Bimodal liquid biopsy for cancer immunotherapy based on peptide engineering and nanoscale analysis

Jiyoon Bu; Woo jin Jeong; Roya Jafari; Luke J. Kubiatowicz; Ashita Nair; Michael J. Poellmann; Rachel S. Hong; Elizabeth W. Liu; Randall H. Owen; Piper A. Rawding; Caroline M. Hopkins; Da Won Kim; Daniel J. George; Andrew J. Armstrong; Petr Král; Andrew Z. Wang; Justine Bruce; Tian Zhang; Randall J. Kimple; Seungpyo Hong

doi:10.1016/j.bios.2022.114445

Bimodal liquid biopsy for cancer immunotherapy based on peptide engineering and nanoscale analysis

Jiyoon Bu, Woo jin Jeong, Roya Jafari, Luke J. Kubiatowicz, Ashita Nair, Michael J. Poellmann, Rachel S. Hong, Elizabeth W. Liu, Randall H. Owen, Piper A. Rawding, Caroline M. Hopkins, Da Won Kim, Daniel J. George, Andrew J. Armstrong, Petr Král, Andrew Z. Wang, Justine Bruce, Tian Zhang, Randall J. Kimple, Seungpyo Hong

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

14 Scopus citations

Abstract

Despite its high potential, PD-L1 expressed by tumors has not been successfully utilized as a biomarker for estimating treatment responses to immunotherapy. Circulating tumor cells (CTCs) and tumor-derived exosomes that express PD-L1 can potentially be used as biomarkers; however, currently available assays lack clinically significant sensitivity and specificity. Here, a novel peptide-based capture surface is developed to effectively isolate PD-L1-expressing CTCs and exosomes from human blood. For the effective targeting of PD-L1, this study integrates peptide engineering strategies to enhance the binding strength and specificity of a β-hairpin peptide derived from PD-1 (pPD-1). Specifically, this study examines the effect of poly(ethylene glycol) spacers, the secondary peptide structure, and modification of peptide sequences (e.g., removal of biologically redundant amino acid residues) on capture efficiency. The optimized pPD-1 configuration captures PD-L1-expressing tumor cells and tumor-derived exosomes with 1.5-fold (p = 0.016) and 1.2-fold (p = 0.037) higher efficiencies, respectively, than their whole antibody counterpart (aPD-L1). This enhanced efficiency is translated into more clinically significant detection of CTCs (1.9-fold increase; p = 0.035) and exosomes (1.5-fold increase; p = 0.047) from patients' baseline samples, demonstrating stronger correlation with patients’ treatment responses. Additionally, we confirmed that the clinical accuracy of our system can be further improved by co-analyzing the two biomarkers (bimodal CTC/exosome analysis). These data demonstrate that pPD-1-based capture is a promising approach for capturing PD-L1-expressing CTCs and exosomes, which can be used as a reliable biomarker for cancer immunotherapy.

Original language	English (US)
Article number	114445
Journal	Biosensors and Bioelectronics
Volume	213
DOIs	https://doi.org/10.1016/j.bios.2022.114445
State	Published - Oct 1 2022
Externally published	Yes

Keywords

Bimodal liquid biopsy
Cancer immunotherapy
Circulating tumor cells
Exosomes
Peptide engineering

ASJC Scopus subject areas

Biotechnology
Biophysics
Biomedical Engineering
Electrochemistry

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10.1016/j.bios.2022.114445

Cite this

Bu, J., Jeong, W. J., Jafari, R., Kubiatowicz, L. J., Nair, A., Poellmann, M. J., Hong, R. S., Liu, E. W., Owen, R. H., Rawding, P. A., Hopkins, C. M., Kim, D. W., George, D. J., Armstrong, A. J., Král, P., Wang, A. Z., Bruce, J., Zhang, T., Kimple, R. J., & Hong, S. (2022). Bimodal liquid biopsy for cancer immunotherapy based on peptide engineering and nanoscale analysis. Biosensors and Bioelectronics, 213, Article 114445. https://doi.org/10.1016/j.bios.2022.114445

Bu, J, Jeong, WJ, Jafari, R, Kubiatowicz, LJ, Nair, A, Poellmann, MJ, Hong, RS, Liu, EW, Owen, RH, Rawding, PA, Hopkins, CM, Kim, DW, George, DJ, Armstrong, AJ, Král, P, Wang, AZ, Bruce, J, Zhang, T, Kimple, RJ & Hong, S 2022, 'Bimodal liquid biopsy for cancer immunotherapy based on peptide engineering and nanoscale analysis', Biosensors and Bioelectronics, vol. 213, 114445. https://doi.org/10.1016/j.bios.2022.114445

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title = "Bimodal liquid biopsy for cancer immunotherapy based on peptide engineering and nanoscale analysis",

abstract = "Despite its high potential, PD-L1 expressed by tumors has not been successfully utilized as a biomarker for estimating treatment responses to immunotherapy. Circulating tumor cells (CTCs) and tumor-derived exosomes that express PD-L1 can potentially be used as biomarkers; however, currently available assays lack clinically significant sensitivity and specificity. Here, a novel peptide-based capture surface is developed to effectively isolate PD-L1-expressing CTCs and exosomes from human blood. For the effective targeting of PD-L1, this study integrates peptide engineering strategies to enhance the binding strength and specificity of a β-hairpin peptide derived from PD-1 (pPD-1). Specifically, this study examines the effect of poly(ethylene glycol) spacers, the secondary peptide structure, and modification of peptide sequences (e.g., removal of biologically redundant amino acid residues) on capture efficiency. The optimized pPD-1 configuration captures PD-L1-expressing tumor cells and tumor-derived exosomes with 1.5-fold (p = 0.016) and 1.2-fold (p = 0.037) higher efficiencies, respectively, than their whole antibody counterpart (aPD-L1). This enhanced efficiency is translated into more clinically significant detection of CTCs (1.9-fold increase; p = 0.035) and exosomes (1.5-fold increase; p = 0.047) from patients' baseline samples, demonstrating stronger correlation with patients{\textquoteright} treatment responses. Additionally, we confirmed that the clinical accuracy of our system can be further improved by co-analyzing the two biomarkers (bimodal CTC/exosome analysis). These data demonstrate that pPD-1-based capture is a promising approach for capturing PD-L1-expressing CTCs and exosomes, which can be used as a reliable biomarker for cancer immunotherapy.",

keywords = "Bimodal liquid biopsy, Cancer immunotherapy, Circulating tumor cells, Exosomes, Peptide engineering",

author = "Jiyoon Bu and Jeong, {Woo jin} and Roya Jafari and Kubiatowicz, {Luke J.} and Ashita Nair and Poellmann, {Michael J.} and Hong, {Rachel S.} and Liu, {Elizabeth W.} and Owen, {Randall H.} and Rawding, {Piper A.} and Hopkins, {Caroline M.} and Kim, {Da Won} and George, {Daniel J.} and Armstrong, {Andrew J.} and Petr Kr{\'a}l and Wang, {Andrew Z.} and Justine Bruce and Tian Zhang and Kimple, {Randall J.} and Seungpyo Hong",

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year = "2022",

month = oct,

day = "1",

doi = "10.1016/j.bios.2022.114445",

language = "English (US)",

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AU - Bu, Jiyoon

AU - Jeong, Woo jin

AU - Jafari, Roya

AU - Kubiatowicz, Luke J.

AU - Nair, Ashita

AU - Poellmann, Michael J.

AU - Hong, Rachel S.

AU - Liu, Elizabeth W.

AU - Owen, Randall H.

AU - Rawding, Piper A.

AU - Hopkins, Caroline M.

AU - Kim, Da Won

AU - George, Daniel J.

AU - Armstrong, Andrew J.

AU - Král, Petr

AU - Wang, Andrew Z.

AU - Bruce, Justine

AU - Zhang, Tian

AU - Kimple, Randall J.

AU - Hong, Seungpyo

PY - 2022/10/1

Y1 - 2022/10/1

N2 - Despite its high potential, PD-L1 expressed by tumors has not been successfully utilized as a biomarker for estimating treatment responses to immunotherapy. Circulating tumor cells (CTCs) and tumor-derived exosomes that express PD-L1 can potentially be used as biomarkers; however, currently available assays lack clinically significant sensitivity and specificity. Here, a novel peptide-based capture surface is developed to effectively isolate PD-L1-expressing CTCs and exosomes from human blood. For the effective targeting of PD-L1, this study integrates peptide engineering strategies to enhance the binding strength and specificity of a β-hairpin peptide derived from PD-1 (pPD-1). Specifically, this study examines the effect of poly(ethylene glycol) spacers, the secondary peptide structure, and modification of peptide sequences (e.g., removal of biologically redundant amino acid residues) on capture efficiency. The optimized pPD-1 configuration captures PD-L1-expressing tumor cells and tumor-derived exosomes with 1.5-fold (p = 0.016) and 1.2-fold (p = 0.037) higher efficiencies, respectively, than their whole antibody counterpart (aPD-L1). This enhanced efficiency is translated into more clinically significant detection of CTCs (1.9-fold increase; p = 0.035) and exosomes (1.5-fold increase; p = 0.047) from patients' baseline samples, demonstrating stronger correlation with patients’ treatment responses. Additionally, we confirmed that the clinical accuracy of our system can be further improved by co-analyzing the two biomarkers (bimodal CTC/exosome analysis). These data demonstrate that pPD-1-based capture is a promising approach for capturing PD-L1-expressing CTCs and exosomes, which can be used as a reliable biomarker for cancer immunotherapy.

AB - Despite its high potential, PD-L1 expressed by tumors has not been successfully utilized as a biomarker for estimating treatment responses to immunotherapy. Circulating tumor cells (CTCs) and tumor-derived exosomes that express PD-L1 can potentially be used as biomarkers; however, currently available assays lack clinically significant sensitivity and specificity. Here, a novel peptide-based capture surface is developed to effectively isolate PD-L1-expressing CTCs and exosomes from human blood. For the effective targeting of PD-L1, this study integrates peptide engineering strategies to enhance the binding strength and specificity of a β-hairpin peptide derived from PD-1 (pPD-1). Specifically, this study examines the effect of poly(ethylene glycol) spacers, the secondary peptide structure, and modification of peptide sequences (e.g., removal of biologically redundant amino acid residues) on capture efficiency. The optimized pPD-1 configuration captures PD-L1-expressing tumor cells and tumor-derived exosomes with 1.5-fold (p = 0.016) and 1.2-fold (p = 0.037) higher efficiencies, respectively, than their whole antibody counterpart (aPD-L1). This enhanced efficiency is translated into more clinically significant detection of CTCs (1.9-fold increase; p = 0.035) and exosomes (1.5-fold increase; p = 0.047) from patients' baseline samples, demonstrating stronger correlation with patients’ treatment responses. Additionally, we confirmed that the clinical accuracy of our system can be further improved by co-analyzing the two biomarkers (bimodal CTC/exosome analysis). These data demonstrate that pPD-1-based capture is a promising approach for capturing PD-L1-expressing CTCs and exosomes, which can be used as a reliable biomarker for cancer immunotherapy.

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KW - Cancer immunotherapy

KW - Circulating tumor cells

KW - Exosomes

KW - Peptide engineering

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ER -

Bimodal liquid biopsy for cancer immunotherapy based on peptide engineering and nanoscale analysis

Abstract

Keywords

ASJC Scopus subject areas

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