Desmoglein-driven dynamic signaling in pemphigus vulgaris: a systematic review of pathogenic pathways.

IF 6.5 1区医学 Q1 CELL & TISSUE ENGINEERING

npj Regenerative Medicine Pub Date : 2025-08-22 DOI:10.1038/s41536-025-00426-x

Siavash Rahimi, William V J Hariton, Fattaneh Khalaj, Ralf J Ludwig, Luca Borradori, Eliane J Müller

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Abstract

Epithelial tissue integrity is maintained through specialized intercellular junctions known to coordinate homeostatic processes. In this context, outside-in signaling and mechanotransduction through desmosomal cadherins, the building blocks of desmosomes and main stress bearers in epithelial tissue, are only starting to emerge. To better understand the dual function of desmosomal cadherins in structural integrity and cellular signaling, we here performed a systematic, unbiased review on pathogenic signaling effectors identified in models and patients with pemphigus vulgaris (PV). PV is an autoimmune blistering disorder characterized by disruption of desmosomal transadhesion through autoantibodies mainly targeting the desmosomal cadherins desmoglein (Dsg) 3 or Dsg1 and Dsg3. The survey of functionally validated pathogenic pathways published since inception in 1977 up to mid-2024 identifies 128 studies and 128 signaling molecules, highlighting a coherent network of biomechanical, bioelectrical, and biochemical signaling events. This in-depth analysis will stimulate future research as well as development of potential therapeutic applications beyond PV.

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寻常型天疱疮的粘粒蛋白驱动的动态信号：对致病途径的系统回顾。

上皮组织的完整性是通过专门的细胞间连接来维持的，这些细胞间连接可以协调稳态过程。在这种情况下，通过桥粒钙粘蛋白的外向内信号传导和机械转导才刚刚开始出现，桥粒钙粘蛋白是上皮组织中桥粒和主要应激承受者的基石。为了更好地了解桥粒钙粘蛋白在结构完整性和细胞信号传导方面的双重功能，我们在这里对寻常型天疱疮（PV）模型和患者中发现的致病性信号效应物进行了系统、公正的回顾。PV是一种自身免疫性起泡疾病，其特征是通过主要针对桥粒钙粘蛋白桥粒蛋白（Dsg） 3或Dsg1和Dsg3的自身抗体破坏桥粒的转粘。从1977年开始到2024年中期发表的功能验证的致病途径调查确定了128项研究和128个信号分子，突出了生物力学，生物电和生化信号事件的连贯网络。这一深入的分析将刺激未来的研究以及PV以外潜在治疗应用的发展。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

npj Regenerative Medicine Engineering-Biomedical Engineering

CiteScore

10.00

自引率

1.40%

发文量

审稿时长

12 weeks

期刊介绍： Regenerative Medicine, an innovative online-only journal, aims to advance research in the field of repairing and regenerating damaged tissues and organs within the human body. As a part of the prestigious Nature Partner Journals series and in partnership with ARMI, this high-quality, open access journal serves as a platform for scientists to explore effective therapies that harness the body's natural regenerative capabilities. With a focus on understanding the fundamental mechanisms of tissue damage and regeneration, npj Regenerative Medicine actively encourages studies that bridge the gap between basic research and clinical tissue repair strategies.