Loss of Parkin, encoded by PARK2 gene, is a major cause of autosomal recessive Parkinson's disease. In Drosophila and mammalian cell models Parkin has been shown in to play a role in various processes essential to maintenance of mitochondrial quality, including mitochondrial dynamics, biogenesis and degradation. However, the relevance of altered mitochondrial quality control mechanisms to neuronal survival in vivo is still under debate. We addressed this issue in the brain of PARK2−/− mice using an integrated mitochondrial evaluation, including analysis of respiration by polarography or by fluorescence, respiratory complexes activity by spectrophotometric assays, mitochondrial membrane potential by rhodamine 123 fluorescence, mitochondrial DNA content by real time PCR, and oxidative stress by total glutathione measurement, proteasome activity, SOD2 expression and proteins oxidative damage. Respiration rates were lowered in PARK2 −/− brain with high resolution but not standard respirometry. This defect was specific to the striatum, where it was prominent in neurons but less severe in astrocytes. It was present in primary embryonic cells and did not worsen in vivo from 9 to 24 months of age. It was not associated with any respiratory complex defect, including complex I. Mitochondrial inner membrane potential in PARK2−/− mice was similar to that of wild-type mice but showed increased sensitivity to uncoupling with ageing in striatum. The presence of oxidative stress was suggested in the striatum by increased mitochondrial glutathione content and oxidative adducts but normal proteasome activity showed efficient compensation. SOD2 expression was increased only in the striatum of PARK2−/− mice at 24 months of age. Altogether our results show a tissue-specific mitochondrial defect, present early in life of PARK2−/− mice, mildly affecting respiration, without prominent impact on mitochondrial membrane potential, whose underlying mechanisms remain to be elucidated, as complex I defect and prominent oxidative damage were ruled out.
BACKGROUND AND PURPOSEParkinson's disease (PD) is usually diagnosed clinically from classical motor symptoms, while definitive diagnosis is made postmortem, based on the presence of Lewy bodies and nigral neuron cell loss. α-Synuclein (ASYN), the main protein component of Lewy bodies, clearly plays a role in the neurodegeneration that characterizes PD. Additionally, mutation in the SNCA gene or copy number variations are associated with some forms of familial PD. Here, the objective of the study was to evaluate whether olesoxime, a promising neuroprotective drug can prevent ASYN-mediated neurotoxicity. EXPERIMENTAL APPROACHWe used here a novel, mechanistically approachable and attractive cellular model based on the inducible overexpression of human wild-type ASYN in neuronally differentiated human neuroblastoma (SHSY-5Y) cells. This model demonstrates gradual cellular degeneration, coinciding temporally with the appearance of soluble and membrane-bound ASYN oligomers and cell death combining both apoptotic and non-apoptotic pathways. KEY RESULTSOlesoxime fully protected differentiated SHSY-5Y cells from cell death, neurite retraction and cytoplasmic shrinkage induced by moderate ASYN overexpression. This protection was associated with a reduction in cytochrome c release from mitochondria and caspase-9 activation suggesting that olesoxime prevented ASYN toxicity by preserving mitochondrial integrity and function. In addition, olesoxime displayed neurotrophic effects on neuronally differentiated SHSY-5Y cells, independent of ASYN expression, by promoting their differentiation. CONCLUSIONS AND IMPLICATIONSBecause ASYN is a common underlying factor in many cases of PD, olesoxime could be a promising therapy to slow neurodegeneration in PD.
CD73 (NT5E) is a cell membrane ectoenzyme of the NTPDase family that plays a major role in the conversion of AMP into Adenosine (Ado). Within the tumor microenvironment, accumulation of Ado causes immune suppression and dysregulation of immune cell infiltrates resulting in tumor spreading. CD73 expression in the tumor environment has been associated with poor disease outcome and/or with a pro-metastatic phenotype. Thus, targeting CD73 may promote anti-tumor immunity by reducing Ado accumulation and may block tumor cell metastasis by inhibiting CD73 on tumor cells. Here, we describe the generation and characterization of novel anti-human CD73 antibodies, intended for the treatment of a wide range of cancers. The research leading to these results has received funding from the European Community's Seventh Framework Program (FP7/2007-2013) under grant agreement n°602200. Antibodies were discovered that inhibited CD73 function by different mechanisms, including the direct blocking of CD73 enzymatic activity or the down-modulation of membrane CD73 expression. Epitope mapping revealed that antibodies acting by these different modes of action bound to distinct sites on CD73. All selected antibodies cross-react with cynomolgus CD73 protein and have strong avidity and affinity for membrane or recombinant CD73, by flow cytometry and Surface Plasmon Resonance, respectively. Antibodies that inhibit CD73 enzymatic activity strongly reduce AMP catabolism by both recombinant and cellular CD73 with IC50 in the nanomolar range. They also efficiently reverse ATP- and AMP-mediated T cell suppression in in vitro assays in presence of both CD39+ and CD73+ cells. The antibodies that induce down-modulation of cellular CD73 expression do not block recombinant CD73 enzyme activity and partially inhibit cellular CD73 activity; they reverse ATP- but not AMP-dependent T cell suppression. The antibodies displaying the most interesting features were humanized. Evaluation of their activity in animal models is ongoing. Citation Format: Marc Giraudon Paoli, Severine Augier, Marilyne Royannez Blemont, Céline Rodriguez, Hélène Rispaud Blanc, Stéphanie Chanteux, Nicolas Gourdin, Laurent Gauthier, Christine Ménétrier Caux, Yannis Morel, Christophe Caux, Carine Paturel, Ivan Perrot. Discovery and characterization of new original blocking antibodies targeting the CD73 immune checkpoint for cancer immunotherapy. [abstract]. In: Proceedings of the 107th Annual Meeting of the American Association for Cancer Research; 2016 Apr 16-20; New Orleans, LA. Philadelphia (PA): AACR; Cancer Res 2016;76(14 Suppl):Abstract nr 2344.
Within the tumor microenvironment, adenosine causes immune suppression and dysregulation of immune cell infiltrates resulting in tumor spreading. Adenosine accumulation results from the hydrolysis of extracellular immunoactivating ATP and ADP into AMP by the CD39 (ENTPD1) ectonucleotidase. AMP can be further hydrolyzed into immunosuppressive Adenosine (Ado) by CD73 (NT5E), a cell membrane ectonucleotidase of the NTPDase family.The immunosuppressive role of CD39 expressed on both Tregs and tumor cells has been demonstrated in several reports. Conversely, CD73 expression in the tumor environment has been associated with poor disease outcome and/or with a pro-metastatic phenotype. Blockade of CD39 and CD73 may promote anti-tumor immunity directly by accumulating immunostimulating ATP for CD39 and indirectly by reducing adenosine accumulation for both targets.In cancer tissue, using IHC and flow cytometry analyses, we observed that while CD73 is often expressed by tumor cells, CD39 is more frequently up-regulated on tumor infiltrating cells compared to PBMC or adjacent non-tumor tissue. We next describe the discovery and preclinical development of a unique anti-huCD39 blocking antibody and of an anti-human CD73 antibody for cancer immunotherapy. These anti-CD39 and anti-CD73 antibodies specifically bind with high affinity to huCD39 and huCD73 proteins, respectively. They potently inhibit enzyme activity of their respective targets under their soluble and membrane-associated forms, without inducing down-modulation of these enzymes expressed at the cell surface. Innate's antibodies efficiently reverse Ado-mediated T cell suppression in vitro in presence of ATP and both CD39- and CD73-expressing immune cells and additionally exhibit unique features. The anti-CD39 Ab maintains high concentration of ATP in the extracellular compartment that enhances DC activation and subsequent T cell proliferation in vitro. The anti-CD73 blocking Ab exhibits a more potent ability to block soluble and membrane-associated CD73 enzyme activity than benchmark Abs currently in clinical development. Finally, in vivo blockade of ATP/Ado pathway in CD39ko mice resulted in improved anti-tumor efficacy of immunogenic cell death inducer chemotherapy and of immune checkpoint therapies, including PD1 and CTLA4.Taken together, these data support the clinical development of anti-CD39 and anti-CD73 neutralizing Abs for cancer immunotherapy, potentially in combination with chemotherapy or Immune Checkpoint therapy. The humanized anti-huCD39 and anti-huCD73 monoclonal antibodies are currently in preclinical development.The research leading to CD73 results were obtained within the TumAdoR collaborative consortium that received funding from the European Community's Seventh Framework Program (FP7/2007-2013) under grant agreement n°602200. Citation Format: Ivan Perrot, Marc Giraudon Paoli, Séverine Augier, Marilyne Royannez Blemont, Marion Gaudin, Frédéric Bosco, Rachel Courtois, Stephane Delahaye, Diana Jecko, Nicolas Gourdin, Maryline Salin Agu, Cyril Perrier, Paul Ricaut, Aurélie Docquier, Stéphanie Chanteux, Benjamin Rossi, Agnès Représa, Caroline Denis, Romain Remark, Cécile Bonnafous, Laurent Gauthier, Ariane Morel, Nathalie Bonnefoy, Jérémy Bastid, Yannis Morel, Carine Paturel. Preclinical development of humanized CD39 and CD73 blocking antibodies targeting the ATP/adenosine immune checkpoint pathway for cancer immunotherapy [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2018; 2018 Apr 14-18; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2018;78(13 Suppl):Abstract nr 2718.
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