Teristics of the disease. In addition, the available animal models fall short in accurately representing the characteristics of AMD due to absence of human genetic polymorphisms and long-term exposure to oxidative stress and environmental factors [8]. The generation of induced pluripotent stem cells (iPSCs) from somatic cells and their differentiation to various cell types offers new promise for autologous cell replacement therapies [9, 10]. These iPSCs also provide a prominent source for modeling diseases for which there is no adequate animal or in vitro model and may be used for in vitro drug screening [11]. Several groups have successfully differentiated RPE from iPSCs [12, 13] and we have demonstrated that iPSC-derived RPE are phenotypically and functionally similar to native RPE [14], thus offering promise for cell replacement therapy and disease modeling in AMD. A recent study has DoravirineMedChemExpress Doravirine associated the abnormal ARMS2/HTRA1 expression in iPSC-RPE from AMD patients with decreased SOD2 defense against oxidative stress making RPE more susceptible to oxidative damage [15]. Another study reprogrammed T cells from patients with dry type AMD into iPSCs-RPE and showed reduced antioxidant ability in AMD RPE as compared to normal RPE cells [16]. Recently, dysregulated autophagy in RPE was associated with increased susceptibility to oxidative stress and AMD [17, 18]. Another study related the decline in clearance system to induction of inflammasome PubMed ID:https://www.ncbi.nlm.nih.gov/pubmed/27385778 signaling in human ARPE-19 cell line [19]. A more recent study reported mtDNA damage in RPE that mayimpact mitochondrial function [20]. However, to date, the phenotypic characterization of AMD patient-specific iPSC-RPE, as well as the underlying mechanisms responsible for the pathophysiology of AMD remains to be elucidated. We cultured RPE from AMD and age-matched normal donors. Because primary RPE undergo senescence in culture by passaging, we generated iPSCs from the RPE of AMD and normal donor eyes with CFH, HTRA1/ ARMS2, LOC abnormal alleles, or with FACTOR B protective alleles, followed by differentiation into RPE (AMD RPE-iPSC-RPE and Normal RPE-iPSC-RPE) (Table 1). We also generated iPSCs from skin fibroblasts of a dry AMD patient with CFH, HTRA1/ARMS2, LOC, and FACTOR B risk alleles, and differentiated them into RPE (Skin AMD iPSC-RPE) (Table 1). This approach allowed us to establish an inexhaustible in vitro disease model to study the molecular mechanisms of AMD. A number of order AZD3759 retinal pathologies including AMD are associated with mitochondrial dysfunction [21]. Dysfunctional mitochondria induce increased levels of ROS, mitochondrial DNA (mtDNA) damage, and defective metabolic activity [22]. A major role in mitochondrial biogenesis and oxidative metabolism is played by peroxisome proliferator-activated receptor-gamma coactivator (PGC)-1 (PGC-1). Its repression contributes to disorders such as obesity, diabetes, neurodegeneration, and cardiomyopathy [23?7]. Recently DNA sequence variants in PPARGC1A gene coding for PGC-1 were reported to be associated with neovascular (NV) AMD and AMD-associated loci [28]. A more recent study reported a role for PGC-1 in induction of human RPE oxidative metabolism and antioxidant capacity [29]. PGC-1 is shown to play an important role in mitochondrial biogenesis and turnover [30, 31]; it also plays a role in autophagy/mitophagy in a manner that is specific to cellular metabolic state [32, 33]. In addition, PGC-1 is known to regulate the expression of electron transp.Teristics of the disease. In addition, the available animal models fall short in accurately representing the characteristics of AMD due to absence of human genetic polymorphisms and long-term exposure to oxidative stress and environmental factors [8]. The generation of induced pluripotent stem cells (iPSCs) from somatic cells and their differentiation to various cell types offers new promise for autologous cell replacement therapies [9, 10]. These iPSCs also provide a prominent source for modeling diseases for which there is no adequate animal or in vitro model and may be used for in vitro drug screening [11]. Several groups have successfully differentiated RPE from iPSCs [12, 13] and we have demonstrated that iPSC-derived RPE are phenotypically and functionally similar to native RPE [14], thus offering promise for cell replacement therapy and disease modeling in AMD. A recent study has associated the abnormal ARMS2/HTRA1 expression in iPSC-RPE from AMD patients with decreased SOD2 defense against oxidative stress making RPE more susceptible to oxidative damage [15]. Another study reprogrammed T cells from patients with dry type AMD into iPSCs-RPE and showed reduced antioxidant ability in AMD RPE as compared to normal RPE cells [16]. Recently, dysregulated autophagy in RPE was associated with increased susceptibility to oxidative stress and AMD [17, 18]. Another study related the decline in clearance system to induction of inflammasome PubMed ID:https://www.ncbi.nlm.nih.gov/pubmed/27385778 signaling in human ARPE-19 cell line [19]. A more recent study reported mtDNA damage in RPE that mayimpact mitochondrial function [20]. However, to date, the phenotypic characterization of AMD patient-specific iPSC-RPE, as well as the underlying mechanisms responsible for the pathophysiology of AMD remains to be elucidated. We cultured RPE from AMD and age-matched normal donors. Because primary RPE undergo senescence in culture by passaging, we generated iPSCs from the RPE of AMD and normal donor eyes with CFH, HTRA1/ ARMS2, LOC abnormal alleles, or with FACTOR B protective alleles, followed by differentiation into RPE (AMD RPE-iPSC-RPE and Normal RPE-iPSC-RPE) (Table 1). We also generated iPSCs from skin fibroblasts of a dry AMD patient with CFH, HTRA1/ARMS2, LOC, and FACTOR B risk alleles, and differentiated them into RPE (Skin AMD iPSC-RPE) (Table 1). This approach allowed us to establish an inexhaustible in vitro disease model to study the molecular mechanisms of AMD. A number of retinal pathologies including AMD are associated with mitochondrial dysfunction [21]. Dysfunctional mitochondria induce increased levels of ROS, mitochondrial DNA (mtDNA) damage, and defective metabolic activity [22]. A major role in mitochondrial biogenesis and oxidative metabolism is played by peroxisome proliferator-activated receptor-gamma coactivator (PGC)-1 (PGC-1). Its repression contributes to disorders such as obesity, diabetes, neurodegeneration, and cardiomyopathy [23?7]. Recently DNA sequence variants in PPARGC1A gene coding for PGC-1 were reported to be associated with neovascular (NV) AMD and AMD-associated loci [28]. A more recent study reported a role for PGC-1 in induction of human RPE oxidative metabolism and antioxidant capacity [29]. PGC-1 is shown to play an important role in mitochondrial biogenesis and turnover [30, 31]; it also plays a role in autophagy/mitophagy in a manner that is specific to cellular metabolic state [32, 33]. In addition, PGC-1 is known to regulate the expression of electron transp.