Integrated Design of a Membrane-Lytic Peptide-Based Intravenous Nanotherapeutic Suppresses Triple-Negative Breast Cancer

Charles H. Chen; Yu Han Liu; Arvin Eskandari; Jenisha Ghimire; Leon Chien Wei Lin; Zih Syun Fang; William C. Wimley; Jakob P. Ulmschneider; Kogularamanan Suntharalingam; Che Ming Jack Hu; Martin B. Ulmschneider

doi:10.1002/advs.202105506

Integrated Design of a Membrane-Lytic Peptide-Based Intravenous Nanotherapeutic Suppresses Triple-Negative Breast Cancer

Charles H. Chen, Yu Han Liu, Arvin Eskandari, Jenisha Ghimire, Leon Chien Wei Lin, Zih Syun Fang, William C. Wimley, Jakob P. Ulmschneider, Kogularamanan Suntharalingam, Che Ming Jack Hu, Martin B. Ulmschneider^*

^*Corresponding author for this work

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

10 Citations (Scopus)

Abstract

Membrane-lytic peptides offer broad synthetic flexibilities and design potential to the arsenal of anticancer therapeutics, which can be limited by cytotoxicity to noncancerous cells and induction of drug resistance via stress-induced mutagenesis. Despite continued research efforts on membrane-perforating peptides for antimicrobial applications, success in anticancer peptide therapeutics remains elusive given the muted distinction between cancerous and normal cell membranes and the challenge of peptide degradation and neutralization upon intravenous delivery. Using triple-negative breast cancer as a model, the authors report the development of a new class of anticancer peptides. Through function-conserving mutations, the authors achieved cancer cell selective membrane perforation, with leads exhibiting a 200-fold selectivity over non-cancerogenic cells and superior cytotoxicity over doxorubicin against breast cancer tumorspheres. Upon continuous exposure to the anticancer peptides at growth-arresting concentrations, cancer cells do not exhibit resistance phenotype, frequently observed under chemotherapeutic treatment. The authors further demonstrate efficient encapsulation of the anticancer peptides in 20 nm polymeric nanocarriers, which possess high tolerability and lead to effective tumor growth inhibition in a mouse model of MDA-MB-231 triple-negative breast cancer. This work demonstrates a multidisciplinary approach for enabling translationally relevant membrane-lytic peptides in oncology, opening up a vast chemical repertoire to the arms race against cancer.

Original language	English
Article number	2105506
Journal	Advanced Science
Volume	9
Issue number	13
Early online date	4 Mar 2022
DOIs	https://doi.org/10.1002/advs.202105506
Publication status	Published - 5 May 2022

Keywords

anticancer peptides
drug resistance
membrane-active anticancer agents
multicellular tumor spheroids
murine models
nanoparticles
triple negative breast cancer

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1002/advs.202105506

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Chen, C. H., Liu, Y. H., Eskandari, A., Ghimire, J., Lin, L. C. W., Fang, Z. S., Wimley, W. C., Ulmschneider, J. P., Suntharalingam, K., Hu, C. M. J., & Ulmschneider, M. B. (2022). Integrated Design of a Membrane-Lytic Peptide-Based Intravenous Nanotherapeutic Suppresses Triple-Negative Breast Cancer. Advanced Science, 9(13), Article 2105506. https://doi.org/10.1002/advs.202105506

@article{db7473b19e564db3b725f5afac6cc2a7,

title = "Integrated Design of a Membrane-Lytic Peptide-Based Intravenous Nanotherapeutic Suppresses Triple-Negative Breast Cancer",

abstract = "Membrane-lytic peptides offer broad synthetic flexibilities and design potential to the arsenal of anticancer therapeutics, which can be limited by cytotoxicity to noncancerous cells and induction of drug resistance via stress-induced mutagenesis. Despite continued research efforts on membrane-perforating peptides for antimicrobial applications, success in anticancer peptide therapeutics remains elusive given the muted distinction between cancerous and normal cell membranes and the challenge of peptide degradation and neutralization upon intravenous delivery. Using triple-negative breast cancer as a model, the authors report the development of a new class of anticancer peptides. Through function-conserving mutations, the authors achieved cancer cell selective membrane perforation, with leads exhibiting a 200-fold selectivity over non-cancerogenic cells and superior cytotoxicity over doxorubicin against breast cancer tumorspheres. Upon continuous exposure to the anticancer peptides at growth-arresting concentrations, cancer cells do not exhibit resistance phenotype, frequently observed under chemotherapeutic treatment. The authors further demonstrate efficient encapsulation of the anticancer peptides in 20 nm polymeric nanocarriers, which possess high tolerability and lead to effective tumor growth inhibition in a mouse model of MDA-MB-231 triple-negative breast cancer. This work demonstrates a multidisciplinary approach for enabling translationally relevant membrane-lytic peptides in oncology, opening up a vast chemical repertoire to the arms race against cancer.",

keywords = "anticancer peptides, drug resistance, membrane-active anticancer agents, multicellular tumor spheroids, murine models, nanoparticles, triple negative breast cancer",

author = "Chen, {Charles H.} and Liu, {Yu Han} and Arvin Eskandari and Jenisha Ghimire and Lin, {Leon Chien Wei} and Fang, {Zih Syun} and Wimley, {William C.} and Ulmschneider, {Jakob P.} and Kogularamanan Suntharalingam and Hu, {Che Ming Jack} and Ulmschneider, {Martin B.}",

note = "Funding Information: C.H.C. and A.E. were supported by KCL PhD scholarships. K.S. thanks the Leverhulme Trust for funding (ECF-2014-178). The authors are grateful to Prof. Robert Weinberg (Whitehead Institute, MIT) for providing the cell lines used in this study. J.P.U. was supported by a China 1000 Plan's Program for Young Talents (13Z127060001). The authors thank Katherine Tripp at the Center for Molecular Biophysics, Johns Hopkins University for helping the experimental setup for isothermal titration calorimeter. The authors thank the Karlsruhe Institute of Technology (KIT) ANKA synchrotron CD beamline staff for support and beamtime. The authors thank Jochen B{\"u}rck at KIT for technical support for ANKA synchrotron CD beamline. The authors thank Bing-Yu Yao and Chi-Long Lin at Academia Sinica for technical supports for nanoprecipitation and confocal microscopy, respectively. The authors thank Timothy K. Lu at Massachusetts Institute of Technology and Jing-Ruey Joanna Yeh at Massachusetts General Hospital for valuable discussions. Funding Information: C.H.C. and A.E. were supported by KCL PhD scholarships. K.S. thanks the Leverhulme Trust for funding (ECF‐2014‐178). The authors are grateful to Prof. Robert Weinberg (Whitehead Institute, MIT) for providing the cell lines used in this study. J.P.U. was supported by a China 1000 Plan's Program for Young Talents (13Z127060001). The authors thank Katherine Tripp at the Center for Molecular Biophysics, Johns Hopkins University for helping the experimental setup for isothermal titration calorimeter. The authors thank the Karlsruhe Institute of Technology (KIT) ANKA synchrotron CD beamline staff for support and beamtime. The authors thank Jochen B{\"u}rck at KIT for technical support for ANKA synchrotron CD beamline. The authors thank Bing‐Yu Yao and Chi‐Long Lin at Academia Sinica for technical supports for nanoprecipitation and confocal microscopy, respectively. The authors thank Timothy K. Lu at Massachusetts Institute of Technology and Jing‐Ruey Joanna Yeh at Massachusetts General Hospital for valuable discussions. Publisher Copyright: {\textcopyright} 2022 The Authors. Advanced Science published by Wiley-VCH GmbH.",

year = "2022",

month = may,

day = "5",

doi = "10.1002/advs.202105506",

language = "English",

volume = "9",

journal = "Advanced Science",

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publisher = "Wiley-VCH Verlag",

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T1 - Integrated Design of a Membrane-Lytic Peptide-Based Intravenous Nanotherapeutic Suppresses Triple-Negative Breast Cancer

AU - Chen, Charles H.

AU - Liu, Yu Han

AU - Eskandari, Arvin

AU - Ghimire, Jenisha

AU - Lin, Leon Chien Wei

AU - Fang, Zih Syun

AU - Wimley, William C.

AU - Ulmschneider, Jakob P.

AU - Suntharalingam, Kogularamanan

AU - Hu, Che Ming Jack

AU - Ulmschneider, Martin B.

N1 - Funding Information: C.H.C. and A.E. were supported by KCL PhD scholarships. K.S. thanks the Leverhulme Trust for funding (ECF-2014-178). The authors are grateful to Prof. Robert Weinberg (Whitehead Institute, MIT) for providing the cell lines used in this study. J.P.U. was supported by a China 1000 Plan's Program for Young Talents (13Z127060001). The authors thank Katherine Tripp at the Center for Molecular Biophysics, Johns Hopkins University for helping the experimental setup for isothermal titration calorimeter. The authors thank the Karlsruhe Institute of Technology (KIT) ANKA synchrotron CD beamline staff for support and beamtime. The authors thank Jochen Bürck at KIT for technical support for ANKA synchrotron CD beamline. The authors thank Bing-Yu Yao and Chi-Long Lin at Academia Sinica for technical supports for nanoprecipitation and confocal microscopy, respectively. The authors thank Timothy K. Lu at Massachusetts Institute of Technology and Jing-Ruey Joanna Yeh at Massachusetts General Hospital for valuable discussions. Funding Information: C.H.C. and A.E. were supported by KCL PhD scholarships. K.S. thanks the Leverhulme Trust for funding (ECF‐2014‐178). The authors are grateful to Prof. Robert Weinberg (Whitehead Institute, MIT) for providing the cell lines used in this study. J.P.U. was supported by a China 1000 Plan's Program for Young Talents (13Z127060001). The authors thank Katherine Tripp at the Center for Molecular Biophysics, Johns Hopkins University for helping the experimental setup for isothermal titration calorimeter. The authors thank the Karlsruhe Institute of Technology (KIT) ANKA synchrotron CD beamline staff for support and beamtime. The authors thank Jochen Bürck at KIT for technical support for ANKA synchrotron CD beamline. The authors thank Bing‐Yu Yao and Chi‐Long Lin at Academia Sinica for technical supports for nanoprecipitation and confocal microscopy, respectively. The authors thank Timothy K. Lu at Massachusetts Institute of Technology and Jing‐Ruey Joanna Yeh at Massachusetts General Hospital for valuable discussions. Publisher Copyright: © 2022 The Authors. Advanced Science published by Wiley-VCH GmbH.

PY - 2022/5/5

Y1 - 2022/5/5

N2 - Membrane-lytic peptides offer broad synthetic flexibilities and design potential to the arsenal of anticancer therapeutics, which can be limited by cytotoxicity to noncancerous cells and induction of drug resistance via stress-induced mutagenesis. Despite continued research efforts on membrane-perforating peptides for antimicrobial applications, success in anticancer peptide therapeutics remains elusive given the muted distinction between cancerous and normal cell membranes and the challenge of peptide degradation and neutralization upon intravenous delivery. Using triple-negative breast cancer as a model, the authors report the development of a new class of anticancer peptides. Through function-conserving mutations, the authors achieved cancer cell selective membrane perforation, with leads exhibiting a 200-fold selectivity over non-cancerogenic cells and superior cytotoxicity over doxorubicin against breast cancer tumorspheres. Upon continuous exposure to the anticancer peptides at growth-arresting concentrations, cancer cells do not exhibit resistance phenotype, frequently observed under chemotherapeutic treatment. The authors further demonstrate efficient encapsulation of the anticancer peptides in 20 nm polymeric nanocarriers, which possess high tolerability and lead to effective tumor growth inhibition in a mouse model of MDA-MB-231 triple-negative breast cancer. This work demonstrates a multidisciplinary approach for enabling translationally relevant membrane-lytic peptides in oncology, opening up a vast chemical repertoire to the arms race against cancer.

AB - Membrane-lytic peptides offer broad synthetic flexibilities and design potential to the arsenal of anticancer therapeutics, which can be limited by cytotoxicity to noncancerous cells and induction of drug resistance via stress-induced mutagenesis. Despite continued research efforts on membrane-perforating peptides for antimicrobial applications, success in anticancer peptide therapeutics remains elusive given the muted distinction between cancerous and normal cell membranes and the challenge of peptide degradation and neutralization upon intravenous delivery. Using triple-negative breast cancer as a model, the authors report the development of a new class of anticancer peptides. Through function-conserving mutations, the authors achieved cancer cell selective membrane perforation, with leads exhibiting a 200-fold selectivity over non-cancerogenic cells and superior cytotoxicity over doxorubicin against breast cancer tumorspheres. Upon continuous exposure to the anticancer peptides at growth-arresting concentrations, cancer cells do not exhibit resistance phenotype, frequently observed under chemotherapeutic treatment. The authors further demonstrate efficient encapsulation of the anticancer peptides in 20 nm polymeric nanocarriers, which possess high tolerability and lead to effective tumor growth inhibition in a mouse model of MDA-MB-231 triple-negative breast cancer. This work demonstrates a multidisciplinary approach for enabling translationally relevant membrane-lytic peptides in oncology, opening up a vast chemical repertoire to the arms race against cancer.

KW - anticancer peptides

KW - drug resistance

KW - membrane-active anticancer agents

KW - multicellular tumor spheroids

KW - murine models

KW - nanoparticles

KW - triple negative breast cancer

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DO - 10.1002/advs.202105506

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Integrated Design of a Membrane-Lytic Peptide-Based Intravenous Nanotherapeutic Suppresses Triple-Negative Breast Cancer

Abstract

Keywords

UN SDGs

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