Ed reagents/materials/analysis tools: IL. Wrote the paper: MLP VMF FC.
Endoglin (Eng) is a transmembrane homodimeric glycoprotein (180 kDa) identified in human vascular endothelial cells where it is highly expressed [1]. Eng is also expressed in many other cells types including smooth muscle cells, mesangial cells, fibroblasts, hepatocytes, and keratinocytes [2]. Eng functions as a nonsignaling coreceptor of the transforming growth factor beta (TGFb) modulating its responses [2,3]. Eng modulates processes mainly related to vascular physiology and pathophysiology [2]. Eng plays a key role in endotheliummediated vascular buy (��)-Imazamox reactivity as it regulates the expression of endothelial nitric oxide synthase (eNOS), and consequently the synthesis of nitric oxide (NO) [4?] and the expression of cyclooxygenase 2 (COX-2) [7]. Eng expression increases during alterations in vascular structure and function as during embryogenesis, inflammation and wound healing [8] and it is necessary for endothelial cell survival during hypoxia [9]. Eng is required for normal angiogenesis during fetal development as Eng null embryos die at 10?1.5 days due to vascular and cardiac abnormalities [9?1]. Eng also modulates various processesinvolved in the regulation of angiogenesis in the adult including tumor growth [12?6]. Furthermore, Eng appears involved in the vascular repair carried out by blood mononuclear cells [17] and is associated to hypertension during pregnancy [18,19]. Mutations in the endoglin gene leading to endoglin haploinsufficiency are the cause of the Hereditary Hemorrhagic Telangiectasia (HHT) type 1 [20,21]. Interestingly, gene expression fingerprinting of blood outgrowth endothelial cells demonstrated that compared to healthy subjects, HHT1 patients show 20 of deregulated genes (upregulated or down regulated) that are involved in metabolic homeostasis [22]. Supporting the link between Eng and metabolism, a relationship between plasma levels of Eng and glycemia was recently found in diabetic patients [23]. In addition, endoglin deficiency is related to endothelial dysfunction [2] and there is a clear association between endothelial dysfunction and alterations in glucose metabolism or metabolic syndrome [24,25]. In spite of these evidences, the endogenous role of Eng on energy balance or glucose metabolism is largely unknown. The present study is the first one aimed to investigate the metabolic phenotype of mice haploinsufficient for Eng (Eng+/2) in normal MedChemExpress Eliglustat conditions or when challenged with high fat diet.Endoglin and Diet-Induced Insulin ResistanceEndoglin and Diet-Induced Insulin ResistanceFigure 1. Body weight, body composition, food intake, and metabolic parameters in mice fed a standard diet. Body weight (A), 23977191 fat mass (B), non-fat mass (C), food intake (D), total energy expenditure (E), energy expenditure corrected by non-fat mass (F), total locomotor activity (G), locomotor activity corrected by non-fat mass (H), respiratory quotient during light phase (I), respiratory quotient during dark phase (J), and 48 h profile of RQ (K) in 8-week male wild type and endoglin heterozygous mice fed a standard diet. Measurements were done during 48 h. n = 6?. *p,0.05. doi:10.1371/journal.pone.0054591.gMaterials and Methods AnimalsGeneration and genotyping of Eng+/2 mice on a C57Bl/6 background was previously described [11,26]. Mice were kept in ventilated rooms, in a pathogen-free facility under conditions of controlled temperature (23uC), humidity (50 ) and ill.Ed reagents/materials/analysis tools: IL. Wrote the paper: MLP VMF FC.
Endoglin (Eng) is a transmembrane homodimeric glycoprotein (180 kDa) identified in human vascular endothelial cells where it is highly expressed [1]. Eng is also expressed in many other cells types including smooth muscle cells, mesangial cells, fibroblasts, hepatocytes, and keratinocytes [2]. Eng functions as a nonsignaling coreceptor of the transforming growth factor beta (TGFb) modulating its responses [2,3]. Eng modulates processes mainly related to vascular physiology and pathophysiology [2]. Eng plays a key role in endotheliummediated vascular reactivity as it regulates the expression of endothelial nitric oxide synthase (eNOS), and consequently the synthesis of nitric oxide (NO) [4?] and the expression of cyclooxygenase 2 (COX-2) [7]. Eng expression increases during alterations in vascular structure and function as during embryogenesis, inflammation and wound healing [8] and it is necessary for endothelial cell survival during hypoxia [9]. Eng is required for normal angiogenesis during fetal development as Eng null embryos die at 10?1.5 days due to vascular and cardiac abnormalities [9?1]. Eng also modulates various processesinvolved in the regulation of angiogenesis in the adult including tumor growth [12?6]. Furthermore, Eng appears involved in the vascular repair carried out by blood mononuclear cells [17] and is associated to hypertension during pregnancy [18,19]. Mutations in the endoglin gene leading to endoglin haploinsufficiency are the cause of the Hereditary Hemorrhagic Telangiectasia (HHT) type 1 [20,21]. Interestingly, gene expression fingerprinting of blood outgrowth endothelial cells demonstrated that compared to healthy subjects, HHT1 patients show 20 of deregulated genes (upregulated or down regulated) that are involved in metabolic homeostasis [22]. Supporting the link between Eng and metabolism, a relationship between plasma levels of Eng and glycemia was recently found in diabetic patients [23]. In addition, endoglin deficiency is related to endothelial dysfunction [2] and there is a clear association between endothelial dysfunction and alterations in glucose metabolism or metabolic syndrome [24,25]. In spite of these evidences, the endogenous role of Eng on energy balance or glucose metabolism is largely unknown. The present study is the first one aimed to investigate the metabolic phenotype of mice haploinsufficient for Eng (Eng+/2) in normal conditions or when challenged with high fat diet.Endoglin and Diet-Induced Insulin ResistanceEndoglin and Diet-Induced Insulin ResistanceFigure 1. Body weight, body composition, food intake, and metabolic parameters in mice fed a standard diet. Body weight (A), 23977191 fat mass (B), non-fat mass (C), food intake (D), total energy expenditure (E), energy expenditure corrected by non-fat mass (F), total locomotor activity (G), locomotor activity corrected by non-fat mass (H), respiratory quotient during light phase (I), respiratory quotient during dark phase (J), and 48 h profile of RQ (K) in 8-week male wild type and endoglin heterozygous mice fed a standard diet. Measurements were done during 48 h. n = 6?. *p,0.05. doi:10.1371/journal.pone.0054591.gMaterials and Methods AnimalsGeneration and genotyping of Eng+/2 mice on a C57Bl/6 background was previously described [11,26]. Mice were kept in ventilated rooms, in a pathogen-free facility under conditions of controlled temperature (23uC), humidity (50 ) and ill.