Chondrocytes embedded in the epiphyseal growth plates of long bones undergo autophagy prior to the induction of osteogenesis

Bone growth takes place through the activities of chondrocytes embedded in the epiphyseal growth plate. Stress conditions in the plate can promote the autophagic response through the modulation of genes controlling metabolite utilization. mTOR plays a critical role in autophagy serving as the sensor that integrates metabolic and growth factor signals. Ongoing studies indicate that terminal chondrocytes exhibit autophagic characteristics. Morphologically, the arrested cells contain double membrane vacuoles; there is a loss of membrane structure, limited staining and organelle destruction. Since the life history of the growth plate chondrocyte is very short, even minor disturbances in the metabolic state can result in gross impairment of growth. We contend that the induction of the autophagic response, permits the terminally differentiated cells to survive the brief rigors of the harsh local microenvironment. Whether chondrocytes can recover from this state, and possibly participate in osteogenesis, is not known at this time.     

Autophagy as a Mechanism of Radiation Sensitization in Breast Tumor Cells

Current studies to define the mechanism by which vitamin D₃ and analogs of vitamin D₃ enhance the response to ionizing radiation in breast tumor cells suggest that these effects are mediated, in large part, through the promotion of autophagic cell death. The residual surviving cell population remains in a senescent, growth arrested state, with minimal recovery of proliferative capacity. It is becoming evident that pathways other than or in addition to apoptosis, including senescence arrest, mitotic catastrophe and autophagy, contribute to loss of self-renewal capacity in tumor cells exposed to chemotherapeutic drugs and ionizing radiation. How and why the cell chooses a particular growth arrest and/or cell death pathway remains a puzzle to be solved.

Addendum to:

Potentiation of Radiation Sensitivity in Breast Tumor Cells by the Vitamin D₃ Analog, EB 1089 through Promotion of Autophagy and Interference with Proliferative Recovery

G. DeMasters, X. Di, R. Shiu, I. Newsham and D.A. Gewirtz

Mol Cancer Ther 2006; 5:2786-97     

Autophagy Induction and Autophagic Cell Death in Effector T Cells

The population size of the T cells is tightly regulated. The T cell number drastically increases in response to their specific antigens. Upon antigen clearance, the T cell number decreases over time. Apoptosis, also called type I programmed cell death, plays an important role in eliminating T cells. The role of autophagic cell death, also called type II programmed cell death, is unclear in T cells. Our recent work demonstrated that autophagy is induced in both Th1 and Th2 cells. Both TCR signaling and IL-2 increase autophagy in T cells, and JNK MAP kinases are required for the induction of autophagy in T cells, whereas caspases and mTOR inhibit autophagy in T cells. Autophagy is required for mediating growth factor withdrawal-dependent cell death in T cells. Here, we hypothesize that autophagic cell death plays an important role in T cell homeostasis.

Addendum to:

Autophagy is Induced in CD4⁺ T Cells and Important for the Growth Factor-Withdrawal Cell Death

C. Li, E. Capan, Y. Zhao, J. Zhao, D. Stolz, S.C. Watkins, S. Jin and B. Lu

J Immunol 2006; 177:5163-8     

ADAM17 Controls Endochondral Ossification by Regulating Terminal Differentiation of Chondrocytes

Endochondral ossification is a highly regulated process that relies on properly orchestrated cell-cell interactions in the developing growth plate. This study is focused on understanding the role of a crucial regulator of cell-cell interactions, the membrane-anchored metalloproteinase ADAM17, in endochondral ossification. ADAM17 releases growth factors, cytokines, and other membrane proteins from cells and is essential for epidermal growth factor receptor (EGFR) signaling and for processing tumor necrosis factor alpha. Here, we report that mice lacking ADAM17 in chondrocytes (A17ΔCh) have a significantly expanded zone of hypertrophic chondrocytes in the growth plate and retarded growth of long bones. This abnormality is caused by an accumulation of the most terminally differentiated type of chondrocytes that produces a calcified matrix. Inactivation of ADAM17 in osteoclasts or endothelial cells does not affect the zone of hypertrophic chondrocytes, suggesting that the main role of ADAM17 in the growth plate is in chondrocytes. This notion is further supported by in vitro experiments showing enhanced hypertrophic differentiation of primary chondrocytes lacking Adam17. The enlarged zone of hypertrophic chondrocytes in A17ΔCh mice resembles that described in mice with mutant EGFR signaling or lack of its ligand transforming growth factor α (TGFα), suggesting that ADAM17 regulates terminal differentiation of chondrocytes during endochondral ossification by activating the TGFα/EGFR signaling axis.     

DDIT3/CHOP promotes autophagy in chondrocytes via SIRT1-AKT pathway

Endoplasmic reticulum (ER) stress can initiate autophagy via unfolded protein response (UPR). As a key downstream gene of UPR, DDIT3/CHOP is expressed in chondrocytes. However, the regulation mechanism of DDIT3/CHOP on autophagy in chondrocytes remains unclear. In this study, the expression levels of autophagic markers Beclin1 and LC3B were found to decrease while p62 increase in the tibial growth plate and costal primary chondrocytes from DDIT3/CHOP KO mice. In vitro, overexpressing DDIT3/CHOP induced autophagy in ATDC5 chondrocytes, displaying an elevated immunofluorescence signal of LC3B and elevated numbers of autophagosomes and autolysosomes. Analysis of the gain- and loss-of-function indicated that the protein level of Beclin1 and the ratio of LC3BII/I increased in DDIT3/CHOP overexpression cells, whereas decreased in DDIT3/CHOP knockdown cells. The decreased level of p62 and additional accumulation of LC3BII caused by chloroquine (CQ) further indicated that DDIT3/CHOP enhanced autophagic flux. Mechanistically, we found that DDIT3/CHOP binds directly to the promoter of SIRT1 to promote its expression by CHIP, qRT-PCR, and Western blot analysis. In addition, SIRT1 enhanced autophagic activity in ATDC5 cells, and inhibition or activation of SIRT1 partially reversed the effect of overexpressing or downregulating DDIT3/CHOP on autophagy. Furthermore, AKT signaling was found to be responsible for DDIT3/CHOP-regulated autophagy in ATDC5 cells. SIRT1 knockdown reversed the effect of DDIT3/CHOP overexpression on AKT signaling. In conclusion, our data clarifies that DDIT3/CHOP promotes autophagy in ATDC5 chondrocytes through the SIRT1-AKT pathway. These results were also confirmed in the primary chondrocytes.     

Clock Genes Influence Gene Expression in Growth Plate and Endochondral Ossification in Mice

We have previously shown transient promotion by parathyroid hormone of Period-1 (Per1) expression in cultured chondrocytes. Here we show the modulation by clock genes of chondrogenic differentiation through gene transactivation of the master regulator of chondrogenesis Indian hedgehog (IHH) in chondrocytes of the growth plate. Several clock genes were expressed with oscillatory rhythmicity in cultured chondrocytes and rib growth plate in mice, whereas chondrogenesis was markedly inhibited in stable transfectants of Per1 in chondrocytic ATDC5 cells and in rib growth plate chondrocytes from mice deficient of brain and muscle aryl hydrocarbon receptor nuclear translocator-like (BMAL1). Ihh promoter activity was regulated by different clock gene products, with clear circadian rhythmicity in expression profiles of Ihh in the growth plate. In BMAL1-null mice, a predominant decrease was seen in Ihh expression in the growth plate with a smaller body size than in wild-type mice. BMAL1 deficit led to disruption of the rhythmic expression profiles of both Per1 and Ihh in the growth plate. A clear rhythmicity was seen with Ihh expression in ATDC5 cells exposed to dexamethasone. In young mice defective of BMAL1 exclusively in chondrocytes, similar abnormalities were found in bone growth and Ihh expression. These results suggest that endochondral ossification is under the regulation of particular clock gene products expressed in chondrocytes during postnatal skeletogenesis through a mechanism relevant to the rhythmic Ihh expression.     

Sex-specific effects of 17β-estradiol and dihydrotestosterone (DHT) on growth plate chondrocytes are dependent on both ERα and ERβ and require palmitoylation to translocate the receptors to the plasma membrane

Rat costochondral cartilage growth plate chondrocytes exhibit cell sex-specific responses to 17β-estradiol (E₂), testosterone, and dihydrotestosterone (DHT). Mechanistically, E₂ and DHT stimulate proliferation and extracellular matrix synthesis in chondrocytes from female and male rats, respectively, by signaling through protein kinase C (PKC) and phospholipase C (PLC). Estrogen receptors (ERα; ERβ) and androgen receptors (ARs) are present in both male and female cells, but it is not known whether they interact to elicit sex-specific signaling. We used specific agonists and antagonists of these receptors to examine the relative contributions of ERs and ARs in membrane-mediated E₂ signaling in female chondrocytes and DHT signaling in male chondrocytes. PKC activity in female chondrocytes was stimulated by agonists of ERα and ERβ and required intact caveolae; PKC activity was inhibited by the E₂ enantiomer and by an inhibitor of ERβ. Western blots of cell lysates co-immunoprecipitated for ERα suggested the formation of a complex containing both ERα and ERß with E₂ treatment. DHT and DHT agonists activated PKC in male cells, while AR inhibition blocked the stimulatory effect of DHT on PKC. Inhibition of ERα and ERβ also blocked PKC activation by DHT. Western blots of whole-cell lysates, plasma membranes, and caveolae indicated the translocation of AR to the plasma membrane and specifically to caveolae with DHT treatment. These results suggest that E₂ and DHT promote chondrocyte differentiation via the ability of ARs and ERs to form a complex. The results also indicate that intact caveolae and palmitoylation of the membrane receptor(s) or membrane receptor complex containing ERα and ERβ is required for E₂ and DHT membrane-associated PKC activity in costochondral cartilage cells.     

HIF-1 Regulation of Chondrocyte Apoptosis: Induction of the Autophagic Pathway

The goal of our investigation was to explore the mechanism by which hypoxia regulates growth plate chondrocyte survival. At low O2 tension, chondrocytes were refractory to a staurosporine (i.e., apoptosis-inducing) challenge. To determine whether hypoxic survival was due to the expression of HIF-1, we evaluated the response of HIF silenced cells to staurosporine. Both, silenced cells and control chondrocytes were equally sensitive to the apoptogen challenge. To learn if resistance was mediated by the proteins of the autophagic pathway, we examined the expression of Beclin 1 and LC3. Both proteins were present in the growth plate as well as in N1511 chondrocytes. Moreover, silencing of Beclin 1 resulted in enhanced chondrocyte death. Thus, this gene served to maintain chondrocyte survival activity. Besides serving a cytoprotective role, it is known that autophagy can function in cell death. Accordingly, to ascertain if autophagy might also sensitize cells to apoptosis, we activated autophagy and examined viability following exposure to an apoptogen. Treatment with the autophagy inhibitor 3-methyladenine rendered the chondrocytes refractory to killing, suggesting that sustained autophagy promoted cell death. We next examined expression of BID and caspase-8. When autophagy was suppressed, chondrocytes promoted caspase-8 activation and activated BID. Finally, we explored the relationship between HIF-1 and Beclin 1. We noted a decrease in Beclin 1 expression and loss of caspase-8 activation in HIF silenced cells and Beclin 1-Bcl-2 association was maintained upon serum starvation. This study indicates that HIF-1 serves to regulate both autophagy and apoptosis.     

Induction of Autophagy by Concanavalin A and its Application in Anti-Tumor Therapy

Concanavalin A (Con A), a lectin from Jack bean seeds that, once bound to the mannose moiety on the cell membrane glycoprotein, is internalized preferentially to the mitochondria. A BNIP3-mediated mitochondria autophagy is then induced, and causes the tumor cells to undergo autophagic cell death. Con A is also a T cell mitogen that can induce autoimmune hepatitis in mice. Because of the dual properties (autophagic cytotoxicity and immunomodulation) via the specific mannose binding, Con A can exert a potent anti-hepatoma therapeutic effect by inhibiting tumor nodule formation in the liver and prolonging the survival of the tumor-bearing mice. The anti-tumor effect is primarily mediated by activated CD8⁺ T cells, and will also establish a tumor antigen-specific immune memory during the hepatic inflammation. This finding provides a novel mechanism in which Con A can be used as an anti-hepatoma agent, and also gives support for the search for natural lectins as anti-cancer compounds.

Addendum to:

Concanavalin A Induces Autophagy in Hepatoma Cells and has a Therapeutic Effect in a Murine In Situ Hepatoma Model

C.P. Chang, M.C. Yang, H.S. Liu, Y.S. Lin, H.Y. Lei HY.Hepatology 2007; 45:286-296.     

HIF-1 regulation of chondrocyte apoptosis: induction of the autophagic pathway

The goal of our investigation was to explore the mechanism by which hypoxia regulates growth plate chondrocyte survival. At low O2 tension, chondrocytes were refractory to a staurosporine (i.e., apoptosis-inducing) challenge. To determine whether hypoxic survival was due to the expression of HIF-1, we evaluated the response of HIF silenced cells to staurosporine. Both, silenced cells and control chondrocytes were equally sensitive to the apoptogen challenge. To learn if resistance was mediated by the proteins of the autophagic pathway, we examined the expression of Beclin 1 and LC3. Both proteins were present in the growth plate as well as in N1511 chondrocytes. Moreover, silencing of Beclin 1 resulted in enhanced chondrocyte death. Thus, this gene served to maintain chondrocyte survival activity. Besides serving a cytoprotective role, it is known that autophagy can function in cell death. Accordingly, to ascertain if autophagy might also sensitize cells to apoptosis, we activated autophagy and examined viability following exposure to an apoptogen. Treatment with the autophagy inhibitor 3-methyladenine rendered the chondrocytes refractory to killing, suggesting that sustained autophagy promoted cell death. We next examined expression of BID and caspase-8. When autophagy was suppressed, chondrocytes promoted caspase-8 activation and activated BID. Finally, we explored the relationship between HIF-1 and Beclin 1. We noted a decrease in Beclin 1 expression and loss of caspase-8 activation in HIF silenced cells and Beclin 1-Bcl-2 association was maintained upon serum starvation. This study indicates that HIF-1 serves to regulate both autophagy and apoptosis.     

The Autophagic Pathway: A Cell Survival Strategy Against the Bacterial Pore-Forming Toxin Vibrio Cholerae Cytolysin

Vibrio cholerae is the causative agent of cholera in humans. In addition to the critical virulence factors cholera toxin and toxin co-regulated pilus, V. cholerae secretes V. cholerae cytolysin (VCC), a pore-forming exotoxin able to induce cell lysis and extensive vacuolation. We have shown that this vacuolation is related to the activation of autophagy in response to VCC action. Furthermore, we found that the autophagic pathway was required to protect cells upon VCC intoxication. Based on additional data presented here, we propose a model aimed to explain the mechanism of cell protection. We postulate that VCC-induced autophagic vacuoles, which display features of multivesicular bodies and enclose the toxin, are implicated in cell defense through VCC degradation involving fusion with lysosomes.

Addendum to:

Protective Role of Autophagy Against Vibrio cholerae Cytolysin, a Pore-Forming Toxin from V. cholerae

M.G. Gutierrez, H.A. Saka, I. Chinen, F.C.M. Zoppino, T. Yoshimori, J.L. Bocco and M.I. Colombo

Proc Natl Acad Sci USA 2007; 104:1829-34     

A role for the membrane Golgi protein Ema in autophagy

Autophagy is a cellular homeostatic response that involves degradation of self-components by the double-membraned autophagosome. The biogenesis of autophagosomes has been well described, but the ensuing processes after autophagosome formation are not clear. In our recent study, we proposed a model in which the Golgi complex contributes to the growth of autophagic structures, and that the Drosophila melanogaster membrane protein Ema promotes this process. In fat body cells of the D. melanogaster ema mutant, the recruitment of the Golgi complex protein Lava lamp (Lva) to autophagic structures is impaired and autophagic structures are very small. In addition, in the ema mutant autophagic turnover of SQSTM1/p62 and mitophagy are impaired. Our study not only identifies a role for Ema in autophagy, but also supports the hypothesis that the Golgi complex may be a potential membrane source for the biogenesis and development of autophagic structures.     

PIM-2 is an independent regulator of chondrocyte survival and autophagy in the epiphyseal growth plate

The overall goal of the investigation was to examine the activity and role of the PIM serine/threonine protein kinases in the growth plate. We showed for the first time that PIM-2 was highly expressed in epiphyseal chondrocytes and that the kinase was required for critical activities linked to cell survival. These activities were independent of those mediated by Akt-1. It was noted that PIM-2 protected chondrocytes from rapamycin sensitized (TOR inhibited) cell death. Since inhibition of mTOR caused autophagy, we examined the autophagic response of PIM-2 silenced cells. We showed that PIM-2 promoted expression and organization of autophagic proteins LC3, and Beclin-1 and enhanced lysosomal acidification. At the same time, PIM-2 modulated the activity of a key regulator of apoptosis, BAD. Since BAD inhibition and Beclin-1 expression activated autophagy, it is likely that induction of the autophagic pathway would serve to inhibit apoptosis and preserve the life of the terminally differentiated chondrocyte. We conclude that PIM-2 regulates a new intermediate stage in the differentiation pathway, the induction of autophagy.     

Cytoprotective Effect of the Elongation Factor-2 Kinase-Mediated Autophagy in Breast Cancer Cells Subjected to Growth Factor Inhibition

Background

Autophagy is a highly conserved and regulated cellular process employed by living cells to degrade proteins and organelles as a response to metabolic stress. We have previously reported that eukaryotic elongation factor-2 kinase (eEF-2 kinase, also known as Ca²⁺/calmodulin-dependent protein kinase III) can positively modulate autophagy and negatively regulate protein synthesis. The purpose of the current study was to determine the role of the eEF-2 kinase-regulated autophagy in the response of breast cancer cells to inhibitors of growth factor signaling.

Methodology/Principal Findings

We found that nutrient depletion or growth factor inhibitors activated autophagy in human breast cancer cells, and the increased activity of autophagy was associated with a decrease in cellular ATP and an increase in activities of AMP kinase and eEF-2 kinase. Silencing of eEF-2 kinase relieved the inhibition of protein synthesis, led to a greater reduction of cellular ATP, and blunted autophagic response. We further showed that suppression of eEF-2 kinase-regulated autophagy impeded cell growth in serum/nutrient-deprived cultures and handicapped cell survival, and enhanced the efficacy of the growth factor inhibitors such as trastuzumab, gefitinib, and lapatinib.

Conclusion/Significance

The results of this study provide new evidence that activation of eEF-2 kinase-mediated autophagy plays a protective role for cancer cells under metabolic stress conditions, and that targeting autophagic survival may represent a novel approach to enhancing the effectiveness of growth factor inhibitors.     

Nicotine Acts on Growth Plate Chondrocytes to Delay Skeletal Growth through the α7 Neuronal Nicotinic Acetylcholine Receptor

Background

Cigarette smoking adversely affects endochondral ossification during the course of skeletal growth. Among a plethora of cigarette chemicals, nicotine is one of the primary candidate compounds responsible for the cause of smoking-induced delayed skeletal growth. However, the possible mechanism of delayed skeletal growth caused by nicotine remains unclarified. In the last decade, localization of neuronal nicotinic acetylcholine receptor (nAChR), a specific receptor of nicotine, has been widely detected in non-excitable cells. Therefore, we hypothesized that nicotine affect growth plate chondrocytes directly and specifically through nAChR to delay skeletal growth.

Methodology/Principal Findings

We investigated the effect of nicotine on human growth plate chondrocytes, a major component of endochondral ossification. The chondrocytes were derived from extra human fingers. Nicotine inhibited matrix synthesis and hypertrophic differentiation in human growth plate chondrocytes in suspension culture in a concentration-dependent manner. Both human and murine growth plate chondrocytes expressed alpha7 nAChR, which constitutes functional homopentameric receptors. Methyllycaconitine (MLA), a specific antagonist of alpha7 nAChR, reversed the inhibition of matrix synthesis and functional calcium signal by nicotine in human growth plate chondrocytes in vitro. To study the effect of nicotine on growth plate in vivo, ovulation-controlled pregnant alpha7 nAChR +/− mice were given drinking water with or without nicotine during pregnancy, and skeletal growth of their fetuses was observed. Maternal nicotine exposure resulted in delayed skeletal growth of alpha7 nAChR +/+ fetuses but not in alpha7 nAChR −/− fetuses, implying that skeletal growth retardation by nicotine is specifically mediated via fetal alpha7 nAChR.

Conclusions/Significance

These results suggest that nicotine, from cigarette smoking, acts directly on growth plate chondrocytes to decrease matrix synthesis, suppress hypertrophic differentiation via alpha7 nAChR, leading to delayed skeletal growth.     

Regulation of Neuronal Autophagy in Axon: Implication of Autophagy in Axonal Function and Dysfunction/Degeneration

Autophagy has recently emerged as potential drug target for prevention of neurodegeneration. However, the details of the autophagy process and regulation in the central nervous system (CNS) are unclear. By using a neuronal excitotoxicity model in mice, we engineered expression of a fluorescent autophagic marker and systematically investigated autophagic activity under neurodegenerative conditions. The study reveals an early response of Purkinje cells to excitotoxic insult by induction of autophagy in axon terminals, and that axonal autophagy is particularly robust in comparison to the cell body and dendrites. The accessibility of axons to rapid autophagy induction suggests local biogenesis of autophagosomes in axons. Characterization of functional interaction between autophagosome protein LC3 and microtubule-associated protein 1B (MAP1B), which is involved in axonal growth, injury and transport provides evidence for neuron- or axon-specific regulation of autophagosomes. Furthermore, we propose that p62/SQSTM1, a putative autophagic substrate, can serve as a marker for evaluating impairment of autophagic degradation, which helps resolve the controversy over autophagy levels under various pathological conditions. Future study of the relationship between autophagy and axonal function (e.g., transport) will provide insight into the mechanism underlying axonopathy which is directly linked to neurodegeneration.

Addendum to:

Induction of Autophagy in Axonal Dystrophy and Degeneration

Q.J. Wang, Y. Ding, Y. Zhong, D.S. Kohtz, N. Mizushima, I.M. Cristea, M.P. Rout, B.T. Chait, N. Heintz and Z. Yue

J Neurosci 2006; 26:8057-68     

Autophagy and Cell-Death Proteases in Plants: Two Wheels of a Funeral Cart

Apoptosis is an evolutionarily young cell-death strategy evolved to disassemble animal cells through the action of the caspase family of proteases and phagocytic clearance. This strategy does not work in plants, which instead feature a phylogenetically older autophagic programmed cell death (PCD), as a bona fide type of cellular suicide. Recent work has begun to address the mechanistic roles for autophagic and proteolytic components, as well as their possible cooperation in plant PCD. A recent study has shown autophagosomal localization of a key cell-death proteolytic activity at the early stage of plant PCD. Here we focus on the relationship between autophagic and proteoloytic components in plant PCD at the cellular and organismal levels.

Addendum to:

Developmental Regulation of a VEIDase Caspase-Like Proteolytic Activity in Barley Caryopsis

M. Borén, A.S. Höglund, P. Bozhkov and C. Jansson

J Exp Bot; In press     

Localized de novo phospholipid synthesis drives autophagosome biogenesis

ABSTRACT

During (macro)autophagy, cells form transient organelles, termed autophagosomes, to target a broad spectrum of substrates for degradation critical to cellular and organismal health. Driven by rapid membrane assembly, an initially small vesicle (phagophore) elongates into a large cup-shaped structure to engulf substrates within a few minutes in a double-membrane autophagosome. In particular, how autophagic membranes expand has been a longstanding question. Here, we summarize our recent work that delineates a pathway that drives phagophore expansion by localized de novo phospholipid synthesis. Specifically, we found that the conserved acyl-CoA synthetase Faa1 localizes to nucleated phagophores to locally activate fatty acids for de novo phospholipid synthesis in the neighboring ER. These newly synthesized phospholipids are then preferentially incorporated into autophagic membranes and drive the expansion of the phagophore into a functional autophagosome. In summary, our work uncovers molecular principles of how cells coordinate phospholipid synthesis and flux with autophagic membrane formation during autophagy.

Abbreviations: ACS: acyl-CoA synthestases; CoA: coenzyme A; ER: endoplasmic reticulum