Lewis lung carcinoma variant with high sensitivity to antitumor antiangiogenic therapy reveals a high capacity to autophagy

Comparative investigation of two variants of Lewis lung carcinoma cells (LLC and LLC/R9) growing under nutrient deficiency caused by long-term incubation without growth medium replacement was performed. It was established that LLC/R9 cells which in contrast to LLC cells had a high sensitivity to antitumor antiangiogenic therapy (AAT) revealed a high dependence of their survival from glucose level in growth medium as well as high capacity to autophagy under nutrient deficiency. Perhaps high autophagy activity in tumor cells may be considered as a marker of tumor AAT sensitivity.     

Autophagy-deficient tumor cells rely on extracellular amino acids to survive upon glutamine deprivation

Macroautophagy/autophagy is a unique protein degradation process by which intracellular materials are recycled for energy homeostasis. However, the metabolic status and energy source of autophagy-defective tumor cells is poorly understood. Here in this study, we found ATF4-dependent amino acid transporter (AAT) gene expression and amino acid uptake were increased in autophagy-deficient cells under conditions of Gln deprivation. Notably, inhibition of amino acid uptake reduced the viability of Gln-deprived autophagy-deficient cells, but not significantly in wild-type cells, suggesting the reliance of autophagy-deficient tumor cells on extracellular amino acid uptake.     

Autophagy in hypoxia protects cancer cells against apoptosis induced by nutrient deprivation through a beclin1‐dependent way in hepatocellular carcinoma

Oxygen deficiency and nutrient deprivation widely exists in solid tumors because of the poor blood supply. However, cancer cells can survive this adverse condition and proliferate continuously to develop. To figure out the way to survive, we investigated the role of autophagy in the microenvironment in hepatocellular carcinoma. In order to simulate the tumor microenvironment more veritably, cells were cultured in oxygen‐nutrient‐deprived condition following a hypoxia preconditioning. As a result, cell death under hypoxia plus nutrient deprivation was much less than that under nutrient deprivation only. And the decreased cell death mainly attributed to the decreased apoptosis. GFP‐LC3 and electron microscopy analysis showed that autophagy was significantly activated in the period of hypoxia preconditioning. However, autophagic inhibitor—3‐MA significantly abrogated the apoptosis reduction in hypoxia, which implied the involvement of autophagy in protection of hepatocellular carcinoma cells against apoptosis induced by starvation. Furthermore, Beclin 1 was proved to play an important role in this process. siRNA targeting Beclin 1 was transfected into hepatocellular carcinoma cells. And both data from western blot detecting the expression of LC3‐II and transmission microscopy observing the accumulation of autophagosomes showed that autophagy was inhibited obviously as a result of Beclin 1 knockdown. Besides, the decreased apoptosis of starved cells under hypoxia was reversed. Taken together, these results suggest that autophagy activated by hypoxia mediates the tolerance of hepatocellular carcinoma cells to nutrient deprivation, and this tolerance is dependent on the activity of Beclin 1. J. Cell. Biochem. 112: 3406–3420, 2011. © 2011 Wiley Periodicals, Inc.     

Plant autophagy puts the brakes on cell death by controlling salicylic acid signaling

It has long been recognized that autophagy in plants is important for nutrient recycling and plays a critical role in the ability of plants to adapt to environmental extremes such as nutrient deprivation. Recent reverse genetic studies, however, hint at other roles for autophagy, showing that autophagy defects in higher plants result in early senescence and excessive immunity-related programmed cell death (PCD), irrespective of nutrient conditions. Until now, the mechanisms by which cells die in the absence of autophagy were unclear. In our study, using biochemical, pharmacological and genetic approaches, we reveal that excessive salicylic acid (SA) signaling is a major factor in autophagy-defective plant-dependent cell death and that the SA signal can induce autophagy. These findings suggest a novel physiological function for plant autophagy that operates via a negative feedback loop to modulate proper SA signaling.     

Nutrient deprivation increases vulnerability of endothelial cells to proinflammatory insults

Nutrient deprivation is a stimulus for oxidative stress and is an established method for induction of cell autophagy and apoptosis. The aims of this study were to identify conditions that evoke superoxide production in cultured human umbilical vein endothelial cells (HUVECs), determine the mechanism of action for this response, and examine whether the stimulus might facilitate the adhesion of human isolated neutrophils to the HUVECs. HUVECs were incubated in M199 medium under conditions of serum starvation (serum-free M199 medium), low serum (medium containing 2% fetal calf serum), and high serum (medium containing 20% fetal calf serum). HUVECs were also incubated under proinflammatory conditions, in medium supplemented with 50 ng/ml tumor necrosis factor-α (TNF-α) or neutrophils preactivated with 10 nM phorbol 12-myristate 13-acetate (PMA). Superoxide production was increased fourfold in serum-starved HUVECs compared to cells incubated in 20% medium, and this was reduced by inhibitors of the mitochondrial electron transport chain and mitochondrial Ca²⁺ uniporter. Superoxide production was 23.6% higher in HUVECs incubated with TNF-α in 2% medium compared to 2% medium alone, but unchanged with TNF-α in 20% medium. PMA-activated neutrophils adhered to morphologically aberrant HUVECs, which were mainly evident under the low-serum condition. The findings show a role of mitochondrial enzymes in superoxide production in response to nutrient deprivation and suggest that proinflammatory responses in HUVECs become manifest when HUVECs are in an already-compromised state.     

Elongation factor-2 kinase: its role in protein synthesis and autophagy

Elongation factor-2 kinase (eEF-2 kinase; Ca(2+)/calmodulin-dependent kinase III) controls the rate of peptide chain elongation. The activity of eEF-2 kinase is increased in many malignancies, yet its precise function in carcinogenesis remains unknown. Autophagy, a well-defined survival pathway in yeast, may also play an important role in oncogenesis. Furthermore, the autophagic response to nutrient deprivation is regulated by the mammalian target of rapamycin (mTOR). eEF-2 kinase lies downstream of mTOR and is regulated by several kinases in this pathway. Therefore, we studied the role of eEF-2 kinase in autophagy. Knockdown of eEF-2 kinase by RNA interference inhibited autophagy in several cell types as measured by light chain 3 (LC3)-II formation, acidic vesicular organelle staining, and electron microscopy. In contrast, overexpression of eEF-2 kinase increased autophagy. Furthermore, inhibition of autophagy markedly decreased the viability of glioblastoma cells grown under conditions of nutrient depletion. These results suggest that eEF-2 kinase plays a regulatory role in the autophagic process in tumor cells and may promote cancer cell survival under conditions of nutrient deprivation. Therefore, eEF-2 kinase activation may be a part of a survival mechanism in glioblastoma, and targeting this kinase may represent a novel approach to cancer treatment.     

CXCR4 positive cells from Lewis lung carcinoma cell line have cancer metastatic stem cell characteristics

There is increasing evidence that cancer stem cells contribute to the initiation and propagation of many tumor. Therefore, to find out and identify the metastatic tumor stem-like cells in Lewis lung cancer cell line (LLC), the expression of CXCR4 was measured in LLC by flow cytometry and observed by laser scanning confocal microscope (LSCM). After the CXCR4(+) LLC cell was isolated from LLC by magnetic cell sorting, its properties were evaluated by their tumorigenic and metastatic potentials. CXCR4(+) cells were counted for 0.18% of the total number of LLC, and immunofluorescent staining cells were identified by LSCM. CXCR4(+) LLC suspension cultured in a serum-free medium, cell spheres expressed a high level of Sca-1. The chemotherapy sensitivity to cisplatin of CXCR4(+) LLC was lower than that of CXCR4(-) LLC. The expression of ABCG2 and IGF1R mRNA in CXCR4(+) LLC was higher than that in CXCR4(-) LLC (P < 0.01). Most of CXCR4(+) LLC cells were close to vascular endothelial cells, aberrant vasculature around it was forming. The expression of VEGF and MMP9 mRNA in CXCR4(+) LLC was higher than that in CXCR4(-) LLC (P < 0.05), the microvessel density (MVD) of CXCR4(+) subsets growing were higher than that of CXCR4(-) subsets growing tumor tissue (P < 0.01). The tumor size, volume, and metastatic foci in the lungs of CXCR4(+) LLC was significantly higher than that in CXCR4(-) LLC (P < 0.001). Similarly, elevated expression of MMP9 and VEGF was also positively associated with CXCR4(+) LLC. Our results demonstrated that CXCR4(+) cells from Lewis lung carcinoma cell line exhibit cancer metastatic stem cell characteristics.     

Autophagy downregulates NLRP3-dependent inflammatory response of intestinal epithelial cells under nutrient deprivation

Dysregulation of inflammation induced by noninfectious stress conditions, such as nutrient deprivation, causes tissue damage and intestinal permeability, resulting in the development of inflammatory bowel diseases. We studied the effect of autophagy on cytokine secretion related to intestinal permeability under nutrient deprivation. Autophagy removes NLRP3 inflammasomes via ubiquitin-mediated degradation under starvation. When autophagy was inhibited, starvation-induced NLRP3 inflammasomes and their product, IL-1β, were significantly enhanced. A prolonged nutrient deprivation resulted in an increased epithelial mesenchymal transition (EMT), leading to intestinal permeability. Under nutrient deprivation, IL-17E/25, which is secreted by IL-1β, demolished the intestinal epithelial barrier. Our results suggest that an upregulation of autophagy maintains the intestinal barrier by suppressing the activation of NLRP3 inflammasomes and the release of their products, including proinflammatory cytokines IL-1β and IL-17E/25, under nutrient deprivation.     

A critical role for autophagy in pancreatic cancer

Autophagy is a regulated catabolic process that leads to the lysosomal degradation of damaged proteins, organelles and other macromolecules, with subsequent recycling of bioenergetic intermediates. The role of autophagy in cancer is undoubtedly complex and likely dependent on tumor type and on the cellular and developmental context. While it has been well demonstrated that autophagy may function as a tumor suppressor, there is mounting evidence that autophagy may have pro-tumorigenic roles, e.g., promoting therapeutic resistance as well as survival under stresses such as hypoxia and nutrient deprivation. These two, seemingly disparate functions can be reconciled by a possible temporal role of autophagy during tumor development, initially suppressing tumor initiation yet supporting tumor growth at later stages.     

Autophagy gets a brake

Autophagy, a highly regulated catabolic process, is controlled by the action of positive and negative regulators. While many of the positive mediators of autophagy have been identified, very little is known about negative regulators that might counterbalance the process. We recently identified deathassociated protein 1 (DAP1) as a suppressor of autophagy and as a novel direct substrate of mammalian target of rapamycin (mTOR). We found that DAP1 is functionally silent in cells growing under rich nutrient supplies through mTOR-dependent inhibitory phosphorylation on two sites, which were mapped to Ser3 and Ser51. During amino acid starvation, mTOR activity is turned off resulting in a rapid reduction in the phosphorylation of DAP1. This caused the conversion of the protein into a suppressor of autophagy, thus providing a buffering mechanism that counterbalances the autophagic flux and prevents its overactivation under conditions of nutrient deprivation. Based on these studies we propose the “gas and brake” concept in which mTOR, the main sensor that regulates autophagy in response to amino acid deprivation, also controls the activity of a specific balancing brake to prevent the overactivation of autophagy.     

A critical role for autophagy in pancreatic cancer

Autophagy is a regulated catabolic process that leads to the lysosomal degradation of damaged proteins, organelles and other macromolecules, with subsequent recycling of bioenergetic intermediates. The role of autophagy in cancer is undoubtedly complex and likely dependent on tumor type and on the cellular and developmental context. While it has been well demonstrated that autophagy may function as a tumor suppressor, there is mounting evidence that autophagy may have pro-tumorigenic roles, e.g., promoting therapeutic resistance as well as survival under stresses such as hypoxia and nutrient deprivation. These two, seemingly disparate functions can be reconciled by a possible temporal role of autophagy during tumor development, initially suppressing tumor initiation yet supporting tumor growth at later stages.     

Inhibitors of insulin-like growth factor-1 receptor tyrosine kinase are preferentially cytotoxic to nutrient-deprived pancreatic cancer cells

Chronic deprivation of nutrients is rare in normal tissues, however large areas of tumor are nutrient-starved and hypoxic due to a disorganized vascular system. Some cancers show an inherent ability to tolerate severe growth conditions. Therefore, we screened chemical compounds to identify cytotoxic agents that function preferentially in nutrient-deprived conditions. We found that AG1024, a specific inhibitor of insulin-like growth factor-1 receptor tyrosine kinase (IGF-1R), showed preferential cytotoxicity to human pancreatic cancer cells in nutrient-deprived conditions relative to cells in nutrient-sufficient conditions. The cytotoxicity of I-OMe-AG538 (another specific inhibitor of IGF-1R kinase) was also enhanced in nutrient-deprived cells. In addition, AG1024 and I-OMe-AG538 potently inhibited IGF-1R activation to nutrient-deprived cells. In contrast, conventional chemotherapeutic drugs, as well as inhibitors of PDGFR and EGFR kinases, elicited weak cytotoxicity. These data indicate that nutrient-deprived human pancreatic cancer cells have increased sensitivity to inhibition of IGF-1R activation. IGF-1R inhibitors offer a promising strategy for anticancer therapeutic approaches that are oriented toward tumor microenvironment.     

Piper longum Constituents Induce PANC-1 Human Pancreatic Cancer Cell Death under Nutrition Starvation

Pancreatic cancer is a highly aggressive form of cancer with a poor prognosis, partly due to ‘austerity’, a phenomenon of tolerance to nutrient deprivation and survival in its hypovascular tumor microenvironment. Anti-austerity agents which preferentially diminish the survival of cancer cells under nutrition starvation is regarded as new generation anti-cancer agents. This study investigated the potential of Piper longum constituents as anti-austerity agents. The ethanolic extract of Piper longum was found to have preferential cytotoxicity towards PANC-1 human pancreatic cancer cells in a nutrient-deprived medium (NDM). Further investigation led to the identification of pipernonaline ( 3 ) as the lead compound with the strongest anti-austerity activity, inducing cell death and inhibiting migration in a normal nutrient medium, as well as strongly inhibiting the Akt/mTOR/autophagy pathway. Therefore, pipernonaline ( 3 ) holds promise as a novel antiausterity agent for the treatment of pancreatic cancer.     

Elongation Factor-2 Kinase: Its Role in Protein Synthesis and Autophagy

Elongation factor-2 kinase (eEF-2 kinase; Ca²⁺/calmodulin-dependent kinase III) controls the rate of peptide chain elongation. The activity of eEF-2 kinase is increased in many malignancies, yet its precise function in carcinogenesis remains unknown. Autophagy, a well-defined survival pathway in yeast, may also play an important role in oncogenesis. Furthermore, the autophagic response to nutrient deprivation is regulated by the mammalian target of rapamycin (mTOR). eEF-2 kinase lies downstream of mTOR and is regulated by several kinases in this pathway. Therefore, we studied the role of eEF-2 kinase in autophagy. Knockdown of eEF-2 kinase by RNA interference inhibited autophagy in several cell types as measured by light chain 3 (LC3)-II formation, acidic vesicular organelle staining, and electron microscopy. In contrast, overexpression of eEF-2 kinase increased autophagy. Furthermore, inhibition of autophagy markedly decreased the viability of glioblastoma cells grown under conditions of nutrient depletion, which increased eEF-2 kinase activity and decreased the activity of S6 kinase, suggesting an involvement of mTOR pathway in the eEF-2 kinase-mediated regulation of autophagy. These results suggest that eEF-2 kinase plays a regulatory role in the autophagic process in tumor cells and may promote cancer cell survival under conditions of nutrient deprivation. Therefore, eEF-2 kinase activation may be a part of a survival mechanism in glioblastoma, and targeting this kinase may represent a novel approach to cancer treatment.

Addendum to:

Elongation Factor-2 Kinase Regulates Autophagy in Human Glioblastoma Cells

H. Wu, J.-M. Yang, S. Jin, H. Zhang and W.N. Hait

Cancer Res 2006; 66:3015-23     

Autophagy: Not good OR bad,but good AND bad

Autophagy is a well-established mechanism to degrade intracellular components and provide a nutrient source to promote survival of cells in metabolic distress. Such stress can be caused by a lack of available nutrients or by insufficient rates of nutrient uptake. Indeed, growth factor deprivation leads to internalization and degradation of nutrient transporters, leaving cells with limited means to access extracellular nutrients even when plentiful. This loss of growth factor signaling and extracellular nutrients ultimately leads to apoptosis, but also activates autophagy, which may degrade intracellular components and provide fuel for mitochondrial bioenergetics. The precise metabolic role of autophagy and how it intersects with the apoptotic pathways in growth factor withdrawal, however, has been uncertain. Our recent findings in growth factor-deprived hematopoietic cells show that autophagy can simultaneously contribute to cell metabolism and initiate a pathway to sensitize cells to apoptotic death. This pathway may promote tissue homeostasis by ensuring that only cells with high resistance to apoptosis may utilize autophagy as a survival mechanism when growth factors are limiting and nutrient uptake decreases.     

Mechanisms of autophagy and apoptosis: Recent developments in breast cancer cells

Autophagy,the pathway whereby cell components are degraded by lysosomes,is involved in the cell response to environmental stresses,such as nutrient deprivation,hypoxia or exposition to chemotherapeutic agents.Under these conditions,which are reminiscent of certain phases of tumor development,autophagy either promotes cell survival or induces cell death. This strengthens the possibility that autophagy could be an important target in cancer therapy,as has been proposed.Here,we describe the regulation of survival and death by autophagy and apoptosis,especially in cultured breast cancer cells.In particular,we discuss whether autophagy represents an apoptosis-independent process and/or if they share common pathways. We believe that understanding in detail the molecular mechanisms that underlie the relationships between autophagy and apoptosis in breast cancer cells could improve the available treatments for this disease.     

The amplified cancer gene LAPTM4B promotes tumor growth and tolerance to stress through the induction of autophagy

Autophagy is a fundamental salvage pathway that encapsulates damaged cellular components and delivers them to the lysosome for degradation and recycling. This pathway usually conducts a protective cellular response to nutrient deprivation and various stresses. Tumor cells live with metabolic stress and use autophagy for their survival during tumor progression and metastasis. Genomic instability in tumor cells may result in amplification of crucial gene(s) for autophagy and upregulate the autophagic pathway. We demonstrate that a cancer-associated gene, LAPTM4B, plays an important role in lysosomal functions and is critical for autophagic maturation. Its amplification and overexpression promote autophagy, which renders tumor cells resistant to metabolic and genotoxic stress and results in more rapid tumor growth.