Hypoxia-induced tumor cell autophagy mediates resistance to anti-angiogenic therapy

While anti-angiogenic therapy was initially greeted enthusiastically by the cancer community, initial successes with this therapeutic modality were tempered by the failure of angiogenesis inhibitors to produce sustained clinical responses in most patients, with resistance to the inhibitors frequently developing. We recently reported that hypoxia increases after the devascularization caused by anti-angiogenic therapy, consistent with the goals of these therapies, but that some tumor cells become resistant and survive the hypoxic insult elicited by anti-angiogenic therapy through autophagy by activating both AMPK and HIF1A pathways. These findings suggest that modulating the autophagy pathway may someday allow anti-angiogenic therapy to fulfill its therapeutic potential. However, further work will clearly be needed to develop more potent and specific autophagy inhibitors and to better understand the regulators of autophagy in malignant cells.     

The autophagic tumor stroma model of cancer or “battery-operated tumor growth”

The role of autophagy in tumorigenesis is controversial. Both autophagy inhibitors (chloroquine) and autophagy promoters (rapamycin) block tumorigenesis by unknown mechanism(s). This is called the “Autophagy Paradox”. We have recently reported a simple solution to this paradox. We demonstrated that epithelial cancer cells use oxidative stress to induce autophagy in the tumor microenvironment. As a consequence, the autophagic tumor stroma generates recycled nutrients that can then be used as chemical building blocks by anabolic epithelial cancer cells. This model results in a net energy transfer from the tumor stroma to epithelial cancer cells (an energy imbalance), thereby promoting tumor growth. This net energy transfer is both unilateral and vectorial, from the tumor stroma to the epithelial cancer cells, representing a true host-parasite relationship. We have termed this new paradigm “The Autophagic Tumor Stroma Model of Cancer Cell Metabolism” or “Battery-Operated Tumor Growth”. In this sense, autophagy in the tumor stroma serves as a “battery” to fuel tumor growth, progression, and metastasis, independently of angiogenesis. Using this model, the systemic induction of autophagy will prevent epithelial cancer cells from using recycled nutrients, while the systemic inhibiton of autophagy will prevent stromal cells from producing recycled nutrients—both effectively “starving” cancer cells. We discuss the idea that tumor cells could become resistant to the systemic induction of autophagy, by the up-regulation of natural endogenous autophagy inhibitors in cancer cells. Alternatively, tumor cells could also become resistant to the systemic induction of autophagy, by the genetic silencing/deletion of pro-autophagic molecules, such as Beclin1. If autophagy resistance develops in cancer cells, then the systemic inhibition of autophagy would provide a therapeutic solution to this type of drug resistance, as it would still target autophagy in the tumor stroma. As such, an anti-cancer therapy that combines the alternating use of both autophagy promoters and autophagy inhibitors would be expected to prevent the onset of drug resistance. We also discuss why anti-angiogenic therapy has been found to promote tumor recurrence, progression, and metastasis. More specifically, anti-angiogenic therapy would induce autophagy in the tumor stroma via the induction of stromal hypoxia, thereby converting a non-aggressive tumor type to a “lethal” aggressive tumor phenotype. Thus, uncoupling the metabolic parasitic relationship between cancer cells and an autophagic tumor stroma may hold great promise for anti-cancer therapy. Finally, we believe that autophagy in the tumor stroma is the local microscopic counterpart of systemic wasting (cancer-associated cachexia), which is associated with advanced and metastatic cancers. Cachexia in cancer patients is not due to decreased energy intake, but instead involves an increased basal metabolic rate and increased energy expenditures, resulting in a negative energy balance. Importantly, when tumors were surgically excised, this increased metabolic rate returned to normal levels. This view of cachexia, resulting in energy transfer to the tumor, is consistent with our hypothesis. So, cancer-associated cachexia may start locally as stromal autophagy, and then spread systemically. As such, stromal autophagy may be the requisite precursor of systemic cancer-associated cachexia.     

The autophagic tumor stroma model of cancer or “battery-operated tumor growth”: A simple solution to the autophagy paradox

The role of autophagy in tumorigenesis is controversial. Both autophagy inhibitors (chloroquine) and autophagy promoters (rapamycin) block tumorigenesis by unknown mechanism(s). This is called the “Autophagy Paradox.” We have recently reported a simple solution to this paradox. We demonstrated that epithelial cancer cells use oxidative stress to induce autophagy in the tumor microenvironment. As a consequence, the autophagic tumor stroma generates recycled nutrients that can then be used as chemical building blocks by anabolic epithelial cancer cells. This model results in a net energy transfer from the tumor stroma to epithelial cancer cells (an energy imbalance), thereby promoting tumor growth. This net energy transfer is both unilateral and vectorial, from the tumor stroma to the epithelial cancer cells, representing a true host-parasite relationship. We have termed this new paradigm “The Autophagic Tumor Stroma Model of Cancer Cell Metabolism” or “Battery-Operated Tumor Growth.” In this sense, autophagy in the tumor stroma serves as a “battery” to fuel tumor growth, progression and metastasis, independently of angiogenesis. Using this model, the systemic induction of autophagy will prevent epithelial cancer cells from using recycled nutrients, while the systemic inhibiton of autophagy will prevent stromal cells from producing recycled nutrients—both effectively “starving” cancer cells. We discuss the idea that tumor cells could become resistant to the systemic induction of autophagy by the upregulation of natural, endogenous autophagy inhibitors in cancer cells. Alternatively, tumor cells could also become resistant to the systemic induction of autophagy by the genetic silencing/deletion of pro-autophagic molecules, such as Beclin1. If autophagy resistance develops in cancer cells, then the systemic inhibition of autophagy would provide a therapeutic solution to this type of drug resistance, as it would still target autophagy in the tumor stroma. As such, an anti-cancer therapy that combines the alternating use of both autophagy promoters and autophagy inhibitors would be expected to prevent the onset of drug resistance. We also discuss why anti-angiogenic therapy has been found to promote tumor recurrence, progression and metastasis. More specifically, anti-angiogenic therapy would induce autophagy in the tumor stroma via the induction of stromal hypoxia, thereby converting a non-aggressive tumor type to a “lethal” aggressive tumor phenotype. Thus, uncoupling the metabolic parasitic relationship between cancer cells and an autophagic tumor stroma may hold great promise for anti-cancer therapy. Finally, we believe that autophagy in the tumor stroma is the local microscopic counterpart of systemic wasting (cancer-associated cachexia), which is associated with advanced and metastatic cancers. Cachexia in cancer patients is not due to decreased energy intake, but instead involves an increased basal metabolic rate and increased energy expenditures, resulting in a negative energy balance. Importantly, when tumors were surgically excised, this increased metabolic rate returned to normal levels. This view of cachexia, resulting in energy transfer to the tumor, is consistent with our hypothesis. So, cancer-associated cachexia may start locally as stromal autophagy and then spread systemically. As such, stromal autophagy may be the requisite precursor of systemic cancer-associated cachexia.Key words: caveolin-1, autophagy, cancer associated fibroblasts, hypoxia, mitophagy, oxidative stress, DNA damage, genomic instability, tumor stroma, wasting (cancer cachexia), Warburg effect     

Autophagy: an 'Achilles' heel of tumorigenesis in TSC and LAM

Mammalian target of rapamycin (mTOR) complex 1 (mTORC1), which is activated in tuberous sclerosis complex (TSC) and lymphangioleiomyomatosis (LAM), is a master regulator of cell growth, cellular metabolism, and autophagy. Treatment of TSC and LAM patients with mTORC1 inhibitors partially decreases the size of brain and kidney tumors, and stabilizes pulmonary function. However, the tumors regrow and lung function continues to decline when treatment is discontinued. We hypothesized that dysregulation of autophagy plays a critical role in the pathogenesis of tumors with mTORC1 hyperactivation and in their response to mTORC1-targeted therapy. We found that cells lacking TSC2 have low levels of autophagy under basal and cellular stress conditions. Using genetic and pharmacological approaches, we discovered that the survival of Tsc2-deficient tumor cells is dependent on autophagy induction. Thus, autophagy inhibitors may have therapeutic potential in TSC and LAM, either as single agent therapy or in combination with mTORC1 inhibitors.     

Autophagy

Mammalian target of rapamycin (mTOR) complex 1 (mTORC1), which is activated in tuberous sclerosis complex (TSC) and lymphangioleiomyomatosis (LAM), is a master regulator of cell growth, cellular metabolism, and autophagy. Treatment of TSC and LAM patients with mTORC1 inhibitors partially decreases the size of brain and kidney tumors, and stabilizes pulmonary function. However, the tumors regrow and lung function continues to decline when treatment is discontinued. We hypothesized that dysregulation of autophagy plays a critical role in the pathogenesis of tumors with mTORC1 hyperactivation and in their response to mTORC1-targeted therapy. We found that cells lacking TSC2 have low levels of autophagy under basal and cellular stress conditions. Using genetic and pharmacological approaches, we discovered that the survival of Tsc2-deficient tumor cells is dependent on autophagy induction. Thus, autophagy inhibitors may have therapeutic potential in TSC and LAM, either as single agent therapy or in combination with mTORC1 inhibitors.     

Autophagy blockade enhances HDAC inhibitors' pro-apoptotic effects: potential implications for the treatment of a therapeutic-resistant malignancy

Malignant peripheral nerve sheath tumors (MPNSTs) are aggressive, highly metastatic, poor prognosis tumors for which effective therapeutic strategies are currently lacking. We summarize recent work focusing on preclinical evaluation of histone deacetylase inhibitors (HDACis) for the treatment of MPNST. HDACis are a novel drug class with anti-cancer therapeutic promise. Using human MPNST cell lines and xenograft models we found that a MPNST subset is highly sensitive to HDACis, whereas a fraction is relatively resistant. HDACis were found to induce autophagy in all MPNST cells in vitro and in vivo; in "sensitive" MPNST cells autophagy occurs in concert with apoptosis, whereas unopposed autophagy develops in "resistant" cells. Genetic and chemical autophagy blockade significantly enhances HDACi-induced apoptotic cell death in both resistant and sensitive cells. Combined chloroquine and HDACi treatment abrogates growth of human MPNST xenografts and lung metastases. The potential role of autophagy in cancer therapeutic response remains controversial; however, our study supports HDACi-induced autophagy as a MPNST survival mechanism. These data also imply that the consequences of drug-induced autophagy may be compound-type, tumor-type, or even molecular context-dependent, suggesting a complex crosstalk between autophagy and apoptosis. Clinical trials evaluating HDACis with autophagy blockade for therapy of MPNST therefore merit consideration.     

Autophagy blockade enhances HDAC inhibitors’ pro-apoptotic effects

Malignant peripheral nerve sheath tumors (MPNSTs) are aggressive, highly metastatic, poor prognosis tumors for which effective therapeutic strategies are currently lacking. We summarize recent work focusing on preclinical evaluation of histone deacetylase inhibitors (HDACis) for the treatment of MPNST. HDACis are a novel drug class with anti-cancer therapeutic promise. Using human MPNST cell lines and xenograft models we found that a MPNST subset is highly sensitive to HDACis, whereas a fraction is relatively resistant. HDACis were found to induce autophagy in all MPNST cells in vitro and in vivo; in “sensitive” MPNST cells autophagy occurs in concert with apoptosis, whereas unopposed autophagy develops in “resistant” cells. Genetic and chemical autophagy blockade significantly enhances HDACi-induced apoptotic cell death in both resistant and sensitive cells. Combined chloroquine and HDACi treatment abrogates growth of human MPNST xenografts and lung metastases. The potential role of autophagy in cancer therapeutic response remains controversial; however, our study supports HDACi-induced autophagy as a MPNST survival mechanism. These data also imply that the consequences of drug-induced autophagy may be compound-type, tumor-type, or even molecular context-dependent, suggesting a complex crosstalk between autophagy and apoptosis. Clinical trials evaluating HDACis with autophagy blockade for therapy of MPNST therefore merit consideration.     

Curbing autophagy and histone deacetylases to kill cancer cells

Cells respond to cytotoxicity by activating a variety of signal transduction pathways. One pathway frequently upregulated during cytotoxic response is macroautophagy (hereafter referred to as autophagy). Previously, we demonstrated that pan-histone deacetylase (HDAC) inhibitors, such as the anticancer agent suberoylanilide hydroxamic acid (SAHA, Vorinostat), can induce autophagy. In this study, we show that HDAC inhibition triggers autophagy by suppressing MTOR and activating the autophagic kinase ULK1. Furthermore, autophagy inhibition can sensitize cells to both apoptotic and nonapoptotic cell death induced by SAHA, suggesting the therapeutic potential of autophagy targeting in combination with SAHA therapy. This study also raised a series of questions: What is the role of HDACs in regulating autophagy? Do individual HDACs have distinct functions in autophagy? How do HDACs regulate the nutrient-sensing kinase MTOR? Since SAHA-induced nonapoptotic cell death is not driven by autophagy, what then is the mechanism underlying the apoptosis-independent death? Tackling these questions should lead to a better understanding of autophagy and HDAC biology and contribute to the development of novel therapeutic strategies.     

Curbing autophagy and histone deacetylases to kill cancer cells

Cells respond to cytotoxicity by activating a variety of signal transduction pathways. One pathway frequently upregulated during cytotoxic response is macroautophagy (hereafter referred to as autophagy). Previously, we demonstrated that pan-histone deacetylase (HDAC) inhibitors, such as the anticancer agent suberoylanilide hydroxamic acid (SAHA, Vorinostat), can induce autophagy. In this study, we show that HDAC inhibition triggers autophagy by suppressing MTOR and activating the autophagic kinase ULK1. Furthermore, autophagy inhibition can sensitize cells to both apoptotic and nonapoptotic cell death induced by SAHA, suggesting the therapeutic potential of autophagy targeting in combination with SAHA therapy. This study also raised a series of questions: What is the role of HDACs in regulating autophagy? Do individual HDACs have distinct functions in autophagy? How do HDACs regulate the nutrient-sensing kinase MTOR? Since SAHA-induced nonapoptotic cell death is not driven by autophagy, what then is the mechanism underlying the apoptosis-independent death? Tackling these questions should lead to a better understanding of autophagy and HDAC biology and contribute to the development of novel therapeutic strategies.     

Autophagy Plays a Critical Role in ChLym-1-Induced Cytotoxicity of Non-Hodgkin’s Lymphoma Cells

Autophagy is a critical mechanism in both cancer therapy resistance and tumor suppression. Monoclonal antibodies have been documented to kill tumor cells via apoptosis, antibody-dependent cellular cytotoxicity (ADCC) and complement-dependent cytotoxicity (CDC). In this study, we report for the first time that chLym-1, a chimeric anti-human HLA-DR monoclonal antibody, induces autophagy in Raji Non-Hodgkin’s Lymphoma (NHL) cells. Interestingly, inhibition of autophagy by pharmacological inhibitors (3-methyladenine and NH₄Cl) or genetic approaches (siRNA targeting Atg5) suppresses chLym-1-induced growth inhibition, apoptosis, ADCC and CDC in Raji cells, while induction of autophagy could accelerate cytotoxic effects of chLym-1 on Raji cells. Furthermore, chLym-1-induced autophagy can mediate apoptosis through Caspase 9 activation, demonstrating the tumor-suppressing role of autophagy in antilymphoma effects of chLym-1. Moreover, chLym-1 can activate several upstream signaling pathways of autophagy including Akt/mTOR and extracellular signal-regulated kinase 1/2 (Erk1/2). These results elucidate the critical role of autophagy in cytotoxicity of chLym-1 antibody and suggest a potential therapeutic strategy of NHL therapy by monoclonal antibody chLym-1 in combination with autophagy inducer.     

Nuclear factor-κB signaling pathway is involved in phospholipase Cε-regulated proliferation in human renal cell carcinoma cells

Glioblastoma is the most aggressive cerebral gliomas. Despite advances in therapies, the prognosis is still very poor. Therefore, novel therapeutic strategies are required. As a proteasome inhibitor, bortezomib has shown its efficacy as an active antitumor agent against a variety of tumors. However, inhibition of proteasome activity leads to cell death and also induces cell autophagy, and due to the dual roles of autophagy in the survival and death of tumor cells, the effect of inhibition of autophagy on glioblastoma cells remains to be explored. We therefore assessed whether bortezomib is capable of inducing autophagy, and investigated the antitumor effect of bortezomib combined with autophagy inhibitors on human glioblastoma U251 and U87 cells. Cell viability was measured by MTT assay. The expressions of autophagy and apoptosis-related proteins were determined by Western blot analysis. U251 and U87 cells proliferation was inhibited in a dose-dependent manner. Both apoptosis and autophagy induced by bortezomib were observed in human glioblastoma U87 and U251 cells. However, when U251 and U87 cells were co-treated with bortezomib and autophagy inhibitors 3-MA or Atg7 siRNA, the autophagy inhibitors blocked the autophagy in the cells and resulted in a further inhibition of cell proliferation and a further increase in cell apoptosis as compared with that treated with bortezomib alone. These findings indicated that combination of bortezomib and autophagy inhibitors may shed new light on glioblastoma treatment.     

Inhibition of autophagosome formation by the benzoporphyrin derivative verteporfin

Autophagy enables cells to degrade and recycle cytoplasmic materials both as a housekeeping mechanism and in response to extracellular stress such as nutrient deprivation. Recent studies indicate that autophagy also functions as a protective mechanism in response to several cancer therapy agents, making it a prospective therapeutic target. Few pharmacological inhibitors suitable for testing the therapeutic potential of autophagy inhibition in vivo are known. An automated microscopy assay was used to screen >3,500 drugs and pharmacological agents and identified one drug, verteporfin, as an inhibitor of autophagosome accumulation. Verteporfin is a benzoporphyrin derivative used in photodynamic therapy, but it inhibits autophagy without light activation. Verteporfin did not inhibit LC3/Atg8 processing or membrane recruitment in response to autophagic stimuli, but it inhibited drug- and starvation-induced autophagic degradation and the sequestration of cytoplasmic materials into autophagosomes. Transient exposure to verteporfin in starvation conditions reduced cell viability whereas cells in nutrient-rich medium were unaffected by drug treatment. Analysis of structural analogs indicated that the activity of verteporfin requires the presence of a substituted cyclohexadiene at ring A of the porphyrin core but that it can tolerate a number of large substituents at rings C and D. The existence of an autophagy inhibitor among FDA-approved drugs should facilitate the investigation of the therapeutic potential of autophagy inhibition in vivo.     

Autophagy is a therapeutic target in anticancer drug resistance

Autophagy is a type of cellular catabolic degradation response to nutrient starvation or metabolic stress. The main function of autophagy is to maintain intracellular metabolic homeostasis through degradation of unfolded or aggregated proteins and organelles. Although autophagic regulation is a complicated process, solid evidence demonstrates that the PI3K-Akt-mTOR, LKB1-AMPK-mTOR and p53 are the main upstream regulators of the autophagic pathway. Currently, there is a bulk of data indicating the important function of autophagy in cancer. It is noteworthy that autophagy facilitates the cancer cells' resistance to chemotherapy and radiation treatment. The abrogation of autophagy potentiates the re-sensitization of therapeutic resistant cancer cells to the anticancer treatment via autophagy inhibitors, such as 3-MA, CQ and BA, or knockdown of the autophagy related molecules. In this review, we summarize the accumulation of evidence for autophagy's involvement in mediating resistance of cancer cells to anticancer therapy and suggest that autophagy might be a potential therapeutic target in anticancer drug resistance in the future.     

Activation of alternative pathways of angiogenesis and involvement of stem cells following anti-angiogenesis treatment in glioma

Malignant gliomas are hypervascular tumors that are highly resistant to all the currently available multimodal treatments. Therefore, anti-angiogenic therapies targeting VEGF or VEGF receptors (VEGFRs) were designed and thought to be an effective tool for controlling the growth of malignant gliomas. However, recent results of early clinical trials using humanized monoclonal antibodies against VEGF (Bevacizumab), as well as small-molecule tyrosine kinase inhibitors that target different VEGF receptors (VEGFRs) (Vatalanib, Vandetanib, Sunitinib, Sorafenib, etc) alone or in combination with other therapeutic agents demonstrated differing outcomes, with the majority of reports indicating that glioma developed resistance to the employed anti-angiogenic treatments. It has been noted that continued anti-angiogenic therapy targeting only the VEGF-VEGFR system might affect pro-angiogenic factors other than VEGF, such as basic fibroblast growth factor (bFGF), stromal derived factor 1 (SDF-1) and Tie-2. These factors may in turn stimulate angiogenesis by mobilizing bone marrow derived precursor cells, such as endothelial progenitor cells (EPCs), which are known to promote angiogenesis and vasculogenesis. In this short review, the current antiangiogenic treatments, possible mechanisms of activation of alternative pathways of angiogenesis, and possible involvement of bone marrow derived progenitor cells in the failure of anti-angiogenic treatments are discussed.     

Targeting autophagy enhances sorafenib lethality for hepatocellular carcinoma via ER stress-related apoptosis

Sorafenib, a potent multikinase inhibitor, has been recognized as the standard systemic treatment for patients with advanced hepatocellular carcinoma (HCC). However, the direct functional mechanism of tumor lethality mediated by sorafenib remains to be fully characterized, and the precise mechanisms of drug resistance are largely unknown. Here, we showed sorafenib induced both apoptosis and autophagy in human HCC cells through a mechanism that involved endoplasmic reticulum (ER) stress and was independent of the MEK1/2-ERK1/2 pathway. Upregulation of IRE1 signals from sorafenib-induced ER stress was critical for the induction of autophagy. Moreover, autophagy activation alleviated the ER stress-induced cell death. Inhibition of autophagy using either pharmacological inhibitors or essential autophagy gene knockdown enhanced cell death in sorafenib treated HCC cell lines. Critically, the combination of sorafenib with the autophagy inhibitor chloroquine produced more pronounced tumor suppression in HCC both in vivo and in vitro. These findings indicated that both ER stress and autophagy were involved in the cell death evoked by sorafenib in HCC cells. The combination of autophagy modulation and molecular targeted therapy is a promising therapeutic strategy in treatment of HCC.     

Targeting autophagy enhances sorafenib lethality for hepatocellular carcinoma via ER stress-related apoptosis

Sorafenib, a potent multikinase inhibitor, has been recognized as the standard systemic treatment for patients with advanced hepatocellular carcinoma (HCC). However, the direct functional mechanism of tumor lethality mediated by sorafenib remains to be fully characterized, and the precise mechanisms of drug resistance are largely unknown. Here, we showed sorafenib induced both apoptosis and autophagy in human HCC cells through a mechanism that involved endoplasmic reticulum (ER) stress and was independent of the MEK1/2-ERK1/2 pathway. Upregulation of IRE1 signals from sorafenib-induced ER stress was critical for the induction of autophagy. Moreover, autophagy activation alleviated the ER stress-induced cell death. Inhibition of autophagy using either pharmacological inhibitors or essential autophagy gene knockdown enhanced cell death in sorafenib treated HCC cell lines. Critically, the combination of sorafenib with the autophagy inhibitor chloroquine produced more pronounced tumor suppression in HCC both in vivo and in vitro. These findings indicated that both ER stress and autophagy were involved in the cell death evoked by sorafenib in HCC cells. The combination of autophagy modulation and molecular targeted therapy is a promising therapeutic strategy in treatment of HCC.     

Autophagy promotes resistance to photodynamic therapy-induced apoptosis selectively in colorectal cancer stem-like cells

Recent studies have indicated that cancer stem-like cells (CSCs) exhibit a high resistance to current therapeutic strategies, including photodynamic therapy (PDT), leading to the recurrence and progression of colorectal cancer (CRC). In cancer, autophagy acts as both a tumor suppressor and a tumor promoter. However, the role of autophagy in the resistance of CSCs to PDT has not been reported. In this study, CSCs were isolated from colorectal cancer cells using PROM1/CD133 (prominin 1) expression, which is a surface marker commonly found on stem cells of various tissues. We demonstrated that PpIX-mediated PDT induced the formation of autophagosomes in PROM1/CD133⁺ cells, accompanied by the upregulation of autophagy-related proteins ATG3, ATG5, ATG7, and ATG12. The inhibition of PDT-induced autophagy by pharmacological inhibitors and silencing of the ATG5 gene substantially triggered apoptosis of PROM1/CD133⁺ cells and decreased the ability of colonosphere formation in vitro and tumorigenicity in vivo. In conclusion, our results revealed a protective role played by autophagy against PDT in CSCs and indicated that targeting autophagy could be used to elevate the PDT sensitivity of CSCs. These findings would aid in the development of novel therapeutic approaches for CSC treatment.     

Autophagic degradation of GZMB/granzyme B

The crucial issue for defining successful natural killer (NK)-based anticancer therapy is the ability of tumor cells to activate resistance mechanisms leading to escape from NK-mediated killing. It is now well established that such mechanisms are likely evolved under hypoxia in the tumor microenvironment. Here, we show that hypoxia-induced autophagy impairs breast cancer cell susceptibility to NK-mediated lysis and that this impairment is reverted by targeting autophagy. We provide evidence that activation of autophagy in hypoxic cells is involved in selective degradation of the pro-apoptotic NK-derived serine protease GZMB/granzyme B, thereby blocking NK-mediated target cell apoptosis. Our in vivo data validate the concept that targeting autophagy in cancer cells promotes tumor regression by facilitating their elimination by NK cells. This study provides a cutting-edge advance in our understanding of how hypoxia-induced autophagy impairs NK-mediated lysis and might pave the way for formulating more effective NK-based antitumor therapy by combining autophagy inhibitors.     

Commentary: Autophagic degradation of GZMB/granzyme B: A new mechanism of hypoxic tumor cell escape from natural killer cell-mediated lysis

The crucial issue for defining successful natural killer (NK)-based anticancer therapy is the ability of tumor cells to activate resistance mechanisms leading to escape from NK-mediated killing. It is now well established that such mechanisms are likely evolved under hypoxia in the tumor microenvironment. Here, we show that hypoxia-induced autophagy impairs breast cancer cell susceptibility to NK-mediated lysis and that this impairment is reverted by targeting autophagy. We provide evidence that activation of autophagy in hypoxic cells is involved in selective degradation of the pro-apoptotic NK-derived serine protease GZMB/granzyme B, thereby blocking NK-mediated target cell apoptosis. Our in vivo data validate the concept that targeting autophagy in cancer cells promotes tumor regression by facilitating their elimination by NK cells. This study provides a cutting-edge advance in our understanding of how hypoxia-induced autophagy impairs NK-mediated lysis and might pave the way for formulating more effective NK-based antitumor therapy by combining autophagy inhibitors.