Developmental programming by maternal obesity alters offspring lifespan and immune function in a diet- and sex-specific manner

Maternal obesity is a growing health concern that predisposes offspring to metabolic dysfunction, immune system alterations, and neurodegenerative disorders. To investigate the intergenerational effects of maternal obesity, we used Drosophila melanogaster models exposed to high-sugar (HSD) and high-fat diets (HFD). We found that maternal diet-induced obesity significantly altered offspring lifespan, immune function, and neuronal health in a sex- and diet-specific manner. Male offspring were particularly susceptible, exhibiting reduced lifespan, impaired climbing ability, and increased axonal degeneration, especially following maternal HFD exposure. Transcriptomic analyses revealed age-dependent and diet-specific changes, with males showing pronounced alterations at 50 days of age. Developmental programming of hemocytes (macrophage-like cells) played a crucial role in these outcomes, as knockdown of key immune pathways such as Relish and Upd3 in hemocytes further influenced lifespan in a diet-specific manner. These findings highlight the complex interplay between maternal diet and immune function, underscoring the importance of immune cells in mediating the long-term health consequences of maternal obesity. Our study provides new insights into conserved mechanisms linking maternal metabolic health to offspring outcomes and emphasizes the continued need for animal models to understand intergenerational health impacts. Female flies were placed on one of three diets: CD (Control Diet), HSD (High Sugar Diet), or HFD (High Fat Diet) for 7 days, and mated with CD-fed male flies. The resulting offspring were maintained on CD, raised under light/dark cycles, and kept in a climate-controlled incubator at 25°C.