棕榈酰基转移酶在肿瘤中的作用及其抑制剂研究进展OA
Research progress on the role of palmitoyl acyl transferases in tumors and their inhibitors
[背景]棕榈酰化是一种常见的蛋白翻译后修饰,主要分为S-棕榈酰化、N-棕榈酰化和O-棕榈酰化,其中S-棕榈酰化最为常见.负责催化S-棕榈酰化的棕榈酰基转移酶(PAT)存在共同的催化结构域DHHC(Asp-His-His-Cys)而被称为DHHC-PAT,简称DHHC.人类DHHC家族有23个成员,与多种肿瘤的发生发展密切相关.自1979年首次报道,直到2018年DHHC20蛋白晶体结构被解析,其研究才取得突破性进展.[进展]本文首先概述了 DHHC的作用机制,其催化的蛋白质翻译后修饰对细胞各种生理活动的影响,进而导致的癌细胞增殖、生长、免疫逃逸等;接着列举了DHHC调控的癌症相关通路及DHHC在不同癌症中的作用机制;最后阐述了近年来DHHC抑制剂的研发状况.[展望]目前多项研究表明DHHC抑制剂在抑制癌细胞生长、诱导癌细胞凋亡等方面具有显著效果.本文通过综述DHHC抑制剂在癌症靶向治疗中的作用机制、研究现状,分析了其面临的挑战与未来发展前景,旨在为癌症靶向治疗提供新的思路与策略.
[Background]Palmitoylation is a prevalent form of post-translational modification in proteins.It includes S-palmitoylation,N-palmitoylation and O-palmitoylation,among which S-palmitoylation is a reversible modification and is the most extensively studied and frequently observed.Palmitoyl acyl transferases(PAT),a family of integral membrane enzymes known as DHHC(Asp-His-His-Cys),are responsible for catalyzing post-translational palmitoylation of substrate proteins,which contain a consensus signature DHHC domain.The human DHHC family comprises 23 members,which exhibit distinct functions in various tissues and cellular contexts.Substantial evidence has linked DHHC family to the oncogenesis and progression of multiple cancers,including breast,lung and colorectal cancers,where they influence tumor cell biology by regulating palmitoylation levels of key signaling pathways or oncogenes.Since the initial report of the DHHC family in 1979,research progressed relatively slowly until the crystal structure of DHHC20 was successfully elucidated in 2018.This breakthrough not only elucidated the molecular mechanisms of palmitoylation catalyzed by the DHHC domain,such as substrate recognition and the specific pathway of palmitoyl group transfer,but also laid the structural foundation for in-depth understanding of the roles of DHHC family members in diseases.Crucially,it identified critical molecular targets for structure-based anticancer drug development against DHHC enzymes,thereby propelling subsequent research toward three frontiers:resolving additional family member structures,exploring their dynamic regulatory mechanisms within tumor microenvironments,and designing isoform-specific inhibitors.[Progress]Recent studies of DHHC have demonstrated that their dysregulation is associated with tumorigenesis,establishing their inhibitors as compelling targets for anticancer therapeutics.This review first delineates the mechanistic basis of DHHC-mediated post-translational modifications and their consequent dysregulation of cellular physiology,promoting cancer cell proliferation,survival,and immune evasion.It then characterizes oncogenic pathways modulated by DHHC across malignancies'including their context-dependent regulatory mechanisms.Structure-driven development of novel inhibitors represents an emerging strategic focus in contemporary drug discovery.For instance,the small-molecule compound PF-670462 promotes DHHC8 degradation,thereby attenuating palmitoylation of glutathione peroxidase 4(GPX4)and enhancing ferroptosis sensitivity.Despite these breakthroughs,DHHC inhibitor research still faces challenges:the functional diversity of family members leads to inadequate inhibitor specificity,and the dynamic regulatory nature of palmitoylation requires drugs to possess sustained inhibitory capacity.Future studies are needed to further elucidate the structures and functions of additional DHHC family members,develop highly specific inhibitors,and explore combination therapy strategies to advance the translation of this field from bench to bedside.Finally,the review synthesizes contemporary advances in DHHC inhibitor development through three strategic paradigms:natural product discovery,drug repurposing,and structure-based drug design.[Perspective]Current research demonstrates that DHHC inhibitors significantly suppress cancer cell proliferation and induce apoptosis,underscoring their therapeutic promise.Inhibitor research has evolved from early non-specific palmitic acid analogs to structure-based precision design,though multi-dimensional breakthroughs are still needed.On one hand,in-depth characterization of each DHHC family member's structure and substrate specificity leveraging technologies like Cryo-EM is required to reveal dynamic palmitoylation regulatory mechanisms and develop highly selective inhibitors.On the other hand,given the spatiotemporal dynamics of palmitoylation in the tumor microenvironment,the design of long-acting inhibitors or exploration of PROTAC(proteolysis-targeting chimera)technologies for sustained DHHC protein regulation is imperative.Moreover,combination strategies represent a pivotal therapeutic frontier.For instance,integrating DHHC inhibitors with immune checkpoint blockade counters immune evasion to enhance anti-tumor immunity,while synergism with chemotherapy or targeted agents may overcome therapeutic resistance.Meanwhile,clinical translation research should be expedited,including identifying patient subgroups with optimal response through biomarker screening,optimizing pharmacokinetic properties,and facilitating the transition of DHHC-targeted therapies from basic research to clinical application.This review summarizes the mechanistic roles and research landscape of DHHC inhibitors in cancer-targeted therapy,analyzes existing challenges and future prospects,and aims to provide novel insights and strategies for cancer precision medicine.
宋亚丽;张承玉;李继森;刘舒雨
河北大学药学院,新型药物制剂与辅料全国重点实验室,药物化学与分子诊断教育部重点实验室,河北 保定 071002河北大学药学院,新型药物制剂与辅料全国重点实验室,药物化学与分子诊断教育部重点实验室,河北 保定 071002河北大学药学院,新型药物制剂与辅料全国重点实验室,药物化学与分子诊断教育部重点实验室,河北 保定 071002河北大学药学院,新型药物制剂与辅料全国重点实验室,药物化学与分子诊断教育部重点实验室,河北 保定 071002
医药卫生
棕榈酰基转移酶抑制剂S-棕榈酰化DHHC(Asp-His-His-Cys)癌症
palmitoyl acyl transferase inhibitorS-palmitoylationDHHC(Asp-His-His-Cys)cancer
《厦门大学学报(自然科学版)》 2026 (1)
29-41,13
国家自然科学基金(82273792)河北大学科研创新团队项目(IT2023C01)河北大学研究生创新资助项目(HBU2025SS034)
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