GRAIL1 Stabilizes Misfolded Mutant p53 through a Ubiquitin Ligase-Independent, Chaperone Regulatory Function.

IF 4.1 2区医学 Q2 CELL BIOLOGY

Molecular Cancer Research Pub Date : 2024-11-01 DOI:10.1158/1541-7786.MCR-24-0361

Paramita Ray, Sangeeta Jaiswal, Daysha Ferrer-Torres, Zhuwen Wang, Derek Nancarrow, Meghan Curtin, May San Martinho, Shannon M Lacy, Srimathi Kasturirangan, Dafydd Thomas, Jason R Spence, Matthias C Truttmann, Kiran H Lagisetty, Theodore S Lawrence, Thomas D Wang, David G Beer, Dipankar Ray

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引用次数: 0

Abstract

Frequent (>70%) TP53 mutations often promote its protein stabilization, driving esophageal adenocarcinoma (EAC) development linked to poor survival and therapy resistance. We previously reported that during Barrett's esophagus progression to EAC, an isoform switch occurs in the E3 ubiquitin ligase RNF128 (aka GRAIL-gene related to anergy in lymphocytes), enriching isoform 1 (hereby GRAIL1) and stabilizing the mutant p53 protein. Consequently, GRAIL1 knockdown degrades mutant p53. But, how GRAIL1 stabilizes the mutant p53 protein remains unclear. In search for a mechanism, here, we performed biochemical and cell biology studies to identify that GRAIL has a binding domain (315-PMCKCDILKA-325) for heat shock protein 40/DNAJ. This interaction can influence DNAJ chaperone activity to modulate misfolded mutant p53 stability. As predicted, either the overexpression of a GRAIL fragment (Frag-J) encompassing the DNAJ binding domain or a cell-permeable peptide (Pep-J) encoding the above 10 amino acids can bind and inhibit DNAJ-Hsp70 co-chaperone activity, thus degrading misfolded mutant p53. Consequently, either Frag-J or Pep-J can reduce the survival of mutant p53 containing dysplastic Barrett's esophagus and EAC cells and inhibit the growth of patient-derived organoids of dysplastic Barrett's esophagus in 3D cultures. The misfolded mutant p53 targeting and growth inhibitory effects of Pep-J are comparable with simvastatin, a cholesterol-lowering drug that can degrade misfolded mutant p53 also via inhibiting DNAJA1, although by a distinct mechanism. Implications: We identified a novel ubiquitin ligase-independent, chaperone-regulating domain in GRAIL and further synthesized a first-in-class novel misfolded mutant p53 degrading peptide having future translational potential.

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GRAIL1 通过独立于泛素连接酶的伴侣调节功能稳定折叠错误的突变 p53。

TP53的频繁突变（>70%）通常会促进其蛋白的稳定，从而推动食管腺癌（EAC）的发展，而食管腺癌的发展与生存率低和耐药性有关。我们以前曾报道过，在巴雷特病（BE）发展为 EAC 的过程中，E3 泛素连接酶 RNF128（又名 GRAIL--与淋巴细胞中的过敏有关的基因）会发生异构体转换，富集异构体 1（即 GRAIL1），从而稳定突变的 p53 蛋白。因此，敲除 GRAIL1 会降解突变 p53。但是，GRAIL1 是如何稳定突变 p53 蛋白的仍不清楚。为了寻找这一机制，我们进行了生化和细胞生物学研究，发现 GRAIL 有一个与 Hsp40/DNAJ 结合的结构域（315-PMCKCDILKA-325）。这种相互作用可以影响 DNAJ 合子的活性，从而调节折叠错误的突变体 p53 的稳定性。正如预测的那样，无论是过量表达包含 DNAJ 结合域的 GRAIL 片段（Frag-J），还是编码上述 10 个氨基酸的细胞渗透肽（Pep-J），都能结合并抑制 DNAJ-Hsp70 协同伴侣的活性，从而降解折叠错误的突变体 p53。因此，Frag-J 或 Pep-J 都能降低含有突变 p53 的发育不良 BE 和 EAC 细胞的存活率，并抑制患者来源的发育不良 BE 器官组织（PDOs）在三维培养中的生长。Pep-J对错误折叠突变体p53的靶向和生长抑制作用与辛伐他汀（一种降低胆固醇的药物）不相上下，后者也能通过抑制DNAJA1降解错误折叠突变体p53，但机制不同。意义：我们在 GRAIL 中发现了一个独立于泛素连接酶的新型伴侣调节结构域，并进一步合成了一种具有未来转化潜力的一流新型错误折叠突变体 p53 降解肽。

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

Molecular Cancer Research 医学-细胞生物学

CiteScore

9.90

自引率

0.00%

发文量

280

审稿时长

4-8 weeks

期刊介绍： Molecular Cancer Research publishes articles describing novel basic cancer research discoveries of broad interest to the field. Studies must be of demonstrated significance, and the journal prioritizes analyses performed at the molecular and cellular level that reveal novel mechanistic insight into pathways and processes linked to cancer risk, development, and/or progression. Areas of emphasis include all cancer-associated pathways (including cell-cycle regulation; cell death; chromatin regulation; DNA damage and repair; gene and RNA regulation; genomics; oncogenes and tumor suppressors; signal transduction; and tumor microenvironment), in addition to studies describing new molecular mechanisms and interactions that support cancer phenotypes. For full consideration, primary research submissions must provide significant novel insight into existing pathway functions or address new hypotheses associated with cancer-relevant biologic questions.