-Sgg S9A control clones (Figure S3A,B) and confirmed that the endogenous expression of Wg was suppressed in UAS-Sgg S9A clones using anti-Wg antibody (shown by the yellow arrow in Figure S4B").The downregulation of Wg signaling (Figure S4B  Next, we tested if Wg, Dronc, JNK, and Yki regulated one another to promote the aggressive growth of Ras V12 ,scrib − tumors (Figure 3).The downregulation of Wg signaling in Ras V12 ,scrib − cells (Figure 3A) resulted in small tumors and a reduction in Wg expression (Figure 3A red, A" grey).Interestingly, depleting Dronc (Figure 3B), JNK (Figure 3C), or Yki (Figure 3D) caused a significant decrease in clone size, but Wg was strongly induced in these clones (Figure 3B"-D").It is notable that Wg is induced in both a cell-autonomous and non-cell-autonomous manner.Normalized signal intensity is quantified in Figure 3E.Thus, we identified that Wg acts upstream of Dronc, JNK, and Yki in the network of signals that promote Ras V12 ,scrib − tumor growth.To test if these signals interact with each other, we checked the effects of Yki depletion (Yki RNAi ; Ras V12 ,scrib − , Figure 4A-D) on Dronc (Figure 4A) and pJNK expression (Figure 4B).The depletion of Yki (confirmed in Figure 4C red, C' grey) did not affect the induction of Dronc (Figure 4A blue, A' grey); however, pJNK expression was downregulated in these clones (Figure 4B red, B' grey).We quantified the normalized mean grey values and plotted the fold change comparing wild-type to Ras V12 ,scrib − and Yki RNAi ; Ras V12 ,scrib − .Graphs show the significant downregulation of Yki and pJNK, whereas Dronc accumulation was not affected (Figure 4D).Next, we downregulated JNK signaling (Figure 4E-G) through the overexpression of a dominant negative form of basket (Bsk) in Ras V12 ,scrib − (Bsk DN ; Ras V12 ,scrib − ), which results in the downregulation of pJNK (Figure 4E blue, E" grey), but Dronc expression remained upregulated in these clones (Figure 4E red, E' grey).Interestingly, Yki expression was also depleted in Bsk DN ; Ras V12 ,scrib − cells (Figure 4F red, F' grey).We plotted the normalized fold change in the expression of Dronc, Yki, and pJNK, which confirms these effects (Figure 4G).Interestingly, the downregulation of Dronc (Dronc RNAi ; Ras V12 ,scrib − , Figure 4H-J) in Ras V12 ,scrib − cells (Figure 4H red, H' grey) showed the downregulation of JNK (Figure 4H blue, H" grey) and Yki (Figure 4I red, I' grey).Quantification shows that compared to wild-type or Ras V12 ,scrib − , the significant downregulation of Yki and JNK is seen in Dronc RNAi ; Ras V12 ,scrib − clones (Figure 4J).The downregulation of Wg (Figure 4K-M) in Ras V12 ,scrib − cells (Sgg S9A ; Ras V12 ,scrib − ) showed the downregulation of Dronc (Figure 4K red, K' grey), pJNK (Figure 4K blue, K" grey), and Yki (Figure 4L red, L' grey).Quantification of the effects of downregulation of Wg revealed significant downregulation of Dronc, Yki, and pJNK compared to Ras V12 ,scrib − clones (Figure 4M).These data show that Dronc levels remain upregulated and comparable to Ras V12 ,scrib − cells in combinations in which either Yki (Figure 4D) or JNK (Figure 4G) are downregulated.Thus, these data suggest that Dronc acts upstream of Yki and JNK in this signaling network.Furthermore, JNK and Yki regulate each other, suggesting that they may act in a feedforward loop downstream of Dronc.Overall, our data suggest that the growth of the Ras V12 ,scrib − clones depended on a network involving Wg-dependent activation of Dronc, which controls a JNK-Yki mediated signal amplification loop that sustains high levels of JNK and Yki activities.

Cooperative Interactions Stimulate the Molecular Network and Tumor Growth
The preceding data led us to ask if oncogene activation, loss of polarity (scrib − ), or cooperative interactions were important in stimulating the molecular network and tumor growth.The loss of polarity (scrib) alone is insufficient to induce aggressive growth in somatic clones (Figures 1 and S1) [8,9,12,38]; therefore, we tested the importance of cooperative interactions on the induction of the Wg-Dronc-JNK-Yki network and tumor growth.We tested two scenarios in which the loss of polarity could synergize with oncogene activation.
In the first scenario, we generated scrib − clones [GFP-negative clones in the FRT82B Ubi-GFP background generated by hs-FLP] in wing discs in which Yki was overexpressed [UAS-Yki] in the posterior compartment using en-GAL4 [en > Yki; scrib − ] (Figure 5).In the eye or wing discs, scrib mutant clones are susceptible to elimination by cell competition due to the upregulation of JNK (Figure S5A-B'), downregulation of Yki activity, as seen through the suppression of diap1-lacZ (Figure S5C-D' yellow arrowheads), and little to no effect on Dronc (Figure S5E) or Wg (Figure S5F) expression.Whereas, consistent with published data, the over-expression of Yki results in robust overgrowth due to the induction of Yki activity, leading to the upregulation of JNK [14,16], activation of DIAP1 (Figure S1F), ectopic induction of Wg [16], and suppression of Dronc [52].Thus, the loss of scrib had clear and distinguishable effects from Yki overexpression (Figures 5 and S5) on all four signals.These distinct effects allowed an ideal opportunity to test altered signaling caused during oncogenic cooperation by Yki overexpression in scrib mutant cells.We found that scrib − clones grew to significantly larger sizes in the posterior (P) compartment in which Yki was overexpressed (Figure 5A-E) and showed reduced E-cadherin expression (Figure 5A, red, grey, red asterisk).Increased Yki activity in the posterior compartment was monitored by ex-lacZ expression (Figure 5B red, B' grey), which also allows marking the anterior-posterior (A/P) boundary (shown in the yellow dotted line in Figure 5).In addition to the increased ex-lacZ staining observed in the posterior compartment due to yki overexpression, Yki activity in the scribcells in the posterior compartment was very strongly induced within and around the clones (Figure 5B, outlined by the yellow line).We called this dramatic increase in Yki activity "super-induction".In these clones, pJNK (Figure 5C   In the second scenario, we tested if the Wg-Dronc-JNK-Yki network was activated during interclonal cooperation when Ras V12 and scrib − cells were adjacent to each other (Ras V12 //scrib − ) [10].
Consistent with previous data, aggressive Ras V12 tumors (GFP-positive) were formed adjacent to smaller scrib − clones (GFP negative, Figure 6A) [10].Interestingly, the Ras V12 clones extruded apically and showed a multi-layered invasive phenotype (Figure 6A-A", Y-Z sections in Figure 6B-B").The Ras V12 clones showed robust growth despite the induction of cell death at the clone boundary between Ras V12 (GFP-positive) and scrib − (GFP-negative) (Figure 6C,C') clones.The expression of Wg was robustly induced in the scrib − clones (Figure 6D,D'), whereas pJNK levels appear upregulated in both scrib − and Ras V12 clones (Figure 6E,E') [10,38].Yki expression showed higher nucleocytoplasmic distribution in the Ras V12 clones (Figure 6F,F').Taken together, these data suggest that the robust growth of the Ras V12 clones was dependent on the interclonal signaling interactions with scrib − clones and involved caspases, Yki, Wg, and JNK signaling.Overall, these two experimental approaches reaffirmed that the induction of the molecular network was intimately linked to tumor growth in diverse scenarios.
tribution in the Ras V12 clones (Figure 6F,F').Taken together, these data suggest that th robust growth of the Ras V12 clones was dependent on the interclonal signaling interaction with scrib − clones and involved caspases, Yki, Wg, and JNK signaling.Overall, these tw experimental approaches reaffirmed that the induction of the molecular network was in timately linked to tumor growth in diverse scenarios.

The Role of Apical-Basal Polarity in the Establishment of Tumor-Specific Molecular Networks
The Wg-Dronc-Yki-JNK network requirement in promoting tumor growth unde various cooperative contexts raised the question if these four signals were sufficient t induce tumors in normal cells or if the loss of polarity is essential to form aggressive tu mors.To test this, we first tested the effect of overexpressing Wg-Dronc-Yki-JNK in no mal cells using the Gal4-UAS system in wing-imaginal discs.We used the wing hinge an

The Role of Apical-Basal Polarity in the Establishment of Tumor-Specific Molecular Networks
The Wg-Dronc-Yki-JNK network requirement in promoting tumor growth under various cooperative contexts raised the question if these four signals were sufficient to induce tumors in normal cells or if the loss of polarity is essential to form aggressive tumors.To test this, we first tested the effect of overexpressing Wg-Dronc-Yki-JNK in normal cells using the Gal4-UAS system in wing-imaginal discs.We used the wing hinge and pouch-specific MS1096-Gal4 (Figure 7A) to drive the expression of transgenes overexpressing Yki (UAS-Yki), Dronc (UAS-proDronc), JNK (UAS-jun aspv ), and Wg (UAS-Arm S10 ) [MS1096 > Yki,pro-Dronc, jun aspv , Arm S10 ], which would result in the activation of all four signals (Figure 7).In wild-type wing discs, DIAP1 (Figure 7B) and pJNK (Figure 7E) are ubiquitously expressed, whereas Wg is expressed in the wing hinge, wing margin, and notum (Figure 7D).Wild-type discs show few randomly dying cells marked by DCP-1 (Figure 7C).Interestingly, the coexpression of these transgenes resulted in hyperplasia of the wing pouch and hinge region (Figure 7F,G).We observed moderate upregulation of DIAP1 in the wing pouch region (Figure 7F') and increased cell death in the wing hinge region (Figure 7F").Both Wg (Figure 7G,G') and pJNK are induced in a patchy pattern in the dorsal hinge region (Figure 7G,G").In control experiments, the overexpression of individual transgenes revealed that the overexpression of Yki (MS1096 > Yki) is capable of driving hyperplasia and the upregulation of DIAP1, Wg, and pJNK (Figure S6A-B").The overexpression of pro-Dronc (MS1096 > proDronc) did not affect disc growth very strongly and showed moderate upregulation of DIAP1, cell death, Wg, and pJNK (Figure S6C-D"), suggesting that pro-Dronc plays a role in promoting survival, but not cell proliferation.Overexpression of jun aspv (MS1096 > jun aspv ) showed the most interesting effects by re-ducing the size of the wing pouch due to strong suppression of DIAP1 and the induction of cell death (Figure S6E-E").Although Wg and pJNK are induced in this combination (Figure S6F-F"), the excessive cell death in the wing pouch does not support the growth of these discs.The activation of the Wg pathway through the overexpression of Arm S10 (MS1096 > Arm S10 ) resulted in the upregulation of DIAP1, Wg, and pJNK (Figure S6G-H").In addition, mild to moderate levels of cell death were observed in the wing pouch (Figure S6G").Taken together, these data suggest that although the coactivation of these transgenes results in increased growth or mild hyperplasia, the presence of normal wildtype cells with intact polarity does not allow for the establishment of the network that would drive the tumor growth.

Discussion
Oncogenic cooperation is a key mechanism for tumor development and progression.Cooperative interactions between oncogenic Ras and loss of scrib − (Ras V12 ,scrib − ) have been elegantly modeled using in vivo mosaic tumor models in Drosophila [8,9,12,38] and multiple mammalian cancer models [59][60][61][62][63].We investigated how altered signaling and cell-cell interactions promote tumorigenesis during oncogenic cooperation.Previously ectopic upregulation of a network of transcription factors, e.g., Upd, JAK-STAT, AP-1, Myc, Ftz, Ets, Irbp18, Xrp1, slow border, and Vrille, were reported to promote the growth and invasiveness of the Ras V12 ,scrib − tumors [64][65][66][67][68]. Data acquired from transcriptomics or RNA-seq have shown the presence of multiple transcription factors in the same genotype suggesting that several pathways and signals may be simultaneously active that culminate in the upregulation of several different transcription factors in tumor cells.These studies also confirm that several transcription factors are active based on the activation of their target genes.However, the potential molecular networks established remained unclear.Here we present evidence to show that a tumor cell-specific network is formed in Ras V12 ,scrib −/− tumors in eye imaginal discs.This network is comprised of Yki, JNK, Wg, and caspases that act to promote fitness and aggressive growth (Figures 1 and S1).Our findings from the eye discs are relevant to other epithelia, like the wing discs as the tumor-specific network, is recapitulated in the en > Yki; scrib − wing tumors (Figure 5).
Of these signals, JNK is very well documented as a modulator of Yki activity in the context of cell competition, compensatory proliferation, regeneration, and neoplastic tumors [12,14].JNK is a pivotal stress-responsive kinase that promotes malignant transformation and metastasis of tumors [38,45].JNK has also emerged as a key paracrine signal that links apoptosis to carcinogenesis [12].In scrib − cells, JNK signaling suppresses Yki activity and promotes cell competition [12,69].Concomitantly, JNK signaling causes the noncell-autonomous propagation of Yki in the cells surrounding scrib − clones and promotes compensatory proliferation [12,69].Thus, in scrib − clones in the wild-type background, JNK (Figure S5B) and Yki (Figure S5C,D) activities are induced in two distinct cell populations, and wild-type levels of Dronc (Figure S5E) or Wg (Figure S5F) are sufficient to support the cell competition-mediated elimination of scrib − cells.Work from our lab and others showed that the suppression of cell death in scrib − cells led to increased proliferation and the loss of differentiation, but not tumorigenesis (Figure S1A,C) [70,71].In contrast, we found that these signaling interactions are significantly altered in Ras V12 ,scrib − cells, as Wg, Dronc, JNK, and Yki are all robustly upregulated (Figures 1 and S1), suggesting a non-apoptotic tumor growth-promoting role for JNK and Dronc and growth-promoting mitogenic roles for Yki and Wg.Using reporter assays for dronc and wg, we found that Ras V12 ,scrib − cells show increased transcription of dronc (Figure 1L-N) and wg (Figure 1O-Q), which was confirmed using qRT-PCR (Figure S2).In addition, increased JNK activity using phospho-specific JNK antibody and Yki activity by diap1-lacZ reporter were confirmed in the Ras V12 ,scrib − clones (Figure S1).These findings are consistent with reports that JNK signaling activity is converted from anti-to pro-tumor growth through the downregulation of Hippo signaling and ultimately leads to Yki activation [14,41].Both Yki/YAP and JNK are linked to Wg signaling, as Wg is induced in a JNK-dependent manner during regenerative growth, tumorigenesis, and compensatory proliferation [51,72,73] and interacts with Yki and the Hippo pathway during organ development and tumorigenesis [74][75][76].In addition, dysregulation of the Hippo, JNK, or Wg pathway is also linked to the activation of caspase-mediated apoptosis, and recently, mild caspase induction was shown to promote tumor growth [77][78][79].Thus, the identification of this molecular network is significant in the context of inter-cellular interactions that promote tumor growth.
Previous studies have shown a role for the JNK and Hippo pathway in Ras V12 scrib − clones [38,41].In our study, an assessment of the roles of JNK, Yki, Dronc, and Wg in Ras V12 ,scrib − tumorigenesis revealed several interesting insights.First, we found that JNK, Yki, Dronc, and Wg were all required for the aggressive growth of Ras V12 ,scrib − -induced tumors, as the downregulation of these signals individually resulted in a significant reduction in tumor growth (Figure 2A).Second, we observed that in the absence of tumor-promoting signals, Ras V12 ,scrib − -induced tumors show reduced survival and fitness (Figure 2).Third, we identified that the four tumor-promoting signals form a tumor cell-specific signaling module in which Wg acts upstream of Dronc, which, in turn, acts upstream of a JNK-Ykimediated positive feedback signal amplification loop (Figures 3 and 4).Signal amplification of Yki and JNK activities caused by the JNK-Yki positive feedback loop plays a key role in promoting tumorigenesis in Ras V12 ,scrib − cells.Fourth, we confirmed that in other instances of oncogenic cooperation (Ras V12 //scrib − ), this signaling module can be recapitulated (Figures 5 and 6).Fifth, the upregulation of JNK and Yki in normal epithelial cells with intact polarity is not sufficient to induce this network and tumor growth (Figures 7 and S6), which is consistent with other instances of developmental interactions between Yki and JNK in polarized epithelia [80,81].Taken together, our studies reveal that increased cellular fitness promoted by a molecular network comprising Wg, Dronc, JNK, and Yki may indeed be a mechanism co-opted for aggressive tumor growth.Furthermore, the overexpression of pathway components in the normal epithelia of wing discs revealed that the signal overactivation levels and the apical-basal polarity context are extremely important.This is because mild hyperplasia can occur by driving the individual transgenes, but robust overgrowth is not seen in cells with intact polarity.Further, for the JNK pathway, a threshold is critical, as stress-induced cell death occurs both when levels of JNK reach above or below the homeostatic levels (Figures 7 and S6).
Another possible mechanism is the differential success of cancer and neighboring normal cells in competing for survival and other extracellular signals in terms of actively internalizing or limiting the extracellular spread of critical signals.In this context, we observed steep differences in the non-cell-autonomous spread of Yki activity among scrib − (Figures 5 and S5C), Ras V12 scrib − (Figure S1G,G'), and en > Yki; scrib − (Figure 5B) cells.Non-cell-autonomous Yki activity spreads to 3-5 cells in scrib − cells, several cells (8-10) in en > Yki; scrib − , and only a few cells (~2) around the Ras V12 ,scrib − clones.Further, cell-autonomous and non-cell-autonomous cell death is observed on the depletion of Yki (Figure 2B), suggesting that cells with impaired Yki expression are vulnerable to elimination by unidentified mechanisms.Interestingly, both cell-autonomous and non-cell-autonomous expression of Wg is seen when the components of the Wg-Dronc-JNK-Yki network are perturbed (Figure 3).Thus, limiting the extracellular spread of key signaling components like Yki or Wg may impact the growth potential of cancer cells.The mechanisms by which cancer cells limit the spread of these signals should be elucidated in future studies and may provide molecular insights about how benign and malignant tumors behave.
The biological significance of our findings is validated by other studies that show the formation of context-dependent Yki/YAP-mediated signaling loops as a bona fide mechanism for tumor growth [82,83].YAP is not only regulated by signaling pathways like Wnt, TGFβ, and notch, but YAP can also collaborate with key cancer pathways to form transcriptional complexes that alter transcriptional programs, specifically in cancer cells [84,85].At least three different mechanisms have been reported.First, YAP and its cognate transcription factors like TEAD control transcription by binding to promoters of target genes.Second, YAP collaborates with other transcription regulators to alter gene expression, for example, in colon cancer cell lines YAP1, β-catenin, and TBX5 transcriptional complex regulate (TCF-or TEAD-independent) target genes [86].Third, YAP/TEAD binds distal regulatory elements to regulate the transcription of target genes [87][88][89].ChIP-seq and deep-sequencing studies in cancer and normal cells showed that several YAP-binding regions also show a consensus motif for AP-1 transcriptional factors, suggesting that YAP/TEAD and AP-1 cooperatively regulate target genes representing a cross-talk between YAP and JNK signaling [88,89].
These findings are especially interesting considering our identification of the tumorcell-specific Wg-Dronc-JNK-Yki molecular network and the JNK-Yki positive feedback signal amplification loop in the Ras V12 scrib − cells.Like YAP, Drosophila Yki is known to regulate transcription by binding to the promoter regions of genes [90].Similarly, Yki can form transcriptional complexes that cooperatively alter gene expression in cancer cells, for example, Yki and the Ecdysone receptor coactivator Taiman were shown to alter the transcriptional output of Yki-inducible Taiman-dependent genes in cells with hyperactive Yki and neoplastic tumor growth [91].Based on our data, it is possible that under conditions of oncogenic cooperation, Yki and the Drosophila AP-1 transcription factors may (cooperatively) bind other regulatory regions to drive altered transcriptional output in cancer cells.This conclusion is further strengthened by the finding that dFos, a component of the Drosophila AP-1 (Drosophila Jun and Fos heterodimer) transcription factor, is required for the JNK-mediated invasiveness of Ras V12 ,scrib − tumors [44,66].In summary, cancer cells may establish specific molecular networks that promote tumor growth and metastasis, and it may be critical to understand these interactions to understand how oncogenic pathways are activated.

Conclusions
Our data are significant in light of emerging data from cancer genome studies that revealed that somatic mutations accrued by precancerous cells essentially activate hallmark cancer pathways that converge on a small number of protein complexes and signaling cascades [6].Our genetic analyses indicate the hierarchy of one such signaling interaction, with Wg acting upstream of Dronc, JNK, and Yki, and in the future, it will be interesting to identify the molecular mechanisms underlying the establishment and regulation of this module.These approaches can also unveil targets for the modulation of the tumor and provide insights into the biomechanics of tumor progression.Our approach of modeling altered signaling interactions in a genetically tractable model is a powerful way to reconstruct key biologically meaningful changes in signaling pathways in cancer cells and provides a functional framework to study the changes in signaling pathway interactions that will generate new insights on mechanisms that promote tumor growth and progression.

Figure 3 .
Figure 3. Wg acts upstream of the molecular network.Panels show Wg expression (red in A-D, grey in A"-D") in MARCM clones (green in A-D, grey in A'-D') of the following genotype:

Figure 5 .
Figure 5. Cooperative interactions induce the Wg-Dronc-JNK-Yki network to stimulate tumor growth.(A) Wing imaginal discs showing en > Yki, scrib − clones (GFP-negative) stained for ex-lacZ (using antibodies to β-gal, (A) blue) and E-cadherin (anti-dCAD2 antibodies, (A) red).The area highlighted by the yellow box is shown at higher magnification in the panels to the right.A cropped image of the clone is shown next to depict changes in polarity and growth.Yellow asterisks show the multi-layered appearance of nuclei positive for ex-lacZ within the en > Yki, scrib − clones, and red asterisks point toward the loss of E-cadherin in the XZ section (along the plain marked in the middle panel), and normal E-cadherin localization is highlighted by red arrows for comparison.(B) Yki activity as assessed by β-gal expression ((B) red, (B') grey) in en > Yki, scrib − clones is shown.(C-E) Wing discs containing en > Yki, scrib − clones (GFP negative) were assayed for ((C) red, (C') grey), ((D) red, (D') grey) or MMP1 ((E) red, (E') grey) expression.The scrib −/− clones in posterior compartment (solid yellow line) and anterior compartment (blue lines) are highlighted for each marker.In all images, the anterior-posterior compartment boundary is marked by a yellow dotted line drawn based on ex-lacZ expression.Images in (A,B) are at 20× magnification, and (C-E) are at 40× magnification.Posterior is to the left and dorsal is up in all discs.Scale bar = 25 µm.

Figure 6 .
Figure 6.Wg-Dronc-JNK-Yki network drives tumor growth during interclonal interactions.(A Ras V12 //scrib -interactions in eye discs show small scrib -clones identified by loss of Scrib expressio (red in A, grey in A') and adjacent Ras V12 clones (GFP positive green in A, grey in A").(B-B") Th YZ projection of the yellow line in A shows a multi-layered Ras V12 clone (GFP).The red asterisk mark the scrib-clones (GFP negative in B,B"), the yellow arrowhead marks the disc proper, and th blue arrowhead marks the peripodial membrane.(C-F) Eye discs show expression of Casp3*(C re C' grey), Wg (D red, D' grey), p-JNK (E red, E' grey), and Yki (F red, F' grey), in Ras V12 //scrib -inte clonal interactions.Note upregulation of Casp3*, Wg and Yki at the boundary of Ras V12 clones.Sca bar = 25 µm.

Figure 6 .
Figure 6.Wg-Dronc-JNK-Yki network drives tumor growth during interclonal interactions.(A) Ras V12 //scrib − interactions in eye discs show small scrib − clones identified by loss of Scrib expression (red in A, grey in A') and adjacent Ras V12 clones (GFP positive green in A, grey in A").(B-B") The YZ projection of the yellow line in A shows a multi-layered Ras V12 clone (GFP).The red asterisks mark the scrib − clones (GFP negative in B,B"), the yellow arrowhead marks the disc proper, and the blue arrowhead marks the peripodial membrane.(C-F) Eye discs show expression of Casp3*(C red, C' grey), Wg (D red, D' grey), p-JNK (E red, E' grey), and Yki (F red, F' grey), in Ras V12 //scrib − interclonal interactions.Note upregulation of Casp3*, Wg and Yki at the boundary of Ras V12 clones.Scale bar = 25 µm.