MECHANISM OF GLUCOSE-INDUCED BIPHASIC INSULIN RELEASE - PHYSIOLOGICAL-ROLE OF ADENOSINE TRIPHOSPHATE-SENSITIVE K+ CHANNEL-INDEPENDENT GLUCOSE ACTION

被引：52

作者：

TAGUCHI, N ^{[1
]}

AIZAWA, T ^{[1
]}

SATO, Y ^{[1
]}

ISHIHARA, F ^{[1
]}

HASHIZUME, K ^{[1
]}

机构：

[1] SHINSHU UNIV, SCH MED, DEPT GERIATR ENDOCRINOL & METAB, MATSUMOTO, NAGANO 390, JAPAN

来源：

ENDOCRINOLOGY | 1995年 / 136卷 / 09期

关键词：

D O I：

10.1210/en.136.9.3942

中图分类号：

R5 [内科学];

学科分类号：

1002 ; 100201 ;

摘要：

The mechanism of glucose-induced biphasic insulin release by the B cell was investigated using isolated rat pancreatic islets. In perifusion experiments, 16.7 mM glucose in combination with 25 mM K+ transformed the high K+-induced monophasic insulin release into a biphasic one in the presence of diazoxide (Dz), an ATP-sensitive K+ channel opener. Inclusion of Dz during the initial 6 min of glucose stimulation abolished the first phase, but was without effect on the second phase. In batch incubation experiments, fuels, including 16.7 mM glucose, 6 mM D-glyceraldehyde, and 10 mM 2-ketoisocaproate, but not sulfonylurea, caused time-dependent potentiation of the B cell so that the response to 25 mM K+, applied later, was increased in the fuel-primed islets. Inclusion of Dz or lowering extracellular Ca2+ (to micromolar range) during the priming, which eliminates the initiation of insulin release, did not eradicate the potentiation. We conclude that high glucose closes ATP-sensitive K+ channels, leading to membrane depolarization, Ca2+ influx, and initiation of insulin release (first phase), and subsequently self-augments insulin release in an ATP-sensitive K+ channel-independent manner (second phase), acting at steps distal to cytosolic Ca2+ elevation. The biphasic insulin release is thus generated by an interaction of ATP-sensitive K+ channel-dependent and -independent glucose actions.

引用

页码：3942 / 3948

页数：7

共 52 条

[1] ATP-SENSITIVE K+ CHANNEL-INDEPENDENT GLUCOSE ACTION IN RAT PANCREATIC BETA-CELL [J].

AIZAWA, T ;

SATO, Y ;

ISHIHARA, F ;

TAGUCHI, N ;

KOMATSU, M ;

SUZUKI, N ;

HASHIZUME, K ;

YAMADA, T .

AMERICAN JOURNAL OF PHYSIOLOGY, 1994, 266 (03) :C622-C627

[2]

Aizawa T, 1992, Endocr Regul, V26, P159

[3]

ASHBY JP, 1981, DIABETOLOGIA, V21, P230

[4] GLUCOSE METABOLISM IN MOUSE PANCREATIC ISLETS [J].

ASHCROFT, SJ ;

HEDESKOV, CJ ;

RANDLE, PJ .

BIOCHEMICAL JOURNAL, 1970, 118 (01) :143-&

[5] GLUCOSE-INDUCED INSULIN RELEASE IN ISLETS OF YOUNG-RATS - TIME-DEPENDENT POTENTIATION AND EFFECTS OF 2-BROMOSTEARATE [J].

BLISS, CR ;

SHARP, GWG .

AMERICAN JOURNAL OF PHYSIOLOGY, 1992, 263 (05) :E890-E896

[6] POTENTIATION OF INSULIN RELEASE BY GLUCOSE IN MAN .1. QUANTITATIVE-ANALYSIS OF ENHANCEMENT OF GLUCOSE-INDUCED INSULIN-SECRETION BY PRETREATMENT WITH GLUCOSE IN NORMAL SUBJECTS [J].

CERASI, E .

ACTA ENDOCRINOLOGICA, 1975, 79 (03) :483-501

[7] THE IMPORTANCE OF CA-2+ FOR GLUCOSE-INDUCED PRIMING IN PANCREATIC-ISLETS [J].

CHALMERS, JA ;

SHARP, GWG .

BIOCHIMICA ET BIOPHYSICA ACTA, 1989, 1011 (01) :46-51

[8]

COOK DL, 1990, DIABETES MELLITUS TH, P89

[9] DYNAMICS OF INSULIN SECRETION BY PERFUSED RAT PANCREAS [J].

CURRY, DL ;

BENNETT, LL ;

GRODSKY, GM .

ENDOCRINOLOGY, 1968, 83 (03) :572-&

[10] MECHANISMS BY WHICH GLUCOSE CAN CONTROL INSULIN RELEASE INDEPENDENTLY FROM ITS ACTION ON ADENOSINE TRIPHOSPHATE-SENSITIVE K+ CHANNELS IN MOUSE B-CELLS [J].

GEMBAL, M ;

DETIMARY, P ;

GILON, P ;

GAO, ZY ;

HENQUIN, JC .

JOURNAL OF CLINICAL INVESTIGATION, 1993, 91 (03) :871-880

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