RCC2 and CD24 cooperate to modulate prostate cancer progression through vimentin ubiquitination and β-catenin activation
Xuelian Cui, Yicun Wang, Chao Zhang, Zhichao Liu, Haiyan Yu, Lizhong Wang, Jiangbing Zhou, Runhua Liu
Xuelian Cui, Yicun Wang, Chao Zhang, Zhichao Liu, Haiyan Yu, Lizhong Wang, Jiangbing Zhou, Runhua Liu
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Research Article Cell biology Genetics Oncology

RCC2 and CD24 cooperate to modulate prostate cancer progression through vimentin ubiquitination and β-catenin activation

Abstract

CD24 promotes prostate cancer progression and metastasis by disrupting the ARF-NPM interaction and impairing p53 signaling. However, the mechanisms underlying CD24-driven metastasis remain unclear. This study identifies a novel interaction between CD24 and Regulator of Chromosome Condensation 2 (RCC2), a protein involved in cell proliferation and migration. IHC analysis of prostate adenocarcinoma samples showed frequent coexpression of CD24 (49%) and RCC2 (82%) with a positive correlation between coexpression of CD24 (49%) and RCC2 (82%). Functional assays revealed complex roles: RCC2 KO suppressed proliferation but increased migration and invasion, while CD24 KO reduced both proliferation and migration. Dual KO of CD24 and RCC2 further inhibited proliferation but had varied effects on migration. In mouse xenografts, RCC2 KO increased lung metastasis without significantly affecting primary tumor growth, while CD24 KO reduced both tumor growth and metastasis. Mechanistically, RCC2 controls migration by promoting ubiquitination and degradation of vimentin, affecting cytoskeletal dynamics. In contrast, CD24 targets RCC2 for degradation, thereby regulating β-catenin signaling. Notably, RCC2 KO enhances β-catenin activity by suppressing inhibitors AXIN2 and APC, whereas CD24 KO inhibits this pathway. These findings reveal a regulatory loop where CD24 and RCC2 reciprocally control proliferation and metastasis, positioning the CD24-RCC2 axis as a promising therapeutic target in prostate cancer.

Authors

Xuelian Cui, Yicun Wang, Chao Zhang, Zhichao Liu, Haiyan Yu, Lizhong Wang, Jiangbing Zhou, Runhua Liu

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Figure 5

Role of Rcc2 in spontaneous prostate cancer progression and metastasis in mouse models.

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Role of Rcc2 in spontaneous prostate cancer progression and metastasis i...
(A) Schematic diagram of spontaneously developed prostate tumors followed up to 12 months of age in genetically engineered mouse models. Tamoxifen was administered at 8 weeks of age to induce Cre-mediated recombination in prostate epithelial cells. (B) Prostate weight analysis in Rcc2-cKO, Pten-cKO, and Rcc2/Pten-cKO mice compared with scrambled control mice at 6-, 8-, 10-, and 12-months after tamoxifen treatment. (C) Kaplan–Meier curves of mPIN incidences up to 40 weeks of age. At 20, 25, 30, 35, and 40 weeks of age, 5 mice per time point were sacrificed for pathological analysis. (D) Histological analysis of prostate tissues in Rcc2/Pten-cKO mice up to 12 months after tamoxifen treatment. Scale bars: 500 μm (left), 50 μm (right). (E) IHC staining in mouse prostate tissues with anti-mouse PTEN, RCC2, AR, E-cadherin, and Vimentin antibodies in Rcc2-cKO, Pten-cKO, and Rcc2/Pten-cKO mice compared with scrambled control mice at 6 months after tamoxifen treatment. Scale bars: 200 μm. (F) Incidence of lung metastasis in Rcc2/Pten-cKO mice compared with Pten-cKO mice at 12 months after tamoxifen treatment. (G) Representative IHC staining of lung metastatic lesions with anti-PSA antibody, confirming the prostatic origin of metastatic tumors. Data are presented as means ± SD. Scale bars in Case 1: 500 μm (left); 200 μm (middle); 50 μm (right). Scale bars in Case 2: 500 μm (left); 100 μm (middle); 50 μm (right). (B) P values were determined by 1-way ANOVA with Tukey’s multiple comparisons test. (C and F) The log-rank test was used to analyze tumor development or metastasis and compare the distribution of time to event between groups. AR, androgen receptor; cKO, conditional knockout; mPIN, mouse prostatic intraepithelial neoplasia; i.p., intraperitoneal injection; PSA, prostate-specific antigen. All experiments were repeated twice.