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特定异构体的破坏揭示了 TAp73γ 通过瘦素在肿瘤发生中的关键作用。

Isoform-specific disruption of the gene reveals a critical role for TAp73γ in tumorigenesis via leptin.

机构信息

Comparative Oncology Laboratory, Schools of Veterinary Medicine and Medicine, University of California, Davis, Davis, United States.

Department of Pathology, University of Texas Southwestern Medical Center, Dallas, United States.

出版信息

Elife. 2023 Aug 31;12:e82115. doi: 10.7554/eLife.82115.

DOI:10.7554/eLife.82115
PMID:37650871
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10471163/
Abstract

a member of the p53 family, is expressed as TAp73 and ΔNp73 along with multiple C-terminal isoforms (α-η). ΔNp73 is primarily expressed in neuronal cells and necessary for neuronal development. Interestingly, while TAp73α is a tumor suppressor and predominantly expressed in normal cells, TAp73 is found to be frequently altered in human cancers, suggesting a role of TAp73 C-terminal isoforms in tumorigenesis. To test this, the TCGA SpliceSeq database was searched and showed that exon 11 (E11) exclusion occurs frequently in several human cancers. We also found that p73α to p73γ isoform switch resulting from E11 skipping occurs frequently in human prostate cancers and dog lymphomas. To determine whether p73α to p73γ isoform switch plays a role in tumorigenesis, CRISPR technology was used to generate multiple cancer cell lines and a mouse model in that E11 is deleted. Surprisingly, we found that in E11-deificient cells, p73γ becomes the predominant isoform and exerts oncogenic activities by promoting cell proliferation and migration. In line with this, E11-deficient mice were more prone to obesity and B-cell lymphomas, indicating a unique role of p73γ in lipid metabolism and tumorigenesis. Additionally, we found that E11deficient mice phenocopies -deficient mice with short lifespan, infertility, and chronic inflammation. Mechanistically, we showed that Leptin, a pleiotropic adipocytokine involved in energy metabolism and oncogenesis, was highly induced by p73γ,necessary for p73γ-mediated oncogenic activity, and associated with p73α to γ isoform switch in human prostate cancer and dog lymphoma. Finally, we showed that E11-knockout promoted, whereas knockdown of p73γ or Leptin suppressed, xenograft growth in mice. Our study indicates that the p73γ-Leptin pathway promotes tumorigenesis and alters lipid metabolism, which may be targeted for cancer management.

摘要

p53 家族的一员,以 TAp73 和 ΔNp73 的形式以及多个 C 端异构体(α-η)表达。ΔNp73 主要在神经元细胞中表达,对神经元发育是必需的。有趣的是,虽然 TAp73α 是一种肿瘤抑制因子,主要在正常细胞中表达,但 TAp73 在人类癌症中经常发生改变,提示 TAp73 C 端异构体在肿瘤发生中的作用。为了验证这一点,搜索了 TCGA SpliceSeq 数据库,结果表明外显子 11(E11)缺失在几种人类癌症中经常发生。我们还发现,由于 E11 跳跃,p73α 到 p73γ 异构体的转换在人类前列腺癌和犬淋巴瘤中经常发生。为了确定 p73α 到 p73γ 异构体的转换是否在肿瘤发生中起作用,我们使用 CRISPR 技术生成了多个癌细胞系和一个 E11 缺失的小鼠模型。令人惊讶的是,我们发现,在 E11 缺失的细胞中,p73γ 成为主要异构体,并通过促进细胞增殖和迁移发挥致癌作用。与此一致的是,E11 缺失的小鼠更容易肥胖和发生 B 细胞淋巴瘤,表明 p73γ 在脂质代谢和肿瘤发生中具有独特的作用。此外,我们发现 E11 缺失的小鼠表型类似于 Leptin 缺陷型小鼠,具有短寿命、不育和慢性炎症。在机制上,我们表明 Leptin 是一种参与能量代谢和肿瘤发生的多效性脂肪细胞因子,被 p73γ 高度诱导,是 p73γ 介导的致癌活性所必需的,与人类前列腺癌和犬淋巴瘤中的 p73α 到 γ 异构体转换有关。最后,我们表明 E11 敲除促进了异种移植在小鼠中的生长,而 p73γ 的敲低或 Leptin 的敲低抑制了异种移植在小鼠中的生长。我们的研究表明,p73γ-Leptin 通路促进肿瘤发生并改变脂质代谢,这可能成为癌症治疗的靶点。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/3e25/10471163/9a90e6758cd6/elife-82115-fig7.jpg
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本文引用的文献

1
The pleiotropic roles of leptin in metabolism, immunity, and cancer.瘦素在代谢、免疫和癌症中的多效作用。
J Exp Med. 2021 May 3;218(5). doi: 10.1084/jem.20191593.
2
Leptin and Cancer: Updated Functional Roles in Carcinogenesis, Therapeutic Niches, and Developments.瘦素与癌症:在癌症发生、治疗靶点和新进展中的功能作用更新。
Int J Mol Sci. 2021 Mar 11;22(6):2870. doi: 10.3390/ijms22062870.
3
Leptin promotes proliferation and inhibits apoptosis of prostate cancer cells by regulating ERK1/2 signaling pathway.瘦素通过调节 ERK1/2 信号通路促进前列腺癌细胞的增殖并抑制其凋亡。
在高瘦素血症背景下,靶向瘦素受体作为乳腺癌治疗方法的潜在作用:一项文献综述
Naunyn Schmiedebergs Arch Pharmacol. 2025 Apr;398(4):3451-3466. doi: 10.1007/s00210-024-03592-9. Epub 2024 Nov 20.
Eur Rev Med Pharmacol Sci. 2020 Aug;24(16):8341-8348. doi: 10.26355/eurrev_202008_22630.
4
An image J plugin for the high throughput image analysis of in vitro scratch wound healing assays.一个用于体外划痕愈合分析高通量图像分析的 Image J 插件。
PLoS One. 2020 Jul 28;15(7):e0232565. doi: 10.1371/journal.pone.0232565. eCollection 2020.
5
Leptin and the endocrine control of energy balance.瘦素与能量平衡的内分泌控制。
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6
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7
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8
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