Mitochondrial energetic and AKT status mediate metabolic effects and apoptosis of metformin in human leukemic cells.

Previous reports demonstrate that metformin, an anti-diabetic drug, can decrease the risk of cancer and inhibit cancer cell growth. However, its mechanism in cancer cells is still unknown. Metformin significantly blocks cell cycle and inhibits cell proliferation and colony formation of leukemic cells. However, the apoptotic response to metformin varies. Furthermore, daily treatment with metformin induces apoptosis and reduces tumor growth in vivo. While metformin induces early and transient activation of AMPK, inhibition of AMPKα1/2 does not abrogate anti-proliferative or pro-apoptotic effects of metformin. Metformin decreases electron transport chain complex I activity, oxygen consumption and mitochondrial ATP synthesis, while stimulating glycolysis for ATP and lactate production, pentose phosphate pathway for purine biosynthesis, fatty acid metabolism, as well as anaplerotic and mitochondrial gene expression. Importantly, leukemic cells with high basal AKT phosphorylation, glucose consumption or glycolysis exhibit a markedly reduced induction of the Pasteur effect in response to metformin and are resistant to metformin-induced apoptosis. Accordingly, glucose starvation or treatment with deoxyglucose or an AKT inhibitor induces sensitivity to metformin. Overall, metformin elicits reprogramming of intermediary metabolism leading to inhibition of cell proliferation in all leukemic cells and apoptosis only in leukemic cells responding to metformin with AKT phosphorylation and a strong Pasteur effect.

TNF-alpha induced PMN apoptosis in whole human blood: protective effect of SSR180575, a potent and selective peripheral benzodiazepine ligand.

The peripheral benzodiazepine receptor (PBR) has been shown to play a key role in the regulation of the mitochondrial process leading to apoptosis. Despite much controversy in the literature on this subject, PBR synthetic ligands (and specifically agonists such as Ro5-4864 and SSR180575) are described as presenting potent anti-apoptotic effect against oxidative stress, TNFalpha- and tamoxifen-induced apoptosis when the PBR ligand is administrated at a low dose, close to the affinity range of the ligand to its receptor. Such anti-apoptotic activity has already been correlated with a protective effect of PBR ligands against ischemia-reperfusion induced tissue dysfunction. Previously, we had shown that SSR180575 is a specific and high affinity PBR ligand of potential interest in pathological cardiovascular, renal and neurodegenerative indications. Beyond its expression in steroid-producing tissues, heart, liver and kidney, the PBR is also known to be highly expressed in blood cells. In this work, we demonstrate by flow cytometry experiments, that SSR180575, at low concentrations, is able to protect polymorphonuclear leukocytes (PMNs) against TNFalpha-induced apoptosis in whole blood. Thus, in a new context, SSR180575 again shows potent anti-apoptotic properties. Moreover, TNFalpha- induced PMN apoptosis appears to be a good surrogate marker for determining SSR180575 blood availability and activity in treated patients.

Apelin/APJ signaling system: a potential link between adipose tissue and endothelial angiogenic processes.

Adipose tissue is an active endocrine organ that produces a variety of secretory factors involved in the initiation of angiogenic processes. The bioactive peptide apelin is the endogenous ligand of the G protein-coupled receptor, APJ. Here we investigated the potential role of apelin and its receptor, APJ, in the angiogenic responses of human endothelial cells and the development of a functional vascular network in a model of adipose tissue development in mice. Treatment of human umbilical vein endothelial cells with apelin dose-dependently increased angiogenic responses, including endothelial cell migration, proliferation, and Matrigel(R) capillary tubelike structure formation. These endothelial effects of apelin were due to activation of APJ, because siRNA directed against APJ, which led to long-lasting down-regulation of APJ mRNA, abolished cell migration induced by apelin in contrast to control nonsilencing siRNA. Hypoxia up-regulated the expression of apelin in 3T3F442A adipocytes, and we therefore determined whether apelin could play a role in adipose tissue angiogenesis in vivo. Epididymal white adipose tissue (EWAT) transplantation was performed as a model of adipose tissue angiogenesis. Transplantation led to increased apelin mRNA levels 2 and 5 days after transplantation associated with tissue hypoxia, as evidenced by hydroxyprobe staining on tissue sections. Graft revascularization evolved in parallel, as the first functional vessels in EWAT grafts were observed 2 days after transplantation and a strong angiogenic response was apparent on day 14. This was confirmed by determination of graft hemoglobin levels, which are indicative of functional vascularization and were strongly increased 5 and 14 days after transplantation. The role of apelin in the graft neovascularization was then assessed by local delivery of stable complex apelin-targeting siRNA leading to dramatically reduced apelin mRNA levels and vascularization (quantified by hemogloblin content) in grafted EWAT on day 5 when compared with control siRNA. Taken together, our data provide the first evidence that apelin/APJ signaling pathways play a critical role in the development of the functional vascular network in adipose tissue. In addition, we have shown that adipocyte-derived apelin can be up-regulated by hypoxia. These findings provide novel insights into the complex relationship between adipose tissue and endothelial vascular function and may lead to new therapeutic strategies to modulate angiogenesis.