Scientific Reports (Sep 2024)

Preclinical modeling of metabolic syndrome to study the pleiotropic effects of novel antidiabetic therapy independent of obesity

  • Jonathan P. Mochel,
  • Jessica L. Ward,
  • Thomas Blondel,
  • Debosmita Kundu,
  • Maria M. Merodio,
  • Claudine Zemirline,
  • Emilie Guillot,
  • Ryland T. Giebelhaus,
  • Paulina de la Mata,
  • Chelsea A. Iennarella-Servantez,
  • April Blong,
  • Seo Lin Nam,
  • James J. Harynuk,
  • Jan Suchodolski,
  • Asta Tvarijonaviciute,
  • José Joaquín Cerón,
  • Agnes Bourgois-Mochel,
  • Faiez Zannad,
  • Naveed Sattar,
  • Karin Allenspach

DOI
https://doi.org/10.1038/s41598-024-71202-y
Journal volume & issue
Vol. 14, no. 1
pp. 1 – 22

Abstract

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Abstract Cardiovascular-kidney-metabolic health reflects the interactions between metabolic risk factors, chronic kidney disease, and the cardiovascular system. A growing body of literature suggests that metabolic syndrome (MetS) in individuals of normal weight is associated with a high prevalence of cardiovascular diseases and an increased mortality. The aim of this study was to establish a non-invasive preclinical model of MetS in support of future research focusing on the effects of novel antidiabetic therapies beyond glucose reduction, independent of obesity. Eighteen healthy adult Beagle dogs were fed an isocaloric Western diet (WD) for ten weeks. Biospecimens were collected at baseline (BAS1) and after ten weeks of WD feeding (BAS2) for measurement of blood pressure (BP), serum chemistry, lipoprotein profiling, blood glucose, glucagon, insulin secretion, NT-proBNP, angiotensins, oxidative stress biomarkers, serum, urine, and fecal metabolomics. Differences between BAS1 and BAS2 were analyzed using non-parametric Wilcoxon signed-rank testing. The isocaloric WD model induced significant variations in several markers of MetS, including elevated BP, increased glucose concentrations, and reduced HDL-cholesterol. It also caused an increase in circulating NT-proBNP levels, a decrease in serum bicarbonate, and significant changes in general metabolism, lipids, and biogenic amines. Short-term, isocaloric feeding with a WD in dogs replicated key biological features of MetS while also causing low-grade metabolic acidosis and elevating natriuretic peptides. These findings support the use of the WD canine model for studying the metabolic effects of new antidiabetic therapies independent of obesity.

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