Your search keyword '"Shu, Guannan"' showing total 27 results

1. Fatty acids metabolism affects the therapeutic effect of anti-PD-1/PD-L1 in tumor immune microenvironment in clear cell renal cell carcinoma

Author

Lin, Hansen, Fu, Liangmin, Li, Pengju, Zhu, Jiangquan, Xu, Quanhui, Wang, Yinghan, Mumin, Mukhtar Adan, Zhou, Xinwei, Chen, Yuhang, Shu, Guannan, Yao, Gaosheng, Chen, Minyu, Lu, Jun, Zhang, Lizhen, Liu, YuJun, Zhao, Yiqi, Bao, Jiahao, Chen, Wei, Luo, Junhang, Li, Xiaofei, Chen, Zhenhua, and Cao, Jiazheng

Published

2023

2. Correction: CircNTNG1 inhibits renal cell carcinoma progression via HOXA5-mediated epigenetic silencing of Slug

Author

Liang, Yanping, Cen, Junjie, Huang, Yong, Fang, Yong, Wang, Yunfei, Shu, Guannan, Pan, Yihui, Huang, Kangbo, Dong, Jiaqi, Zhou, Mi, Xu, Yi, Luo, Junhang, Liu, Min, and Zhang, Jiaxing

Published

2023

3. LRP1 induces anti-PD-1 resistance by modulating the DLL4-NOTCH2-CCL2 axis and redirecting M2-like macrophage polarisation in bladder cancer

Author

Lin, Hansen, Fu, Liangmin, Zhou, Xinwei, Yu, Anze, Chen, Yuhang, Liao, Wuyuan, Shu, Guannan, Zhang, Lizhen, Tan, Lei, Liang, Hui, Wang, Zhu, Deng, Qiong, Wang, Jieyan, Jin, Meiyu, Chen, Zhenhua, Wei, Jinhuan, Cao, Jiazheng, Chen, Wei, Li, Xiaofei, Li, Pengju, Lu, Jun, and Luo, Junhang

Published

2024

4. N6-methyladenosine modification of circMARK2 enhances cytoplasmic export and stabilizes LIN28B, contributing to the progression of Wilms tumor

Author

Shu, Guannan, Zhao, Zhang, Zhao, Tianxin, Deng, Changmi, Zhu, Jiangquan, Han, Yufeng, Chen, Minyu, Jing, Jiajia, Bai, Gaochen, Li, Dian, Li, Feng, He, Jing, Fu, Wen, and Liu, Guochang

Published

2024

5. Supplementary Data 3 from PABPC1L Induces IDO1 to Promote Tryptophan Metabolism and Immune Suppression in Renal Cell Carcinoma

Author

Shu, Guannan, primary, Chen, Minyu, primary, Liao, Wuyuan, primary, Fu, Liangmin, primary, Lin, Mingjie, primary, Gui, Chengpeng, primary, Cen, Junjie, primary, Lu, Jun, primary, Chen, Zhenhua, primary, Wei, Jinhuan, primary, Chen, Wei, primary, Wang, Yinghan, primary, Zhu, Jiangquan, primary, Zhao, Tianxin, primary, Liu, Xiaonan, primary, Jing, Jiajia, primary, Liu, Guo-chang, primary, Pan, Yihui, primary, Luo, Junhang, primary, and Zhang, Jiaxing, primary

Published

2024

6. Supplementary Data 1 from PABPC1L Induces IDO1 to Promote Tryptophan Metabolism and Immune Suppression in Renal Cell Carcinoma

Author

Shu, Guannan, primary, Chen, Minyu, primary, Liao, Wuyuan, primary, Fu, Liangmin, primary, Lin, Mingjie, primary, Gui, Chengpeng, primary, Cen, Junjie, primary, Lu, Jun, primary, Chen, Zhenhua, primary, Wei, Jinhuan, primary, Chen, Wei, primary, Wang, Yinghan, primary, Zhu, Jiangquan, primary, Zhao, Tianxin, primary, Liu, Xiaonan, primary, Jing, Jiajia, primary, Liu, Guo-chang, primary, Pan, Yihui, primary, Luo, Junhang, primary, and Zhang, Jiaxing, primary

Published

2024

7. Table S2 from PABPC1L Induces IDO1 to Promote Tryptophan Metabolism and Immune Suppression in Renal Cell Carcinoma

Author

Shu, Guannan, primary, Chen, Minyu, primary, Liao, Wuyuan, primary, Fu, Liangmin, primary, Lin, Mingjie, primary, Gui, Chengpeng, primary, Cen, Junjie, primary, Lu, Jun, primary, Chen, Zhenhua, primary, Wei, Jinhuan, primary, Chen, Wei, primary, Wang, Yinghan, primary, Zhu, Jiangquan, primary, Zhao, Tianxin, primary, Liu, Xiaonan, primary, Jing, Jiajia, primary, Liu, Guo-chang, primary, Pan, Yihui, primary, Luo, Junhang, primary, and Zhang, Jiaxing, primary

Published

2024

8. Supplementary Data 2 from PABPC1L Induces IDO1 to Promote Tryptophan Metabolism and Immune Suppression in Renal Cell Carcinoma

Author

Shu, Guannan, primary, Chen, Minyu, primary, Liao, Wuyuan, primary, Fu, Liangmin, primary, Lin, Mingjie, primary, Gui, Chengpeng, primary, Cen, Junjie, primary, Lu, Jun, primary, Chen, Zhenhua, primary, Wei, Jinhuan, primary, Chen, Wei, primary, Wang, Yinghan, primary, Zhu, Jiangquan, primary, Zhao, Tianxin, primary, Liu, Xiaonan, primary, Jing, Jiajia, primary, Liu, Guo-chang, primary, Pan, Yihui, primary, Luo, Junhang, primary, and Zhang, Jiaxing, primary

Published

2024

9. Data from PABPC1L Induces IDO1 to Promote Tryptophan Metabolism and Immune Suppression in Renal Cell Carcinoma

Author

Shu, Guannan, primary, Chen, Minyu, primary, Liao, Wuyuan, primary, Fu, Liangmin, primary, Lin, Mingjie, primary, Gui, Chengpeng, primary, Cen, Junjie, primary, Lu, Jun, primary, Chen, Zhenhua, primary, Wei, Jinhuan, primary, Chen, Wei, primary, Wang, Yinghan, primary, Zhu, Jiangquan, primary, Zhao, Tianxin, primary, Liu, Xiaonan, primary, Jing, Jiajia, primary, Liu, Guo-chang, primary, Pan, Yihui, primary, Luo, Junhang, primary, and Zhang, Jiaxing, primary

Published

2024

10. Supplementary Data from PABPC1L Induces IDO1 to Promote Tryptophan Metabolism and Immune Suppression in Renal Cell Carcinoma

Author

Shu, Guannan, primary, Chen, Minyu, primary, Liao, Wuyuan, primary, Fu, Liangmin, primary, Lin, Mingjie, primary, Gui, Chengpeng, primary, Cen, Junjie, primary, Lu, Jun, primary, Chen, Zhenhua, primary, Wei, Jinhuan, primary, Chen, Wei, primary, Wang, Yinghan, primary, Zhu, Jiangquan, primary, Zhao, Tianxin, primary, Liu, Xiaonan, primary, Jing, Jiajia, primary, Liu, Guo-chang, primary, Pan, Yihui, primary, Luo, Junhang, primary, and Zhang, Jiaxing, primary

Published

2024

11. PABPC1L induces IDO1 to promote tryptophan metabolism and immune suppression in renal cell carcinoma

Author

Shu, Guannan, primary, Chen, Minyu, additional, Liao, Wuyuan, additional, Fu, Liangmin, additional, Lin, Mingjie, additional, Gui, Chengpeng, additional, Cen, Junjie, additional, Lu, Jun, additional, Chen, Zhenhua, additional, Wei, Jinhuan, additional, Chen, Wei, additional, Wang, Yinghan, additional, Zhu, Jiangquan, additional, Zhao, Tianxin, additional, Liu, Xiaonan, additional, Jing, Jiajia, additional, Liu, Guo-Chang, additional, Pan, Yihui, additional, Luo, Junhang, additional, and Zhang, Jiaxing, additional

Published

2024

12. CircNTNG1 inhibits renal cell carcinoma progression via HOXA5-mediated epigenetic silencing of Slug

Author

Liang, Yanping, Cen, Junjie, Huang, Yong, Fang, Yong, Wang, Yunfei, Shu, Guannan, Pan, Yihui, Huang, Kangbo, Dong, Jiaqi, Zhou, Mi, Xu, Yi, Luo, Junhang, Liu, Min, and Zhang, Jiaxing

Published

2022

13. N6-methyladenosine modification of circMARK2 enhances cytoplasmic export and stabilizes LIN28B, contributing to the progression of Wilms tumor.

Author

Shu, Guannan, Zhao, Zhang, Zhao, Tianxin, Deng, Changmi, Zhu, Jiangquan, Han, Yufeng, Chen, Minyu, Jing, Jiajia, Bai, Gaochen, Li, Dian, Li, Feng, He, Jing, Fu, Wen, and Liu, Guochang

Subjects

*NEPHROBLASTOMA, *CANCER invasiveness, *CIRCULAR RNA, *RENAL cancer, *IMMUNOSTAINING, *PEDIATRIC nephrology

Abstract

Background: The potential involvement of circular RNAs (circRNAs) and N6-methyladenosine (m6A) modification in the progression of Wilms tumor (WT) has not been fully elucidated. This study investigates the regulatory mechanisms and clinical significance of m6A-modified circMARK2 and its role in WT progression. Methods: We identified dysregulated circRNAs through deep sequencing and validated their expression by qRT-PCR in WT tissues. The biological functions of circMARK2 were assessed using clone formation, transwell migration, and orthotopic animal models. To dissect the underlying mechanisms, we employed RNA immunoprecipitation, RNA pull-down, dual-luciferase reporter assays, Western blotting, and immunofluorescence and immunohistochemical staining. Results: CircMARK2, upregulated in WT tissues, was found to be m6A-modified and promoted cytoplasmic export. It facilitated WT progression by stabilizing LIN28B mRNA through the circMARK2/IGF2BP2 interaction. In vitro and in vivo studies demonstrated that circMARK2 enhances the malignant behavior of WT cells. Clinically, higher circMARK2 levels in tumor tissues of WT patients were linked to increased tumor aggressiveness and reduced survival rates. Conclusions: Our study provides the first comprehensive evidence that m6A-modified circMARK2 contributes to WT progression by enhancing LIN28B mRNA stability, promoting cellular aggressiveness. CircMARK2 emerges as a potential biomarker for prognosis and a promising target for therapeutic intervention in WT, underscoring the clinical relevance of m6A modification in pediatric renal cancer. [ABSTRACT FROM AUTHOR]

Published

2024

14. Circular RNA circSDHC serves as a sponge for miR-127-3p to promote the proliferation and metastasis of renal cell carcinoma via the CDKN3/E2F1 axis

Author

Cen, Junjie, Liang, Yanping, Huang, Yong, Pan, Yihui, Shu, Guannan, Zheng, Zhousan, Liao, Xiaozhong, Zhou, Mi, Chen, Danlei, Fang, Yong, Chen, Wei, Luo, Junhang, and Zhang, Jiaxing

Published

2021

15. EGCG‐LYS Fibrils‐Mediated CircMAP2K2 Silencing Decreases the Proliferation and Metastasis Ability of Gastric Cancer Cells in Vitro and in Vivo

Author

Dong, Jiaqi, primary, Zheng, Zhousan, additional, Zhou, Mi, additional, Wang, Yunfei, additional, Chen, Jiajie, additional, Cen, Junjie, additional, Cao, Tiefeng, additional, Yang, Taowei, additional, Xu, Yi, additional, Shu, Guannan, additional, Lu, Xuanxuan, additional, and Liang, Yanping, additional

Published

2023

16. Exosomal circSPIRE1 mediates glycosylation of E-cadherin to suppress metastasis of renal cell carcinoma

Author

Shu, Guannan, primary, Lu, Xuanxuan, additional, Pan, Yihui, additional, Cen, Junjie, additional, Huang, Kangbo, additional, Zhou, Mi, additional, Lu, Jun, additional, Dong, Jiaqi, additional, Han, Hui, additional, Chen, Wei, additional, Lin, Juan, additional, Luo, Junhang, additional, and Zhang, Jiaxing, additional

Published

2023

17. Data from Extracellular Vesicle-Mediated Transfer of LncRNA IGFL2-AS1 Confers Sunitinib Resistance in Renal Cell Carcinoma

Author

Pan, Yihui, primary, Lu, Xuanxuan, primary, Shu, Guannan, primary, Cen, Junjie, primary, Lu, Jun, primary, Zhou, Mi, primary, Huang, Kangbo, primary, Dong, Jiaqi, primary, Li, Jiaying, primary, Lin, Haishan, primary, Song, Hongde, primary, Xu, Quanhui, primary, Han, Hui, primary, Chen, Zhenhua, primary, Chen, Wei, primary, Luo, Junhang, primary, Wei, Jinhuan, primary, and Zhang, Jiaxing, primary

Published

2023

18. Supplementary Data from Extracellular Vesicle-Mediated Transfer of LncRNA IGFL2-AS1 Confers Sunitinib Resistance in Renal Cell Carcinoma

Author

Pan, Yihui, primary, Lu, Xuanxuan, primary, Shu, Guannan, primary, Cen, Junjie, primary, Lu, Jun, primary, Zhou, Mi, primary, Huang, Kangbo, primary, Dong, Jiaqi, primary, Li, Jiaying, primary, Lin, Haishan, primary, Song, Hongde, primary, Xu, Quanhui, primary, Han, Hui, primary, Chen, Zhenhua, primary, Chen, Wei, primary, Luo, Junhang, primary, Wei, Jinhuan, primary, and Zhang, Jiaxing, primary

Published

2023

19. Fatty acids metabolism affects the therapeutic effect of anti-PD-1/PD-L1 in tumor immune microenvironment in clear cell renal cell carcinoma

Author

Lin, Hansen, primary, Fu, Liangmin, additional, Cao, Jiazheng, additional, Chen, Zhenhua, additional, Lu, Jun, additional, Zhang, Lizhen, additional, Chen, Wei, additional, Li, Xiaofei, additional, Mumin, Mukhtar Adan, additional, Yao, Gaosheng, additional, Bao, Jiahao, additional, Zhao, Yiqi, additional, Liu, Yujun, additional, Zhu, Jiangquan, additional, Wang, Yinghan, additional, Shu, Guannan, additional, Chen, Minyu, additional, Luo, Junhang, additional, Zhou, Xinwei, additional, Chen, Yuhang, additional, Li, Pengju, additional, and Xu, Quanhui, additional

Published

2023

20. EHBP1L1 Drives Immune Evasion in Renal Cell Carcinoma through Binding and Stabilizing JAK1

Author

Pan, Yihui, primary, Shu, Guannan, additional, Fu, Liangmin, additional, Huang, Kangbo, additional, Zhou, Xinwei, additional, Gui, Chengpeng, additional, Liu, Huashan, additional, Jin, Xiaohan, additional, Chen, Minyu, additional, Li, Pengju, additional, Cen, Junjie, additional, Feng, Zihao, additional, Lu, Jun, additional, Chen, Zhenhua, additional, Li, Jiaying, additional, Xu, Quanhui, additional, Wang, Yinghan, additional, Liang, Hui, additional, Wang, Zhu, additional, Deng, Qiong, additional, Chen, Wei, additional, Luo, Junhang, additional, Yang, Jiefeng, additional, Zhang, Jiaxing, additional, and Wei, Jinhuan, additional

Published

2023

21. Hsa_circ_0057105 modulates a balance of epithelial‐mesenchymal transition and ferroptosis vulnerability in renal cell carcinoma.

Author

Cen, Junjie, Liang, Yanping, Feng, Zihao, Chen, Xu, Chen, Jinlong, Wang, Yinghan, Zhu, Jiangquan, Xu, Quanhui, Shu, Guannan, Zheng, Wenbin, Liang, Hui, Wang, Zhu, Deng, Qiong, Cao, Jiazheng, Luo, Junhang, Jin, Xiaohan, and Huang, Yong

Subjects

EPITHELIAL-mesenchymal transition, GENE expression, FLUORESCENCE in situ hybridization, CIRCULAR RNA, ANIMAL experimentation

Abstract

Background: The incidence of renal cell carcinoma (RCC) has increased in recent years. Metastatic RCC is common and remains a major cause of mortality. A regulatory role for circular RNAs (circRNAs) in the occurrence and progression of RCC has been identified, but their function, molecular mechanisms, and potential clinical applications remain poorly understood. Methods: High‐throughput RNA sequencing was used to explore the differential expression of circRNAs and their related pathways in RCC patients. Transwell and CCK‐8 assays were used to assess the function of hsa_circ_0057105 in RCC cells. The clinical relevance of hsa_circ_0057105 was evaluated in a cohort of RCC patients. The hsa_circ_0057105 regulatory axis was defined using RNA pull‐down, luciferase reporter assays, and fluorescence in situ hybridization assays, and the in vivo effect of hsa_circ_0057105 was validated using animal experiments. Results: Single‐sample gene set enrichment analysis and correlation analysis of RNA‐seq data showed that hsa_circ_0057105 was potentially oncogenic and may serve to regulate epithelial‐mesenchymal transition (EMT) activation in RCC. Hsa_circ_0057105 expression was associated with advanced TNM stages and was an independent prognostic factor for poor RCC patient survival. Phenotypic studies show that hsa_circ_0057105 can enhance the migration and invasion abilities of RCC cells. Further, hsa_circ_0057105 was shown to inhibit the expression of miR‐577, a miRNA that regulated the expression of both COL1A1, which induced EMT activation, and VDAC2, which modulated ferroptosis sensitivity. The dual regulatory roles of hsa_circ_0057105 on EMT and ferroptosis sensitivity were verified using rescue experiments. Animal studies confirmed that hsa_circ_0057105 increased the metastatic ability and ferroptosis sensitivity of RCC cells in vivo. Conclusions: In RCC, hsa_circ_0057105 regulates COL1A1 and VDAC2 expression through its sponge effect on miR‐577, acting like a 'double‐edged sword'. These findings provide new insight into the relationship between EMT and ferroptosis in RCC and provide potential biomarkers for RCC surveillance and treatment. [ABSTRACT FROM AUTHOR]

Published

2023

22. Extracellular Vesicle-Mediated Transfer of LncRNA IGFL2-AS1 Confers Sunitinib Resistance in Renal Cell Carcinoma

Author

Pan, Yihui, primary, Lu, Xuanxuan, additional, Shu, Guannan, additional, Cen, Junjie, additional, Lu, Jun, additional, Zhou, Mi, additional, Huang, Kangbo, additional, Dong, Jiaqi, additional, Li, Jiaying, additional, Lin, Haishan, additional, Song, Hongde, additional, Xu, Quanhui, additional, Han, Hui, additional, Chen, Zhenhua, additional, Chen, Wei, additional, Luo, Junhang, additional, Wei, Jinhuan, additional, and Zhang, Jiaxing, additional

Published

2022

23. CircNTNG1 inhibits renal cell carcinoma progression via HOXA5-mediated epigenetic silencing of Slug

Author

Liang, Yanping, primary, Cen, Junjie, additional, Huang, Yong, additional, Fang, Yong, additional, Wang, Yunfei, additional, Shu, Guannan, additional, Pan, Yihui, additional, Dong, Jiaqi, additional, Zhou, Mi, additional, Xu, Yi, additional, Luo, Junhang, additional, Liu, Min, additional, and Zhang, Jiaxing, additional

Published

2022

24. Chitosan‐Gelatin‐EGCG Nanoparticle‐Meditated LncRNA TMEM44‐AS1 Silencing to Activate the P53 Signaling Pathway for the Synergistic Reversal of 5‐FU Resistance in Gastric Cancer

Author

Zhou, Mi, primary, Dong, Jiaqi, additional, Huang, Junqing, additional, Ye, Wen, additional, Zheng, Zhousan, additional, Huang, Kangbo, additional, Pan, Yihui, additional, Cen, Junjie, additional, Liang, Yanping, additional, Shu, Guannan, additional, Ye, Sheng, additional, Lu, Xuanxuan, additional, and Zhang, Jiaxing, additional

Published

2022

25. MRI tracking of autologous pancreatic progenitor-derived insulin-producing cells in monkeys

Author

Zou, Chunlin, primary, Lu, Yi, additional, Teng, Xiahong, additional, Wang, Shuyan, additional, Sun, Xiaoting, additional, Huang, Fen, additional, Shu, Guannan, additional, Huang, Xin, additional, Guo, Hongwei, additional, Chen, Zhiguo, additional, Zhang, Jian, additional, and Zhang, Yu Alex, additional

Published

2017

26. Bladder cancer intrinsic LRFN2 drives anticancer immunotherapy resistance by attenuating CD8 + T cell infiltration and functional transition.

Author

Yu A, Hu J, Fu L, Huang G, Deng D, Zhang M, Wang Y, Shu G, Jing L, Li H, Chen X, Yang T, Wei J, Chen Z, Zu X, and Luo J

Subjects

Humans, Biological Assay, Cell Differentiation, Immunotherapy, Membrane Glycoproteins, Nerve Tissue Proteins, Tumor Microenvironment, Drug Resistance, Neoplasm, CD8-Positive T-Lymphocytes, Urinary Bladder Neoplasms drug therapy

Abstract

Background: Immune checkpoint inhibitor (ICI) therapy improves the survival of patients with advanced bladder cancer (BLCA); however, its overall effectiveness is limited, and many patients still develop immunotherapy resistance. The leucine-rich repeat and fibronectin type-III domain-containing protein (LRFN) family has previously been implicated in regulating brain dysfunction; however, the mechanisms underlying the effect of LRFN2 on the tumor microenvironment (TME) and immunotherapy remain unclear., Methods: Here we combined bulk RNA sequencing, single-cell RNA sequencing, ProcartaPlex multiple immunoassays, functional experiments, and TissueFAXS panoramic tissue quantification assays to demonstrate that LRFN2 shapes a non-inflammatory TME in BLCA., Results: First, comprehensive multiomics analysis identified LRFN2 as a novel immunosuppressive target specific to BLCA. We found that tumor-intrinsic LRFN2 inhibited the recruitment and functional transition of CD8 + T cells by reducing the secretion of pro-inflammatory cytokines and chemokines, and this mechanism was verified in vitro and in vivo. LRFN2 restrained antitumor immunity by inhibiting the infiltration, proliferation, and differentiation of CD8 + T cells in vitro. Furthermore, a spatial exclusivity relationship was observed between LRFN2 + tumor cells and CD8 + T cells and cell markers programmed cell death-1 (PD-1) and T cell factor 1 (TCF-1). Preclinically, LRFN2 knockdown significantly enhanced the efficacy of ICI therapy. Clinically, LRFN2 can predict immunotherapy responses in real-world and public immunotherapy cohorts. Our results reveal a new role for LRFN2 in tumor immune evasion by regulating chemokine secretion and inhibiting CD8 + T-cell recruitment and functional transition., Conclusions: Thus, LRFN2 represents a new target that can be combined with ICIs to provide a potential treatment option for BLCA., Competing Interests: Competing interests: None declared., (© Author(s) (or their employer(s)) 2023. Re-use permitted under CC BY-NC. No commercial re-use. See rights and permissions. Published by BMJ.)

Published

2023

27. Extracellular Vesicle-Mediated Transfer of LncRNA IGFL2-AS1 Confers Sunitinib Resistance in Renal Cell Carcinoma.

Author

Pan Y, Lu X, Shu G, Cen J, Lu J, Zhou M, Huang K, Dong J, Li J, Lin H, Song H, Xu Q, Han H, Chen Z, Chen W, Luo J, Wei J, and Zhang J

Subjects

Humans, Sunitinib pharmacology, Sunitinib therapeutic use, Cell Line, Tumor, Drug Resistance, Neoplasm genetics, Cell Proliferation, Gene Expression Regulation, Neoplastic, Nuclear Proteins metabolism, Carcinoma, Renal Cell drug therapy, Carcinoma, Renal Cell genetics, Carcinoma, Renal Cell pathology, RNA, Long Noncoding genetics, RNA, Long Noncoding metabolism, Kidney Neoplasms drug therapy, Kidney Neoplasms genetics, Kidney Neoplasms pathology, Extracellular Vesicles metabolism

Abstract

Sunitinib resistance remains a serious challenge to the treatment of advanced and metastatic renal cell carcinoma (RCC), yet the mechanisms underlying this resistance are not fully understood. Here, we report that the long noncoding RNA IGFL2-AS1 is a driver of therapy resistance in RCC. IGFL2-AS1 was highly upregulated in sunitinib-resistant RCC cells and was associated with poor prognosis in patients with clear cell RCC (ccRCC) who received sunitinib therapy. IGFL2-AS1 enhanced TP53INP2 expression by competitively binding to hnRNPC, a multifunctional RNA-binding protein that posttranscriptionally suppresses TP53INP2 expression through alternative splicing. Upregulated TP53INP2 enhanced autophagy and ultimately led to sunitinib resistance. Meanwhile, IGFL2-AS1 was packaged into extracellular vesicles through hnRNPC, thus transmitting sunitinib resistance to other cells. N6-methyladenosine modification of IGFL2-AS1 was critical for its interaction with hnRNPC. In a patient-derived xenograft model of sunitinib-resistant ccRCC, injection of chitosan-solid lipid nanoparticles containing antisense oligonucleotide-IGFL2-AS1 successfully reversed sunitinib resistance. These findings indicate a novel molecular mechanism of sunitinib resistance in RCC and suggest that IGFL2-AS1 may serve as a prognostic indicator and potential therapeutic target to overcome resistance., Significance: Extracellular vesicle-packaged IGFL2-AS1 promotes sunitinib resistance by regulating TP53INP2-triggered autophagy, implicating this lncRNA as a potential therapeutic target in renal cell carcinoma., (©2022 The Authors; Published by the American Association for Cancer Research.)

Published

2023