Cornichons: Evolution, AMPA receptor modulation, and emerging roles beyond the nervous system

Brain disorders (Amsterdam, Netherlands) Pub Date : 2025-06-03 DOI:10.1016/j.dscb.2025.100245

Pratibha Bharti , Anshul Assaiya , Bhavya K Dawath , Janesh Kumar

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Abstract

Cornichons are auxiliary proteins that regulate the functions of AMPA receptors (AMPARs), which mediate fast excitatory transmission in the central nervous system. Initially discovered in lower organisms, cornichons have since been found across various species, including mammals and plants, indicating their conserved and broader roles beyond the nervous system. In mammals, cornichons, particularly CNIH2 and CNIH3, modulate the trafficking, gating, and biophysical properties of AMPARs, often working alongside other auxiliary proteins such as TARPs.

Recent structural studies have provided detailed insights into the topology of cornichons, revealing their integration into AMPAR complexes and highlighting their critical role in slowing AMPAR deactivation and desensitization. Their functional impact on excitatory synaptic transmission is subunit-specific and includes the modulation of conductance and ligand affinity. Beyond their role in the central nervous system, cornichons are implicated in intracellular trafficking processes, acting as cargo receptors for various membrane proteins.

This review synthesizes current knowledge on cornichon proteins, from their evolutionary origins and structural properties to their roles in AMPAR regulation and cargo transport. The emerging understanding of cornichons in non-neuronal systems and their potential involvement in neurological diseases opens new avenues for research with potential therapeutic applications.

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柯尼松：进化，AMPA受体调节，以及神经系统以外的新角色

角蛋白是调节AMPA受体（AMPARs）功能的辅助蛋白，在中枢神经系统中介导快速兴奋传递。最初是在低等生物中发现的，后来在包括哺乳动物和植物在内的各种物种中发现了冠状体，这表明它们在神经系统之外的保守和更广泛的作用。在哺乳动物中，角蛋白，特别是CNIH2和CNIH3，调节ampar的运输、门控和生物物理特性，通常与其他辅助蛋白（如TARPs）一起工作。最近的结构研究提供了对隼状子拓扑结构的详细见解，揭示了它们与AMPAR复合物的整合，并强调了它们在减缓AMPAR失活和脱敏中的关键作用。它们对兴奋性突触传递的功能影响是亚基特异性的，包括电导和配体亲和力的调节。除了在中枢神经系统中的作用外，角状子还参与细胞内运输过程，作为各种膜蛋白的货物受体。本文综述了目前关于cornicon蛋白的知识，从它们的进化起源和结构特性到它们在AMPAR调节和货物运输中的作用。对非神经元系统中的角状子及其在神经系统疾病中的潜在参与的新认识为具有潜在治疗应用的研究开辟了新的途径。

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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