Mitochondria-Targeting Type-I Photodrug: Harnessing Caspase-3 Activity for Pyroptotic Oncotherapy

Zhigao Yi; Xujuan Qin; Li Zhang; Huan Chen; Tianlin Song; Zichao Luo; Tao Wang; Junwei Lau; Yelin Wu; Tan Boon Toh; Chun-Sing Lee; Wenbo Bu; Xiaogang Liu

doi:10.1021/jacs.4c01929

Mitochondria-Targeting Type-I Photodrug: Harnessing Caspase-3 Activity for Pyroptotic Oncotherapy

Zhigao Yi, Xujuan Qin, Li Zhang, Huan Chen, Tianlin Song, Zichao Luo, Tao Wang, Junwei Lau, Yelin Wu, Tan Boon Toh, Chun-Sing Lee^*, Wenbo Bu^*, Xiaogang Liu^*

^*Corresponding author for this work

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

43 Citations (Scopus)

Abstract

Precise control of cellular signaling events during programmed cell death is crucial yet challenging for cancer therapy. The modulation of signal transduction in cancer cells holds promise but is limited by the lack of efficient, biocompatible, and spatiotemporally controllable approaches. Here we report a photodynamic strategy that modulates both apoptotic and pyroptotic cell death by altering caspase-3 protein activity and the associated signaling crosstalk. This strategy employs a mitochondria-targeting, near-infrared activatable probe (termed M-TOP) that functions via a type-I photochemical mechanism. M-TOP is less dependent on oxygen and more effective in treating drug-resistant cancer cells, even under hypoxic conditions. Our study shows that higher doses of M-TOP induce pyroptotic cell death via the caspase-3/gasdermin-E pathway, whereas lower doses lead to apoptosis. This photodynamic method is effective across diverse gasdermin-E-expressing cancer cells. Moreover, the M-TOP mediated shift from apoptotic to pyroptotic modulation can evoke a controlled inflammatory response, leading to a robust yet balanced immune reaction. This effectively inhibits both distal tumor growth and postsurgical tumor recurrence. This work demonstrates the feasibility of modulating intracellular signaling through the rational design of photodynamic anticancer drugs. © 2024 American Chemical Society.

Original language	English
Pages (from-to)	9413-9421
Journal	Journal of the American Chemical Society
Volume	146
Issue number	13
Online published	20 Mar 2024
DOIs	https://doi.org/10.1021/jacs.4c01929
Publication status	Published - 3 Apr 2024

Funding

This work was supported by the National Research Foundation, Prime Minister’s Office, Singapore, under its Competitive Research Program (award no. NRF-CRP23-2019-0002) and under its NRF Investigatorship Programme (award no. NRF-NRFI05-2019-0003), Key Program of National Natural Science Foundation of China (#22235004), National Science Foundation for the Young Scientists of China (Grant No. 82202152), Postdoctoral Research Project of China (Grant No. 2022M712416), Innovation Program of Shanghai Municipal Education Commission (#2023ZKZD01), and the Research Grants Council of Hong Kong Special Administrative Region, General Research Fund (Project No. CityU 11300320 and 11318322). All animal experiments were conducted in compliance with the guidelines of the national law and rules and the animal protocol (#202203007S) approved by the Ethic Committee of Animal Care and Use of Fudan University.

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title = "Mitochondria-Targeting Type-I Photodrug: Harnessing Caspase-3 Activity for Pyroptotic Oncotherapy",

abstract = "Precise control of cellular signaling events during programmed cell death is crucial yet challenging for cancer therapy. The modulation of signal transduction in cancer cells holds promise but is limited by the lack of efficient, biocompatible, and spatiotemporally controllable approaches. Here we report a photodynamic strategy that modulates both apoptotic and pyroptotic cell death by altering caspase-3 protein activity and the associated signaling crosstalk. This strategy employs a mitochondria-targeting, near-infrared activatable probe (termed M-TOP) that functions via a type-I photochemical mechanism. M-TOP is less dependent on oxygen and more effective in treating drug-resistant cancer cells, even under hypoxic conditions. Our study shows that higher doses of M-TOP induce pyroptotic cell death via the caspase-3/gasdermin-E pathway, whereas lower doses lead to apoptosis. This photodynamic method is effective across diverse gasdermin-E-expressing cancer cells. Moreover, the M-TOP mediated shift from apoptotic to pyroptotic modulation can evoke a controlled inflammatory response, leading to a robust yet balanced immune reaction. This effectively inhibits both distal tumor growth and postsurgical tumor recurrence. This work demonstrates the feasibility of modulating intracellular signaling through the rational design of photodynamic anticancer drugs. {\textcopyright} 2024 American Chemical Society.",

author = "Zhigao Yi and Xujuan Qin and Li Zhang and Huan Chen and Tianlin Song and Zichao Luo and Tao Wang and Junwei Lau and Yelin Wu and Toh, {Tan Boon} and Chun-Sing Lee and Wenbo Bu and Xiaogang Liu",

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T2 - Harnessing Caspase-3 Activity for Pyroptotic Oncotherapy

AU - Yi, Zhigao

AU - Qin, Xujuan

AU - Zhang, Li

AU - Chen, Huan

AU - Song, Tianlin

AU - Luo, Zichao

AU - Wang, Tao

AU - Lau, Junwei

AU - Wu, Yelin

AU - Toh, Tan Boon

AU - Lee, Chun-Sing

AU - Bu, Wenbo

AU - Liu, Xiaogang

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N2 - Precise control of cellular signaling events during programmed cell death is crucial yet challenging for cancer therapy. The modulation of signal transduction in cancer cells holds promise but is limited by the lack of efficient, biocompatible, and spatiotemporally controllable approaches. Here we report a photodynamic strategy that modulates both apoptotic and pyroptotic cell death by altering caspase-3 protein activity and the associated signaling crosstalk. This strategy employs a mitochondria-targeting, near-infrared activatable probe (termed M-TOP) that functions via a type-I photochemical mechanism. M-TOP is less dependent on oxygen and more effective in treating drug-resistant cancer cells, even under hypoxic conditions. Our study shows that higher doses of M-TOP induce pyroptotic cell death via the caspase-3/gasdermin-E pathway, whereas lower doses lead to apoptosis. This photodynamic method is effective across diverse gasdermin-E-expressing cancer cells. Moreover, the M-TOP mediated shift from apoptotic to pyroptotic modulation can evoke a controlled inflammatory response, leading to a robust yet balanced immune reaction. This effectively inhibits both distal tumor growth and postsurgical tumor recurrence. This work demonstrates the feasibility of modulating intracellular signaling through the rational design of photodynamic anticancer drugs. © 2024 American Chemical Society.

AB - Precise control of cellular signaling events during programmed cell death is crucial yet challenging for cancer therapy. The modulation of signal transduction in cancer cells holds promise but is limited by the lack of efficient, biocompatible, and spatiotemporally controllable approaches. Here we report a photodynamic strategy that modulates both apoptotic and pyroptotic cell death by altering caspase-3 protein activity and the associated signaling crosstalk. This strategy employs a mitochondria-targeting, near-infrared activatable probe (termed M-TOP) that functions via a type-I photochemical mechanism. M-TOP is less dependent on oxygen and more effective in treating drug-resistant cancer cells, even under hypoxic conditions. Our study shows that higher doses of M-TOP induce pyroptotic cell death via the caspase-3/gasdermin-E pathway, whereas lower doses lead to apoptosis. This photodynamic method is effective across diverse gasdermin-E-expressing cancer cells. Moreover, the M-TOP mediated shift from apoptotic to pyroptotic modulation can evoke a controlled inflammatory response, leading to a robust yet balanced immune reaction. This effectively inhibits both distal tumor growth and postsurgical tumor recurrence. This work demonstrates the feasibility of modulating intracellular signaling through the rational design of photodynamic anticancer drugs. © 2024 American Chemical Society.

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Mitochondria-Targeting Type-I Photodrug: Harnessing Caspase-3 Activity for Pyroptotic Oncotherapy

Abstract

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GRF: Conjugated Oligomer Nanoparticles for Type-I Photodynamic Therapy of Cancer with Near Infrared Radiation

GRF: Design of Organic Charge Transfer Complex Nanoparticles for Biomedical Applications

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Mitochondria-Targeting Type-I Photodrug: Harnessing Caspase-3 Activity for Pyroptotic Oncotherapy

Abstract

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GRF: Conjugated Oligomer Nanoparticles for Type-I Photodynamic Therapy of Cancer with Near Infrared Radiation

GRF: Design of Organic Charge Transfer Complex Nanoparticles for Biomedical Applications

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