- Research
- Open access
- Published:
Synergistic inter-clonal cooperation involving crosstalk, co-option and co-dependency can enhance the invasiveness of genetically distant cancer clones
BMC Ecology and Evolution volume 23, Article number: 20 (2023)
Abstract
Background
Despite intensive research, cancer remains a major health problem. The difficulties in treating cancer reflect the complex nature of this disease, including high levels of heterogeneity within tumours. Intra-tumour heterogeneity creates the conditions for inter-clonal competition and selection, which could result in selective sweeps and a reduction in levels of heterogeneity. However, in addition to competing, cancer clones can also cooperate with each other, and the positive effects of these interactions on the fitness of clones could actually contribute to maintaining the heterogeneity of tumours. Consequently, understanding the evolutionary mechanisms and pathways involved in such activities is of great significance for cancer treatment. This is particularly relevant for metastasis (i.e., tumor cell migration, invasion, dispersal and dissemination), which is the most lethal phase during cancer progression. To explore if and how genetically distant clones can cooperate during migration and invasion, this study used three distinct cancer cell lines with different metastatic potentials.
Results
We found that (i) the conditioned media from two invasive lines (breast and lung) increased the migration and invasion potential of a poorly metastatic line (breast), and (ii) this inter-clonal cooperative interaction involved the TGF-β1 signalling pathway. Furthermore, when the less aggressive line was co-cultured with the highly metastatic breast line, the invasive potential of both lines was enhanced, and this outcome was dependent on the co-option (through TGF-β1 autocrine-paracrine signalling) of the weakly metastatic clone into expressing an enhanced malignant phenotype that benefited both clones (i.e., a “help me help you” strategy).
Conclusions
Based on our findings, we propose a model in which crosstalk, co-option, and co-dependency can facilitate the evolution of synergistic cooperative interactions between genetically distant clones. Specifically, we suggest that synergistic cooperative interactions can easily emerge, regardless of the degree of overall genetic/genealogical relatedness, via crosstalk involving metastatic clones able to constitutively secrete molecules that induce and maintain their own malignant state (producer-responder clones) and clones that have the ability to respond to those signals (responder clones) and express a synergistic metastatic behaviour. Taking into account the lack of therapies that directly affect the metastatic process, interfering with such cooperative interactions during the early steps in the metastatic cascade could provide additional strategies to increase patient survival.
Background
Despite intensive research, cancer remains the second cause of death worldwide [1]. The difficulties in curing cancer or preventing tumour progression reflect the complex nature of this disease, including high levels of heterogeneity between and within tumours. In particular, increased intra-tumour heterogeneity is generally linked to poor prognosis and poses a direct problem to therapies as drug resistance will ultimately evolve [2, 3]. According to the clonal evolution model of cancer, intra-tumour heterogeneity creates the conditions for inter-clonal competition and selection, which could result in selective sweeps and a general reduction in levels of heterogeneity [4]. However, it has been suggested that in addition to competing, cancer clones could also cooperate with each other (e.g., [5]), and the positive effects of these activities on the fitness of clones can actually contribute to maintaining the heterogeneity of tumours [6]. In addition, cooperation has been linked to drug resistance [7, 8], tumour growth [9, 10] and increased metastatic potential [11].
It should be noted that the term cooperation is generally used (including in the context of cancer) to denote either (i) an adaptive social behaviour that provides a benefit to another individual and evolved at least partially due to that benefit, or (ii) an interaction that is based on activities resulting in fortuitous benefits (such as feeding upon waste products) that, nevertheless, could evolve into cooperative behaviours (see discussion in [12]). In the former context, the actor can gain indirect benefits by directing the act towards individuals that carry the cooperative gene (e.g., involving discrimination or assortment; costly/altruistic cooperation) or direct fitness benefits that outweigh the costs of performing the behaviour (e.g., through shared interests in cooperation; mutually beneficial cooperation). Similarly, in the latter context, either one or both partners can benefit (commensalism vs. mutualism). Notably, although mutually beneficial cooperation and mutualism are often used synonymously, the two terms in fact describe very different processes: mutually beneficial cooperation implies a single behaviour that affects both the actor and recipient, whereas mutualism describes the effects that each partner has on the other—as in between species (see discussion in [12]). The most common framework for cooperation among tumour cells is the “by-product mutualism” proposed by Axelrod et al. [5], in which partially or fully transformed subclones exchange diffusible factors associated with their routine activities, which might result in benefits that neither could access alone.
Metastasis—characterized by the ability of tumour cells to migrate, invade neighbouring tissues and spread to new sites within the body, is the most lethal stage during cancer progression. To migrate, tumour cells need to undergo several changes—known as the epithelial-mesenchymal transition (EMT) [13], in which cell transition from an epithelial state (with cells connected to each other and attached to the basal membrane) to a mesenchymal state (involving the loss of cell-cell connections and adhesion) followed by the acquisition of cytoplasmic extensions and migratory abilities. The classical view of metastasis envisions single cells migrating and invading neighbouring tissues, dispersing via the vascular system, and disseminating to distant locations. However, more recent findings that some of these steps (e.g., migration, invasion, dispersal) might, in fact, involve groups of cells rather than single cells allows for the possibility that cooperation can actually contribute to successful dispersal, colonization and poor prognosis [11].
In the early stages of metastasis, such cooperative interactions can involve the induction of changes in the phenotype/state of a nearby clone that increase its metastatic potential. For example, it has been suggested that aggressive cancer cells can release signals (e.g., cytokines, chemokines, growth factors, exosomes, miRNAs) that induce EMT and enhance the metastatic potential of non-metastatic clones (see examples using melanoma [14], lung [15, 16] and breast cancer cell lines [17, 18]). Additionally, prostate mesenchymal clones were found to secrete a matricellular protein that increased the invasive capacity of epithelial clones after inducing EMT [19].
Alternatively, it has been proposed that metastatic cells facilitate the dispersal of less- or non-metastatic clones by remodelling the tumour microenvironment. For instance, leader cells can enhance the invasion of follower cells through the extracellular matrix [20, 21]. In other cases, cells that have undergone EMT degrade the surrounding matrix, which then allows the non-metastatic cells to passively enter the bloodstream and establish colonies in secondary sites [22, 23]. In one case, poorly invasive melanoma cells were found to take advantage of the more invasive cells by secreting an unidentified factor that induces a switch in the mode of invasion of the invasive cells, from proteolytic-independent to MT1-MMP-dependent [23].
Overall, despite such examples of possible inter-clonal cooperative interactions affecting the metastatic potential of a tumour, the specific interactions (in terms of the outcome for both interacting clones) and mechanisms involved in these activities are not fully understood. In most reported cases, the interaction appears to benefit one clone, while the effect of the interaction on the other clone is less clear. Nevertheless, in some cases, the interaction seems to benefit both partners, but the exact mechanisms are not known.
Furthermore, the contexts facilitating the emergence and stability of such cooperative interactions during the early stages of the metastatic process are not well understood. While kinship could favour cooperation among related subclones, the increased levels of genetic heterogeneity in advanced tumours might require additional explanations (outside the general framework of “by-product mutualism”; [5]). Furthermore, a better understanding of the general processes and mechanisms involved in initiating and maintaining cooperative activities among cancer cells could provide new therapeutic strategies and targets to inhibit the progression of metastasis.
In this study, we (i) addressed whether genetically distant clones with different metastatic potentials can cooperate to enhance each other’s and their own invasiveness (i.e., synergistic cooperation), (ii) investigated the signalling pathway involved in such inter-clonal cooperation, and (iii) developed a model for the emergence of cooperative interactions in the absence of close genetic/genealogical relatedness. To do so, we used two molecularly and cytologically different breast cancer cell lines that reflect the most common breast cancer cell types—basal (MDA-MB-231; highly aggressive) and luminal (MCF7; less aggressive) as well as a highly metastatic non-small cell lung cancer cell line (derived from NCI-H2122). To simulate a heterogeneous tumour in which different clones can affect each other through diffusible factors (crosstalk), we either subjected each line to the conditioned medium of the other line or grew the two cell lines in co-culture systems (as separate groups sharing the medium or as mixed populations in direct contact). To evaluate their metastatic behaviour, we assessed morphological changes associated with EMT and investigated the capacity of cells to migrate and invade. Based on our findings, we propose a model in which crosstalk, co-option, and co-dependency can facilitate the evolution of synergistic cooperative interactions between genetically distant clones.
Results
MDA-MB-231 induces an EMT-like change in MCF7
To address whether the highly metastatic clone, MDA-MB-231 (abbreviated as MDA from herein on), can induce an EMT-like change in the less metastatic clone, MCF7, we either subjected MCF7 to the conditioned medium (CM) collected from MDA or co-cultured the two cell lines (as a mixture, in a 1:1 ratio). We found that in the presence of MDA or its conditioned medium, MCF7 cells acquired a mesenchymal-like morphology (Fig. 1a and b). Specifically, cell extensions associated with an EMT were observed in MCF7 cultures after 72 h of treatment with MDA conditioned media (MDA_CM) or exogenous Transforming Growth Factor-β1 (TGF-β1) as a positive control (TGF-β1 is a known inducer of EMT [24])—but not when exposed to their own CM (MCF7_CM) (Fig. 1a). Similar extensions were also developed by MCF7 cells when co-cultured with MDA cells for 72 h; on the other hand, the morphology of MDA did not change when in the presence of MCF7 (Fig. 1b).
MDA-MB-231 increases the migration potential of MCF7
To address whether the observed EMT-like changes induced by MDA are associated with an enhanced ability to migrate, we assessed the migration potential of MCF7 in the presence of the conditioned medium from MDA (using both wound-healing and transwell assays) as well as in co-culture with MDA (wound-healing assay). Overall, the migration of MCF7 increased in all contexts. Specifically, the conditioned medium from MDA significantly increased the migration of MCF7 (compared to the effect induced by its own CM) to a level similar to that promoted by TGF-β1 (Fig. 2a and b). Note that the conditioned medium from MCF7 also had a small effect on the migration of MCF7 in the transwell (but not the wound healing) assay. This can be due to a variety of factors, including the increased exposure time (72 vs. 48 h) and subsequent nutrient depletion as well as the added chemotactic component in the transwell assay (i.e., cells are attracted and respond through directional migration). The migration of MCF7 was also significantly increased when MCF7 and MDA cells were co-cultured (in separate patches in the same well) (Fig. 2c). On the other hand, the migration of MDA was not affected in the presence of MCF7_CM or when in co-culture with MCF7 (Fig. 2d and e).
TGF-β1 is involved in the MDA-induced migration of MCF7
As MDA is known to secrete TGF-β1 [27, 28], we tested whether this growth factor is responsible for the increased migration of MCF7 when in the presence of MDA. To do so, we used either a TGF-β receptor I inhibitor or antibodies against TGF-β. We found that inhibiting either the TGF-β receptor I or the TGF-β1 itself significantly decreased the effect of MDA_CM on the migration of MCF7, with the TGF-β receptor I inhibitor completely blocking its effect (Fig. 3a and b). Consistent with MDA secreting and responding to its own TGF-β1 (i.e., autocrine signalling; [28]), the TGF-β receptor I inhibitor also decreased the migration of MDA (Fig. 3c). On the other hand, the TGF-β receptor I inhibitor did not affect the un-induced migration of MCF7 (Fig. 3a), suggesting that the weak constitutive MCF7 migration does not rely on TGF-β1.
To further confirm that TGF-β1 is involved in the effect of MDA_CM on MCF7, we fractionated the CM based on molecular weight and exposed MCF7 to the various fractions. We found that the most effective fractions were those containing molecules between 30 and 100 kDa, and above 100 kDa (Fig. 4a), which is consistent with the size of the various TGF-β1 forms—including active forms around 25 kDa and 50 kDa [29] and latent forms of ~ 95 kDa and ~ 220 kDa [29, 30]. Furthermore, the activity of these fractions was decreased by the addition of the TGF-β receptor I inhibitor (Fig. 4b). Also, as acidification can activate latent forms of TGF-β1 [31], we lowered the pH of the MDA_CM to 4.5 and observed a slight increase in its migratory effect on MCF7 (Fig. 4c).
TGF-β1 mediates crosstalk between cancer cell types of very different origins
To explore the possibility that these findings were not specific to interactions between breast cancer cell types, we used a lung cancer cell line – H2122 AS, in conjunction with either MCF7 or MDA. First, we tested the effect of the conditioned medium from H2122 AS on the migration abilities of MCF7. We found that the inducing effect of H2122AS_CM on MCF7 migration was even higher than that of the MDA_CM (Fig. 5a). Consistent with this effect involving TGF-β1, the migration of MCF7 decreased (but was not entirely blocked) in the presence of the TGF-β receptor I inhibitor (Fig. 5b). Second, we tested whether the MDA_CM was also able to affect the H2122 AS, and found a significant increase in its migration potential (Fig. 5c). Again, consistent with this effect involving TGF-β1, the receptor inhibitor fully blocked the effect of the MDA_CM on H2122 AS migration (Fig. 5d). However, in contrast to MDA, the TGF-β receptor I inhibitor (at the same concentration) did not affect the constitutive migration of H2122 AS (Figs. 3c and 5d).
The invasion of both MDA and MCF7 increases when in co-culture
To address whether the presence of MDA can also enhance the invasive potential of MCF7, we first assessed the number of invaded MCF7 cells in the presence of MDA_CM. We found that MCF7 invaded significantly more when exposed to MDA_CM (relative to both control cells and cells exposed to their own CM; Fig. 6a). In contrast, the MCF7 conditioned media did not affect the invasion of MDA (Fig. 6b). To further evaluate the interaction between the two cell types, we mixed fluorescently labelled MCF7 and unlabelled MDA cells in a 1:1 ratio and allowed them to invade in a co-culture transwell assay. As controls, we used monocultures of each line containing the same number of cells as the total number in the co-culture (i.e., both mono and co-cultures were initiated with the same number of cells). We found that the overall number of invaded cells in the co-culture was higher than in either of the two monocultures, indicating that this mixed population had a higher overall invasion potential relative to either of the two corresponding single-clone populations of the same size (Fig. 6c). Then, to assess the direct effects of the interaction on the invasion of each line, we compared the numbers of invaded cells in co-culture vs. monoculture, for each line (Fig. 6d). We found that the number of invaded MCF7 cells more than doubled when MCF7 and MDA were co-cultured, relative to the same number of MCF7 cells in monoculture. Nevertheless, surprisingly, the number of invaded MDA cells also increased in the presence of MCF7 cells (to almost double, relative to when in monoculture) (Fig. 6d), suggesting that MDA also benefited from this interaction.
Cooperative invasion is dependent on the ability of MCF7 to respond to TGF-β1
To test whether the increased invasive ability of MDA was dependent on the acquired invasive phenotype of MCF7, we suppressed the ability of MCF7 to respond to the TGF-β1 released by MDA by pre-incubating the cells (for 1 h) with the TGFβRI inhibitor prior to co-culturing the two lines. We found that when MCF7 was pretreated with the inhibitor, the invasive abilities of both lines were lower relative to control co-cultures (Fig. 7a), indicating that the invasive benefit of MDA is dependent on the MCF7 being able to respond to the TGF-β1 released by MDA. In addition, to confirm that this ability does provide an invasion benefit when in a heterogeneous tumour we co-cultured both receptor-positive and receptor-inhibited MCF7 in the presence of MDA (1:1:2 ratio). As expected, the invasion of receptor-positive MCF7 cells exceeded that of receptor-inhibited MCF7 cells, indicating a competitive advantage for the former when in the presence of MDA (Fig. 7b). Also, MDA showed an increased invasion in the presence of only receptor-positive cells MCF7 relative to a mix of the two MCF7 populations (Fig. 7c).
Discussion
In this study, we set out to fully investigate how clones with different metastatic potentials interact, with respect to both the effect of the interaction on each clone as well as the mechanisms involved. For instance, in terms of benefits, several scenarios can be envisioned: (i) the less metastatic clone benefits, with no cost or benefit to the highly metastatic clone (passive benefit; commensalism); (ii) the highly metastatic clone can take advantage of the less aggressive clone to increase its own invasion potential without a benefit to the latter (recruitment); (iii) the highly metastatic clone can co-opt the less aggressive clone into expressing a metastatic behaviour that will increase the invasiveness of both clones (synergistic cooperation). In terms of mechanisms, the highly metastatic clone can employ specific signalling molecules to induce a change in the less metastatic clone (i.e., paracrine signalling) or take advantage of the same signalling pathway involved in maintaining its own metastatic potential (i.e., autocrine signalling).
To address these potential scenarios, we chose two breast cancer cell lines with different aggressiveness levels and very different secretome profiles. MDA-MB-231 (a basal and more aggressive subtype) overexpresses more than 25 specific proteins, while MCF7 (a luminal and less aggressive subtype) secretes fifteen unique proteins [32]. Moreover, MDA releases factors that can maintain its metastatic potential (i.e., autocrine signalling) [33], including TGF-β1. In addition, to test if such interactions could be generalized to other cancer types and can involve genetically distant clones, we also used a highly metastatic non-small cell lung cancer cell line (H2122 AS). Compared to previous reports, this study not only characterized the interactions between genetically distant clones with respect to the effect on both clones but also identified the signalling pathway involved. In addition, we provide a model that can explain the emergence of cooperative interactions among genetically distant clones.
The TGF-β1 pathway mediates the co-option of a weakly metastatic clone into expressing an increased malignant phenotype
Our data show that MDA is able to induce EMT, enhanced migration and invasion in MCF7. These findings are consistent with other studies reporting that more aggressive breast lines can enhance the metastatic potential of less metastatic lines. For instance, several aggressive breast cell lines were shown to increase the metastatic abilities of non-metastatic cells through the secretion of miR-200 packaged in extracellular vesicles [17] or through paracrine GLI activation involving Hedgehog ligands (without inducing EMT) [18]. However, in our system, we found that MDA induced EMT and increased the migration of MCF7 through soluble (i.e., not packed into exosomes) TGF-β1, and both the neutralization of TGF-β1 with antibodies and the inhibition of the TGF-β receptor I interfered with the ability of MDA to enhance the metastatic potential of MCF7. MDA is known to secrete large amounts of TGF-β1 to maintain its own metastatic potential (autocrine signalling) [34], and as expected, the inhibition of MDA’s TGF-β receptor I suppressed its migration abilities.
Interestingly, although the non-small cell lung cancer line we used is also able to secrete TGF-β1, its constitutive migration does not seem to be affected by the TGF-β receptor I inhibitor (at least not at the concentration that is effective for MDA), suggesting that its migration is not solely dependent on TGF-β1. This is consistent with a previous study reporting that inter-clonal paracrine signalling between two non-small cell lung cancer lines resulting in EMT induction involved TGF-β1 in conjunction with miRNAs [15].
Overall, our findings show that both aggressive clones (of different cancer types) secrete high levels of TGF-β1, and this released TGF-β1 can contribute to the co-option of the less metastatic clone through paracrine signalling. TGF-β1 is broadly present in the tumour microenvironment and is associated with maintaining the metastatic tumour potential in an autocrine manner [35,36,37]. Also, the serum levels of TGF-β1 are known to increase following tumour progression in patients with colorectal carcinoma [37], prostatic cancer [38], and breast cancer [39]; and such increase is frequently associated with poor prognosis [40]. Thus, it is likely that TGF-β1 is implicated in similar interactions in many types of cancer.
However, for the emergence of such TGFβ1-mediated positive interactions, the co-opted clone needs to express TGF-β receptors and be able to activate migration and invasion through a TGF-β1-mediated signalling pathway. Indeed, we found that MCF7 was able to respond to exogenous TGF-β1, and the inhibition of the TGF-β receptor I suppressed the effect of both TGF-β1 and the conditioned medium from MDA. Interestingly, a previous study exploring the transmission of aggressivity between breast cancer lines reported that the expression of metastatic features in MCF7 in response to conditioned medium from MDA did not involve TGF-β1 paracrine signalling [41]. Instead, the effect was attributed to the secretion of cytokines, such as G-CSF, GM-CSF, MCP-1, and IL-8. In that study, although the conditioned media from MDA increased MCF7 invasion, it only induced a partial EMT in MCF7; and MCF7 did not respond to exogenous TGF-β1 [41]. However, consistent with our findings, many other studies have reported that TGF-β1 does induce EMT (and the expression of mesenchymal markers) and migration in MCF7 [42,43,44]. These conflicting results might be due to the observation that MCF7 differentially expresses TGF-β receptor II depending on the cell passage number and the downregulation of Sp1 [43, 44]. In our MCF7 cell line, both TGF-β receptors I and II are constitutively expressed (our unpublished data).
Inter-clonal synergistic cooperative interactions can increase tumour invasion potential
Positive interactions among cancer cells can be defined as unilateral (one partner passively benefits from the activity of the other; commensalism) or mutually beneficial (both partners benefit; mutualism) [5]. In this study, we have investigated the effect of inter-clonal interactions in the context of both migration and invasion. Interestingly, although MCF7 benefited from the presence of MDA in terms of increasing its own migration potential, the migration of MDA was not affected by MCF7. In other words, in terms of individual migration alone, this interaction did not appear mutually beneficial. Rather, MCF7 unilaterally increased its metastatic abilities by taking advantage of the TGF-β1 released by MDA as part of its own autocrine signalling. In theory, this interaction can result in competition between the two clones. Nevertheless, in the context of a tumour, a unilateral interaction resulting in increased metastatic potential of the recipient might still provide benefits to the actor in other fitness components. Indeed, we found that the invasive potentials of both lines were enhanced when the two lines were co-cultured in direct contact, suggesting that in vivo, such inter-clonal interactions can be mutually beneficial and synergistic.
An increase in each other’s invasiveness was previously reported when several MDA-MB-231 subclones were subjected to each other’s conditioned medium or co-cultured in vitro and in vivo, and this increase involved the release of unknown soluble factors [45]. However, in our system, the conditioned medium from non-induced MCF7 did not affect the migratory or invasive ability of MDA, suggesting that the two clones are not exchanging soluble factors. Also, MCF7 that was previously treated with an inhibitor of the TGF-β receptor I was not able to augment the migration of MDA when in co-culture. These findings argue that MCF7 cannot directly influence the behaviour of MDA, and can benefit MDA only indirectly—that is, if first exposed to the TGF-β1 secreted by MDA. In other words, the ability of MCF7 to “help” MDA is dependent on MDA first “helping” MCF7. Following this activation step, the two clones act synergistically to enhance each other’s (and their own) invasion potentials through either the shared secretion of soluble factors (e.g., proteases), taking advantage of each other’s remodelling of the extracellular matrix, or both. Notably, an increase in MMP-9 (a matrix metalloproteinase) secretion was found when MCF7 was beforehand stimulated with exogenous TGF-β1 for 24 h and co-cultured (though not in direct contact) with MDA-MB-231 [42], suggesting that TGFβ1-activated MCF7 can release invasion proteases. The collectively produced and shared proteases (i.e., public good) can then contribute to the increased invasion potential of both lines.
Similarly, in a rat mammary carcinoma cell line with two stable subtypes, an unknown soluble factor released by one subtype induced collagenase secretion by the other clone, such that collagenase could only be sufficiently secreted when both cellular types were present [46]. Also, in the melanoma system mentioned earlier [23], both protease and extracellular matrix remodelling have been found to facilitate collective invasion, though an increase in the invasion of the highly metastatic line was not reported (i.e., the interaction was not synergistic).
Interestingly, this type of inter-clonal synergistic cooperation has also been reported in the social amoeba Dictyostelium discoideum. Specifically, chimeric slugs of D. discoideum migrate farther than monoclonal slugs containing the same number of their own cells present in the mixed group (i.e., 50%), indicating that the advantages of size (i.e., increased migration potential and likelihood to reach a new food patch; [47]) resulting from “pooling” cells of different clones can drive cooperation (chimeric synergy) among unrelated clones [48]. Moreover, different species of Dictyostelium can also cooperate to form chimeric larger fruiting bodies, which are thought to be advantageous for overall dispersal [49].
Co-option of autocrine signalling can facilitate cooperative interactions among genetically distant clones
Based on our findings, we propose a model (Fig. 8) whereby highly metastatic clones can co-opt (through TGF-β1 signalling) weakly or non-metastatic clones into expressing increased metastatic features, which in turn will enhance the invasion ability of the former (through released proteases and/or extracellular matrix remodelling)—i.e., a “help me help you” strategy, and ultimately result in an increase in the overall invasion potential of the tumour. Our finding that the conditioned medium from a lung cancer cell line can enhance the metastatic potential of a breast cancer line (and vice versa) indicate that this type of co-option of autocrine TGF-β1 signalling into paracrine signalling can involve genetically and phenotypically distinct clones and can take place in many types of cancer.
Overall, we argue that crosstalk involving metastatic clones able to constitutively secrete signalling molecules that induce and maintain their own malignant state (producer-responder clones) and clones that express the cognate receptors to those ligands and are able to switch to a malignant phenotype (responder clones) can provide the basis for the emergence of synergistic cooperative interactions within a tumour (Fig. 9). Specifically, in a heterogeneous tumour, responder/receptor positive clones will benefit from the presence of producer-responder clones and increase their representation (through increased migration and invasion) in the nearby tissue relative to non-responder/receptor negative clones. Similarly, producer-responder clones that are found in the presence of responder clones will gain an invasion advantage relative to solitary producer-responder clones of the same size.
In this scenario, a trait (i.e., autocrine signalling) that increases individual fitness (in terms of invasion potential) in a solitary context can be co-opted into a cooperative trait if, when expressed in a heterogeneous group context, it can also increase the fitness of group members that do not express the signal but can respond to it in a similar manner (Fig. 9). If the response also benefits the producer clone, this interaction can be stable in the absence of relatedness (i.e., kin selection is not required as both clones gain direct benefits). In conditions in which the ability to invade nearby tissue provides a strong fitness advantage (as when tumour microenvironments deteriorate), such interactions can be favoured and can determine the composition of the invading population.
This is especially relevant if producer-responders are at low frequency as their invasion potential will be increased in a mixed population relative to a solitary clone of the same size (Fig. 9). Also, in later stages, such a mixed population might be favoured over a monoclonal producer-responder population as at high cell density, the increased levels of released TGF-β1 inhibit proliferation [50]. However, due to diffusion gradients and limits, these interactions will likely be dependent on cell numbers and density and be restricted to parts of the tumours, and thus could result in the coexistence of patches of cooperative and non-cooperative clones [51, 52]. Notably, basal and luminal cell clones are known to co-exist in mammary tumours (see [9, 10] and references therein).
This specific heterogeneity is also likely to affect invasion dynamics and the release of circulating tumour cell (CTC) clusters (i.e., from areas where both responder and producer-responder clones co-exist). Furthermore, the presence of both clones will reflect in the composition of CTC clusters (which are known to contain a mixture of mesenchymal and epithelial cells [53, 54]) and can also be beneficial in the subsequent steps during the metastatic process, especially the invasion and colonization of new tissues.
Although we focused on TGF-β1, the principles proposed here could apply to other signalling pathways. We suggest that such synergistic inter-clonal cooperative interactions can easily emerge between any producer-responder and responder clones that express the same cognate ligand-receptor system, regardless of the degree of overall genetic/genealogical relatedness. This model allows genetically distant clones to engage in cooperative interactions that are not initiated around public goods or exchange of products (as in most other previously proposed types of cooperation in cancer; e.g., [5]).
Furthermore, in contrast to other forms of cooperation, this cooperative system is less sensitive to inter-clonal cheating, because of the co-dependent nature of the benefit (i.e., “help me help you”). In addition, because the ability to respond to TGF-β1 provides both a cooperative benefit (e.g., shared proteases or remodelling of the tumour microenvironment) as well as a personal benefit (i.e., migration in response to TGF-β1), cheating (i.e., loss of migration by not responding to TGF-β1) can be costly; and this personal cost can stabilize the cooperative interaction, as shown in other cooperative systems [54, 55]. Lastly, although nearby non-responder clones or intra-clone cheaters could, in theory, passively benefit from this type of cooperation (if the outcome of the interaction involves the remodelling of the tumour microenvironment which could facilitate passive invasion of non-responders; [54, 55]), our data (Fig. 7b) suggest that they would still be outcompeted by the responder clones and the cooperative system will be maintained.
Clinical implications, limitations and future research
This study underscores the importance of deciphering the nature and mechanistic basis of inter-clonal cooperative interactions that could take place during cancer progression. This is particularly relevant to metastasis—for which treatment options are limited, despite the fact that it is responsible for most cancer-related deaths [56]. Identifying the main players and signalling pathways involved in inter-clonal crosstalk during the early stages of metastasis can help develop new strategies and targets to slow down the metastatic process. One advantage of strategies targeting inter-clonal cooperation is that they would negatively affect all clones involved in a specific type of cooperative interaction, regardless of their overall genetic make-up. In this context, Metformin—a drug used to treat type 2 diabetes, could be effective in tumours producing and responding to TGF-β1 as it can inhibit both TGF-β1’s production and the response to TGF-β1 as well as inactivate the TGF-β1 itself (e.g., [57,58,59]).
However, as for all in vitro studies, these findings require in vivo validation. This is especially important as many signaling pathways potentially involved in inter-clonal cooperation in cancer are also associated with normal developmental and physiological processes. Therefore, these approaches should be used in conjunction with other strategies that can take advantage of specific metabolic aspects of cancer cells (e.g., sensitivity to starvation; e.g., [60] or the tumour microenvironment (e.g., hypoxia). Nevertheless, taking into account the negative impact that metastasis has on cancer prognosis and the lack of therapies that directly affect this process, interfering with the specific cooperative behaviours that tumour cells engage in should provide an additional approach to increase patient survival.
Methods
Cell lines and culturing conditions
The two human breast cancer cell lines used in this study, MCF7 and MDA-MB-231, were obtained from ATCC (www.atcc.org). An adherent non-small cell lung cancer line (H2122 AS) was derived from a line that grows as a mixture of adherent and suspension cells (NCI-H2122; ATCC) through selective passages of the adherent population [61]. All cell lines were grown in low/physiological glucose levels (5.5 mM; to simulate physiological glucose levels) Dulbecco’s Modified Eagle Medium (Gibco) supplemented with 10% fetal bovine serum (FBS; ATCC) and 1% Penicillin/Streptomycin (Gibco) at 37 °C with 5% CO2. Cells were passaged by enzymatic dissociation with 0.05% trypsin-EDTA (Gibco) when 80% confluence was reached.
Conditioned media
To collect the conditioned media (CM), cells were grown in 5.5 mM glucose DMEM with 10% FBS until the monolayer reached around 90% confluence. Cells were then washed with PBS and maintained in DMEM with low FBS (1%) for 24 h (low FBS reduces the level of proteins and growth factors present in the conditioned medium). The collected conditioned medium was centrifuged at 1000×g for 10 min, and the supernatant was passed through a 0.2 μm syringe filter and stored at − 20 °C. To test the effect of CM, cells were incubated for up to 72 h with 25% CM (diluted in regular media); the CM was refreshed daily.
For some experiments, the conditioned media was also filtered using Amicon® Ultra Centrifugal Filter Units (Millipore) with different cut-offs (100 kDa, 30 kDa, and 10 kDa) according to the manufacturer’s instructions. The fractions were tested for their ability to induce migration.
Reagents
Human Recombinant TGF-β1 (R&D systems; at 10 ng/ml final concentration) was used as a positive control. A TGF-β receptor I inhibitor (SB431542; EMD Millipore; 10 µM final concentration) and antibodies against TGF-β1, 2, 3 (1D11; R&D systems; at 2 µg/ml final concentration) were used to block the response to TGF-β1 and the TGF-β1 itself, respectively.
Fluorescence staining and microscopy
For co-culture experiments, cells were stained with either DiO or DiD (Invitrogen™ Vybrant™) following the manufacturer’s instructions. The stained cells were co-cultured for 72 h and fixed with 2% paraformaldehyde. Slides were photographed at 20✕ magnification using a LEICA DM R (Epi-Fluorescence Microscope) with FITC and TRICT filters.
Wound healing assays
To assess migration, we performed wound healing assays. Gaps within cell monolayers were achieved using cross-shaped inserts (Ibidi; www.ibidi.com). Cells were seeded at 105 cells/cm2 in DMEM with 1% FBS (low levels of FBS inhibit cell proliferation during migration assays) and were allowed to adhere overnight. After the inserts were lifted, wells were washed with PBS, and fresh medium was added. The cells were allowed to migrate and fill in the gap while the medium was refreshed daily. For co-culture assays, each cell line was seeded in a separate insert in the same well. Once cells were attached, the inserts were removed, and DMEM with 1% FBS was added. The plates were placed on a shaker (45 rpm) to ensure the diffusion and mixing of the medium. Random fields of the gap were imaged every 24 h. At the end of the assay, when cells occupied around 80% of the gap (24 h for MDA, 48 h for H2122 AS, and 48 to 72 h for MCF7), the cell layers were fixed with 70% ethanol and stained with 0.2% crystal violet (as previous described in [25] and [26]). Gap width was measured using the Wound Healing Tool implemented in Fiji Image J. The % of the area that was occupied (Af) relative to the area at the start of the assay (Ai) was calculated (\(\% occupied area=(Ai-Af)/\left(Ai\text{*}100\right)\)).
Transwell assays
Migration and invasion were also assayed using transwell inserts (Corning). 105 cells were seeded in the inserts and placed in wells with media containing a chemoattractant (i.e., DMEM with 10% FBS). Cells were allowed to migrate through the 8 μm porous membrane towards the chemoattractant. After 48 h, cells that migrated to the underside of the insert were fixed with 70% ethanol and stained with 0.2% crystal violet (as previous described in [25] and [26]). Five random fields of view from the stained insert were photographed using brightfield microscopy at 10x magnification. Cells attached to the underside of the insert were counted for each field of view and averaged. The same protocol was followed to assess invasive abilities. Cells were placed onto inserts containing a layer of 1 mg/ml Matrigel (Corning), and the number of cells that invaded was assessed after 72 h. In the co-culture experiments, one cell line (MCF7) was pre-labelled with DiO or DiD, and the other (MDA) was unstained. At the end of the assay, the cells were fixed with 2% paraformaldehyde. As above, the number of invaded fluorescent cells was assessed, and all invaded cells were stained with crystal violet. The number of MDA cells that invaded was calculated by subtracting the number of invaded MCF7 cells (i.e., fluorescent) from the total number of invaded cells (stained with crystal violet).
Statistical analyses
Each experiment included triplicate controls and treatments, and was performed several times independently. Data were expressed as mean ± SEM of the triplicates within one experiment. Unpaired, two-tailed Student’s t-tests or one-way ANOVA with Sidak’s test for multiple comparisons were performed to assess the statistical significance of the relevant comparisons. Data analysis was performed using Prism GraphPad 8; p ≤ 0.05 was considered statistically significant.
Data availability
The datasets generated and/or analysed during the current study are available in the Zenodo repository, https://zenodo.org/record/7504499#.Y7XWfdWZOUk.
References
Sung H, Ferlay J, Siegel RL, Laversanne M, Soerjomataram I, Jemal A, Bray F. Global cancer statistics 2020: GLOBOCAN estimates of incidence and mortality worldwide for 36 cancers in 185 countries. CA Cancer J Clin. 2021;71:209–49.
Marusyk A, Polyak K. Tumor heterogeneity: causes and consequences. Biochim Biophys Acta. 2010;1805:105–17.
Marusyk A, Almendro V, Polyak K. Intra-tumour heterogeneity: a looking glass for cancer? Nat Rev Cancer. 2012;12:323–34.
Nowell PC. Linked references are available on JSTOR for this article: the clonal evolution of tumor cell populations. Science. 1976;80–:23–8.
Axelrod R, Axelrod DE, Pienta KJ. Evolution of cooperation among tumor cells. Proc Natl Acad Sci USA. 2006;103:13474–9.
Zhou H, Neelakantan D, Ford HL. Clonal cooperativity in heterogenous cancers. Semin Cell Dev Biol. 2017;64:79–89.
Hobor S, Van Emburgh BO, Crowley E, Misale S, Di Nicolantonio F, Bardelli A. TGFα and amphiregulin paracrine network promotes resistance to EGFR blockade in colorectal cancer cells. Clin Cancer Res. 2014;20:6429–38.
Osswald M, Jung E, Sahm F, et al. Brain tumour cells interconnect to a functional and resistant network. Nature. 2015;528:93–8.
Inda MDM, Bonavia R, Mukasa A, et al. Tumor heterogeneity is an active process maintained by a mutant EGFR-induced cytokine circuit in glioblastoma. Genes Dev. 2010;24:1731–45.
Cleary AS, Leonard TL, Gestl SA, Gunther EJ. Tumour cell heterogeneity maintained by cooperating subclones in Wnt-driven mammary cancers. Nature. 2014;508:113–7.
Yang Y, Zheng H, Zhan Y, Fan S. An emerging tumor invasion mechanism about the collective cell migration. Am J Transl Res. 2019;11:5301–12.
West SA, Griffin AS, Gardner A. Social semantics: altruism, cooperation, mutualism, strong reciprocity and group selection. J Evol Biol. 2007;20:415–32.
Yeung KT, Yang J. Epithelial–mesenchymal transition in tumor metastasis. Mol Oncol. 2017;11:28–39.
Hao S, Ye Z, Li F, Meng Q, Qureshi M, Yang J, Xiang J. Epigenetic transfer of metastatic activity by uptake of highly metastatic B16 melanoma cell-released exosomes. Exp Oncol. 2006;28:126–31.
Camerlingo R, Miceli R, Marra L, et al. Conditioned medium of primary lung cancer cells induces EMT in A549 lung cancer cell line by TGF-ß1 and miRNA21 cooperation. PLoS ONE. 2019;14:1–17.
Kwon MC, Proost N, Song JY, Sutherland KD, Zevenhoven J, Berns A. Paracrine signaling between tumor subclones of mouse SCLC: a critical role of ETS transcription factor Pea3 in facilitating metastasis. Genes Dev. 2015;29:1587–92.
Le MTN, Hamar P, Guo C, Basar E, Perdigão-Henriques R, Balaj L, Lieberman J. MiR-200-containing extracellular vesicles promote breast cancer cell metastasis. J Clin Invest. 2014;124:5109–28.
Neelakantan D, Zhou H, Oliphant MUJ, et al. EMT cells increase breast cancer metastasis via paracrine GLI activation in neighbouring tumour cells. Nat Commun. 2017. https://doi.org/10.1038/ncomms15773.
Mateo F, Meca-Cortés Ó, Celià-Terrassa T, et al. SPARC mediates metastatic cooperation between CSC and non-CSC prostate cancer cell subpopulations. Mol Cancer. 2014;13:1–17.
Perrin L, Belova E, Bayarmagnai B, Tüzel E. Gligorijevic B invadopodia enable cooperative invasion and metastasis of breast cancer cells. Commun Biol. 2023;26:1–14.
Tsuji T, Ibaragi S, Shima K, Hu MG, Katsurano M, Sasaki A, Hu G. Epithelial–mesenchymal transition induced by growth suppressor p12 CDK2-AP1 promotes tumor cell local invasion but suppresses distant colony growth. Cancer Res. 2008;11:10377–86.
Tsuji T, Ibaragi S, Shima K, Hu MG, Katsurano M, Sasaki A, Hu GF. Epithelial-mesenchymal transition induced by growth suppressor p12 CDK2-AP1 promotes tumor cell local invasion but suppresses distant colony growth. Cancer Res. 2008;68:10377–86.
Chapman A, del Ama LF, Ferguson J, Kamarashev J, Wellbrock C, Hurlstone A. Heterogeneous tumor subpopulations cooperate to drive invasion. Cell Rep. 2014;8:688–95.
Kim BN, Ahn DH, Kang N, et al. TGF-β induced EMT and stemness characteristics are associated with epigenetic regulation in lung cancer. Sci Rep. 2020;10:1–11.
Ho MH, Liao MH, Lin YL, Lai CH, Lin PI, Chen RM. Improving effects of chitosan nanofiber scaffolds on osteoblast proliferation and maturation. Int J Nanomedicine. 2014;9:4293–304.
Cruz ALS, Carrossini N, Teixeira LK, Ribeiro-Pinto LF, Bozza PT, Viola JPB. Cell cycle progression regulates Biogenesis and Cellular localization of lipid droplets. Mol Cell Biol. 2019. https://doi.org/10.1128/mcb.00374-18.
Ren J, Smid M, Iaria J, Salvatori DCF, Dam H, Van, Zhu HJ, Martens JWM, Dijke P. Gremlin 1 promotes breast cancer progression. Breast Cancer Res. 2019;21:1–19.
Liu J, Liao S, Diop-Frimpong B, Chen W, Goel S, Naxerova K, Ancukiewicz M, Boucher Y, Jain RK, Xu L. TGF-β blockade improves the distribution and efficacy of therapeutics in breast carcinoma by normalizing the tumor stroma. Proc Natl Acad Sci USA. 2012;109:16618–23.
Baillie R, Coombes RC, Smith J. Multiple forms of TGF-β1 in breast tissue: a biologically active form of the small latent complex of TGF-β1. Eur J Cancer Part A. 1996;32:1566–73.
Bonewald LF, Wakefield L, Oreffo ROC, Escobedo A, Twardzik DR, Mundy GR. Latent forms of transforming growth factor-β (TGFβ) derived from bone cultures: identification of a naturally occurring 100-kDa complex with similarity to recombinant latent TGFβ. Mol Endocrinol. 1991;5:741–51.
Lyons RM, Keski-Oja J, Moses HL. Proteolytic activation of latent transforming growth factor-β from fibroblast-conditioned medium. J Cell Biol. 1988;106:1659–65.
Ziegler YS, Moresco JJ, Yates JR, Nardulli AM. Integration of breast cancer secretomes with clinical data elucidates potential serum markers for disease detection, diagnosis, and prognosis. PLoS ONE. 2016;11:1–24.
Jiang S, Zhang M, Zhang Y, et al. WNT5B governs the phenotype of basal-like breast cancer by activating WNT signaling. Cell Commun Signal. 2019;17:1–19.
Martínez-Carpio PA, Mur C, Fernández-Montolí ME, Ramon JM, Rosel P, Navarro MA. Secretion and dual regulation between epidermal growth factor and transforming growth factor-β1 in MDA-MB-231 cell line in 42-hour-long cultures. Cancer Lett. 1999;147:25–9.
Daroqui MC, Vazquez P, Bal De Kier Joffé E, Bakin AV, Puricelli LI. TGF-β autocrine pathway and MAPK signaling promote cell invasiveness and in vivo mammary adenocarcinoma tumor progression. Oncol Rep. 2012;28:567–75.
Liu Z, Bandyopadhyay A, Nichols W R. Blockade of Autocrine TGF-β signaling inhibits stem cell phenotype, survival, and metastasis of murine breast Cancer cells. J Stem Cell Res Ther. 2012;02:1–8.
Shim KS, Kim KH, Han WS, Park EB. Elevated serum levels of transforming growth factor-β1 in patients with colorectal carcinoma: its association with tumor progression and its significant decrease after curative surgical resection. Cancer. 1999;85:554–61.
Wikström P, Stattin P, Franck-Lissbrant I, Damber JE, Bergh A. Transforming growth factor β1 is associated with angiogenesis, metastasis, and poor clinical outcome in prostate cancer. Prostate. 1998;37:19–29.
Sheen-Chen SM, Chen HS, Sheen CW, Eng HL, Chen WJ. Serum levels of transforming growth factor β1 in patients with breast cancer. Arch Surg. 2001;136:937–40.
Liu S, Chen S, Zeng J. TGF-β signaling: a complex role in tumorigenesis (review). Mol Med Rep. 2018;17:699–704.
Espinoza-Sánchez NA, Vadillo E, Balandrán JC, Monroy-García A, Pelayo R, Fuentes-Pananá EM. Evidence of lateral transmission of aggressive features between different types of breast cancer cells. Int J Oncol. 2017;51:1482–96.
Mahdi SHA, Cheng H, Li J, Feng R. The effect of TGF-beta-induced epithelial-mesenchymal transition on the expression of intracellular calcium-handling proteins in T47D and MCF-7 human breast cancer cells. Arch Biochem Biophys. 2015;583:18–26.
Wang L, Xu C, Liu X, et al. TGF-β1 stimulates epithelial-mesenchymal transition and cancer-associated myoepithelial cell during the progression from in situ to invasive breast cancer. Cancer Cell Int. 2019;19:1–13.
Wang Y, Lui WY. Transforming growth factor-β1 attenuates junctional adhesion molecule-A and contributes to breast cancer cell invasion. Eur J Cancer. 2012;48:3475–87.
Martín-Pardillos A, Valls Chiva Á, Bande Vargas G, et al. The role of clonal communication and heterogeneity in breast cancer. BMC Cancer. 2019;19:1–26.
Lyons JG, Siew K, O’Grady RL. Cellular interactions determining the production of collagenase by a rat mammary carcinoma cell line. Int J Cancer. 1989;43:119–25.
Kuzdzal-Fick JJ, Foster KR, Queller DC, Strassmann JE. Exploiting new terrain: an advantage to sociality in the slime mold Dictyostelium discoideum. Behav Ecol. 2007;18:433–7.
Foster KR, Fortunato A, Strassmann JE, Queller DC. The costs and benefits of being a chimera. Proc R Soc B Biol Sci. 2002;269:2357–62.
Jack CN, Ridgeway JG, Mehdiabadi NJ, Jones EI, Edwards TA, Queller DC, Strassmann JE. Segregate or cooperate- a study of the interaction between two species of Dictyostelium. BMC Evol Biol. 2008;8:1–10.
Li J, Ballim D, Rodriguez M, Cui R, Goding CR, Teng H, Prince S. The anti-proliferative function of the tgf-β1 signaling pathway involves the repression of the oncogenic tbx2 by its homologue tbx3. J Biol Chem. 2014;289:35633–43.
Youk H, Lim WA. Secreting and sensing the same molecule allows cells to achieve versatile social behaviors. Science. 2014;11:80. https://doi.org/10.1126/science.1242782.
Archetti M, Ferraro DA, Christofori G. Heterogeneity for IGF-II production maintained by public goods dynamics in neuroendocrine pancreatic cancer. Proc Natl Acad Sci USA. 2015;112:1833–8.
Hou JM, Krebs M, Ward T, Sloane R, Priest L, Hughes A, Clack G, Ranson M, Blackhall F, Dive C. Circulating tumor cells as a window on metastasis biology in lung cancer. Am J Pathol. 2011;178:989–96.
Cameron-Pack ME, König SG, Reyes-Guevara A, Reyes-Prieto A, Nedelcu AM. A personal cost of cheating can stabilize reproductive altruism during the early evolution of clonal multicellularity. Biol Lett. 2022;18:20220059.
Foster KR, Shaulsky G, Strassmann JE, Queller DC, Thompson CRL. Pleiotropy as a mechanism to stabilize cooperation. Nature. 2004;431:693–6.
Mehlen P, Puisieux A. Metastasis: a question of life or death. Nat Rev Cancer. 2006;6:449–58.
Xiao H, Zhang J, Xu Z, et al. Metformin is a novel suppressor for transforming growth factor (TGF)-β1. Sci Rep. 2016;6:1–9
Li NS, Zou JR, Lin H, Ke R, He XL, Xiao L, Huang D, Luo L, Lv N, Luo Z. LKB1/AMPK inhibits TGF-β1 production and the TGF-β signaling pathway in breast cancer cells. Tumor Biol. 2016;37:8249–58.
Juban G, Saclier M, Yacoub-Youssef H, et al. AMPK Activation regulates LTBP4-Dependent TGF-β1 secretion by pro-inflammatory macrophages and controls fibrosis in Duchenne muscular dystrophy. Cell Rep. 2018;25:2163–2176e6.
Raffaghello L, Lee C, Safdie FM, Wei M, Madia F, Bianchi G, Longo VD. Starvation-dependent differential stress resistance protects normal but not cancer cells against high-dose chemotherapy. Proc Natl Acad Sci USA. 2008;105:8215–20.
Jong ED, Chan ICW, Nedelcu AM. A model-system to address the impact of phenotypic heterogeneity and plasticity on the development of cancer therapies. Front Oncol. 2019;9:1–8.
Acknowledgements
Not applicable.
Funding
CSC and JDH were supported by funds from the New Brunswick Innovation Foundation and the University of New Brunswick. Funds from the University of New Brunswick Research Fund are also acknowledged.
Author information
Authors and Affiliations
Contributions
CSC designed and performed experiments, analyzed data, wrote the manuscript.JDH contributed to experiments, data analysis and manuscript preparation. AMN contributed to project and experimental design, data interpretation and manuscript preparation. All authors read and approved the final manuscript.
Corresponding author
Ethics declarations
Ethics approval and consent to participate
Not applicable.
Consent for publication
Not applicable.
Competing interests
The authors declare no competing interests.
Additional information
Publisher’s Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/. The Creative Commons Public Domain Dedication waiver (http://creativecommons.org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated in a credit line to the data.
About this article
Cite this article
Carneiro, C.S., Hapeman, J.D. & Nedelcu, A.M. Synergistic inter-clonal cooperation involving crosstalk, co-option and co-dependency can enhance the invasiveness of genetically distant cancer clones. BMC Ecol Evo 23, 20 (2023). https://doi.org/10.1186/s12862-023-02129-7
Received:
Accepted:
Published:
DOI: https://doi.org/10.1186/s12862-023-02129-7