12622 Molecular Physiology And Compensatory Response In Maladapted Pancreatic Islets Of Humanized Mice Model For Type 1 Diabetes

Abstract Disclosure: A. Hussain: None. A. Aldasouqi: None. S. Rafiqi: None. S.S. Khan: None. R. Paparodis: None. J.C. Jaume: None. S. Imam: None. Genetic predisposition linked with specific HLA (DR and DQ) alleles, environmental factors, and other uncharacterized physiological aberrations triggers a...

Ausführliche Beschreibung

Gespeichert in:
Bibliographische Detailangaben
Veröffentlicht in:Journal of the Endocrine Society 2024-10, Vol.8 (Supplement_1)
Hauptverfasser: Hussain, Ashaq, Aldasouqi, Ahmad, Rafiqi, Shafiya Imtiaz, Khan, Saira Saeed, Paparodis, Rodis, Jaume, Juan Carlos, Imam, Shahnawaz
Format: Artikel
Sprache:eng
Schlagworte:
Online-Zugang:Volltext
Tags: Tag hinzufügen
Keine Tags, Fügen Sie den ersten Tag hinzu!
Beschreibung
Zusammenfassung:Abstract Disclosure: A. Hussain: None. A. Aldasouqi: None. S. Rafiqi: None. S.S. Khan: None. R. Paparodis: None. J.C. Jaume: None. S. Imam: None. Genetic predisposition linked with specific HLA (DR and DQ) alleles, environmental factors, and other uncharacterized physiological aberrations triggers an autoimmune attack and depletion of β cells in pancreatic islets, leading to decreased insulin secretion and diabetes. Our laboratory has generated humanized mice carrying the antigen-presenting HLA-DQ8 diabetes-linked haplotype and expressing the human autoantigen GAD65 in pancreatic beta cells. These humanized mice spontaneously develop type 1 diabetes (T1D) and represent the full spectrum of pathophysiological conditions experienced in T1D. Using humanized mice as a model of study, we studied the molecular physiology and compensatory response in maladapted pancreas under normal physiological conditions and hyperglycemic stress of T1D. We studied the differential expression of some important genes by quantitative PCR in maladapted islets to identify the physiological processes affected during the initial oxidative stress exerted by autoimmune conditions. Our results confirmed that levels of cyclin B, cMyc, Cyc D, Cyc E, PDGFRA, and NOTCH are reduced during autoimmune insult, reflecting the poor regenerative capacity of islet cells. However, Cyc A has an elevated expression, reflecting that islet cells, particularly the β cells of Type 1 diabetic mice, may have regenerative potential that may be explored. The genes for Desmin and Survivin showed decreased expression, whereas genes for Smad and Synuclein displayed increased expression. The genes for insulin and somatostatin showed elevated expression, whereas the gene for glucagon displayed reduced expression. The results suggest that during autoimmune insults, the β cells moderately whip up the synthesis of insulin-specific RNA to maintain the requirements. Among the endoplasmic reticulum-specific molecular chaperones, Calnexin showed an elevated expression, whereas calreticulin displayed a reduced expression. Among the genes involved with the architecture of the islet, Lamin and Integrin both display increased expression, reflecting the dynamic change in islet architecture during the autoimmune depletion of β cells. We also investigated the expression of ER-specific stress genes both at RNA and protein levels. Our preliminary results have confirmed that ER-specific stress genes showed an elevated expression d
ISSN:2472-1972
2472-1972
DOI:10.1210/jendso/bvae163.851