Insulin suppresses glucose production (GP) via both extrahepatic (indirect) and hepatic (direct) effects. We have shown that the direct effect, undetectable in moderately hyperglycemic diabetic dogs, is restored by insulin-induced euglycemia. The first aim of the present study was to determine whether euglycemia per se, and not the excess insulin needed to obtain it, restores the direct effect of insulin on GP. Basal insulin was given portally in depancreatized dogs to attain only moderate hyperglycemia, then an additional insulin was given portally or peripherally to match the peripheral insulin levels and thus to obtain a greater hepatic insulinization with portal delivery. Plasma glucose was allowed to fall to euglycemia before a euglycemic clamp was performed. During euglycemia, there was a tendency (P=0.075) for greater suppression of GP by portal than peripheral insulin. Also, there was a significantly different effect of time (P=0.01) on GP in the two groups, with greater suppression over time in the portal group. The second aim was to test the hypothesis that because of inadequate hepatic insulinization and consequent lack of direct inhibition of GP, peripheral insulin replacement requires peripheral hyperinsulinemia to achieve euglycemia. Portal or peripheral insulin was given to achieve euglycemia and basal GP, and insulin levels were measured. More peripheral insulinemia was required with peripheral than portal insulin replacement to maintain similar euglycemia and GP. Our conclusions are as follows: (1) euglycemia per se is sufficient to acutely restore the direct effect of insulin on GP and (2) at euglycemia, peripheral replacement of insulin, as in insulin-treated diabetes, results in peripheral hyperinsulinemia but unchanged basal GP.
Neehar Gupta, Edward Park, Harmanjit Sandhu, Tracy Goh, Vaja Tchipashvili, and Adria Giacca
Edward Park, Victor Wong, Xinyu Guan, Andrei I Oprescu, and Adria Giacca
Recent evidence indicates that inflammatory pathways are causally involved in insulin resistance. In particular, Iκ Bα kinase β (IKKβ ), which can impair insulin signaling directly via serine phosphorylation of insulin receptor substrates (IRS) and/or indirectly via induction of transcription of proinflammatory mediators, has been implicated in free fatty acid (FFA)-induced insulin resistance in skeletal muscle. However, it is unclear whether liver IKKβ activation plays a causal role in hepatic insulin resistance caused by acutely elevated FFA. In the present study, we wished to test the hypothesis that sodium salicylate, which inhibits IKKβ , prevents hepatic insulin resistance caused by short-term elevation of FFA. To do this, overnight-fasted Wistar rats were subject to 7-h i.v. infusion of either saline or Intralipid plus 20 U/ml heparin (IH; triglyceride emulsion that elevates FFA levels in vivo) with or without salicylate. Hyperinsulinemic–euglycemic clamp with tracer infusion was performed to assess insulin-induced stimulation of peripheral glucose utilization and suppression of endogenous glucose production (EGP). Infusion of IH markedly decreased (P < 0.05) insulin-induced stimulation of peripheral glucose utilization and suppression of EGP, which were completely prevented by salicylate co-infusion. Furthermore, salicylate reversed IH-induced 1) decrease in Iκ Bα content; 2) increase in serine phosphorylation of IRS-1 (Ser 307) and IRS-2 (Ser 233); 3) decrease in tyrosine phosphorylation of IRS-1 and IRS-2; and 4) decrease in serine 473-phosphorylated Akt in the liver. These results demonstrate that inhibition of IKKβ prevents FFA-induced impairment of hepatic insulin signaling, thus implicating IKKβ as a causal mediator of hepatic insulin resistance caused by acutely elevated plasma FFA.
Sandra Pereira, Wen Qin Yu, María E Frigolet, Jacqueline L Beaudry, Yaniv Shpilberg, Edward Park, Cristina Dirlea, B L Grégoire Nyomba, Michael C Riddell, I George Fantus, and Adria Giacca
We have shown in rats that sodium salicylate (SS), which inhibits IkBa kinase B (IKKB), prevents hepatic and peripheral insulin resistance caused by short-term (7 h) i.v. administration of Intralipid and heparin (IH). We wished to further determine whether this beneficial effect of SS persisted after prolonged (48 h) IH infusion, which better mimics the chronic free fatty acid (FFA) elevation of obesity. Hence, we performed hyperinsulinemic euglycemic clamps with tritiated glucose methodology to determine hepatic and peripheral insulin sensitivity in rats infused with saline, IH, IH and SS, or SS alone. SS prevented peripheral insulin resistance (P<0.05) caused by prolonged plasma FFA elevation; however, it did not prevent hepatic insulin resistance. In skeletal muscle, protein levels of phospho-IkBa were augmented by prolonged IH administration and this was prevented by SS, suggesting that IH activates while SS prevents the activation of IKKB. Markers of IKKB activation, namely protein levels of phospho-IkBa and IkBa, indicated that IKKB is not activated in the liver after prolonged FFA elevation. Phosphorylation of serine 307 at insulin receptor substrate (IRS)-1, which is a marker of proximal insulin resistance, was not altered by IH administration in the liver, suggesting that this is not a site of hepatic insulin resistance in the prolonged lipid infusion model. Our results suggest that the role of IKKB in fat-induced insulin resistance is time and tissue dependent and that hepatic insulin resistance induced by prolonged lipid elevation is not due to an IRS-1 serine 307 kinase.