Malnourishment during early lactation disrupts the ontogenetic distribution of the CART and α-MSH anorexigenic molecules in the arcuate/paraventricular pathway and lateral hypothalamus in male rats.

Developmental malnourishment impacts the energetic metabolism control throughout life. In rat offspring, a 0% protein diet during the first 10 days of lactation results in leptin resistance and in alterations in: feeding behavior, serum leptin and neuropeptide Y (NPY) levels in the hypothalamic arcuate nucleus (ARC)/paraventricular (PVN) pathway. Here, the distributions of alpha-melanocyte stimulating hormone (α-MSH) and cocaine and amphetamine regulated transcript (CART), anorexigenic molecules, were immunohistochemically assessed in the ARC, PVN and lateral hypothalamus (LH) nuclei. Rat dams were subjected to one of the following diet protocols from postnatal day (P) 1-10: 1) Protein-free (PFG, 0% protein chow); 2) Pair-fed (UFG, normoprotein chow); 3) Control group (CG, normoprotein chow). PFG, UFG and CG male offspring were analyzed at different time points, from P5 to P180. In the ARC, PFG α-MSH and CART were increased from P10 to P45 when compared to CG and UFG. In the PVN, α-MSH and CART peaks in PFG animals were delayed from P20 to P30 when compared to CG. In the LH, CART was more intense in PFG animals than in UFG and CG ones by P20, and, by P30, UFG immunostaining became less intense than in CG. In conclusion, aproteic diet altered the ontogenetic distribution of both anorexigenic molecules. In the PVN, the peak was delayed to P30, which coincides with the leptin peak and follows the previously described NPY (orexigenic) peak in this model. The permanent LH CART and α-MSH increase may be associated with the previously observed PFG hypophagia.

Maternal protein-free diet during lactation programs male Wistar rat offspring for increased novelty-seeking, locomotor activity, and visuospatial performance.

It is well established that chronic undernutrition has detrimental impacts on brain development and maturation. However, protein malnutrition during the period specifically encompassing the brain growth spurt has not been widely studied, particularly regarding its effects on adolescent and adult offspring behavior. Here, we assessed the effects of a protein-free diet during the 1st 10 postnatal days on the macronutrient content of the milk produced by lactating Wistar rats, on their maternal behavior, and on the offspring's behavior. Lactating dams were fed either a protein-free or a normoprotein diet from litter parturition to Postnatal Day 10 (P10). All dams received the normoprotein diet after P10. Offspring were tested in the elevated plus-maze (anxiety-like behavior), hole board arena (novelty-seeking and locomotor activity), and radial arm water maze (memory-learning) at either P40 (adolescents) or P90 (adults). The protein-free diet reduced milk protein content at P10 but not at P20. Carbohydrate and lipid contents were unaffected. Serum corticosterone levels in the offspring (at P10, P40, or P90) and dams (at P21) were not affected by the protein-free diet. Maternal behavior was also unchanged. In the offspring, no differences were observed between groups regarding anxiety-like behaviors at both ages. The protein-free diet increased adolescent locomotor activity as well as adult novelty-seeking behavior and memory performance. Our results indicate that the brain growth spurt period is particularly sensitive to protein malnutrition, showing that even a brief nutritional insult during this period can cause specific age-dependent behavioral effects on the offspring. (PsycINFO Database Record