Michelangelo Campanella scite author profile

Macroautophagy is an evolutionary conserved lysosomal pathway involved in the turnover of cellular macromolecules and organelles. In spite of its essential role in tissue homeostasis, the molecular mechanisms regulating mammalian macroautophagy are poorly understood. Here, we demonstrate that a rise in the free cytosolic calcium ([Ca(2+)](c)) is a potent inducer of macroautophagy. Various Ca(2+) mobilizing agents (vitamin D(3) compounds, ionomycin, ATP, and thapsigargin) inhibit the activity of mammalian target of rapamycin, a negative regulator of macroautophagy, and induce massive accumulation of autophagosomes in a Beclin 1- and Atg7-dependent manner. This process is mediated by Ca(2+)/calmodulin-dependent kinase kinase-beta and AMP-activated protein kinase and inhibited by ectopic Bcl-2 located in the endoplasmatic reticulum (ER), where it lowers the [Ca(2+)](ER) and attenuates agonist-induced Ca(2+) fluxes. Thus, an increase in the [Ca(2+)](c) serves as a potent inducer of macroautophagy and as a target for the antiautophagy action of ER-located Bcl-2.

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The autophagy-associated factors DRAM1 and p62 regulate cell migration and invasion in glioblastoma stem cells

Galavotti¹,

Bartesaghi²,

et al. 2012

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The aggressiveness of glioblastoma multiforme (GBM) is defined by local invasion and resistance to therapy. Within established GBM, a subpopulation of tumor-initiating cells with stem-like properties (GBM stem cells, GSCs) is believed to underlie resistance to therapy. The metabolic pathway autophagy has been implicated in the regulation of survival in GBM. However, the status of autophagy in GBM and its role in the cancer stem cell fraction is currently unclear. We found that a number of autophagy regulators are highly expressed in GBM tumors carrying a mesenchymal signature, which defines aggressiveness and invasion, and are associated with components of the MAPK pathway. This autophagy signature included the autophagy-associated genes DRAM1 and SQSTM1, which encode a key regulator of selective autophagy, p62. High levels of DRAM1 were associated with shorter overall survival in GBM patients. In GSCs, DRAM1 and SQSTM1 expression correlated with activation of MAPK and expression of the mesenchymal marker c-MET. DRAM1 knockdown decreased p62 localization to autophagosomes and its autophagy-mediated degradation, thus suggesting a role for DRAM1 in p62-mediated autophagy. In contrast, autophagy induced by starvation or inhibition of mTOR/PI-3K was not affected by either DRAM1 or p62 downregulation. Functionally, DRAM1 and p62 regulate cell motility and invasion in GSCs. This was associated with alterations of energy metabolism, in particular reduced ATP and lactate levels. Taken together, these findings shed new light on the role of autophagy in GBM and reveal a novel function of the autophagy regulators DRAM1 and p62 in control of migration/invasion in cancer stem cells.

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Inorganic Polyphosphate and Energy Metabolism in Mammalian Cells

Pavlov

Aschar‐Sobbi

Campanella

et al. 2010

Journal of Biological Chemistry

164

177

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Inorganic polyphosphate (poly P) is a polymer made from as few as 10 to several hundred phosphate molecules linked by phosphoanhydride bonds similar to ATP. Poly P is ubiquitous in all mammalian organisms, where it plays multiple physiological roles. The metabolism of poly P in mammalian organisms is not well understood. We have examined the mechanism of poly P production and the role of this polymer in cell energy metabolism. Poly P levels in mitochondria and intact cells were estimated using a fluorescent molecular probe, 4,6-diamidino-2-phenylindole. Poly P levels were dependent on the metabolic state of the mitochondria. Poly P levels were increased by substrates of respiration and in turn reduced by mitochondrial inhibitor (rotenone) or an uncoupler (carbonyl cyanide p-trifluoromethoxyphenylhydrazone). Oligomycin, an inhibitor of mitochondrial ATP-synthase, blocked the production of poly P. Enzymatic depletion of poly P from cells significantly altered the rate of ATP metabolism. We propose the existence of a feedback mechanism where poly P production and cell energy metabolism regulate each other. Inorganic polyphosphate (poly P)2 is found in all living organisms ranging from bacteria to mammals (1). Poly P performs multiple physiological functions, which are distinct and dependent on the type of organism and the subcellular localization of the polymer. In microorganisms, poly P primarily plays a role in transcription. Additionally, poly P serves as an energy store (2) and as a reserve pool of inorganic phosphates (3). However, in mammalian organisms, poly P plays predominantly a regulatory role (4) and has been implicated in the regulation of enzyme activity in cancer cells (5), stimulation of blood coagulation (6), regulation of mitochondrial ion transport (7), and regulation of respiratory chain activity (8).Although a specific enzyme(s) responsible for poly P production in mammals is currently not known (1), poly P synthesis has been detected in intact mammalian cells. Lysis of mammalian cells leads to loss of poly P synthesis activity, suggesting that poly P synthesis in mammalian cells is likely an energy-dependent process linked to membrane transport and integrity (1, 9). Taking into account that the membrane potential generated at the mitochondrial inner membrane is a major energy source for cellular metabolism, we hypothesized that mitochondria may be the likely source of poly P production in mammalian cells.Poly P is found in mammalian cells at significantly lower levels when compared with microorganisms (9); therefore, it is very difficult to adapt poly P measurement methods developed for bacterial studies for the study of mammalian cells. Recently we developed a protocol, which we optimized for suitability for measuring low amounts of poly P using the fluorescent probe 4Ј,6-diamidino-2-phenylindole (DAPI) (10). In our previous study we used this method to confirm poly P hydrolyzing activity of yeast polyphosphatase expressed in mitochondria of mammalian cultured cells (8). Here we take advantag...

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