par Austin, Amazon A.L.F.;Daniels Gatward, Lydia L.F.;Cnop, Miriam 
;Santos, Gabriel;Andersson, David;Sharp, Sally;Gentry, Clive;Bevan, Stuart;Jones, Peter Martin;King, Aileen A.J.F.
Référence Diabetes (New York, N.Y.), 69, 12, page (2667-2677)
Publication Publié, 2020-12-01
;Santos, Gabriel;Andersson, David;Sharp, Sally;Gentry, Clive;Bevan, Stuart;Jones, Peter Martin;King, Aileen A.J.F.Référence Diabetes (New York, N.Y.), 69, 12, page (2667-2677)
Publication Publié, 2020-12-01
Article révisé par les pairs
| Résumé : | Animal models are important tools in diabetes research because ethical and logistical constraints limit access to human tissue. β-Cell dysfunction is a common contributor to the pathogenesis of most types of diabetes. Spontaneous hyperglycemia was developed in a colony of C57BL/6J mice at King’s College London (KCL). Sequencing identified a mutation in the Ins2 gene, causing a glycine-to-serine substitution at position 32 on the B chain of the preproinsulin 2 molecule. Mice with the Ins2+/G32S mutation were named KCL Ins2 G32S (KINGS) mice. The same mutation in humans (rs80356664) causes dominantly inherited neonatal diabetes. Mice were characterized, and β-cell function was investigated. Male mice became overtly diabetic at ∼5 weeks of age, whereas female mice had only slightly elevated nonfasting glycemia. Islets showed decreased insulin content and impaired glucose-induced insulin secretion, which was more severe in males. Transmission electron microscopy and studies of gene and protein expression showed β-cell endoplasmic reticulum (ER) stress in both sexes. Despite this, β-cell numbers were only slightly reduced in older animals. In conclusion, the KINGS mouse is a novel model of a human form of diabetes that may be useful to study β-cell responses to ER stress. |
