E3 ubiquitin ligase CHIP facilitates cAMP and cGMP signalling cross-talk by polyubiquitinating PDE9A.

IF 9.4 1区生物学 Q1 BIOCHEMISTRY & MOLECULAR BIOLOGY

EMBO Journal Pub Date : 2025-01-13 DOI:10.1038/s44318-024-00351-7

Xiaoyan Hao, Zhengwei Hu, Mengjie Li, Shuo Zhang, Mibo Tang, Chenwei Hao, Shasha Qi, Yuanyuan Liang, Michael F Almeida, Kaitlan Smith, Chunyan Zuo, Yanmei Feng, Mengnan Guo, Dongrui Ma, Shuangjie Li, Zhiyun Wang, Yuemeng Sun, Zhifen Deng, Chengyuan Mao, Zongping Xia, Yong Jiang, Yanxia Gao, Yuming Xu, Jonathan C Schisler, Changhe Shi

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引用次数: 0

Abstract

The carboxyl terminus of Hsc70-interacting protein (CHIP) is pivotal for managing misfolded and aggregated proteins via chaperone networks and degradation pathways. In a preclinical rodent model of CHIP-related ataxia, we observed that CHIP mutations lead to increased levels of phosphodiesterase 9A (PDE9A), whose role in this context remains poorly understood. Here, we investigated the molecular mechanisms underlying the role of PDE9A in CHIP-related ataxia and demonstrated that CHIP binds to PDE9A, facilitating its polyubiquitination and autophagic degradation. Conversely, dysfunctional CHIP disrupts this process, resulting in PDE9A accumulation, increased cGMP hydrolysis, and impaired PKG phosphorylation of CHIP at serine 19. This cascade further amplifies PDE9A accumulation, ultimately disrupting mitophagy and triggering neuronal apoptosis. Elevated PKA levels inhibit PDE9A degradation, further exacerbating this neuronal dysfunction. Notably, pharmacological inhibition of PDE9A via Bay 73-6691 or virus-mediated CHIP expression restored the balance of cGMP/cAMP signalling. These interventions protect against cerebellar neuropathologies, particularly Purkinje neuron mitophagy dysfunction. Thus, PDE9A upregulation considerably exacerbates ataxia associated with CHIP mutations, and targeting the interaction between PDE9A and CHIP is an innovative therapeutic strategy for CHIP-related ataxia.

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E3泛素连接酶CHIP通过多泛素化PDE9A促进cAMP和cGMP信号串导。

hsc70相互作用蛋白（CHIP）的羧基端是通过伴侣网络和降解途径管理错误折叠和聚集蛋白的关键。在CHIP相关共济失调的临床前啮齿动物模型中，我们观察到CHIP突变导致磷酸二酯酶9A （PDE9A）水平升高，其在这种情况下的作用尚不清楚。在这里，我们研究了PDE9A在CHIP相关共济失调中作用的分子机制，并证明CHIP与PDE9A结合，促进其多泛素化和自噬降解。相反，CHIP功能失调会破坏这一过程，导致PDE9A积累，cGMP水解增加，PKG在19号丝氨酸上的CHIP磷酸化受损。这个级联进一步放大PDE9A的积累，最终破坏线粒体自噬并引发神经元凋亡。升高的PKA水平抑制PDE9A的降解，进一步加剧了这种神经功能障碍。值得注意的是，通过Bay 73-6691或病毒介导的CHIP表达对PDE9A的药理学抑制恢复了cGMP/cAMP信号的平衡。这些干预措施可以防止小脑神经病变，特别是浦肯野神经元自噬功能障碍。因此，PDE9A上调显著加剧了与CHIP突变相关的共济失调，靶向PDE9A与CHIP之间的相互作用是治疗CHIP相关共济失调的一种创新策略。

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

EMBO Journal 生物-生化与分子生物学

CiteScore

18.90

自引率

0.90%

发文量

246

审稿时长

1.5 months

期刊介绍： The EMBO Journal has stood as EMBO's flagship publication since its inception in 1982. Renowned for its international reputation in quality and originality, the journal spans all facets of molecular biology. It serves as a platform for papers elucidating original research of broad general interest in molecular and cell biology, with a distinct focus on molecular mechanisms and physiological relevance. With a commitment to promoting articles reporting novel findings of broad biological significance, The EMBO Journal stands as a key contributor to advancing the field of molecular biology.