5221Knockout of purinergic receptor Y13 (P2Y13) results in an improved outcome in metabolic syndrome in mice

Abstract

Abstract Background Metabolic syndrome clusters the main risk factors for cardiovascular diseases and endocrine dysfunction. Novel studies show that the important underlying mechanism is a long term inflammation of adipose tissue with a gradual shift from the anti-inflammatory M2 towards the pro-inflammatory M1 macrophages (pathognomonic). Massive hypertrophy induces adipocyte death, which releases DAMPs like nucleotides recognized by purinergic receptors orchestrating ongoing inflammatory process. Interestingly, we found Gi coupled P2Y13R only expressed on M1 macrophages, not in M0 (unstimulated) and M2 macrophages. Nevertheless, the role of P2Y13R in the immune system and especially macrophages is currently unknown. Given its pivotal role in central metabolic processes (P2Y13R has been described in insulin secretory signalling) together with its unique expression in its pathognomonic inflammatory macrophage subtype makes it an interesting candidate to investigate its role in metabolic syndrome. Purpose Due to the unique expression of P2Y13R on M1 macrophages we hypothesise an improved outcome in a high-fat diet induced metabolic syndrome by interfering with the P2Y13 signalling cascade. Methods BMDM differentiation to macrophages using M-CSF and subsequent stimulation with medium (M0), LPS and IFNγ (M1) or IL4 (M2); Expression of P2Rs quantified using Taqman qPCR. Male C57Bl6/J wild-type (WT) and P2Y13-deficient (KO) mice were fed with a high-fat diet (HFD) for 20 weeks; On week 15 we performed the ITT, on week 16 the GTT. Metabolic performance was monitored by metabolic caging. Results We observed a unique expression of P2Y13R on M1 macrophages. Adult P2Y13-deficient mice showed a higher O2 consumption compared to adult C57Bl6/J wild-type mice (AUC of O2 consumption 2nd day= KO: 61620±2261mL/kg vs WT: 53830±916.1mL/kg, p=0.0331). Although both P2Y13−/− mice and WT littermates consumed comparable amount of food (daily food intake per mouse → KO: 3.97±0.25g vs WT: 3.76±0.18g), P2Y13 deficient animals showed significantly decelerated weight gain (e.g. on week 15 → KO: 142±2% (n=10) vs WT: 198±5% (n=10), p<0.0001). Obese P2Y13−/− animals outperformed obese WT littermates in a peritoneal glucose tolerance test (2h after glucose injection → KO: 272.9±21.0 mg/dL (n=10) vs WT: 532.6±21.2 (n=10) mg/dL, p<0.0001). There was no difference in the cell amount of stromal vascular fraction cells. Conclusion Global P2Y13 deficiency leads to an improved outcome in metabolic syndrome with an increased protection against developing an insulin resistance as shown through an improved glucose tolerance and basal glucose levels, a decelerated weight gain despite comparable food consumption and a better metabolic turnover. Observing these beneficial metabolic improvements, we hypothesise that antagonization of P2Y13R could be a promising therapeutic target in the field of metabolic syndrome.