Metabolic programming of adipose tissue in female C57Bl 6 mice offspring by maternal high fat feeding and obesity results in greater adaptability to dietary fat content and resistance to high fat diet-induced glucose intolerance compared to male mice

Abstract

Maternal lifestyle influence may be a factor in the worldwide prevalence of obesity and its complications, including diabetes. Studies investigating the effect of the perinatal maternal environment have produced a range of results, sometimes diametrically opposite. The present study was designed to investigate how obesity and weight gain in pregnant mice affects energy balance, body composition and glucose homeostasis in their offspring, both at a young age on standard diet and when older and fed a high-fat diet. At six weeks of age both male and female offspring from mothers fed a high fat diet had a shorter body length than those from mothers fed standard chow. In contrast to males, female offspring also contained a higher proportion of fat and had elevated circulating leptin and adiponectin. Their gonadal fat pads were heavier and contained larger adipocytes, whereas male offspring had proportionally more smaller adipocytes. Six-week-old female, but not male, offspring had increased gonadal fat gene expression of acetyl CoA carboxylase 1, the rate-limiting step in lipid biosynthesis, and decreased gene expression of carnitine palmitoyl transferase 1, the rate-limiting step in fatty acid oxidation. Maternal high fat diet had no effect on glucose tolerance in six-week-old mice, but this was achieved with higher insulin levels in females. Contrastingly, when the offspring were fed a high fat diet for three months, female, but not male, offspring were leaner than those from mothers fed standard chow. Their gonadal fat depots were lighter and the adipocytes were smaller. Female, but not male, offspring fed high fat diet had decreased gonadal fat gene expression of acetyl CoA carboxylase 1, and increased gene expression of carnitine palmitoyl transferase 1. High fat diet-induced glucose intolerance and elevated plasma insulin concentration were improved in female, but not male, offspring. Plasma leptin and adiponectin remained higher in female offspring on high fat diet with resistin levels being lower. These results suggest that the gonadal fat of female offspring is more adaptable to different levels of dietary fat exposure, increasing storage when levels are low and increasing oxidation when levels are high. This may help female offspring be more resistant to the detrimental effects of high fat diet than male mice.