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Early weaning induces short‐ and long‐term effects on pancreatic islets in Wistar rats of both sexes
Author(s) -
Pietrobon Carla Bruna,
Miranda Rosiane Aparecida,
Bertasso Iala Milene,
Mathias Paulo Cezar de Freitas,
Bonfleur Maria Lúcia,
Balbo Sandra Lucinei,
Reis Marise Auxiliadora de Barros,
Latorraca Márcia Queiroz,
Arantes Vanessa Cristina,
Oliveira Elaine,
Lisboa Patrícia Cristina,
Moura Egberto Gaspar
Publication year - 2020
Publication title -
the journal of physiology
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.802
H-Index - 240
eISSN - 1469-7793
pISSN - 0022-3751
DOI - 10.1113/jp278833
Subject(s) - offspring , weaning , medicine , endocrinology , insulin resistance , lactation , bromocriptine , insulin , diabetes mellitus , glucose homeostasis , prolactin , type 2 diabetes , obesity , biology , pregnancy , hormone , genetics
Key points The World Health Organization recommends exclusive breastfeeding until 6 months of age as an important strategy to reduce child morbidity and mortality. Studies have associated early weaning with the development of obesity and type 2 diabetes in adulthood. In our model, we demonstrated that early weaning leads to increased insulin secretion in adolescent males and reduced insulin secretion in adult offspring. Early weaned males exhibit insulin resistance in skeletal muscle. Early weaning did not change insulin signalling in the muscle of female offspring. Taking into account that insulin resistance is one of the primary factors for the development of type 2 diabetes mellitus, this work demonstrates the importance of breastfeeding in the fight against this disease.Abstract Early weaning (EW) leads to short‐ and long‐term obesity and diabetes. This phenotype is also observed in experimental models, in which early‐weaned males exhibit abnormal insulinaemia in adulthood. However, studies regarding the effect of EW on pancreatic islets are rare. We investigated the mechanisms by which glycaemic homeostasis is altered in EW models through evaluations of insulin secretion and its signalling pathway in offspring. Lactating Wistar rats and their pups were divided into the following groups: non‐pharmacological EW (NPEW): mothers were wrapped with an adhesive bandage on the last 3 days of lactation; pharmacological EW (PEW): mothers received bromocriptine to inhibit prolactin (1 mg/kg body mass/day) on the last 3 days of lactation; and control (C): pups underwent standard weaning at PN21. Offspring of both sexes were euthanized at PN45 and PN180. At PN45, EW males showed higher insulin secretion ( vs . C). At PN170, PEW males exhibited hyperglycaemia in an oral glucose tolerance test ( vs . C and NPEW). At PN180, EW male offspring were heavier; however, both sexes showed higher visceral fat. Insulin secretion was lower in EW offspring of both sexes. Males from both EW groups had lower glucokinase in islets, but unexpectedly, PEW males showed higher GLUT2, than did C. EW males exhibited lower insulin signalling in muscle. EW females exhibited no changes in these parameters compared with C. We demonstrated distinct alterations in the insulin secretion of EW rats at different ages. Despite the sex dimorphism in insulin secretion in adolescence, both sexes showed impaired insulin secretion in adulthood due to EW.