Maternal postnatal early overfeeding induces sex-related cardiac dysfunction and alters sexually hormones levels in young offspring.

Postnatal early overfeeding (PO) is a risk factor for cardiometabolic disorders. However, remains unknown the cardiac effects in the second generation from postnatal overfed dams. Our aim was to investigate the effects of maternal PO on cardiac parameters in second generation (F2) offspring. For this, pregnant Wistar rats (F0) were divided into two groups: normal litter (NL, 9 pups) and small litter (SL, 3 pups). At P70, female offspring (F1) of both groups were mated with non-PO male rats. At P21 male and female F2 offspring (NLO and SLO) were weaned, and at P45 they were euthanized to evaluate the cardiac function and sample collection. Male and female SLO showed increased body weight, food intake and adiposity. Blood estradiol levels were increased in the male SLO and decreased in the female SLO. Blood testosterone levels increased in SLO females, but not change in SLO male rats. Although SLO offspring presented cardiac hypertrophy, only males had ex vivo functional impairments, such as reduction of the intraventricular systolic pressure and dP/dt. Male and female SLO had increased interstitial fibrosis; however, only the male SLO had increased perivascular fibrosis. In addition, only male rats from SLO group had decreased AKT and Type 2 Ang-2 receptor, increased catalase and type alpha estrogenic receptor protein levels. Maternal PO leads to obese phenotype and alters sex-steroid levels in both male and female offspring. Although both sexes showed cardiac hypertrophy, only male offspring showed cardiac dysfunction, which may be related with Ang2 and AKT signaling impairments.

Long-term effects of early overfeeding and food restriction during puberty on cardiac remodeling in adult rats.

Nutritional disorders during the perinatal period cause cardiometabolic dysfunction, which is observable in the early overfeeding (EO) experimental model. Therefore, severe caloric restriction has the potential of affecting homeostasis through the same epigenetic mechanisms, and its effects need elucidation. This work aims to determine the impact of food restriction (FR) during puberty in early overfed obese and non-obese animals in adult life. Three days after delivery (PN3), Wistar rats were separated into two groups: normal litter (NL; 9 pups) and small litter (SL; 3 pups). At PN30, some offspring were subjected to FR (50%) until PN60, or maintained with free access to standard chow. NL and SL animals submitted to food restriction (NLFR and SLFR groups) were kept in recovery with free access to standard chow from PN60 until PN120. Body weight and food intake were monitored throughout the experimental period. At PN120 cardiovascular parameters were analyzed and the animals were euthanized for sample collection. SLNF and SLFR offspring were overweight and had increased adiposity. Differences in blood pressure were observed only between obese and non-obese animals. Obese and FR animals have cardiac remodeling showing cardiomyocyte hypertrophy and the presence of interstitial and perivascular fibrosis. FR animals also show increased expression of AT1 and AT2 receptors and of total ERK and p-ERK. The present study showed that EO leads to the obese phenotype and cardiovascular disruptions. Interestingly, we demonstrated that severe FR during puberty leads to cardiac remodeling.

Postnatal early overfeeding induces cardiovascular dysfunction by oxidative stress in adult male Wistar rats.

AIMS: Obesity is associated with innumerous comorbidities, including cardiovascular diseases, that occur by various mechanisms, including hyperactivation of the renin angiotensin system, oxidative stress and cardiovascular overload. Postnatal early overfeeding (PO) leads to metabolic imprinting that induces weight gain throughout life, and in this paper, we aimed to evaluate cardiovascular parameters and cardiac molecular changes due to obesity induced early in life by PO. MAIN METHODS: Male Wistar rats (120-days-old), raised in normal (NL) or small litters (SL), were submitted to cardiac assessment by transthoracic echocardiography and blood pressure evaluation. Thereafter, the hearts and aorta rings from these animals were submitted to ex-vivo isolated assays. Still, cardiac morphological and molecular analyses were performed. KEY FINDINGS: PO induced ventricular hypertrophy, raised blood pressure, increased fibrosis, and ex-vivo cardiac dysfunction in the SL group. Furthermore, SL animals presented impaired vascular relaxation and increased vascular constriction responses. Besides functional alterations, SL animals presented augmented RAB-1b and SOD-1, despite no changes in RAS receptors expression or Akt/eNOS pathway. SIGNIFICANCE: Taken together, our results consolidate the knowledge that the PO during lactation is critical for cardiometabolic programming, leading to oxidative stress and cardiac remodeling in later stages of life.