Bioengineered protein nanocarrier facilitating siRNA escape from lysosomes for targeted RNAi therapy in glioblastoma

Yiliang Jin; Baoli Zhang; Jianru Li; Zhenxi Guo; Chen Zhang; Xuehui Chen; Long Ma; Zhuoran Wang; Haiyin Yang; Yong Li; Yuhua Weng; Yuanyu Huang; Xiyun Yan; Kelong Fan

doi:10.1126/sciadv.adr9266

Bioengineered protein nanocarrier facilitating siRNA escape from lysosomes for targeted RNAi therapy in glioblastoma

Yiliang Jin, Baoli Zhang, Jianru Li, Zhenxi Guo, Chen Zhang, Xuehui Chen, Long Ma, Zhuoran Wang, Haiyin Yang, Yong Li, Yuhua Weng, Yuanyu Huang, Xiyun Yan^*, Kelong Fan^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

Abstract

RNA interference (RNAi) represents a promising gene-specific therapy against tumors. However, its clinical translation is impeded by poor performance of lysosomal escape and tumor targeting. This challenge is especially prominent in glioblastoma (GBM) therapy, necessitating the penetration of the blood-brain barrier (BBB). Leveraging the intrinsic tumor-targeting and BBB traversing capability of human H-ferritin, we designed a series of ferritin variants with positively charged cavity and truncated carboxyl terminus, termed tHFn(+). These nanocarriers respond to weak acid and disassemble in endosomal compartments, exposing the internal positive charges to facilitate the lysosomal escape of loaded small interfering RNA (siRNA). Functioning as universal siRNA nanocarriers, tHFn(+) significantly enhanced the uptake of different siRNAs and suppressed gene expressions associated with GBM progression. Furthermore, tHFn(+) traversed the BBB and targeted glioma in vivo by binding to its receptors (e.g., transferrin receptor 1). tHFn(+)-delivered siRNAs exhibited exceptional therapeutic effects against glioma in vivo, advancing RNAi therapeutics beyond GBM for the treatment of various diseases.

Original language	English
Article number	eadr9266
Journal	Science advances
Volume	11
Issue number	8
DOIs	https://doi.org/10.1126/sciadv.adr9266
Publication status	Published - 21 Feb 2025

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Jin, Y., Zhang, B., Li, J., Guo, Z., Zhang, C., Chen, X., Ma, L., Wang, Z., Yang, H., Li, Y., Weng, Y., Huang, Y., Yan, X., & Fan, K. (2025). Bioengineered protein nanocarrier facilitating siRNA escape from lysosomes for targeted RNAi therapy in glioblastoma. Science advances, 11(8), Article eadr9266. https://doi.org/10.1126/sciadv.adr9266

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title = "Bioengineered protein nanocarrier facilitating siRNA escape from lysosomes for targeted RNAi therapy in glioblastoma",

abstract = "RNA interference (RNAi) represents a promising gene-specific therapy against tumors. However, its clinical translation is impeded by poor performance of lysosomal escape and tumor targeting. This challenge is especially prominent in glioblastoma (GBM) therapy, necessitating the penetration of the blood-brain barrier (BBB). Leveraging the intrinsic tumor-targeting and BBB traversing capability of human H-ferritin, we designed a series of ferritin variants with positively charged cavity and truncated carboxyl terminus, termed tHFn(+). These nanocarriers respond to weak acid and disassemble in endosomal compartments, exposing the internal positive charges to facilitate the lysosomal escape of loaded small interfering RNA (siRNA). Functioning as universal siRNA nanocarriers, tHFn(+) significantly enhanced the uptake of different siRNAs and suppressed gene expressions associated with GBM progression. Furthermore, tHFn(+) traversed the BBB and targeted glioma in vivo by binding to its receptors (e.g., transferrin receptor 1). tHFn(+)-delivered siRNAs exhibited exceptional therapeutic effects against glioma in vivo, advancing RNAi therapeutics beyond GBM for the treatment of various diseases.",

author = "Yiliang Jin and Baoli Zhang and Jianru Li and Zhenxi Guo and Chen Zhang and Xuehui Chen and Long Ma and Zhuoran Wang and Haiyin Yang and Yong Li and Yuhua Weng and Yuanyu Huang and Xiyun Yan and Kelong Fan",

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doi = "10.1126/sciadv.adr9266",

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T1 - Bioengineered protein nanocarrier facilitating siRNA escape from lysosomes for targeted RNAi therapy in glioblastoma

AU - Jin, Yiliang

AU - Zhang, Baoli

AU - Li, Jianru

AU - Guo, Zhenxi

AU - Zhang, Chen

AU - Chen, Xuehui

AU - Ma, Long

AU - Wang, Zhuoran

AU - Yang, Haiyin

AU - Li, Yong

AU - Weng, Yuhua

AU - Huang, Yuanyu

AU - Yan, Xiyun

AU - Fan, Kelong

PY - 2025/2/21

Y1 - 2025/2/21

N2 - RNA interference (RNAi) represents a promising gene-specific therapy against tumors. However, its clinical translation is impeded by poor performance of lysosomal escape and tumor targeting. This challenge is especially prominent in glioblastoma (GBM) therapy, necessitating the penetration of the blood-brain barrier (BBB). Leveraging the intrinsic tumor-targeting and BBB traversing capability of human H-ferritin, we designed a series of ferritin variants with positively charged cavity and truncated carboxyl terminus, termed tHFn(+). These nanocarriers respond to weak acid and disassemble in endosomal compartments, exposing the internal positive charges to facilitate the lysosomal escape of loaded small interfering RNA (siRNA). Functioning as universal siRNA nanocarriers, tHFn(+) significantly enhanced the uptake of different siRNAs and suppressed gene expressions associated with GBM progression. Furthermore, tHFn(+) traversed the BBB and targeted glioma in vivo by binding to its receptors (e.g., transferrin receptor 1). tHFn(+)-delivered siRNAs exhibited exceptional therapeutic effects against glioma in vivo, advancing RNAi therapeutics beyond GBM for the treatment of various diseases.

AB - RNA interference (RNAi) represents a promising gene-specific therapy against tumors. However, its clinical translation is impeded by poor performance of lysosomal escape and tumor targeting. This challenge is especially prominent in glioblastoma (GBM) therapy, necessitating the penetration of the blood-brain barrier (BBB). Leveraging the intrinsic tumor-targeting and BBB traversing capability of human H-ferritin, we designed a series of ferritin variants with positively charged cavity and truncated carboxyl terminus, termed tHFn(+). These nanocarriers respond to weak acid and disassemble in endosomal compartments, exposing the internal positive charges to facilitate the lysosomal escape of loaded small interfering RNA (siRNA). Functioning as universal siRNA nanocarriers, tHFn(+) significantly enhanced the uptake of different siRNAs and suppressed gene expressions associated with GBM progression. Furthermore, tHFn(+) traversed the BBB and targeted glioma in vivo by binding to its receptors (e.g., transferrin receptor 1). tHFn(+)-delivered siRNAs exhibited exceptional therapeutic effects against glioma in vivo, advancing RNAi therapeutics beyond GBM for the treatment of various diseases.

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JO - Science advances

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M1 - eadr9266

ER -

Bioengineered protein nanocarrier facilitating siRNA escape from lysosomes for targeted RNAi therapy in glioblastoma

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