Cover Story Current Issue

Weaning involves a dietary switch in mammals, progressively decreasing the reliance on the consumption of a fat-rich milk diet in favour of a carbohydrate-rich diet. Metabolic adaptation to this shift in macronutrient consumption is characterized by reduced hepatic gluconeogenesis, increased liver glycogen content, and changes in lipid metabolism. Such metabolic changes are supported by various nutritional, hormonal, and neuronal factors. Dietary changes during weaning are shown to drive β-cell proliferation and maturation, which is important for the optimal endocrine function of the pancreas. A switch from the nutrient sensor target of rapamycin (mTORC1) to the energy sensor 5′-adenosine monophosphate-activated protein kinase (AMPK) was found critical for functional maturation of β-cells. Furthermore, changes in the macronutrient composition during the weaning process drive alterations in the gut microbiome, which is essential for the development of immune tolerance. The major calcium absorption pathway also changes during weaning, from the paracellular pathway during the suckling stage to the vitamin D dependent transcellular pathway post-weaning. However, the factors that regulate these post-weaning metabolic adaptations are not fully understood.

Full text

 

Current Issue

Dorsal raphe nucleus MC4R-GABAergic neurons regulate feeding and anxiety

Satoshi Yamagata, Francesca Copperi, Gavin Thomas White, Jung Dae Kim, Sabrina Diano

Objective

The melanocortin receptor 4 (MC4R) plays a key role in the CNS regulation of metabolism. In addition to its role within the hypothalamus, other brain areas, including the dorsal raphe nucleus (DRN), express MC4R. However, the identity and role of these neurons in metabolism regulation are not fully understood. We performed studies to address these questions.

Methods

We generated Mc4r-cre;Vgat-FlpO and Mc4r-cre;Vglut2-FlpO mice to determine the contribution of these MC4R neuronal populations in DRN. We then chemogenetically activated or inhibited the GABAergic and glutamatergic populations of MC4R. Finally, we selectively deleted MC4R from these two neuronal populations and studied the impact on whole-body metabolism.

Results

We found that about 60% of DRN MC4R neurons are GABAergic (Vgat), while only about 20% are glutamatergic (Vglut2). Most of the projections onto DRN neurons originated from the arcuate nucleus (ARC)-POMC neurons, and only a small input from the nucleus of the solitary tract (NTS)-POMC neurons was identified. Significant projections of DRN MC4R/Vgat neurons were observed in the paraventricular nucleus of the hypothalamus (PVN). Chemogenetic activation or inhibition of MC4R/Vgat neurons increased or inhibited food intake, respectively. No effects were observed when the same approach was used in MC4R/Vglut2 neurons. Furthermore, only chemogenetic manipulation of the MC4R/Vgat neurons affected anxiety-like behavior, which was associated with changes in serotonin staining in the DRN. Finally, MC4R-selective deletion in Vgat but not Vglut2 neurons affected whole-body metabolism.

Conclusions

These findings suggest that DRN MC4R/Vgat neurons receiving projections from the ARC POMC neurons and projecting to the hypothalamic PVN play a role in metabolism regulation. In addition, this same DRN neuronal subpopulation affects anxiety-like behavior by modulating DRN serotonin neurons.

Articles in Press

Dorsal raphe nucleus MC4R-GABAergic neurons regulate feeding and anxiety

Satoshi Yamagata, Francesca Copperi, Gavin Thomas White, Jung Dae Kim, Sabrina Diano

Objective

The melanocortin receptor 4 (MC4R) plays a key role in the CNS regulation of metabolism. In addition to its role within the hypothalamus, other brain areas, including the dorsal raphe nucleus (DRN), express MC4R. However, the identity and role of these neurons in metabolism regulation are not fully understood. We performed studies to address these questions.

Methods

We generated Mc4r-cre;Vgat-FlpO and Mc4r-cre;Vglut2-FlpO mice to determine the contribution of these MC4R neuronal populations in DRN. We then chemogenetically activated or inhibited the GABAergic and glutamatergic populations of MC4R. Finally, we selectively deleted MC4R from these two neuronal populations and studied the impact on whole-body metabolism.

Results

We found that about 60% of DRN MC4R neurons are GABAergic (Vgat), while only about 20% are glutamatergic (Vglut2). Most of the projections onto DRN neurons originated from the arcuate nucleus (ARC)-POMC neurons, and only a small input from the nucleus of the solitary tract (NTS)-POMC neurons was identified. Significant projections of DRN MC4R/Vgat neurons were observed in the paraventricular nucleus of the hypothalamus (PVN). Chemogenetic activation or inhibition of MC4R/Vgat neurons increased or inhibited food intake, respectively. No effects were observed when the same approach was used in MC4R/Vglut2 neurons. Furthermore, only chemogenetic manipulation of the MC4R/Vgat neurons affected anxiety-like behavior, which was associated with changes in serotonin staining in the DRN. Finally, MC4R-selective deletion in Vgat but not Vglut2 neurons affected whole-body metabolism.

Conclusions

These findings suggest that DRN MC4R/Vgat neurons receiving projections from the ARC POMC neurons and projecting to the hypothalamic PVN play a role in metabolism regulation. In addition, this same DRN neuronal subpopulation affects anxiety-like behavior by modulating DRN serotonin neurons.

Save the Date

12th Helmholtz 
Diabetes Conference 
22-24. Sep, Munich

2022 impact factor: 6.6

You are what you eat

Here is a video of Vimeo. When the iframes is activated, a connection to Vimeo is established and, if necessary, cookies from Vimeo are also used. For further information on cookies policy click here.

Auf Werbeinhalte, die vor, während oder nach Videos von WEBSITE-URL eingeblendet werden, hat WEBSITE-URL keinen Einfluss. Wir übernehmen keine Gewähr für diese Inhalte. Weitere Informationen finden Sie hier.