Kavli Affiliate: Gabriel Silva
| Authors: Pedro Rocha Tenorio, Gabriel Smolak Sobieski e Silva, Débora Hipólito Quadreli, Glaura Scantamburlo Alves Fernandes and Fábio Goulart de Andrade
| Summary:
Purpose This study aimed to investigate whether food processing, alone or combined with high-fat/high-sugar content, promotes obesity, metabolic syndrome (MtS), and oxidative stress in adult rats. Methods Male Wistar rats were fed for 10 weeks with either a commercial grain-based diet (C/GB), a balanced semi-purified diet (B/SP), or a high-fat/high-sugar semi-purified diet (HFS/SP). Murinometric, metabolic, histological, and oxidative parameters were assessed. Multivariate clustering and principal component analysis (PCA) were used to identify metabolic phenotypes. Results Despite similar caloric intake, B/SP-fed rats developed increased adiposity and body weight without metabolic disturbances. In contrast, HFS/SP-fed animals exhibited hyperglycemia, dyslipidemia, hepatic steatosis, and marked systemic oxidative stress despite no excess weight gain. Clustering analysis identified three partially overlapping phenotypes: a metabolically healthy profile (C/GB), an intermediate profile resembling metabolically healthy obesity (B/SP), and a distinct metabolically unhealthy non-obese group (HFS/SP). The overlap between B/SP and C/GB groups suggests a transitional zone rather than sharply defined states. Oxidative stress markers and hepatic steatosis were strongly associated with metabolic impairments, especially in the HFS/SP group. Conclusion Diet composition and processing play a decisive role in shaping metabolic and redox phenotypes, independent of caloric intake or body mass. These findings support the fuel partitioning hypothesis and expand the translational relevance of Wistar rats by demonstrating intermediate and overlapping metabolic states resembling human obesity subtypes not previously documented, highlighting the potential of male Wistar rats as a versatile model to study diverse obesity-related metabolic phenotypes relevant to human conditions.