Austin Matthew C, Muralidharan Charanya, Roy Saptarshi, Crowder Justin J, Piganelli Jon D, Linnemann Amelia K
Department of Biochemistry & Molecular Biology, Indiana University School of Medicine, Indianapolis, IN, United States.
Department of Medicine, Indiana University School of Medicine, Indianapolis, IN, United States.
Front Immunol. 2025 Jan 29;16:1504583. doi: 10.3389/fimmu.2025.1504583. eCollection 2025.
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.
To assess the role of autophagy in β-cell health and survival, and whether defects in autophagy render islets more immunogenic.
We knocked out the critical autophagy enzyme, ATG7, in the β-cells of mice (ATG7) 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 islets and evaluated how impaired autophagy affects EndoC-βH1 HLA-I expression under basal and IFNα stimulated conditions. Lastly, we co-cultured ATG7 islet cells with diabetogenic BDC2.5 helper T cells and evaluated T cell activation.
We found that all ATG7 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 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.
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.
1型糖尿病(T1D)由遗传和环境因素共同引发,这些因素会触发自身免疫介导的胰腺β细胞破坏。β细胞应激反应途径(如自噬)的缺陷可能在疾病发展过程中激活和/或加剧免疫反应方面发挥重要作用。此前,我们发现T1D发病前β细胞自噬受损,这表明该途径与T1D发病机制有关。
评估自噬在β细胞健康和存活中的作用,以及自噬缺陷是否会使胰岛更具免疫原性。
我们敲除小鼠β细胞中的关键自噬酶ATG7(ATG7),然后监测血糖、进行葡萄糖耐量试验,并评估胰岛整体mRNA和蛋白质水平。我们还评估了ATG7胰岛中MHC-I的表达以及CD45 +免疫细胞的存在情况,并评估了基础和IFNα刺激条件下自噬受损如何影响EndoC-βH1 HLA-I的表达。最后,我们将ATG7胰岛细胞与致糖尿病的BDC2.5辅助性T细胞共培养,并评估T细胞活化情况。
我们发现所有ATG7小鼠在11 - 15周龄时都患上了糖尿病。基因本体分析显示,参与炎症过程、内质网应激反应和内质网相关降解途径的通路显著上调。有趣的是,我们还观察到参与MHC-I呈递的蛋白质上调,这表明β细胞自噬缺陷可能会改变免疫肽组或抗原库,并增强β细胞的免疫可见性。为支持这一假设,我们在ATG7胰岛中观察到MHC-I表达增加和CD45 +免疫细胞增多。我们还证明,当自噬降解受到抑制时,EndoC β细胞中的HLA-I会上调。在基础和IFNα刺激条件下均观察到这种效应。相反,溶酶体酸化/功能刺激剂C381可降低HLA-I表达。最后,我们表明,在存在自噬缺陷的胰岛细胞时,BDC2.5 T细胞活化增强。
我们的研究结果表明,β细胞自噬对细胞存活/功能至关重要。β细胞自噬缺陷会诱导内质网应激,改变抗原产生途径,并增强MHC-I/HLA-I向监视免疫细胞呈递。总体而言,我们的结果表明自噬缺陷使β细胞更容易受到免疫攻击和破坏。
