GPX4 Over-expression Is Associated with Increased Senescence Burden and Metabolic Dysfunction

Abstract

Chronic inflammation is a hallmark of obesity, diabetes, and cardiovascular disease (CVD), contributing to morbidity and mortality worldwide. Adipose tissue inflammation is commonly observed in obesity-related diseases and is considered a critical driver of metabolic dysfunction. Cellular senescence, a state of cell cycle arrest, accumulates in adipose tissues in obesity and contributes to tissue inflammation through the production of pro-inflammatory factors known as the SASP (senescence associated secretory phenotype). Novel therapeutics targeting senescent cells have been shown to improve metabolic function in obesity, although the underlying mechanisms of senescent cell accumulation and clearance are not well known. Here, we compared a genetically modified mouse model that overexpresses glutathione peroxidase 4 (GPX4), with wildtype (WT) littermate mice. GPX4 is an antioxidant, selenoenzyme, and a key regulator of ferroptosis, an iron-dependent form of regulated cell death. Previous in vitro studies have shown that activation of ferroptosis through inhibition of GPX4 is associated with a decrease in senescence burden, suggesting that ferroptosis may serve as a novel senolytic pathway. We hypothesized that overexpression of GPX4 in the transgenic (TG) mice will reduce ferroptosis, increase senescence burden, and impair metabolic function compared to WT mice. To determine the effects of ferroptosis on metabolic function, GPX4 WT and TG mice were fed either a 60% high fat diet (HFD) or normal chow (NC) ad libitum for 8-10 weeks. We found higher body, liver, and white adipose tissue (WAT) mass in GPX4 TG compared to WT mice fed NC and HFD (Interaction all p<0.0003, 0.0001, 0.0044, n=8-10/group). After HFD, T cell infiltration in the WAT was higher in GPX4 TG mice compared to WT (Interaction all p<0.0253), and both CD8 and CD4 were significantly different from NC controls, contributing to metabolic dysfunction in these animals (p=0.027,0.207, n=4/group). Mice fed HFD demonstrated increased glucose intolerance compared to NC controls (p=0.029, p=0.0216, n=8-12/group), however, the TG HFD mice were trending towards higher glucose intolerance compared to WT HFD (p=0.17). Compared to NC and HFD fed WT mice, there was increased gene expression for the senescence markers, p16 (all p<0.0041) and p21(all p<0.002), as well as increased expression of SASP factors, CXCL2 (all p<0.0055), TNFa (all p<0.0159), and PAI1 (all p<0.05, n=5-7/group) in the HFD fed TG mice, indicating increased senescence burden in the TG HFD mice. Malondialdehyde (MDA), a byproduct and marker of ferroptosis, was elevated in the HFD fed WT mice (p=0.0002) compared to all other groups, indicating increased ferroptosis. HFD fed TG mice also had increased expression of ferritin (all p<0.0079, n=5/group) compared to all other groups, suggesting resistance to ferroptosis that may contribute to the increased senescence burden in the TG HFD group. Together these data demonstrate that increases in cellular senescence and impairments in metabolic function after HFD are exacerbated by increased GPX4 expression, suggesting that GPX4 may be a novel target to decrease senescence and improve metabolic function through induction of the ferroptosis pathway. Funded in part by awards from National Institute of Health Awards R01 AG 060395, R01 AG048366, T32 HL139451-05, T32 HL007576, R01 AG077751, Nora Eccles Treadwell Foundation (NEFT), and Veteran's Affairs Merit Review Award I01 BX004492. This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.