Dysregulation of hepatic lipid and cholesterol metabolism is a significant contributor to cardiometabolic health, resulting in excessive liver lipid accumulation and ultimately non-alcoholic steatohepatitis (NASH). Therapeutic activators of the AMP-Activated Protein Kinase (AMPK) have been proposed as a treatment for metabolic diseases; we show that the AMPK β1-biased activator PF-06409577 is capable of lowering hepatic and systemic lipid and cholesterol levels in both rodent and monkey preclinical models. PF-06409577 is able to inhibit de novo lipid and cholesterol synthesis pathways, and causes a reduction in hepatic lipids and mRNA expression of markers of hepatic fibrosis. These effects require AMPK activity in the hepatocytes. Treatment of hyperlipidemic rats or cynomolgus monkeys with PF-06409577 for 6 weeks resulted in a reduction in circulating cholesterol. Together these data suggest that activation of AMPK β1 complexes with PF-06409577 is capable of impacting multiple facets of liver disease and represents a promising strategy for the treatment of NAFLD and NASH in humans.
Diabetic nephropathy remains an area of high unmet medical need, with current therapies that slow down, but do not prevent, the progression of disease. A reduced phosphorylation state of adenosine monophosphate-activated protein kinase (AMPK) has been correlated with diminished kidney function in both humans and animal models of renal disease. Here, we describe the identification of novel, potent, small molecule activators of AMPK that selectively activate AMPK heterotrimers containing the 1 subunit. After confirming that human and rodent kidney predominately express AMPK1, we explore the effects of pharmacological activation of AMPK in the ZSF1 rat model of diabetic nephropathy. Chronic administration of these direct activators elevates the phosphorylation of AMPK in the kidney, without impacting blood glucose levels, and reduces the progression of proteinuria to a greater degree than the current standard of care, angiotensin-converting enzyme inhibitor ramipril. Further analyses of urine biomarkers and kidney tissue gene expression reveal AMPK activation leads to the modulation of multiple pathways implicated in kidney injury, including cellular hypertrophy, fibrosis, and oxidative stress. These results support the need for further investigation into the potential beneficial effects of AMPK activation in kidney disease.
Myeloperoxidase (MPO) is a highly abundant protein within the neutrophil that is associated with lipoprotein oxidation, and increased plasma MPO levels are correlated with poor prognosis after myocardial infarct. Thus, MPO inhibitors have been developed for the treatment of heart failure and acute coronary syndrome in humans. 2-(6-(5-Chloro-2-methoxyphenyl)-4-oxo-2-thioxo-3,4-dihydropyrimidin-1(2H)-yl)acetamide PF-06282999 is a recently described selective small molecule mechanism-based inactivator of MPO. Here, utilizing PF-06282999, we investigated the role of MPO to regulate atherosclerotic lesion formation and composition in the Ldlr-/- mouse model of atherosclerosis. Though MPO inhibition did not affect lesion area in Ldlr-/- mice fed a Western diet, reduced necrotic core area was observed in aortic root sections after MPO inhibitor treatment. MPO inhibition did not alter macrophage content in and leukocyte homing to atherosclerotic plaques. To assess non-invasive monitoring of plaque inflammation, [18F]-Fluoro-deoxy-glucose (FDG) was administered to Ldlr-/- mice with established atherosclerosis that had been treated with clinically relevant doses of PF-06282999, and reduced FDG signal was observed in animals treated with a dose of PF-06282999 that corresponded with reduced necrotic core area. These data suggest that MPO inhibition does not alter atherosclerotic plaque area or leukocyte homing, but rather alters the inflammatory tone of atherosclerotic lesions; thus, MPO inhibition could have utility to promote atherosclerotic lesion stabilization and prevent atherosclerotic plaque rupture.
An assessment of thermoneutral housing conditions on murine cardiometabolic function
Mouse models are used to model human diseases and perform pharmacological efficacy testing to advance therapies to humans; most of these studies are conducted in room temperature conditions. At room temperature (22°C), mice are cold stressed and must utilize brown adipose tissue (BAT) to maintain body temperature. This cold stress increases catecholamine tone to maintain adipocyte lipid release via lipolysis, which will fuel adaptive thermogenesis. Maintaining rodents at thermoneutral temperatures (28°C) ameliorates the need for adaptive thermogenesis, thus reducing catecholamine tone and BAT activity. Cardiovascular tone is also determined by catecholamine levels in rodents, as beta adrenergic stimuli are primary drivers of not only lipolytic, but also ionotropic and chronotropic responses. As mice have increased catecholamine tone at room temperature, we investigated how thermoneutral housing conditions would impact cardiometabolic function. Here, we show a rapid and reversible effect of thermoneutrality on both heart rate and blood pressure in chow fed animals, which was blunted in animals fed high fat diet. Animals subjected to transverse aortic constriction displayed compensated hypertrophy at room temperature, while animals displayed less hypertrophy and trends towards worse systolic function at thermoneutrality. Despite these dramatic changes in blood pressure and heart rate at thermoneutral housing conditions, enalapril effectively improved cardiac hypertrophy and gene expression alterations. There were surprisingly few differences in cardiac parameters in high fat fed animals at thermoneutrality. Overall, these data suggest that thermoneutral housing may alter some aspects of cardiac remodeling in preclinical mouse models of heart failure.
Circulating increases in branched chain amino acid (BCAA) levels have long been associated with type II diabetes and metabolic syndrome. Emerging data also suggest that impaired BCAA catabolism may play a role in heart failure progression. BCAA are catabolized via the branched chain ketoacid (BCKA) dehydrogenase enzyme complex (BCKDH). BCKD kinase (BCKDK) is a negative regulator of BCAA catabolism through its inhibitory phosphorylation of the BCKDHE1a subunit, and the phosphatase PPM1k dephosphorylates this same site to activate BCAA catabolism. Using an inhibitor of BCKDK (BT2), BCAA catabolism is increased in vivo. Here, we utilized metabolomics to evaluate the contribution of BCAA catabolism to substrate preference in heart and skeletal muscle. Surprisingly, BCKDK inhibition with BT2 had no effect on incorporation of glucose into TCA cycle intermediates in heart or skeletal muscle. Because others have recently shown that the primary site of BCAA catabolism is skeletal muscle, we knocked down BCKDK and PPM1k in human skeletal myocytes to further investigate how BCKDK loss or inhibition affects substrate utilization. Similar to our in vivo observations, knockdown of BCKDK and PPM1k had no effect on glucose and pyruvate utilization in a mitochondrial function assay. However, an increase in maximal respiration was observed after BCKDK knockdown when fatty acids were used. To evaluate the mechanisms underlying this increase we then performed RNAseq in these cells after BCKDK and PPM1K knockdown and observed changes in a number of genes that may explain these alterations in substrate utilization. Finally, we performed C13 BCAA metabolomics in human skeletal myocytes after BT2 treatment or knockdown of BCKDK and PPM1k. Using BT2, we observed a dose-responsive reduction in BCKA production from C13 BCAA by the muscle cells as expected; however, though BCKA production was increased after PPM1k was knocked down, we surprisingly did not observe a decrease in BCKA production after BCKDK knockdown. Collectively these data suggest that BCKDK inhibition may improve metabolism and cardiac function by altering substrate preference in skeletal myocytes.
Circulating increases in branched chain amino acid (BCAA) levels have long been associated with type 2 diabetes and metabolic syndrome. Emerging data also suggest that BCAA catabolism may play a role in heart failure progression. It is hypothesized that decreased catabolism, rather than increased consumption of BCAAs, is responsible for these correlations. Branched chain ketoacid (BCKA) dehydrogenase (BCKDH) kinase (BCKDK) is a negative regulator of BCAA catabolism through its inhibitory phosphorylation of the BCKDH E1a subunit. Using the BCKDK inhibitor molecule BT2, we demonstrate here a reduction of BCAA, BCKA and tissue p-BCKDH levels concomitant with improved glucose tolerance and reduced insulin levels in diet-induced obese mice after only one day of treatment. To investigate the mechanisms underlying this protection, we assessed plasma biomarkers and tissue gene expression after fasting and re-feeding in glucose intolerant high fat diet-fed animals. Remarkably, BT2 treated animals demonstrated reduced plasma glucose levels after re-feed, which was accompanied by dramatic reductions in plasma insulin levels, reduced activation of Akt in peripheral tissues, and a failure to suppress plasma free fatty acids and lipolytic machinery in adipose tissue. RNAseq was performed in liver to assess changes in gene expression profiles, and while over 400 genes were differentially regulated in vehicle treated re-fed mice compared with vehicle treated fasted mice, there were no differentially regulated genes in BT2 re-fed animals compared with BT2 fasted animals. These data suggest that activation of BCAA catabolism with the BCKDK inhibitor BT2 impairs the systemic response to feeding. Disclosure E. Bollinger: Employee; Self; Pfizer Inc. C.P. Siddall: Employee; Self; Pfizer Inc. Employee; Spouse/Partner; Vertex Pharmaceuticals. T. Greizer: None. J.L. Libera: None. G. Hariri: None. E.E. Pashos: Employee; Self; Pfizer Inc. A. Shipstone: None. A. Hadjipanayis: None. Z. Sun: None. G. Xing: None. M.F. Clasquin: Employee; Spouse/Partner; Merck & Co., Inc. Employee; Self; Pfizer Inc. B.B. Zhang: Employee; Spouse/Partner; Janssen Pharmaceuticals, Inc. Employee; Self; Pfizer Inc. Other Relationship; Self; Eli Lilly and Company. R.A. Miller: Employee; Self; Pfizer Inc. R. Roth Flach: Employee; Self; Pfizer Inc.
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