Alloxan and ninhydrin affect insulin release by first stimulation and then inhibition of subsequent glucose-induced insulin release from the β-cells in the islets of Langerhans. The structures of D-glucose and D-mannose, the two hexoses that protect against them and initiate insulin release, were analyzed and found to share with alloxan and ninhydrin common molecular properties. These common molecular properties were: An oxygen at C(1); a hydroxyl at C(2), either axial or equatorial; an equatorial oxygen at C(3); and at position 5 an electron density. Further structural analysis revealed that alloxan and ninhydrin would require little, if any, additional volume than that required for recognition of the active hexoses, D-glucose and D-mannose at a common site. Other hexoses (1-deoxy-D-glucose, 2-deoxy-D-glucose, D-allose, D-galactose, lyxose, xylose, 6-deoxy-D-glucose, and L-glucose) which either did not protect against alloxan and ninhydrin or did not initiate insulin release were found to vary in their structure from the active hexoses. Based on the presently available evidence, a hypothesis was advanced that alloxan, ninhydrin, and the active hexoses interact at a common receptor to initiate the first phase of insulin release.
[1]
C. D. Barry,et al.
Alloxan Stimulation and Inhibition of Insulin Release from Isolated Rat Islets of Langerhans
,
1978,
Diabetes.
[2]
P. Lacy,et al.
Effect of Alloxan on Insulin Secretion in Isolated Rat Islets Perifused in Vitro
,
1974,
Diabetes.
[3]
G. Grodsky,et al.
Regulation of pancreatic insulin and glucagon secretion.
,
1976,
Annual review of physiology.
[4]
F. Matschinsky,et al.
A comparison of the utilization rates and hormone-releasing actions of glucose, mannose, and fructose in isolated pancreatic islets.
,
1977,
The Journal of biological chemistry.
[5]
W. Bolton.
The crystal structure of alloxan
,
1964
.