PDF icon Download PDF
Horm Metab Res 2010; 42(2): 110-114
DOI: 10.1055/s-0029-1241822
Original Basic

© Georg Thieme Verlag KG Stuttgart · New York

Opening of ATP-sensitive Potassium Channel by Insulin in the Brain-induced Insulin Secretion in Wistar Rats

T. T. Yang1 , S-M. Ling2 , C-W. Tsao3 , J-T. Cheng2 , 4
  • 1Graduate Institute of Basic Medical Science, China Medical University, Taichung City, Taiwan, R. O. C
  • 2Department of Pharmacology, College of Medicine, National Cheng Kung University, Tainan City, Taiwan, R. O. C
  • 3Department of Nursing, Chung Hwa University of Medical Technology, Tainan County, Taiwan, R. O. C
  • 4Department of Medical Research, Chi-Mei Medical Center, Yang Kang City, Tainan County, Taiwan, R. O. C
Further Information

Publication History

received 08.08.2009

accepted 07.10.2009

Publication Date:
04 November 2009 (online)

Also available ateRef
   Permissions and Reprints
Preview

Abstract

Cerebral insulin can regulate glucose homeostasis via activation of the parasympathetic nervous system, which results in the reduction of hepatic glucose output. However, the precise mechanism(s) through which cerebral insulin directly exerts an effect on insulin secretion remains unclear. In the present study, we found that cerebral administration of insulin caused an increase of plasma insulin concentration and a concomitant decrease in plasma glucose levels within one hour. These effects were blocked by vagotomy or intraperitoneal injection of 1,1-dimethyl-4-diphenylacetoxypiperidinium iodide, a specific M3 antagonist. The mediating influence of parasympathetic activation can thus be considered. The adenosine triphosphate-sensitive potassium (K-ATP) channel is a key mediator of the cerebral action of insulin. The plasma glucose-lowering action of insulin was abolished by cerebral administration of glibenclamide or repaglinide at concentrations sufficient to block K-ATP channels. In conclusion, our findings suggest that cerebral insulin may induce insulin release by stimulating the opening of K-ATP channels, which in turn activate parasympathetic tone in pancreatic tissue.

Key words

insulin - intracerebral injection - vagotomy - ATP-sensitive potassium channel - rat

References

  • 1 Wada A, Yokoo H, Yanagita T, Kobayashi H. New twist on neuronal insulin receptor signaling in health, disease, and therapeutics.  J Pharmacol Sci. 2005;  99 128-143
    Search in Google Scholar
  • 2 Plum L, Belgardt BF, Bruning JC. Central insulin action in energy and glucose homeostasis.  J Clin Invest. 2006;  116 1761-1766
    Search in Google Scholar
  • 3 Niswender KD, Baskin DG, Schwartz MW. Insulin and its evolving partnership with leptin in the hypothalamic control of energy homeostasis.  Trends Endocrinol Metab. 2004;  15 362-369
    Search in Google Scholar
  • 4 Plum L, Schubert M, Bruning JC. The role of insulin receptor signaling in the brain.  Trends Endocrinol Metab. 2005;  16 59-65
    Search in Google Scholar
  • 5 Obici S, Zhang BB, Karkanias G, Rossetti L. Hypothalamic insulin signaling is required for inhibition of glucose production.  Nat Med. 2002;  8 1376-1382
    Search in Google Scholar
  • 6 Pocai A, Lam TK, Gutierrez-Juarez R, Obici S, Schwartz GJ, Bryan J, Aguilar-Bryan L, Rossetti L. Hypothalamic K(ATP) channels control hepatic glucose production.  Nature. 2005;  434 1026-1031
    Search in Google Scholar
  • 7 Woods SC, Makous W, Hutton RA. Temporal parameters of conditioned hypoglycemia.  J Comp Physiol Psychol. 1969;  69 301-307
    Search in Google Scholar
  • 8 Hutton RA, Woods SC, Makous WL. Conditioned hypoglycemia: Pseudoconditioning controls.  J Comp Physiol Psychol. 1970;  71 198-201
    Search in Google Scholar
  • 9 Woods SC. Conditioned hypoglycemia: effect of vagotomy and pharmacological blockade.  Am J Physiol. 1972;  223 1424-1427
    Search in Google Scholar
  • 10 Stockhorst U, Gritzmann E, Klopp K, Schottenfeld-Naor Y, Hübinger A, Berresheim HW, Steingrüber HJ, Gries FA. Classical conditioning of insulin effects in healthy humans.  Psychosom Med. 1999;  61 424-435
    Search in Google Scholar
  • 11 Stockhorst U, Steingruber HJ, Scherbaum WA. Classically conditioned responses following repeated insulin and glucose administration in humans.  Behav Brain Res. 2000;  110 143-159
    Search in Google Scholar
  • 12 Stockhorst U, Mahl N, Krueger M, Huenig A, Schottenfeld-Naor Y, Huebinger A, Berresheim HW, Steingrueber HJ, Scherbaum WA. Classical conditioning and conditionability of insulin and glucose effects in healthy humans.  Physiol Behav. 2004;  81 375-388
    Search in Google Scholar
  • 13 Norgren R, Smith GP. Central distribution of subdiaphragmatic vagal branches in the rat.  J Comp Neurol. 1988;  273 207-223
    Search in Google Scholar
  • 14 Duttaroy A, Zimliki CL, Gautam D, Cui Y, Mears D, Wess J. Muscarinic stimulation of pancreatic insulin and glucagon release is abolished in m3 muscarinic acetylcholine receptor-deficient mice.  Diabetes. 2004;  53 1714-1720
    Search in Google Scholar
  • 15 Iismaa TP, Kerr EA, Wilson JR, Carpenter L, Sims N, Biden TJ. Quantitative and functional characterization of muscarinic receptor subtypes in insulin-secreting cell lines and rat pancreatic islets.  Diabetes. 2000;  49 392-398
    Search in Google Scholar
  • 16 Tang SH, Sharp GW. Identification of muscarinic receptor subtypes in RINm5F cells by means of polymerase chain reaction, subcloning, and DNA sequencing.  Diabetes. 1997;  46 1419-1423
    Search in Google Scholar
  • 17 Barlow RB, McMillen LS, Veale MA. The use of 4-diphenylacetoxy-N-(2-chloroethyl)piperidine (4-DAMP mustard) for estimating the apparent affinities of some agonists acting at muscarinic receptors in guinea-pig ileum.  Br J Pharmacol. 1991;  102 657-662
    Search in Google Scholar
  • 18 Nonogaki K. New insights into sympathetic regulation of glucose and fat metabolism.  Diabetologia. 2000;  43 533-549
    Search in Google Scholar
  • 19 Teff KL. Visceral nerves: vagal and sympathetic innervation.  JPEN J Parenter Enteral Nutr. 2008;  32 569-571
    Search in Google Scholar
  • 20 Matsuhisa M, Yamasaki Y, Shiba Y, Nakahara I, Kuroda A, Tomita T, Iida M, Ikeda M, Kajimoto Y, Kubota M, Hori M. Important role of the hepatic vagus nerve in glucose uptake and production by the liver.  Metabolism. 2000;  49 11-16
    Search in Google Scholar
  • 21 Gautam D, Han SJ, Hamdan FF, Jeon J, Li B, Li JH, Cui Y, Mears D, Lu H, Deng C, Heard T, Wess J. A critical role for beta cell M3 muscarinic acetylcholine receptors in regulating insulin release and blood glucose homeostasis in vivo.  Cell Metab. 2006;  3 449-461
    Search in Google Scholar
  • 22 Vatamaniuk MZ, Horyn OV, Vatamaniuk OK, Doliba NM. Acetylcholine affects rat liver metabolism via type 3 muscarinic receptors in hepatocytes.  Life Sci. 2003;  72 1871-1882
    Search in Google Scholar
  • 23 Fischbach GD, Frank E, Jessell TM, Rubin LL, Schuetze SM. Accumulation of acetylcholine receptors and acetylcholinesterase at newly formed nerve-muscle synapses.  Pharmacol Rev. 1978;  30 411-428
    Search in Google Scholar
  • 24 Panten U, Schwanstecher M, Schwanstecher C. Sulfonylurea receptors and mechanism of sulfonylurea action.  Exp Clin Endocrinol Diabetes. 1996;  104 1-9
    Search in Google Scholar
  • 25 Quesada I, Soria B. Intracellular location of KATP channels and sulphonylurea receptors in the pancreatic beta-cell: new targets for oral antidiabetic agents.  Curr Med Chem. 2004;  11 2707-2716
    Search in Google Scholar

Correspondence

Prof. J-T. Cheng

Department of Pharmacology College of Medicine

National Cheng Kung University

Tainan City

70101 Taiwan

R. O. C.

Phone: +886/6/331 85 16

Fax: +886/6/238 65 48

Email: jtcheng@mail.ncku.edu.tw