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Dysfunctional β-cell autophagy induces β-cell stress and enhances islet immunogenicity

Matthew C. Austin, Charanya Muralidharan, Saptarshi Roy, Justin J. Crowder, Jon D. Piganelli, Amelia K. Linnemann

2025Frontiers in Immunology14 citationsDOIOpen Access PDF

Abstract

Background Type 1 Diabetes (T1D) is caused by a combination of genetic and environmental factors that trigger autoimmune-mediated destruction of pancreatic β-cells. Defects in β-cell stress response pathways such as autophagy may play an important role in activating and/or exacerbating the immune response in disease development. Previously, we discovered that β-cell autophagy is impaired prior to the onset of T1D, implicating this pathway in T1D pathogenesis. Aims To assess the role of autophagy in β-cell health and survival, and whether defects in autophagy render islets more immunogenic. Methods We knocked out the critical autophagy enzyme, ATG7, in the β-cells of mice (ATG7 Δβ-cell ) then monitored blood glucose, performed glucose tolerance tests, and evaluated bulk islet mRNA and protein. We also assessed MHC-I expression and presence of CD45+ immune cells in ATG7 Δβ-cell islets and evaluated how impaired autophagy affects EndoC-βH1 HLA-I expression under basal and IFNα stimulated conditions. Lastly, we co-cultured ATG7 Δβ-cell islet cells with diabetogenic BDC2.5 helper T cells and evaluated T cell activation. Results We found that all ATG7 Δβ-cell mice developed diabetes between 11-15 weeks of age. Gene ontology analysis revealed a significant upregulation of pathways involved in inflammatory processes, response to ER stress, and the ER-associated degradation pathway. Interestingly, we also observed upregulation of proteins involved in MHC-I presentation, suggesting that defective β-cell autophagy may alter the immunopeptidome, or antigen repertoire, and enhance β-cell immune visibility. In support of this hypothesis, we observed increased MHC-I expression and CD45+ immune cells in ATG7 Δβ-cell islets. We also demonstrate that HLA-I is upregulated in EndoC β-cells when autophagic degradation is inhibited. This effect was observed under both basal and IFNα stimulated conditions. Conversely, a stimulator of lysosome acidification/function, C381, decreased HLA-I expression. Lastly, we showed that in the presence of islet cells with defective autophagy, there is enhanced BDC2.5 T cell activation. Conclusions Our findings demonstrate that β-cell autophagy is critical to cell survival/function. Defective β-cell autophagy induces ER stress, alters pathways of antigen production, and enhances MHC-I/HLA-I presentation to surveilling immune cells. Overall, our results suggest that defects in autophagy make β-cells more susceptible to immune attack and destruction.

Topics & Concepts

AutophagyImmune systemDownregulation and upregulationBiologyCell biologyCellT cellMajor histocompatibility complexAntigen presentationImmunologyApoptosisGeneGeneticsPancreatic function and diabetesDiabetes and associated disordersAutophagy in Disease and Therapy
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