IntroductionIn the human brain, there are at least as many astrocytes as neurons. Astrocytes are known to modulate neuronal function in several ways. Thus, they may also contribute to cerebral insulin actions. Therefore, we examined whether primary human astrocytes are insulin-responsive and whether their metabolic functions are affected by the hormone.MethodsCommercially available Normal Human Astrocytes were grown in the recommended medium. Major players in the insulin signaling pathway were detected by real-time RT-PCR and Western blotting. Phosphorylation events were detected by phospho-specific antibodies. Glucose uptake and glycogen synthesis were assessed using radio-labeled glucose. Glycogen content was assessed by histochemistry. Lactate levels were measured enzymatically. Cell proliferation was assessed by WST-1 assay.ResultsWe detected expression of key proteins for insulin signaling, such as insulin receptor β-subunit, insulin receptor substrat-1, Akt/protein kinase B and glycogen synthase kinase 3, in human astrocytes. Akt was phosphorylated and PI-3 kinase activity increased following insulin stimulation in a dose-dependent manner. Neither increased glucose uptake nor lactate secretion after insulin stimulation could be evidenced in this cell type. However, we found increased insulin-dependent glucose incorporation into glycogen. Furthermore, cell numbers increased dose-dependently upon insulin treatment.DiscussionThis study demonstrated that human astrocytes are insulin-responsive at the molecular level. We identified glycogen synthesis and cell proliferation as biological responses of insulin signaling in these brain cells. Hence, this cell type may contribute to the effects of insulin in the human brain.
Diabetes is caused by a combination of impaired responsiveness to insulin and reduced production of insulin by the pancreas. Until recently, the decline of insulin production had been ascribed to β‐cell death. But recent research has shown that β‐cells do not die in diabetes, but undergo a silencing process, termed “dedifferentiation.” The main implication of this discovery is that β‐cells can be revived by appropriate treatments. We have shown that mitochondrial abnormalities are a key step in the progression of β‐cell dysfunction towards dedifferentiation. In normal β‐cells, mitochondria generate energy required to sustain insulin production and its finely timed release in response to the body's nutritional status. A normal β‐cell can adapt its mitochondrial fuel source based on substrate availability, a concept known as “metabolic flexibility.” This capability is the first casualty in the progress of β‐cell failure. β‐Cells lose the ability to select the right fuel for mitochondrial energy production. Mitochondria become overloaded, and accumulate by‐products derived from incomplete fuel utilization. Energy production stalls, and insulin production drops, setting the stage for dedifferentiation. The ultimate goal of these investigations is to explore novel treatment paradigms that will benefit people with diabetes.
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