EGFR signaling promotes basal autophagy for lipid homeostasis and somatic stem cell maintenance in the Drosophila testis

ABSTRACT

In contrast to stress-induced macroautophagy/autophagy that happens during nutrient deprivation and other environmental challenges, basal autophagy is thought to be an important mechanism that cells utilize for homeostatic purposes. For instance, basal autophagy is used to recycle damaged and malfunctioning organelles and proteins to provide the building blocks for the generation of new ones throughout life. In addition, specialized autophagic processes, such as lipophagy, the autophagy-induced breakdown of lipid droplets (LDs), and glycophagy (breakdown of glycogen), are employed to maintain proper energy levels in the cell. The importance of autophagy in the regulation of stem cell behavior has been the focus of recent studies. However, the upstream signals that control autophagic activity in stem cells and the precise role of autophagy in stem cells are only starting to be elucidated. In a recent publication, we described how the Egfr (epidermal growth factor receptor) pathway stimulates basal autophagy to support the maintenance of somatic cyst stem cells (CySCs) and to control lipid levels in the Drosophila testis.     

AMPKα promotes basal autophagy induction in Dictyostelium discoideum

Autophagy is a degradation process, wherein long-lived proteins, damaged organelles, and protein aggregates are degraded to maintain cellular homeostasis. Upon starvation, 5′-AMP-activated protein kinase (AMPK) initiates autophagy. We show that ampkα⁻ cells exhibit 50% reduction in pinocytosis and display defective phagocytosis. Re-expression of AMPKα in ampkα⁻ cells co-localizes with red fluorescence protein-tagged bacteria. The ampkα⁻ cells show reduced cell survival and autophagic flux under basal and starvation conditions. Co-immunoprecipitation studies show conservation of the AMPK–ATG1 axis in basal autophagy. Computational analyses suggest that the N-terminal region of DdATG1 is amenable for interaction with AMPK. Furthermore, β-actin was found to be a novel interacting partner of AMPK, attributed to the alteration in macropinocytosis and phagocytosis in the absence of AMPK. Additionally, ampkα⁻ cells exhibit enhanced poly-ubiquitinated protein levels and allied large ubiquitin-positive protein aggregates. Our findings suggest that AMPK provides links among pinocytosis, phagocytosis, autophagy, and is a requisite for basal autophagy in Dictyostelium.     

MicroRNA targets autophagy in pancreatic cancer cells during cancer therapy

The therapeutic outcome of pancreatic cancer is generally poor due to the inherent or acquired resistance of cancer cells to treatment. Pancreatic cancer cells have higher basal autophagy levels than other cancer cell types, which may correlate with their nonresponsiveness to the available cancer therapy. Therefore, understanding the mechanisms behind autophagy activation in pancreatic cancer cells may ultimately improve therapeutic outcomes. Here we demonstrated that MIR23B is a potent inhibitor of autophagy. MIR23B targets the 3′UTR of the autophagy-related gene ATG12, thereby decreasing autophagic activity and ultimately promoting radiation-induced pancreatic cancer cell death. Thus, our study clarified some of the underlying molecular mechanisms of activated autophagy in response to cancer therapy in pancreatic cancer.     

Selective autophagy gets more selective: Uncoupling of autophagy flux and xenophagy flux in Mycobacterium tuberculosis-infected macrophages

Induction of autophagy has been reported as a potential means to eliminate intracellular pathogens. Corroborating that, many studies report inhibition of autophagy as a survival strategy of bacterial pathogens. Incidentally, autophagy at the basal level is critical for survival of host cells including macrophages. We asked how a bacterial pathogen could inhibit autophagy for its survival if the inhibition resulted in cell death. In a recent study we show distinct regulation of autophagy in Mycobacterium tuberculosis (Mtb)-infected macrophages where Mtb containing- and nonMtb-containing autophagosomes show different fates in terms of maturation. We show that upon Mtb infection, there is no dramatic change in the autophagy flux in macrophages. However, autophagosomes that contain the virulent strains of Mtb show selective resilience to the maturation phase of autophagy. Surprisingly, nonMtb-containing autophagosomes in the infected cells continue to mature into autolysosomes. The block in the xenophagy flux is missing in the case of avirulant infections. We show that this selectivity is achieved through selective exclusion of RAB7 from virulent Mtb-containing autophagosomes, thereby restricting the formation of amphisomes.     

Role of OSGIN1 in mediating smoking-induced autophagy in the human airway epithelium

Enhanced macroautophagy/autophagy is recognized as a component of the pathogenesis of smoking-induced airway disease. Based on the knowledge that enhanced autophagy is linked to oxidative stress and the DNA damage response, both of which are linked to smoking, we used microarray analysis of the airway epithelium to identify smoking upregulated genes known to respond to oxidative stress and the DNA damage response. This analysis identified OSGIN1 (oxidative stress induced growth inhibitor 1) as significantly upregulated by smoking, in both the large and small airway epithelium, an observation confirmed by an independent small airway microarray cohort, TaqMan PCR of large and small airway samples and RNA-Seq of small airway samples. High and low OSGIN1 expressors have different autophagy gene expression patterns in vivo. Genome-wide correlation of RNAseq analysis of airway basal/progenitor cells showed a direct correlation of OSGIN1 mRNA levels to multiple classic autophagy genes. In vitro cigarette smoke extract exposure of primary airway basal/progenitor cells was accompanied by a dose-dependent upregulation of OSGIN1 and autophagy induction. Lentivirus-mediated expression of OSGIN1 in human primary basal/progenitor cells induced puncta-like staining of MAP1LC3B and upregulation of MAP1LC3B mRNA and protein and SQSTM1 mRNA expression level in a dose and time-dependent manner. OSGIN1-induction of autophagosome, amphisome and autolysosome formation was confirmed by colocalization of MAP1LC3B with SQSTM1 or CD63 (endosome marker) and LAMP1 (lysosome marker). Both OSGIN1 overexpression and knockdown enhanced the smoking-evoked autophagic response. Together, these observations support the concept that smoking-induced upregulation of OSGIN1 is one link between smoking-induced stress and enhanced-autophagy in the human airway epithelium.     

Systemic regulation of autophagy in Caenorhabditis elegans

When no supply of environmental nutrients is available, cells induce autophagy, thereby generating a source of emergency metabolic substrates and energy to maintain the basal cellular activity needed for survival. This autophagy response to starvation has been well characterized in various multicellular organisms, including worms, flies, and mice. Although prosurvival effects of autophagy in response to starvation are well known in animals, the mechanisms by which animals regulate and coordinate autophagy systemically remain elusive. Using C. elegans as a model system, we found that specific amino acids could regulate starvation-induced autophagy, and that MGL-1 and MGL-2, Caenorhabditis elegans homologs of metabotropic glutamate receptors, were involved. MGL-1 and MGL-2 specifically acted in AIY and AIB neurons, respectively, to modulate the autophagy response in other tissues such as pharyngeal muscle. Our recent study suggests that the autophagy response to starvation, previously thought to be cell-autonomous, can be systemically regulated, and that there is a specific sensor for monitoring systemic amino acids levels in Caenorhabditis elegans.     

Autophagy Genes Protect Against Disease Caused by Polyglutamine Expansion Proteins in Caenorhabditis elegans

Expanded polyglutamine (polyQ) proteins aggregate intracellularly in Huntington’s disease and other neurodegenerative disorders. The lysosomal degradation pathway, autophagy, is known to promote clearance of polyQ protein aggregates in cultured cells. Moreover, basal autophagy in neuronal cells in mice prevents neurodegeneration by suppressing the accumulation of abnormal intracellular proteins. However, it is not yet known whether autophagy genes play a role in vivo in protecting against disease caused by mutant aggregate-prone, expanded polyQ proteins. To examine this question, we used two models of polyQ-induced toxicity in C. elegans, including the expression of polyQ40 aggregates in muscle and the expression of a human huntingtin disease fragment containing a polyQ tract of 150 residues (Htn-Q150) in ASH sensory neurons. Here, we show that genetic inactivation of autophagy genes accelerates the accumulation of polyQ40 aggregates in C. elegans muscle cells and exacerbates polyQ40-induced muscle dysfunction. Autophagy gene inactivation also increases the accumulation of Htn-Q150 aggregates in C. elegans ASH sensory neurons and results in enhanced neurodegeneration. These data provide in vivo genetic evidence that autophagy genes suppress the accumulation of polyQ aggregates and protect cells from disease caused by polyQ toxicity.     

p65/RelA binds and activates the beclin 1 promoter

We unveiled novel p65/RelA consensus sites in the promoter of the beclin 1 gene and demonstrate that p65/RelA positively modulates canonical autophagy in various human cell lines both under basal conditions and upon induction by ceramide. Interestingly, we find that T cell receptor-dependent activation of Jurkat cells triggers an increase in the binding of p65/RelA to the beclin 1 promoter accompanied by enhanced autophagy, suggesting that p65/RelA could regulate T-cell activation and homeostasis through autophagy.     

Berberine attenuates autophagy in adipocytes by targeting BECN1

The lysosomal degradation pathway, autophagy, is essential for the maintenance of cellular homeostasis. Recently, autophagy has been demonstrated to be required in the process of adipocyte conversion. However, its role in mature adipocytes under physiological and pathological conditions remains unclear. Here, we report a major function of BECN1 in the regulation of basal autophagy in mature adipocytes. We also show that berberine, a natural plant alkaloid, inhibits basal autophagy in adipocytes and adipose tissue of mice fed a high-fat diet via downregulation of BECN1 expression. We further demonstrate that berberine has a pronounced effect on the stability of Becn1 mRNA through the Mir30 family. These findings explore the potential of BECN1 as a key molecule and a drug target for regulating autophagy in mature adipocytes.     

Role for DUSP1 (dual-specificity protein phosphatase 1) in the regulation of autophagy

Accumulating evidence suggests that mitogen-activated protein kinases (MAPKs) regulate macroautophagy/autophagy. However, the involvement of dual-specificity protein phosphatases (DUSPs), endogenous inhibitors for MAPKs, in autophagy remains to be determined. Here we report that DUSP1/MKP-1, the founding member of the DUSP family, plays a critical role in regulating autophagy. Specifically, we demonstrate that DUSP1 knockdown by shRNA in human ovarian cancer CAOV3 cells and knockout in murine embryonic fibroblasts, increases both basal and rapamycin-increased autophagic flux. Overexpression of DUSP1 had the opposite effect. Importantly, knockout of Dusp1 promoted phosphorylation of ULK1 at Ser555, and BECN1/Beclin 1 at Ser15, and the association of PIK3C3/VPS34, ATG14, BECN1 and MAPK, leading to the activation of the autophagosome-initiating class III phosphatidylinositol 3-kinase (PtdIns3K) complex. Furthermore, knockdown and pharmacological inhibitor studies indicated that DUSP1-mediated suppression of autophagy reflected inactivation of the MAPK1-MAPK3 members of the MAPK family. Knockdown of DUSP1 sensitized CAOV3 cells to rapamycin-induced antigrowth activity. Moreover, CAOV3-CR cells, a line that had acquired cisplatin resistance, exhibited an elevated DUSP1 level and were refractory to rapamycin-induced autophagy and cytostatic effects. Knockdown of DUSP1 in CAOV3-CR cells restored sensitivity to rapamycin. Collectively, this work identifies a previously unrecognized role for DUSP1 in regulating autophagy and suggests that suppression of DUSP1 may enhance the therapeutic activity of rapamycin.     

Stimulation of autophagy suppresses the intracellular survival of Burkholderia pseudomallei in mammalian cell lines

Burkholderia pseudomallei is the causative agent of melioidosis, a tropical infection of humans and other animals. The bacterium is an intracellular pathogen that can escape from endosomes into the host cytoplasm, where it replicates and infects adjacent cells. We investigated the role played by autophagy in the intracellular survival of B. pseudomallei in phagocytic and non-phagocytic cell lines. Autophagy was induced in response to B. pseudomallei invasion of murine macrophage (RAW 264.7) cells and a proportion of the bacteria co-localized with the autophagy effector protein LC3, a marker for autophagosome formation. Pharmacological stimulation of autophagy in RAW 264.7 and murine embryonic fibroblast (MEF) cell lines resulted in increased co-localization of B. pseudomallei with LC3 while basal levels of co-localization could be abrogated using inhibitors of the autophagic pathway. Furthermore, induction of autophagy decreased the intracellular survival of B. pseudomallei in these cell lines, but bacterial survival was not affected in MEF cell lines deficient in autophagy. Treatment of infected macrophages with chloramphenicol increased the proportion of bacteria within autophagosomes indicating that autophagic evasion is an active process relying on bacterial protein synthesis. Consistent with this hypothesis, we identified a B. pseudomallei type III secreted protein, BopA, which plays a role in mediating bacterial evasion of autophagy. We conclude that the autophagic pathway is a component of the innate defense system against invading B. pseudomallei, but which the bacteria can actively evade. However, when autophagy is pharmacologically induced using rapamycin, bacteria are actively sequestered in autophagosomes, ultimately decreasing their survival.     

CUP-5, the C. elegans ortholog of the mammalian lysosomal channel protein MLN1/TRPML1, is required for proteolytic degradation in autolysosomes

The process of macroautophagy (herein referred to as autophagy) involves the formation of a closed double-membrane structure, called the autophagosome, and its subsequent fusion with lysosomes to form an autolysosome. Lysosomes are regenerated from autolysosomes after degradation of the sequestrated materials. In this study, we showed that mutations in cup-5, encoding the C. elegans Mucolipin 1 homolog, cause defects in the autophagy pathway. In cup-5 mutants, a variety of autophagy substrates accumulate in enlarged vacuoles that display characteristics of late endosomes and lysosomes, indicating defective proteolytic degradation in autolysosomes. We further revealed that lysosomes in coelomocytes (scavenger cells located in the body cavity) are smaller in size and more numerous in mutants with loss of autophagy activity. Furthermore, the enlarged vacuole accumulation abnormality and embryonic lethality of cup-5 mutants are partially suppressed by reduced autophagy activity. Our results indicate that the basal constitutive level of autophagy activity regulates the size and number of lysosomes and provides insights into the molecular mechanisms underlying mucolipidosis type IV disease.     

Atg5 and Ambra1 differentially modulate neurogenesis in neural stem cells

Neuroepithelial cells undergoing differentiation efficiently remodel their cytoskeleton and shape in an energy-consuming process. The capacity of autophagy to recycle cellular components and provide energy could fulfill these requirements, thus supporting differentiation. However, little is known regarding the role of basal autophagy in neural differentiation. Here we report an increase in the expression of the autophagy genes Atg7, Becn1, Ambra1 and LC3 in vivo in the mouse embryonic olfactory bulb (OB) during the initial period of neuronal differentiation at E15.5, along with a parallel increase in neuronal markers. In addition, we observed an increase in LC3 lipidation and autophagic flux during neuronal differentiation in cultured OB-derived stem/progenitor cells. Pharmacological inhibition of autophagy with 3-MA or wortmannin markedly decreased neurogenesis. These observations were supported by similar findings in two autophagy-deficient genetic models. In Ambra1 loss-of-function homozygous mice (gt/gt) the expression of several neural markers was decreased in the OB at E13.5 in vivo. In vitro, Ambra1 haploinsufficient cells developed as small neurospheres with an impaired capacity for neuronal generation. The addition of methylpyruvate during stem/progenitor cell differentiation in culture largely reversed the inhibition of neurogenesis induced by either 3-MA or Ambra1 haploinsufficiency, suggesting that neural stem/progenitor cells activate autophagy to fulfill their high energy demands. Further supporting the role of autophagy for neuronal differentiation Atg5-null OB cells differentiating in culture displayed decreased TuJ1 levels and lower number of cells with neurites. These results reveal new roles for autophagy-related molecules Atg5 and Ambra1 during early neuronal differentiation of stem/progenitor cells.     

Impaired autophagy due to constitutive mTOR activation sensitizes TSC2-null cells to cell death under stress

It has been well documented that cells deficient in either TSC1 or TSC2 are highly sensitive to various cell death stimuli. In this study, we utilized the TSC2^-/- mouse embryonic fibroblasts (MEFs) to study the involvement of autophagy in the enhanced susceptibility of TSC2-null cells to cell death. We first confirmed that both TSC1-null and TSC2-null MEFs are more sensitive to apoptosis in response to amino acid starvation (EBSS) and hypoxia. Second, we found that both the basal and inducible autophagy in TSC2^-/- MEFs is impaired, mainly due to constitutive activation of mTORC1. Third, suppression of autophagy by chloroquine and Atg7 knockdown sensitizes TSC2^+/+ cells, but not TSC2^-/- cells, to EBSS-induced cell death. Conversely, the inhibition of mTORC1 by raptor knockdown and rapamycin activates autophagy and subsequently rescues TSC2^-/- cells. Finally, in starved cells, nutrient supplementations (insulin-like growth factor-1 (IGF-1) and leucine) enhanced cell death in TSC2^-/- cells, but reduced cell death in TSC2^+/+ cells. Taken together, these data indicate that constitutive activation of mTORC1 in TSC2^-/- cells leads to suppression of autophagy and enhanced susceptibility to stress-mediated cell death. Our findings thus provide new insights into the complex relationships among mTOR, autophagy and cell death, and support the possible autophagy-targeted intervention strategies for the treatment of TSC-related pathologies.     

Suppression of basal autophagy reduces lung cancer cell proliferation and enhances caspase-dependent and -independent apoptosis by stimulating ROS formation

Autophagy is a catabolic process involved in the turnover of organelles and macromolecules which, depending on conditions, may lead to cell death or preserve cell survival. We found that some lung cancer cell lines and tumor samples are characterized by increased levels of lipidated LC3. Inhibition of autophagy sensitized non-small cell lung carcinoma (NSCLC) cells to cisplatin-induced apoptosis; however, such response was attenuated in cells treated with etoposide. Inhibition of autophagy stimulated ROS formation and treatment with cisplatin had a synergistic effect on ROS accumulation. Using genetically encoded hydrogen peroxide probes directed to intracellular compartments we found that autophagy inhibition facilitated formation of hydrogen peroxide in the cytosol and mitochondria of cisplatin-treated cells. The enhancement of cell death under conditions of inhibited autophagy was partially dependent on caspases, however, antioxidant NAC or hydroxyl radical scavengers, but not the scavengers of superoxide or a MnSOD mimetic, reduced the release of cytochrome c and abolished the sensitization of the cells to cisplatin-induced apoptosis. Such inhibition of ROS prevented the processing and release of AIF (apoptosis-inducing factor) and HTRA2 from mitochondria. Furthermore, suppression of autophagy in NSCLC cells with active basal autophagy reduced their proliferation without significant effect on the cell-cycle distribution. Inhibition of cell proliferation delayed accumulation of cells in the S phase upon treatment with etoposide that could attenuate the execution stage of etoposide-induced apoptosis. These findings suggest that autophagy suppression leads to inhibition of NSCLC cell proliferation and sensitizes them to cisplatin-induced caspase-dependent and -independent apoptosis by stimulation of ROS formation.     

A fine-tuning mechanism underlying self-control for autophagy: deSUMOylation of BECN1 by SENP3

ABSTRACT

The roles of SUMOylation and the related enzymes in autophagic regulation are unclear. Based on our previous studies that identified the SUMO2/3-specific peptidase SENP3 as an oxidative stress-responsive molecule, we investigated the correlation between SUMOylation and macroautophagy/autophagy. We found that Senp3^± mice showed increased autophagy in the liver under basal and fasting conditions, compared to Senp3^+/+ mice. We constructed a liver-specific senp3 knockout mouse; these Senp3-deficient liver tissues showed increased autophagy as well. Autophagic flux was accelerated in hepatic and other cell lines following knockdown of SENP3, both before and after the cells underwent starvation in the form of the serum and amino acid deprivation. We demonstrated that BECN1/beclin 1, the core molecule of the BECN1-PIK3C3 complex, could be SUMO3-conjugated by PIAS3 predominantly at K380 and deSUMOylated by SENP3. The basal SUMOylation of BECN1 was increased upon cellular starvation, which enhanced autophagosome formation by facilitating BECN1 interaction with other complex components UVRAG, PIK3C3 and ATG14, thus promoting PIK3C3 activity. In contrast, SENP3 deSUMOylated BECN1, which impaired BECN1-PIK3C3 complex formation or stability to suppress the PIK3C3 activity. DeSUMOylation of BECN1 restrained autophagy induction under basal conditions and especially upon starvation when SENP3 had accumulated in response to the increased generation of reactive oxygen species. Thus, while reversible SUMOylation regulated the degree of autophagy, SENP3 provided an intrinsic overflow valve for fine-tuning autophagy induction.     

Azacitidine-resistant SKM1 myeloid cells are defective for AZA-induced mitochondrial apoptosis and autophagy

Azacitidine (AZA) is the current treatment for patients with high-risk myelodysplastic syndrome, but resistance is a common feature of AZA-treated patients. To investigate the mechanisms associated with AZA resistance in vitro, we generated AZA-resistant SKM1 myeloid cells, called hereafter AZA-R. AZA-R cells exhibit impaired mitochondrial membrane permeabilization and caspase activation in response to AZA compared to their AZA-sensitive (AZA-S) counterpart. AZA induced LC3-II accumulation and cathepsin B activity in AZA-S cells, two hallmarks of autophagy. AZA-R cells displayed increased basal autophagy but are resistant to AZA-mediated autophagy. Inhibition of autophagy using LC3 siRNA revealed that autophagy is protective in AZA-S cells and AZA-R cells in basal conditions. By contrast, AZA-R cells exhibited impaired autophagy in response to AZA. Collectively, our findings indicate that AZA promotes apoptosis and autophagy in SKM1 cells, and that AZA-R cells are resistant to both apoptosis and autophagy induced by AZA.     

HMGB1 is involved in autophagy inhibition caused by SNCA/α-synuclein overexpression

SNCA/α-synuclein and its rare mutations are considered as the culprit proteins in Parkinson disease (PD). Wild-type (WT) SNCA has been shown to impair macroautophagy in mammalian cells and in transgenic mice. In this study, we monitored the dynamic changes in autophagy process and confirmed that overexpression of both WT and SNCA^A53T inhibits autophagy in PC12 cells in a time-dependent manner. Furthermore, we showed that SNCA binds to both cytosolic and nuclear high mobility group box 1 (HMGB1), impairs the cytosolic translocation of HMGB1, blocks HMGB1-BECN1 binding, and strengthens BECN1-BCL2 binding. Deregulation of these molecular events by SNCA overexpression leads to autophagy inhibition. Overexpression of BECN1 restores autophagy and promotes the clearance of SNCA. siRNA knockdown of Hmgb1 inhibits basal autophagy and abolishes the inhibitory effect of SNCA on autophagy while overexpression of HMGB1 restores autophagy. Corynoxine B, a natural autophagy inducer, restores the deficient cytosolic translocation of HMGB1 and autophagy in cells overexpressing SNCA, which may be attributed to its ability to block SNCA-HMGB1 interaction. Based on these findings, we propose that SNCA-induced impairment of autophagy occurs, in part, through HMGB1, which may provide a potential therapeutic target for PD.