Application of single-cell RNA sequencing in optimizing a combinatorial therapeutic strategy in metastatic renal cell carcinoma

Kyu Tae Kim; Hye Won Lee; Hae Ock Lee; Hye Jin Song; Da Eun Jeong; Sang Shin; Hyunho Kim; Yoojin Shin; Do Hyun Nam; Byong Chang Jeong; David G. Kirsch; Kyeung Min Joo; Woong Yang Park

doi:10.1186/s13059-016-0945-9

Application of single-cell RNA sequencing in optimizing a combinatorial therapeutic strategy in metastatic renal cell carcinoma

Kyu Tae Kim
, Hye Won Lee
, Hae Ock Lee
, Hye Jin Song
, Da Eun Jeong
, Sang Shin
, Hyunho Kim
, Yoojin Shin
, Do Hyun Nam
, Byong Chang Jeong
, David G. Kirsch
, Kyeung Min Joo
, Woong Yang Park

Sungkyunkwan University

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

177 Scopus citations

Abstract

BACKGROUND: Intratumoral heterogeneity hampers the success of marker-based anticancer treatment because the targeted therapy may eliminate a specific subpopulation of tumor cells while leaving others unharmed. Accordingly, a rational strategy minimizing survival of the drug-resistant subpopulation is essential to achieve long-term therapeutic efficacy.

RESULTS: Using single-cell RNA sequencing (RNA-seq), we examine the intratumoral heterogeneity of a pair of primary renal cell carcinoma and its lung metastasis. Activation of drug target pathways demonstrates considerable variability between the primary and metastatic sites, as well as among individual cancer cells within each site. Based on the prediction of multiple drug target pathway activation, we derive a combinatorial regimen co-targeting two mutually exclusive pathways for the metastatic cancer cells. This combinatorial strategy shows significant increase in the treatment efficacy over monotherapy in the experimental validation using patient-derived xenograft platforms in vitro and in vivo.

CONCLUSIONS: Our findings demonstrate the investigational application of single-cell RNA-seq in the design of an anticancer regimen. The approach may overcome intratumoral heterogeneity which hampers the success of precision medicine.

Original language	English
Article number	80
Pages (from-to)	80
Number of pages	1
Journal	Genome Biology
Volume	17
DOIs	https://doi.org/10.1186/s13059-016-0945-9
State	Published - 29 Apr 2016

Keywords

Drug response
Patient-derived xenograft
Renal cell carcinoma
Single cell analysis
Tumor heterogeneity

UN SDGs

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

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10.1186/s13059-016-0945-9

Cite this

Kim, K. T., Lee, H. W., Lee, H. O., Song, H. J., Jeong, D. E., Shin, S., Kim, H., Shin, Y., Nam, D. H., Jeong, B. C., Kirsch, D. G., Joo, K. M., & Park, W. Y. (2016). Application of single-cell RNA sequencing in optimizing a combinatorial therapeutic strategy in metastatic renal cell carcinoma. Genome Biology, 17, 80. Article 80. https://doi.org/10.1186/s13059-016-0945-9

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abstract = "BACKGROUND: Intratumoral heterogeneity hampers the success of marker-based anticancer treatment because the targeted therapy may eliminate a specific subpopulation of tumor cells while leaving others unharmed. Accordingly, a rational strategy minimizing survival of the drug-resistant subpopulation is essential to achieve long-term therapeutic efficacy.RESULTS: Using single-cell RNA sequencing (RNA-seq), we examine the intratumoral heterogeneity of a pair of primary renal cell carcinoma and its lung metastasis. Activation of drug target pathways demonstrates considerable variability between the primary and metastatic sites, as well as among individual cancer cells within each site. Based on the prediction of multiple drug target pathway activation, we derive a combinatorial regimen co-targeting two mutually exclusive pathways for the metastatic cancer cells. This combinatorial strategy shows significant increase in the treatment efficacy over monotherapy in the experimental validation using patient-derived xenograft platforms in vitro and in vivo.CONCLUSIONS: Our findings demonstrate the investigational application of single-cell RNA-seq in the design of an anticancer regimen. The approach may overcome intratumoral heterogeneity which hampers the success of precision medicine.",

keywords = "Drug response, Patient-derived xenograft, Renal cell carcinoma, Single cell analysis, Tumor heterogeneity",

author = "Kim, \{Kyu Tae\} and Lee, \{Hye Won\} and Lee, \{Hae Ock\} and Song, \{Hye Jin\} and Jeong, \{Da Eun\} and Sang Shin and Hyunho Kim and Yoojin Shin and Nam, \{Do Hyun\} and Jeong, \{Byong Chang\} and Kirsch, \{David G.\} and Joo, \{Kyeung Min\} and Park, \{Woong Yang\}",

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AU - Kim, Kyu Tae

AU - Lee, Hye Won

AU - Lee, Hae Ock

AU - Song, Hye Jin

AU - Jeong, Da Eun

AU - Shin, Sang

AU - Kim, Hyunho

AU - Shin, Yoojin

AU - Nam, Do Hyun

AU - Jeong, Byong Chang

AU - Kirsch, David G.

AU - Joo, Kyeung Min

AU - Park, Woong Yang

PY - 2016/4/29

Y1 - 2016/4/29

N2 - BACKGROUND: Intratumoral heterogeneity hampers the success of marker-based anticancer treatment because the targeted therapy may eliminate a specific subpopulation of tumor cells while leaving others unharmed. Accordingly, a rational strategy minimizing survival of the drug-resistant subpopulation is essential to achieve long-term therapeutic efficacy.RESULTS: Using single-cell RNA sequencing (RNA-seq), we examine the intratumoral heterogeneity of a pair of primary renal cell carcinoma and its lung metastasis. Activation of drug target pathways demonstrates considerable variability between the primary and metastatic sites, as well as among individual cancer cells within each site. Based on the prediction of multiple drug target pathway activation, we derive a combinatorial regimen co-targeting two mutually exclusive pathways for the metastatic cancer cells. This combinatorial strategy shows significant increase in the treatment efficacy over monotherapy in the experimental validation using patient-derived xenograft platforms in vitro and in vivo.CONCLUSIONS: Our findings demonstrate the investigational application of single-cell RNA-seq in the design of an anticancer regimen. The approach may overcome intratumoral heterogeneity which hampers the success of precision medicine.

AB - BACKGROUND: Intratumoral heterogeneity hampers the success of marker-based anticancer treatment because the targeted therapy may eliminate a specific subpopulation of tumor cells while leaving others unharmed. Accordingly, a rational strategy minimizing survival of the drug-resistant subpopulation is essential to achieve long-term therapeutic efficacy.RESULTS: Using single-cell RNA sequencing (RNA-seq), we examine the intratumoral heterogeneity of a pair of primary renal cell carcinoma and its lung metastasis. Activation of drug target pathways demonstrates considerable variability between the primary and metastatic sites, as well as among individual cancer cells within each site. Based on the prediction of multiple drug target pathway activation, we derive a combinatorial regimen co-targeting two mutually exclusive pathways for the metastatic cancer cells. This combinatorial strategy shows significant increase in the treatment efficacy over monotherapy in the experimental validation using patient-derived xenograft platforms in vitro and in vivo.CONCLUSIONS: Our findings demonstrate the investigational application of single-cell RNA-seq in the design of an anticancer regimen. The approach may overcome intratumoral heterogeneity which hampers the success of precision medicine.

KW - Drug response

KW - Patient-derived xenograft

KW - Renal cell carcinoma

KW - Single cell analysis

KW - Tumor heterogeneity

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JO - Genome Biology

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ER -

Application of single-cell RNA sequencing in optimizing a combinatorial therapeutic strategy in metastatic renal cell carcinoma

Abstract

Keywords

UN SDGs

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