Abstract
The responsiveness of glucose sensing per se to regulate whole-body glucose homeostasis is dependent on the ability of a rise in glucose to lower hepatic glucose production and increase peripheral glucose uptake in vivo In both rodents and humans, glucose sensing is lost in diabetes and obesity, but the site(s) of impairment remains elusive. Here, we first report that short-term high-fat feeding disrupts hypothalamic glucose sensing to lower glucose production in rats. Second, leptin administration into the hypothalamus of high-fat-fed rats restored hypothalamic glucose sensing to lower glucose production during a pancreatic (basal insulin)-euglycemic clamp and increased whole-body glucose tolerance during an intravenous glucose tolerance test. Finally, both chemical inhibition of hypothalamic lactate dehydrogenase (LDH) (achieved via hypothalamic LDH inhibitor oxamate infusion) and molecular knockdown of LDHA (achieved via hypothalamic lentiviral LDHA shRNA injection) negated the ability of hypothalamic leptin infusion to enhance glucose sensing to lower glucose production in high fat-fed rats. In summary, our findings illustrate that leptin enhances LDHA-dependent glucose sensing in the hypothalamus to lower glucose production in high-fat-fed rodents in vivo.
Highlights
The hallmark feature of type 2 diabetes is traditionally viewed as insulin resistance resulting in elevated hepatic glucose production and impaired glucose uptake in peripheral tissues
We first determined whether the hypothalamus is a site of glucose unresponsiveness in the short-term 3-day high-fat–fed model as 3 days of high-fat feeding in rats induces inflammation, endoplasmic reticulum stress, and insulin resistance in the hypothalamus and the dorsal vagal complex (10 –12) as well
The loss of glucose sensing in leptin-deficient ob/ob mice [5] could be restored by direct hypothalamic leptin administration as restoration of hypothalamic leptin action is effective in improving glucose tolerance in leptin receptor– deficient Koletsky rats [8] as well
Summary
We first determined whether the hypothalamus is a site of glucose unresponsiveness in the short-term 3-day high-fat–fed model as 3 days of high-fat feeding in rats induces inflammation, endoplasmic reticulum stress, and insulin resistance in the hypothalamus and the dorsal vagal complex (10 –12) as well
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