Cover Story Current Issue

Maternal nutrition exerts profound and lasting effects on infant development, with implications extending beyond somatic growth to long-term brain function and metabolic health. For example, newborns from mothers with obesity or diabetes exhibit increased susceptibility to metabolic disorders, including insulin resistance (IR) and type 2 diabetes (T2D), often emerging in childhood or adolescence. While genetic inheritance contributes to this intergenerational risk, early-life nutritional exposures are increasingly recognized as primary drivers of persistent metabolic programming. Among key classes of nutrients, branched-chain amino acids (BCAAs)—leucine, isoleucine, and valine—have emerged as potent modulators of metabolic health in human adults. Elevated circulating BCAAs are among the most accurate predictors of future insulin resistance (IR) and T2D, with a two-fold increase in serum levels conferring a 2.5-fold risk of diabetes onset within 6–10 years. This elevation can directly cause organ toxicity, exacerbating metabolic deficits in a feed-forward loop. However, the extent to which maternal BCAA overnutrition during gestation and lactation impacts offspring metabolic programming and predisposes to dysfunction remains unclear.

Full text

 

Current Issue

Protein kinase C epsilon deletion in AgRP neurons modulates hypothalamic glucose sensing and improves glucose tolerance in mice

Amanda E. Brandon, Chenxu Yan, Xuan Zhang, Chi Kin Ip, ... Carsten Schmitz-Peiffer

Protein kinase C epsilon deletion in AgRP neurons modulates hypothalamic glucose sensing and improves glucose tolerance in mice

Objectives

Global but not liver-specific deletion of protein kinase C epsilon (PKCε) improves glucose tolerance in fat-fed mice, suggesting that extra-hepatic tissues are involved. AgRP neurons within the arcuate nucleus (ARC) of the hypothalamus can affect glucose homeostasis acutely, in addition to their role in energy homeostasis. We therefore deleted PKCε specifically in AgRP neurons to examine its effects at this site.

Methods

Fat-fed AgRP-PKCε−/− mice were subjected to glucose tolerance tests and euglycaemic-hyperinsulinaemic clamps. c-Fos and tyrosine hydroxylase were used as markers to map neuronal activity in serial brain sections. Transcriptional changes in liver and adipose tissue were examined by qRT-PCR while alterations in protein levels and phosphorylation were determined by immunoblotting and mass spectrometry.

Results

Fat-fed AgRP-PKCε−/− mice exhibited improved glucose tolerance but not insulin sensitivity determined by clamp. c-Fos mapping demonstrated that glucose challenge resulted in greater activation of neurons in the paraventricular nucleus (PVN) in AgRP-PKCε−/− mice, but reduced expression of tyrosine hydroxylase in the PVN, suggestive of reduced sympathetic outflow. This was associated with a reduction in hormone sensitive lipase phosphorylation and plasma fatty acid levels. Proteomic analysis indicated overlapping alterations in proteins and protein phosphorylation in adipose tissue and liver, consistent with changes in a common, potentially neuronal, cell type.

Conclusions

Ablation of PKCε in AgRP neurons improves glucose homeostasis in fat-fed mice. This appears to be mediated through glucose sensing mechanisms, potentially reducing sympathetic outflow from the hypothalamus to tissues such as adipose, reducing lipolysis to indirectly lower hepatic glucose production.

Articles in Press

Protein kinase C epsilon deletion in AgRP neurons modulates hypothalamic glucose sensing and improves glucose tolerance in mice

Amanda E. Brandon, Chenxu Yan, Xuan Zhang, Chi Kin Ip, ... Carsten Schmitz-Peiffer

Protein kinase C epsilon deletion in AgRP neurons modulates hypothalamic glucose sensing and improves glucose tolerance in mice

Objectives

Global but not liver-specific deletion of protein kinase C epsilon (PKCε) improves glucose tolerance in fat-fed mice, suggesting that extra-hepatic tissues are involved. AgRP neurons within the arcuate nucleus (ARC) of the hypothalamus can affect glucose homeostasis acutely, in addition to their role in energy homeostasis. We therefore deleted PKCε specifically in AgRP neurons to examine its effects at this site.

Methods

Fat-fed AgRP-PKCε−/− mice were subjected to glucose tolerance tests and euglycaemic-hyperinsulinaemic clamps. c-Fos and tyrosine hydroxylase were used as markers to map neuronal activity in serial brain sections. Transcriptional changes in liver and adipose tissue were examined by qRT-PCR while alterations in protein levels and phosphorylation were determined by immunoblotting and mass spectrometry.

Results

Fat-fed AgRP-PKCε−/− mice exhibited improved glucose tolerance but not insulin sensitivity determined by clamp. c-Fos mapping demonstrated that glucose challenge resulted in greater activation of neurons in the paraventricular nucleus (PVN) in AgRP-PKCε−/− mice, but reduced expression of tyrosine hydroxylase in the PVN, suggestive of reduced sympathetic outflow. This was associated with a reduction in hormone sensitive lipase phosphorylation and plasma fatty acid levels. Proteomic analysis indicated overlapping alterations in proteins and protein phosphorylation in adipose tissue and liver, consistent with changes in a common, potentially neuronal, cell type.

Conclusions

Ablation of PKCε in AgRP neurons improves glucose homeostasis in fat-fed mice. This appears to be mediated through glucose sensing mechanisms, potentially reducing sympathetic outflow from the hypothalamus to tissues such as adipose, reducing lipolysis to indirectly lower hepatic glucose production.

SAVE THE DATE!

13th
Helmholtz Diabetes Conference 
Munich, 21-23. Sep 2026                                                                                                                             

2024 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.