Cell proliferation in pancreatic cancer is determined by a complex network of signaling pathways. Despite the extensive understanding of these protein-mediated signaling processes, there are no significant drug discoveries that could considerably improve a patient’s survival. However, the recent understanding of lipid-mediated signaling gives a new perspective on the control of the physiological state of pancreatic cells. Lipid signaling plays a major role in the induction of cytocidal autophagy and can be exploited using synthetic lipids to induce cell death in pancreatic cancer cells. In this work, we studied the activity of a synthetic lipid, tri-2-hydroxyarachidonein (TGM4), which is a triacylglycerol mimetic that contains three acyl moieties with four double bonds each, on cellular and in vivo models of pancreatic cancer. We demonstrated that TGM4 inhibited proliferation of Mia-PaCa-2 (human pancreatic carcinoma) and PANC-1 (human pancreatic carcinoma of ductal cells) in in vitro models and in an in vivo xenograft model of Mia-PaCa-2 cells. In vitro studies demonstrated that TGM4 induced cell growth inhibition paralleled with an increased expression of PARP and CHOP proteins together with the presence of sub-G0 cell cycle events, indicating cell death. This cytocidal effect was associated with elevated ER stress or autophagy markers such as BIP, LC3B, and DHFR. In addition, TGM4 activated peroxisome proliferator-activated receptor gamma (PPAR-γ), which induced elevated levels of p-AKT and downregulation of p-c-Jun. We conclude that TGM4 induced pancreatic cell death by activation of cytocidal autophagy. This work highlights the importance of lipid signaling in cancer and the use of synthetic lipid structures as novel and potential approaches to treat pancreatic cancer and other neoplasias.
Background Alzheimer’s disease (AD) is a neurodegenerative disease with as yet no efficient therapies. Many drugs and therapies have been designed and developed against this neurodegenerative disease, although none has successfully terminated a phase‐III clinical trial in humans. To shift the perspective for the design of new AD therapies, membrane lipid therapy has been tested, which assumes that brain lipid alterations lie upstream in the pathophysiology of AD. A hydroxylated derivative of docosahexaenoic acid was used, 2‐hydroxy‐docosahexaenoic acid (DHA‐H), which has shown efficacy against hallmarks of AD pathology in a transgenic mouse model of AD (5xFAD). Method Lipid samples were obtained from cultured cells and blood plasma and brain from WT and 5xFAD mice. Both, cell cultures and animals were treated with DHA‐H and DHA under different conditions. Mice were subjected to the Radial Arm Maze test during the last month of treatment just before sacrifice. Fatty acid analysis was performed by GC‐FID and GC‐MS (Gas Chromatography‐Flame Ionization Detector and ‐Mass Spectrometry) and the lipidomic analysis carried out by ESI‐MS (Electrospray ionization‐Mass Spectrometry). Result Here, for the first time, DHA‐H is shown to undergo α‐oxidation to generate the heneicosapentaenoic acid (HPA, C21:5, n‐3) metabolite, an odd‐chain omega‐3 polyunsaturated fatty acid that accumulates in cell cultures, mouse blood plasma and brain tissue upon DHA‐H treatment. Interestingly, DHA‐H does not share metabolic routes with its natural analog DHA (C22:6, n‐3) but rather, DHA‐H and DHA accumulate distinctly, both having different effects on cell fatty acid composition. This is partly explained because DHA‐H α‐hydroxyl group provokes steric hindrance on fatty acid carbon 1, which in turn leads to diminished uptake by cultured cells and accumulation as free fatty acid in cell membranes. Finally, DHA‐H administration to mice elevated the brain HPA levels which in turn were directly and positively correlated with cognitive spatial scores in AD mice. This effect appeared in the apparent absence of DHA‐H and without any significant change DHA levels in brain. Conclusion The evidence presented in this work suggest that the metabolic conversion of DHA‐H into HPA could represent a key event in the therapeutic effects of DHA‐H against AD.
Background DHA‐H (Hydroxy‐docosahexaenoic acid) is a molecule in development for Alzheimer’s disease (AD) treatment based on the concept of membrane lipid therapy (melitherapy). Once entered the cell, DHA‐H is metabolized via α‐oxidation to the fatty acid HPA (Heneicosapentaenoic acid). DHA‐H has been shown to reduce the amyloidogenic processing of Amyloid Precursor Protein (APP), as well as having a neuroprotective effect in cellular models. Although the mechanism of action of DHA‐H is not yet fully understood, results obtained in excitotoxicity models and lipid profile analysis suggest that HPA could be a DHA‐H effector. Methods : APP processing was assessed in cell cultures of HEK293 and N2a neuroblastoma cell lines and analyzed by western blot. Neuroprotective effect of DHA‐H and HPA was tested in neuron cells differentiated from SH‐SY5Y neuroblastoma cells that were stimulated with NMDA (N‐Methyl‐D‐Aspartate)/Ca to induce excitotoxicity. Lipid samples for lipid profile analysis were obtained from the same cultured cells by addition of chloroform/methanol. Fatty acids were transformed into methyl esters and analyzed by GC‐FID (Gas Chromatography‐Flame ionization detector). Results : DHA‐H administration decreases the levels of derivatives from the APP amyloidogenic processing. DHA‐H and HPA showed a neuroprotective effect in a neuronal model of NMDA‐induced excitotoxicity. DHA‐H administration does not significantly alter the main fatty acids but clearly increases HPA levels in the cells. Conclusion All these results together demonstrate that DHA‐H exerts neuroprotection and prevents amyloidogenic processing possibly through its metabolic intermediate HPA. Therefore, HPA appears as a new promising molecule for Alzheimer’s therapy.
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