A flow-proteometric platform for analyzing protein concentration (FAP): Proof of concept for quantification of PD-L1 protein in cells and tissues

Chao Kai Chou; Po Jung Huang; Pei Hsiang Tsou; Yongkun Wei; Heng Huan Lee; Ying Nai Wang; Yen Liang Liu; Colin Shi; Hsin Chih Yeh; Jun Kameoka; Mien Chie Hung

doi:10.1016/j.bios.2018.05.053

A flow-proteometric platform for analyzing protein concentration (FAP): Proof of concept for quantification of PD-L1 protein in cells and tissues

Chao Kai Chou, Po Jung Huang, Pei Hsiang Tsou, Yongkun Wei, Heng Huan Lee, Ying Nai Wang, Yen Liang Liu, Colin Shi, Hsin Chih Yeh, Jun Kameoka^*, Mien Chie Hung

^*Corresponding author for this work

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

6 Citations (Scopus)

Abstract

Protein expression level is critically related to the cell physiological function. However, current methodologies such as Western blot (WB) and Immunohistochemistry (IHC) in analyzing the protein level are rather semi-quantitative and without the information of actual protein concentration. We have developed a microfluidic technique termed a “flow-proteometric platform for analyzing protein concentration (FAP)” that can measure the concentration of a target protein in cells or tissues without the requirement of a calibration standard, e.g., the purified target molecules. To validate our method, we tested a number of control samples with known target protein concentrations and showed that the FAP measurement resulted in concentrations that well matched the actual concentrations in the control samples (coefficient of determination [R²], 0.998), demonstrating a dynamic range of concentrations from 0.13 to 130 pM of a detection for 2 min. We successfully determined a biomarker protein (for predicting the treatment response of cancer immune check-point therapy) PD-L1 concentration in cancer cell lines (HeLa PD-L1 and MDA-MB-231) and breast cancer patient tumor tissues without any prior process of sample purification and standard line construction. Therefore, FAP is a simple, faster, and reliable method to measure the protein concentration in cells and tissues, which can support the conventional methods such as WB and IHC to determine the actual protein level.

Original language	English
Pages (from-to)	97-103
Number of pages	7
Journal	Biosensors and Bioelectronics
Volume	117
DOIs	https://doi.org/10.1016/j.bios.2018.05.053
Publication status	Published - 2018 Oct 15
Externally published	Yes

Keywords

Microfluidics
Protein concentration
Quantified immunohistochemistry
Single molecule
Standard free

ASJC Scopus subject areas

Biotechnology
Biophysics
Biomedical Engineering
Electrochemistry

UN SDGs

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

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10.1016/j.bios.2018.05.053

Cite this

Chou, C. K., Huang, P. J., Tsou, P. H., Wei, Y., Lee, H. H., Wang, Y. N., Liu, Y. L., Shi, C., Yeh, H. C., Kameoka, J., & Hung, M. C. (2018). A flow-proteometric platform for analyzing protein concentration (FAP): Proof of concept for quantification of PD-L1 protein in cells and tissues. Biosensors and Bioelectronics, 117, 97-103. https://doi.org/10.1016/j.bios.2018.05.053

@article{8711937ea81b4ab799663232979a884c,

title = "A flow-proteometric platform for analyzing protein concentration (FAP): Proof of concept for quantification of PD-L1 protein in cells and tissues",

abstract = "Protein expression level is critically related to the cell physiological function. However, current methodologies such as Western blot (WB) and Immunohistochemistry (IHC) in analyzing the protein level are rather semi-quantitative and without the information of actual protein concentration. We have developed a microfluidic technique termed a “flow-proteometric platform for analyzing protein concentration (FAP)” that can measure the concentration of a target protein in cells or tissues without the requirement of a calibration standard, e.g., the purified target molecules. To validate our method, we tested a number of control samples with known target protein concentrations and showed that the FAP measurement resulted in concentrations that well matched the actual concentrations in the control samples (coefficient of determination [R2], 0.998), demonstrating a dynamic range of concentrations from 0.13 to 130 pM of a detection for 2 min. We successfully determined a biomarker protein (for predicting the treatment response of cancer immune check-point therapy) PD-L1 concentration in cancer cell lines (HeLa PD-L1 and MDA-MB-231) and breast cancer patient tumor tissues without any prior process of sample purification and standard line construction. Therefore, FAP is a simple, faster, and reliable method to measure the protein concentration in cells and tissues, which can support the conventional methods such as WB and IHC to determine the actual protein level.",

keywords = "Microfluidics, Protein concentration, Quantified immunohistochemistry, Single molecule, Standard free",

author = "Chou, {Chao Kai} and Huang, {Po Jung} and Tsou, {Pei Hsiang} and Yongkun Wei and Lee, {Heng Huan} and Wang, {Ying Nai} and Liu, {Yen Liang} and Colin Shi and Yeh, {Hsin Chih} and Jun Kameoka and Hung, {Mien Chie}",

note = "Funding Information: This work was funded in part by the following: National Institutes of Health (CCSG P30 CA 016672) to the shRNA and ORFeome Core and the Clinical Trials Support Resource; Cancer Prevention & Research Institutes of Texas (RP160710 and DP150052); Breast Cancer Research Foundation (BCRF-17-069); National Breast Cancer Foundation, Inc.; Patel Memorial Breast Cancer Endowment Fund; The University of Texas MD Anderson-China Medical University and Hospital Sister Institution Fund (to M.-C.H.); Ministry of Health and Welfare, China Medical University Hospital Cancer Research Center of Excellence (MOHW107-TDU-B-212-114024 and MOHW107-TDU-B-212-112015); Center for Biological Pathways; H.-C.Y acknowledges the support of this work by the Robert A. Welch Foundation (F-1833), NIH (CA193038) and NSF (1611451). We also thank Dr. Shang-Wei Tsai and Dr. Jin-Chern Chiou at National Chiao Tung University in Taiwan for supporting the microchannel fabrication, Dr. Shih-Chu Liao and Dr. Beniamino Barbieri in ISS Inc. for the technical support, and Dr. Jennifer Hsu and Ms. Sunita Patterson for providing editing support. Funding Information: This work was funded in part by the following: National Institutes of Health ( CCSG P30 CA 016672 ) to the shRNA and ORFeome Core and the Clinical Trials Support Resource; Cancer Prevention & Research Institutes of Texas ( RP160710 and DP150052 ); Breast Cancer Research Foundation ( BCRF-17-069 ); National Breast Cancer Foundation, Inc.; Patel Memorial Breast Cancer Endowment Fund; The University of Texas MD Anderson-China Medical University and Hospital Sister Institution Fund (to M.-C.H.); Ministry of Health and Welfare, China Medical University Hospital Cancer Research Center of Excellence ( MOHW107-TDU-B-212-114024 and MOHW107-TDU-B-212-112015 ); Center for Biological Pathways; H.-C.Y acknowledges the support of this work by the Robert A. Welch Foundation (F-1833), NIH ( CA193038 ) and NSF ( 1611451 ). We also thank Dr. Shang-Wei Tsai and Dr. Jin-Chern Chiou at National Chiao Tung University in Taiwan for supporting the microchannel fabrication, Dr. Shih-Chu Liao and Dr. Beniamino Barbieri in ISS Inc. for the technical support, and Dr. Jennifer Hsu and Ms. Sunita Patterson for providing editing support. Publisher Copyright: {\textcopyright} 2018 Elsevier B.V.",

year = "2018",

month = oct,

day = "15",

doi = "10.1016/j.bios.2018.05.053",

language = "English",

volume = "117",

pages = "97--103",

journal = "Biosensors and Bioelectronics",

issn = "0956-5663",

publisher = "Elsevier Ltd",

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TY - JOUR

T1 - A flow-proteometric platform for analyzing protein concentration (FAP)

T2 - Proof of concept for quantification of PD-L1 protein in cells and tissues

AU - Chou, Chao Kai

AU - Huang, Po Jung

AU - Tsou, Pei Hsiang

AU - Wei, Yongkun

AU - Lee, Heng Huan

AU - Wang, Ying Nai

AU - Liu, Yen Liang

AU - Shi, Colin

AU - Yeh, Hsin Chih

AU - Kameoka, Jun

AU - Hung, Mien Chie

N1 - Funding Information: This work was funded in part by the following: National Institutes of Health (CCSG P30 CA 016672) to the shRNA and ORFeome Core and the Clinical Trials Support Resource; Cancer Prevention & Research Institutes of Texas (RP160710 and DP150052); Breast Cancer Research Foundation (BCRF-17-069); National Breast Cancer Foundation, Inc.; Patel Memorial Breast Cancer Endowment Fund; The University of Texas MD Anderson-China Medical University and Hospital Sister Institution Fund (to M.-C.H.); Ministry of Health and Welfare, China Medical University Hospital Cancer Research Center of Excellence (MOHW107-TDU-B-212-114024 and MOHW107-TDU-B-212-112015); Center for Biological Pathways; H.-C.Y acknowledges the support of this work by the Robert A. Welch Foundation (F-1833), NIH (CA193038) and NSF (1611451). We also thank Dr. Shang-Wei Tsai and Dr. Jin-Chern Chiou at National Chiao Tung University in Taiwan for supporting the microchannel fabrication, Dr. Shih-Chu Liao and Dr. Beniamino Barbieri in ISS Inc. for the technical support, and Dr. Jennifer Hsu and Ms. Sunita Patterson for providing editing support. Funding Information: This work was funded in part by the following: National Institutes of Health ( CCSG P30 CA 016672 ) to the shRNA and ORFeome Core and the Clinical Trials Support Resource; Cancer Prevention & Research Institutes of Texas ( RP160710 and DP150052 ); Breast Cancer Research Foundation ( BCRF-17-069 ); National Breast Cancer Foundation, Inc.; Patel Memorial Breast Cancer Endowment Fund; The University of Texas MD Anderson-China Medical University and Hospital Sister Institution Fund (to M.-C.H.); Ministry of Health and Welfare, China Medical University Hospital Cancer Research Center of Excellence ( MOHW107-TDU-B-212-114024 and MOHW107-TDU-B-212-112015 ); Center for Biological Pathways; H.-C.Y acknowledges the support of this work by the Robert A. Welch Foundation (F-1833), NIH ( CA193038 ) and NSF ( 1611451 ). We also thank Dr. Shang-Wei Tsai and Dr. Jin-Chern Chiou at National Chiao Tung University in Taiwan for supporting the microchannel fabrication, Dr. Shih-Chu Liao and Dr. Beniamino Barbieri in ISS Inc. for the technical support, and Dr. Jennifer Hsu and Ms. Sunita Patterson for providing editing support. Publisher Copyright: © 2018 Elsevier B.V.

PY - 2018/10/15

Y1 - 2018/10/15

N2 - Protein expression level is critically related to the cell physiological function. However, current methodologies such as Western blot (WB) and Immunohistochemistry (IHC) in analyzing the protein level are rather semi-quantitative and without the information of actual protein concentration. We have developed a microfluidic technique termed a “flow-proteometric platform for analyzing protein concentration (FAP)” that can measure the concentration of a target protein in cells or tissues without the requirement of a calibration standard, e.g., the purified target molecules. To validate our method, we tested a number of control samples with known target protein concentrations and showed that the FAP measurement resulted in concentrations that well matched the actual concentrations in the control samples (coefficient of determination [R2], 0.998), demonstrating a dynamic range of concentrations from 0.13 to 130 pM of a detection for 2 min. We successfully determined a biomarker protein (for predicting the treatment response of cancer immune check-point therapy) PD-L1 concentration in cancer cell lines (HeLa PD-L1 and MDA-MB-231) and breast cancer patient tumor tissues without any prior process of sample purification and standard line construction. Therefore, FAP is a simple, faster, and reliable method to measure the protein concentration in cells and tissues, which can support the conventional methods such as WB and IHC to determine the actual protein level.

AB - Protein expression level is critically related to the cell physiological function. However, current methodologies such as Western blot (WB) and Immunohistochemistry (IHC) in analyzing the protein level are rather semi-quantitative and without the information of actual protein concentration. We have developed a microfluidic technique termed a “flow-proteometric platform for analyzing protein concentration (FAP)” that can measure the concentration of a target protein in cells or tissues without the requirement of a calibration standard, e.g., the purified target molecules. To validate our method, we tested a number of control samples with known target protein concentrations and showed that the FAP measurement resulted in concentrations that well matched the actual concentrations in the control samples (coefficient of determination [R2], 0.998), demonstrating a dynamic range of concentrations from 0.13 to 130 pM of a detection for 2 min. We successfully determined a biomarker protein (for predicting the treatment response of cancer immune check-point therapy) PD-L1 concentration in cancer cell lines (HeLa PD-L1 and MDA-MB-231) and breast cancer patient tumor tissues without any prior process of sample purification and standard line construction. Therefore, FAP is a simple, faster, and reliable method to measure the protein concentration in cells and tissues, which can support the conventional methods such as WB and IHC to determine the actual protein level.

KW - Microfluidics

KW - Protein concentration

KW - Quantified immunohistochemistry

KW - Single molecule

KW - Standard free

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AN - SCOPUS:85048180831

SN - 0956-5663

VL - 117

SP - 97

EP - 103

JO - Biosensors and Bioelectronics

JF - Biosensors and Bioelectronics

ER -

A flow-proteometric platform for analyzing protein concentration (FAP): Proof of concept for quantification of PD-L1 protein in cells and tissues

Abstract

Keywords

ASJC Scopus subject areas

UN SDGs

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