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Commentary Free access | 10.1172/JCI39457
1Department of Cancer Genetics, British Columbia Cancer Research Centre, and British Columbia Cancer Agency, Vancouver, British Columbia, Canada. 2Department of Biochemistry and Molecular Biology, University of British Columbia, Vancouver, British Columbia, Canada. 3Department of Cellular and Structural Biology and Department of Pediatrics, Greehey Children’s Cancer Research Institute, University of Texas Health Science Center, San Antonio, Texas, USA.
Address correspondence to: Charles Keller, University of Texas Health Science Center at San Antonio, 8403 Floyd Curl Drive, MC-7784, San Antonio, Texas 78229-3900, USA. Phone: (210) 562-9062; Fax: (210) 562-9014; E-mail: kellerc2@uthscsa.edu.
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1Department of Cancer Genetics, British Columbia Cancer Research Centre, and British Columbia Cancer Agency, Vancouver, British Columbia, Canada. 2Department of Biochemistry and Molecular Biology, University of British Columbia, Vancouver, British Columbia, Canada. 3Department of Cellular and Structural Biology and Department of Pediatrics, Greehey Children’s Cancer Research Institute, University of Texas Health Science Center, San Antonio, Texas, USA.
Address correspondence to: Charles Keller, University of Texas Health Science Center at San Antonio, 8403 Floyd Curl Drive, MC-7784, San Antonio, Texas 78229-3900, USA. Phone: (210) 562-9062; Fax: (210) 562-9014; E-mail: kellerc2@uthscsa.edu.
Find articles by Dedhar, S. in: JCI | PubMed | Google Scholar
1Department of Cancer Genetics, British Columbia Cancer Research Centre, and British Columbia Cancer Agency, Vancouver, British Columbia, Canada. 2Department of Biochemistry and Molecular Biology, University of British Columbia, Vancouver, British Columbia, Canada. 3Department of Cellular and Structural Biology and Department of Pediatrics, Greehey Children’s Cancer Research Institute, University of Texas Health Science Center, San Antonio, Texas, USA.
Address correspondence to: Charles Keller, University of Texas Health Science Center at San Antonio, 8403 Floyd Curl Drive, MC-7784, San Antonio, Texas 78229-3900, USA. Phone: (210) 562-9062; Fax: (210) 562-9014; E-mail: kellerc2@uthscsa.edu.
Find articles by Keller, C. in: JCI | PubMed | Google Scholar
Published May 26, 2009 - More info
Although most reports describe the protein kinase integrin-linked kinase (ILK) as a proto-oncogene, occasional studies detail opposing functions in the regulation of normal and transformed cell proliferation, differentiation, and apoptosis. Here, we demonstrated that ILK functions as an oncogene in the highly aggressive pediatric sarcoma alveolar rhabdomyosarcoma (ARMS) and as a tumor suppressor in the related embryonal rhabdomyosarcoma (ERMS). These opposing functions hinge on signaling through a noncanonical ILK target, JNK1, to the proto-oncogene c-Jun. RNAi-mediated depletion of ILK induced activation of JNK and its target, c-Jun, resulting in growth of ERMS cells, whereas in ARMS cells, it led to loss of JNK/c-Jun signaling and suppression of growth both in vitro and in vivo. Ectopic expression of the fusion gene characteristic of ARMS (paired box 3–forkhead homolog in rhabdomyosarcoma [PAX3-FKHR]) in ERMS cells was sufficient to convert them to an ARMS signaling phenotype and render ILK activity oncogenic. Furthermore, restoration of JNK1 in ARMS reestablished a tumor-suppressive function for ILK. These findings indicate what we believe to be a novel effector pathway regulated by ILK, provide a mechanism for interconversion of oncogenic and tumor-suppressor functions of a single regulatory protein based on the genetic background of the tumor cells, and suggest a rationale for tailored therapy of rhabdomyosarcoma based on the different activities of ILK.
Adam D. Durbin, Gino R. Somers, Michael Forrester, Malgorzata Pienkowska, Gregory E. Hannigan, David Malkin
Although the molecular differences between embryonal rhabdomyosarcoma (ERMS) and alveolar rhabdomyosarcoma (ARMS) have been extensively interrogated, effective therapies tailored to a particular rhabdomyosarcoma subtype have yet to emerge. Patients with ERMS have shown incremental improvement using current multimodal therapy, but survival rates for metastatic ARMS remain poor. In this issue of the JCI, Durbin and colleagues demonstrate that integrin-linked kinase (ILK) acts as a tumor suppressor in ERMS and as a proto-oncogene in ARMS, and that the opposing functions of this enzyme are dependent on the JNK1 signaling pathway (see the related article beginning on page 1558). Their findings suggest that targeting ILK may represent a focused therapeutic strategy for the treatment of ARMS.
Rhabdomyosarcoma (RMS) is an aggressive muscle cancer and the most common soft-tissue sarcoma of childhood (1). A great paradox lies in the fact that 2 forms of RMS have remarkably different potentials for cure. Wherein embryonal RMS (ERMS) accounts for more than half of RMS cases, the long-term survival for the metastatic form of this disease exceeds 40% (2). On the other hand, alveolar RMS (ARMS) accounts for one-quarter of RMS cases, but the cure rate for its metastatic form is 20% or less (2, 3). Although the Intergroup Rhabdomyosarcoma Study Group (IRSG) takes histological subtype into account in risk stratification, there is no substantial differentiation between the 2 subtypes with respect to the therapeutic approach, which consists of surgery, chemotherapy, and radiation (4). Despite encouragement that the outcome for ERMS appears to be improving incrementally since the inception of multimodality therapy, the long-term survival for metastatic ARMS has been dismal and largely unchanged for decades (3, 5).
Integrin-linked kinase (ILK) is well recognized as an oncogenic protein and is highly expressed in numerous human cancers, including melanoma, lung, head and neck, pancreas, and prostate cancers (6, 7). Importantly, the degree of ILK expression correlates with tumor stage and grade in many of these malignancies, and strong ILK expression is often a poor prognostic indicator (8, 9). Previous work has defined ILK as a key regulator of cellular events critical to cancer progression, including proliferation, survival, adhesion, migration, invasion, and angiogenesis (6, 7). The inhibition of ILK expression and/or activity using genetic and pharmacologic strategies has established the requirement of ILK for tumor growth. The necessity of ILK for cancer progression, particularly in carcinomas, has centered on the capacity of ILK to phosphorylate and regulate downstream signaling targets of the PI3K pathway, notably Akt and glycogen synthase kinase–3β (6, 7). ILK functionality is dependent on cellular context, however, and ILK is reported to suppress growth in certain circumstances (6).
In this issue of the JCI, Durbin et al. (10) present one set of fundamental biological differences between ERMS and ARMS: the levels of ILK, JNK1, and the phosphorylated JNK1 protein. The authors used a series of model systems, including cultured human cells, murine xenografts, and primary human tumors, to demonstrate that ILK functions as a tumor suppressor in ERMS, whereas it acts as an oncogene in ARMS. In contrast to many cancer models, Akt or MAPK signaling remained unaffected by inhibition of ILK, and the opposing functions of ILK in these tumors were attributed to the presence of a noncanonical target of ILK, JNK1 (Figure 1). This work is intriguing because it attempts to provide a mechanistic basis for the oncogenic versus tumor-suppressive functions attributed to ILK. In their report, Durbin et al. focus on JNK1 as a mediator of proliferation (10) — yet much of the literature highlights the role of JNK as a proapoptotic factor that stabilizes p53 or promotes apoptosis by c-Jun–mediated transcription of proapoptotic genes (11). What biology underlies the difference in JNK activity in these 2 subtypes of RMS? An intriguing possibility may lie in the ratio between ILK and JNK, wherein low JNK levels result in c-Jun–mediated survival and proliferation, but high and sustained JNK (and c-Jun) levels lead to apoptosis.
Differential regulation of JNK by ILK in ARMS versus ERMS. Shown are potential mechanisms of cell growth regulation in ARMS versus ERMS tumor cells related to signaling through ILK, JNK1, and c-Jun. ILK functions are regulated through signals initiated by ECM-integrin interactions or growth factor (GF) stimulation (6). In more clinically favorable cases of ERMS, Durbin et al. (10) demonstrate, in their study in this issue of the JCI, that ILK suppresses phosphorylation of JNK1 and c-Jun, thereby preventing accelerated cell proliferation. While the exact mechanism remains to be shown, the repression of JNK phosphorylation by ILK in this tumor subtype may occur through additional intermediates, including a complex of ILK-associated serine/threonine phosphatase 2C (ILKAP) with apoptosis signal–regulating kinase 1 (ASK1). In ARMS, JNK1 levels are diminished by the PAX3-FKHR oncoprotein, thereby leaving other pathways open to modulating or inducing c-Jun phosphorylation and accelerating cell proliferation. In these tumors, the oncogenic effects of ILK may involve regulation of JNK1 phosphorylation, as suggested by Durbin et al., and/or ILK-induced activation of α-NAC. RTK, receptor tyrosine kinase.
Durbin et al. showed that for ERMS, ILK expression resulted in inhibition of JNK phosphorylation, possibly through one or more intermediate effectors (10). siRNA-mediated depletion of ILK reversed the suppression of JNK phosphorylation and led to phosphorylation of c-Jun. Phospho–c-Jun, as a presumed component of a heterodimeric activator protein 1 (AP-1) complex, regulates cell proliferation. Consistent with the role of ILK as a tumor suppressor in ERMS, the authors report that ILK expression in primary tumor samples from patients with invasive and metastatic ERMS in unfavorable anatomical locations (i.e., stage III or IV at diagnosis) was significantly reduced compared with less invasive or less metastatic ERMS in more favorable anatomical locations (i.e., stage I or II at diagnosis). ILK expression was also positively associated with survival for ERMS patients at all disease stages at diagnosis. Durbin et al. point out that chromosomal locus 11p15 is a frequent site of loss of imprinting/loss of heterozygosity in ERMS, and this region also contains the ILK gene (10). In ERMS, p53 loss of function is also not uncommon — indeed, familial p53 haploinsufficiency, or Li-Fraumeni syndrome, was a description of familial ERMS (12). Therefore, could loss of the ILK locus for high-stage ERMS lead to increased levels of phospho-JNK, and could concurrent p53 loss result in phospho-JNK–mediated c-Jun phosphorylation and proliferation, instead of phospho-JNK/p53–mediated apoptosis? This speculative scenario is one possible way to integrate the present findings into the genetics defined to date for ERMS.
In contrast to their results for ERMS, Durbin et al. show in mouse xenografts that ILK functioned as an oncogene in ARMS and that ILK inhibition slowed tumor growth (10). Previous work has shown that 55% or more of ARMS patients harbor a translocation-mediated chimeric oncogene resulting from the fusion of paired box 3 (PAX3) to forkhead homolog in rhabdomyosarcoma (FKHR, also known as FOXO1A; ref. 13). Introduction of the PAX3-FKHR chimeric transcription factor into ERMS cells resulted in decreased JNK1B1 transcript levels. In these PAX3-FKHR–expressing ERMS cells, siRNA-mediated suppression of ILK expression resulted in decreased tumor cell growth in vitro, similar to the behavior of ARMS cells when ILK was experimentally depleted (10). The authors further showed that restoration of JNK1 protein in ARMS led to a situation more like ERMS, in which decreased ILK expression led to increased tumor cell growth. It may be that ARMS cells escape phospho-JNK/p53–mediated apoptosis in this situation because p53 loss of function is also not uncommon in ARMS (14). Thus, JNK1 protein levels appear to be at the crux of whether ILK acts as a tumor suppressor in ERMS or as an oncogene in ARMS (Figure 1).
There is perhaps a common biological thread connecting human ERMS and ARMS tumors. In the studies by Durbin and colleagues (10), both ERMS cells with experimentally decreased levels of ILK (i.e., diminished tumor suppression) and ARMS cells with native levels of oncogenic ILK exhibited elevated levels of phospho–c-Jun. In their work, a dominant-negative c-Jun mutant suppressed tumor cell growth in the former instance (10), and might be assumed to do the same in the latter, which suggests that phospho–c-Jun is helping to drive tumor growth in ARMS and clinical stage III/IV ERMS. Paradoxically, sustained and very elevated levels of c-Jun, as seen in response to the immunosuppressant/mammalian target of rapamycin inhibitor rapamycin, leads to c-Jun–mediated apoptosis when p53 is absent (15). Therefore, phospho–c-Jun, as a component of an AP-1 complex, may act as a proliferative factor when present at levels below a particular threshold; however, high and sustained levels of phospho–c-Jun, as found during periods of cellular stress, can lead to apoptosis of cells. While it is beyond the scope of this commentary to address AP-1 signaling (reviewed in ref. 16), a closer examination of c-Jun heterodimerization partners (e.g., c-Fos and JunB) under conditions of stress in ERMS and ARMS may be warranted.
The study by Durbin et al. (10) raises a number of important questions that remain to be resolved. The authors provide compelling evidence of the Jekyll and Hyde nature of ILK: its tumor-suppressive function in ERMS and its oncogenic role in ARMS. A key issue, however, is the mechanism by which ILK targets JNK activity. How does ILK function to suppress JNK activation in ERMS, yet activate JNK in ARMS? Initial investigations did not demonstrate the presence of a direct interaction between ILK and JNK (10), leaving open the possibility that additional, as-yet-unidentified proteins are required for effective signaling between ILK and JNK. One potential mediator is ILK-associated serine/threonine phosphatase 2C, which is known to associate not only with ILK, but also with an upstream activator of JNK called apoptosis signal–regulating kinase 1 (Figure 1 and ref. 17). It is also possible that part of the effect of ILK on JNK and c-Jun is mediated by ILK-induced activation of the c-Jun transcriptional coactivator nascent polypeptide–associated complex and coactivator α (α-NAC; Figure 1). It has previously been shown that ILK phosphorylates α-NAC at serine 43, resulting in its nuclear accumulation and potentiation of c-Jun–mediated transcriptional regulation (18).
Durbin et al. used siRNA to transiently suppress ILK expression in the ERMS and ARMS cell lines prior to the inoculation of these cells into a xenograft model (10). Importantly, the cell lines were implanted 3 days after introduction of the siRNA into the cells, a time point at which ILK expression was effectively inhibited (10). However, the short-term depletion of target gene expression afforded by the use of siRNA, in contrast to the stable knockdown that can be achieved using shRNA technologies, leaves open to debate the precise role of ILK in tumor growth in this model. Certainly, depletion of ILK expression prior to introduction of the ERMS and ARMS cells into the mouse xenograft model resulted in striking and sustained effects on tumor growth, as well as on apoptosis and angiogenesis. However, ILK expression ultimately returned in both tumor groups, which suggests that ILK depletion may be critical as much for early tumor establishment as for signaling to the JNK pathway during growth. The use of shRNA to stably depress ILK levels and/or the use of inducible systems to provide native ILK expression during tumor establishment may help to further address this issue.
The data presented by Durbin et al. (10) suggest that prospective evaluation of the ILK/JNK1/c-Jun signaling axis may be worthwhile in the pursuit of molecular diagnostics for risk stratification of RMS patients at diagnosis. More importantly, these studies allude to what we believe to be a novel therapeutic strategy for the treatment of ARMS — the inhibition of the activity or expression of ILK. This can be accomplished with small-molecule ILK inhibitors that have been extensively characterized in preclinical models of several types of cancers (reviewed in refs. 6, 7). In addition, genetic strategies involving silencing ILK expression can also be considered, given the advances in shRNA and siRNA delivery strategies. However, the effects of ILK inhibitors would be untoward in ERMS. Given the high rate of misdiagnosis of ARMS versus ERMS (as high as 37%; refs. 4, 19) and the possibility that ILK signaling may be different under nascent versus stressed conditions such as chemotherapy, it may be well worth additional time in the laboratory to understand the basis of this intriguing difference in ILK behavior in RMS subtypes.
Conflict of interest: S. Dedhar is a Scientific Consultant for QLT Inc. C. Keller is a cofounder of Numira Biosciences Inc.
Nonstandard abbreviations used: AP-1, activator protein 1; ARMS, alveolar RMS; ERMS, embryonal RMS; FKHR, forkhead homolog in rhabdomyosarcoma; ILK, integrin-linked kinase; α-NAC, nascent polypeptide–associated complex and coactivator α; PAX3, paired box 3; RMS, rhabdomyosarcoma.
Reference information: J. Clin. Invest.119:1452–1455 (2009). doi:10.1172/JCI39457.
See the related article at JNK1 determines the oncogenic or tumor-suppressive activity of the integrin-linked kinase in human rhabdomyosarcoma.