Hippo 信号通路在器官再生过程中的作用机制研究进展

陈帅; 李安鹏; 李星星; 赵庆杰; 邹燕

doi:10.12206/j.issn.2097-2024.202301008

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Hippo 信号通路在器官再生过程中的作用机制研究进展

海军军医大学药学系, 上海 200433

92805部队医院, 山东青岛 266300

详细信息

作者简介:
陈　帅，硕士，Email：467022514@qq.com

通讯作者: 邹　燕，博士，教授，研究方向：多肽药物研究，Email：zouyan0622@126.com

Research progress on the mechanism of Hippo signaling pathway in organ regeneration

School of Pharmacy, Naval Medical University, Shanghai 200433, China

92805 Military Hospital, Qingdao 266300, China

摘要: Hippo 信号通路是多细胞动物体内调节细胞增殖和凋亡的主要信号通路之一，在组织稳态维持和器官生长调控中都发挥着非常重要的功能。大多数哺乳动物的再生潜力有限，近年来研究表明 Hippo 信号通路在多种组织器官的再生中至关重要。该综述主要介绍Hippo信号通路在器官再生中的作用以及相关靶点和抑制剂的研究进展，分析Hippo信号通路促进再生的机制，为器官再生相关疾病的治疗提供理论参考。

关键词:

Abstract: Hippo signal pathway is one of the main signal pathways regulating cell proliferation and apoptosis in multicellular animals, which plays a vital role in the maintenance of tissue homeostasis and the regulation of organ growth. Most mammals have limited regenerative potential, and recent studies have shown that Hippo signal pathway is critical in the regeneration of various tissues and organs. The role of Hippo signaling pathway in organ regeneration and the research progress of related targets were introduced, the mechanism of Hippo signaling pathway promoting regeneration analyzes were aralyzed in this review, which provide theoretical reference for the treatment of diseases related to organ regeneration.

Key words:

Hippo 信号通路在器官再生过程中的作用机制研究进展

1. 海军军医大学药学系, 上海 200433

2. 92805部队医院, 山东青岛 266300

作者简介:
陈　帅，硕士，Email：467022514@qq.com

通讯作者: 邹　燕，博士，教授，研究方向：多肽药物研究，Email：zouyan0622@126.com

收稿日期: 2023-01-10

修回日期: 2023-06-07

刊出日期: 2023-08-25

关键词:

Hippo 信号通路 /

器官再生 /

靶点 /

抑制剂

全文HTML

多细胞生物的出现是进化过程的一个里程碑事件，器官大小的精密调控对于多细胞动物的发育和再生过程都非常重要。Hippo 信号通路是多细胞动物体内调节细胞增殖和凋亡的主要信号通路之一，在组织稳态维持和器官大小调控中起着关键作用^[1] 。

Hippo信号通路由一系列蛋白激酶及转录共激活因子组成，可调节细胞增殖和凋亡^[2-3]，在胚胎发育和组织器官生长发育中至关重要^[4]。以哺乳动物为例，当Hippo信号通路激活的时候，在上游信号输入因子的作用下，MST1/2被磷酸化后与SAV结合，进一步激活LATS1/2以及MOB1A/B，两者结合后将下游的转录辅因子YAP/TAZ磷酸化，随后与14-3-3蛋白结合，最后被降解或隔离在细胞质中，无法进入细胞核进行转录，从而阻止细胞增殖。当Hippo信号通路被阻断或失活时，YAP/TAZ进入细胞核，与TEAD形成功能杂交转录因子，启动促增殖和促生存基因，促进细胞增殖（图1）^[5-7]。

图 1 Hippo信号通路模式图

作为转录共激活因子，YAP/TAZ不具有DNA结合域，它们通过与转录因子TEAD1-4相互作用促进下游，如CTGF、CYR61、ANKRD1等靶基因的表达，从而启动YAP/TAZ的促增殖和抗凋亡功能，激活细胞周期和细胞存活基因的转录，促进器官的生长发育^[8]。

当Hippo信号通路各组分处于相对平衡状态时，机体可保持正常生理功能，严格控制细胞的增殖与凋亡，进而调控器官的形状与大小。最近研究表明， Hippo 信号通路在心脏、肝脏、肌肉等多种组织器官的发育与再生中发挥重要作用。然而大多数哺乳动物的再生潜力有限，只有少数器官具有一定的再生能力。本文简要概述Hippo信号通路在器官再生中的作用机制，阐明其在器官发育、再生重塑中的作用，总结靶向 Hippo信号通路的小分子及多肽抑制剂，为临床治疗器官损伤等疾病提供理论依据。

4. Hippo通路在皮肤再生中的作用机制研究

皮肤是保护机体免受外部损伤的最大器官，通过基底膜分为表皮层及真皮层。表皮通过不断更新来维持皮肤的动态平衡，表皮组织的自我更新和伤口愈合主要依赖于表皮干细胞^[39]。

YAP主要分布于皮肤基底细胞的细胞核中，是表皮干细胞增殖和组织扩张的关键调节剂，对表皮稳态的维持和伤口愈合都特别重要^[40-41]。在小鼠皮肤表皮干细胞中，敲除YAP会导致严重的表皮发育不全，小鼠的表皮变薄，角质层减少，导致表皮组织形成不足，无法维持表皮形态^[42]。在成年小鼠皮肤中缺失YAP和TAZ可轻微影响基底层细胞的增殖，并引起毛发脱落^[41]。相反，Sav1突变体中YAP的过度激活导致基底干细胞过度增殖，从而导致皮肤增厚，皮肤过度增生并伴有不成熟分化，最终导致鳞状细胞癌^[43]。

5. 总结与展望

综上所述，Hippo 信号通路与人类组织器官大小调控与再生密切相关。近年来，关于Hippo 信号通路在器官再生过程中的作用机制研究取得了一些进展，同时也确认了一些影响Hippo信号通路的相关靶点，但是人们对 Hippo 信号通路的认识还不够完善，比如需进一步探究如何精细调节 Hippo 通路信号及影响因子等。另外，Hippo 信号通路与其他信号通路在调控器官再生相关机制中既有交叉又有重合，将来的研究需要考虑这些信号通路的参与所带来的干扰。

近期研究发现了很多潜在化合物能够调节Hippo信号通路的活性，但是大部分药物的研究局限于动物试验阶段，进入临床试验的药物比较少。同时也产生了很多新的问题，很多药物的作用靶点缺乏特异性，可能会带来其他不良反应，因此有必要进行进一步的研究。

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