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In 1902, Ralph Larrabee provided intriguing evidence suggesting parallels between the changes in white blood cell counts observed in Boston Marathon runners and those seen in specific disease states. Notably he also noted a considerable leukocytosis of the inflammatory type, suggesting a potential link between extreme exercise and inflammatory responses. This early observation laid the groundwork for further investigations into the complex relationship between exercise intensity, immune system activation, and health outcomes, igniting an ongoing debate about the impact of exercise on the immune system.

Today we know exercise shows quantifiable and observable benefits to human health across multiple scales, but the specific genetic and biological processes and pathways underlying these benefits remain unclear. This is primarily caused by individuals exhibiting significant physiological variations in their response to exercise training, coupled with the diverse methods, subjects and timelines used in studying this phenomenon, which impacts the potential for clear and reproducible analysis. A deeper grasp of the metabolic and cellular impacts of exercise could lead to more targeted exercise approaches. Additionally, unraveling the molecular shifts induced by various exercise methods may hasten the identification of pharmaceutical targets for improving metabolic well-being. To combat the global pandemic of physical inactivity and its associated toll of 5.3 million deaths annually, we must gain a better understanding of the fundamental principles governing physical activity’s benefits.

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Intestinal gluconeogenesis controls the neonatal development of hypothalamic feeding circuits

 

Judith Estrada-Meza, Jasmine Videlo, Clara Bron, Adeline Duchampt, ... Amandine Gautier-Stein

Intestinal gluconeogenesis controls the neonatal development of hypothalamic feeding circuits

Objective

 

Intestinal gluconeogenesis (IGN) regulates adult energy homeostasis in part by controlling the same hypothalamic targets as leptin. In neonates, leptin exhibits a neonatal surge controlling axonal outgrowth between the different hypothalamic nuclei involved in feeding circuits and autonomic innervation of peripheral tissues involved in energy and glucose homeostasis. Interestingly, IGN is induced during this specific time-window. We hypothesized that the neonatal pic of IGN also regulates the development of hypothalamic feeding circuits and sympathetic innervation of adipose tissues.

Methods

We genetically induced neonatal IGN by overexpressing G6pc1 the catalytic subunit of glucose-6-phosphatase (the mandatory enzyme of IGN) at birth or at twelve days after birth. The neonatal development of hypothalamic feeding circuits was studied by measuring Agouti-related protein (AgRP) and Pro-opiomelanocortin (POMC) fiber density in hypothalamic nuclei of 20-day-old pups. The effect of the neonatal induction of intestinal G6pc1 on sympathetic innervation of the adipose tissues was studied via tyrosine hydroxylase (TH) quantification. The metabolic consequences of the neonatal induction of intestinal G6pc1 were studied in adult mice challenged with a high-fat/high-sucrose (HFHS) diet for 2 months.

Results

Induction of intestinal G6pc1 at birth caused a neonatal reorganization of AgRP and POMC fiber density in the paraventricular nucleus of the hypothalamus, increased brown adipose tissue tyrosine hydroxylase levels, and protected against high-fat feeding-induced metabolic disorders. In contrast, inducing intestinal G6pc1 12 days after birth did not impact AgRP/POMC fiber densities, adipose tissue innervation or adult metabolism.

Conclusion

These findings reveal that IGN at birth but not later during postnatal life controls the development of hypothalamic feeding circuits and sympathetic innervation of adipose tissues, promoting a better management of metabolism in adulthood.

 

 

Articles in Press

Intestinal gluconeogenesis controls the neonatal development of hypothalamic feeding circuits

 

Judith Estrada-Meza, Jasmine Videlo, Clara Bron, Adeline Duchampt, ... Amandine Gautier-Stein

Intestinal gluconeogenesis controls the neonatal development of hypothalamic feeding circuits

Objective

 

Intestinal gluconeogenesis (IGN) regulates adult energy homeostasis in part by controlling the same hypothalamic targets as leptin. In neonates, leptin exhibits a neonatal surge controlling axonal outgrowth between the different hypothalamic nuclei involved in feeding circuits and autonomic innervation of peripheral tissues involved in energy and glucose homeostasis. Interestingly, IGN is induced during this specific time-window. We hypothesized that the neonatal pic of IGN also regulates the development of hypothalamic feeding circuits and sympathetic innervation of adipose tissues.

Methods

We genetically induced neonatal IGN by overexpressing G6pc1 the catalytic subunit of glucose-6-phosphatase (the mandatory enzyme of IGN) at birth or at twelve days after birth. The neonatal development of hypothalamic feeding circuits was studied by measuring Agouti-related protein (AgRP) and Pro-opiomelanocortin (POMC) fiber density in hypothalamic nuclei of 20-day-old pups. The effect of the neonatal induction of intestinal G6pc1 on sympathetic innervation of the adipose tissues was studied via tyrosine hydroxylase (TH) quantification. The metabolic consequences of the neonatal induction of intestinal G6pc1 were studied in adult mice challenged with a high-fat/high-sucrose (HFHS) diet for 2 months.

Results

Induction of intestinal G6pc1 at birth caused a neonatal reorganization of AgRP and POMC fiber density in the paraventricular nucleus of the hypothalamus, increased brown adipose tissue tyrosine hydroxylase levels, and protected against high-fat feeding-induced metabolic disorders. In contrast, inducing intestinal G6pc1 12 days after birth did not impact AgRP/POMC fiber densities, adipose tissue innervation or adult metabolism.

Conclusion

These findings reveal that IGN at birth but not later during postnatal life controls the development of hypothalamic feeding circuits and sympathetic innervation of adipose tissues, promoting a better management of metabolism in adulthood.

 

 

You are what you eat

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