Abstract

This work examined the novel hypothesis that reduced levels of H(2)S or L-cysteine (LC) play a role in the impaired glucose metabolism seen in diabetes. 3T3L1 adipocytes were treated with high glucose (HG, 25 mM) in the presence or absence of LC or H(2)S. Both LC and H(2)S treatments caused an increase in phosphatidylinositol-3,4,5 trisphosphate (PIP3), AKT phosphorylation, and glucose utilization in HG-treated cells. The effect of LC on PIP3 and glucose utilization was prevented by propargylglycine, an inhibitor of cystathionine γ-lyase that catalyzes H(2)S formation from LC. This demonstrates that H(2)S mediates the effect of LC on increased PIP3 and glucose utilization. H(2)S and LC caused phosphatidylinositol 3-kinase activation and PTEN inhibition. Treatment with LC, H(2)S, or PIP3 increased the phosphorylation of IRS1, AKT, and PKCζ/λ as well as GLUT4 activation and glucose utilization in HG-treated cells. This provides evidence that PIP3 is involved in the increased glucose utilization observed in cells supplemented with LC or H(2)S. Comparative signal silencing studies with siAKT2 or siPKCζ revealed that PKCζ phosphorylation is more effective for the GLUT4 activation and glucose utilization in LC-, H(2)S-, or PIP3-treated cells exposed to HG. This is the first report to demonstrate that H(2)S or LC can increase cellular levels of PIP3, a positive regulator of glucose metabolism. The PIP3 increase is mediated by PI3K activation and inhibition of PTEN but not of SHIP2. This study provides evidence for a molecular mechanism by which H(2)S or LC can up-regulate the insulin-signaling pathways essential for maintenance of glucose metabolism.

Highlights

  • H2S and L-cysteine (LC) levels are low in diabetes

  • Supplementation with LC prevented the decrease in PI3K and increase in phosphatase and tensin homolog (PTEN) caused by high glucose (HG)

  • Treatment with H2S caused a significant increase in PI3K and a decrease in PTEN compared with treatment with HG alone

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Summary

Background

H2S and L-cysteine (LC) levels are low in diabetes. Results: H2S or LC inhibits PTEN and activates IRS1, PI3K, AKT, PKC␨/␭, GLUT4, and PIP3 levels and glucose utilization in cells exposed to high glucose. Comparative signal silencing studies with siAKT2 or siPKC␨ revealed that PKC␨ phosphorylation is more effective for the GLUT4 activation and glucose utilization in LC-, H2S-, or PIP3-treated cells exposed to HG. This is the first report to demonstrate that H2S or LC can increase cellular levels of PIP3, a positive regulator of glucose metabolism. This study provides evidence for a novel molecular mechanism by which H2S or LC supplementation can help improve glucose metabolism via activation of the PI3K/PIP3/phospho-AKT insulin signaling pathway using an adipocyte cell model

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