Methylated DNA markers for plasma detection of ovarian cancer: Discovery, validation, and clinical feasibility

Lisa M. Marinelli; John B. Kisiel; Seth W. Slettedahl; Douglas W. Mahoney; Maureen A. Lemens; Vijayalakshmi Shridhar; William R. Taylor; Julie K. Staub; Xiaoming Cao; Patrick H. Foote; Kelli N. Burger; Calise K. Berger; Maria C. O'Connell; Karen A. Doering; Maria Giakoumopoulos; Hannah Berg; Carla Volkmann; Adam Solsrud; Hatim T. Allawi; Michael Kaiser; Abram M. Vaccaro; Catherine Albright Crawford; Cynthia Moehlenkamp; Gracie Shea; Melissa S. Deist; J. Kenneth Schoolmeester; Sarah E. Kerr; Mark E. Sherman; Jamie N. Bakkum-Gamez

doi:10.1016/j.ygyno.2022.03.018

Methylated DNA markers for plasma detection of ovarian cancer: Discovery, validation, and clinical feasibility

Lisa M. Marinelli, John B. Kisiel, Seth W. Slettedahl, Douglas W. Mahoney, Maureen A. Lemens, Vijayalakshmi Shridhar, William R. Taylor, Julie K. Staub, Xiaoming Cao, Patrick H. Foote, Kelli N. Burger, Calise K. Berger, Maria C. O'Connell, Karen A. Doering, Maria Giakoumopoulos, Hannah Berg, Carla Volkmann, Adam Solsrud, Hatim T. Allawi, Michael KaiserAbram M. Vaccaro, Catherine Albright Crawford, Cynthia Moehlenkamp, Gracie Shea, Melissa S. Deist, J. Kenneth Schoolmeester, Sarah E. Kerr, Mark E. Sherman, Jamie N. Bakkum-Gamez

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

Abstract

Objective: Aberrant DNA methylation is an early event in carcinogenesis which could be leveraged to detect ovarian cancer (OC) in plasma. Methods: DNA from frozen OC tissues, benign fallopian tube epithelium (FTE), and buffy coats from cancer-free women underwent reduced representation bisulfite sequencing (RRBS) to identify OC MDMs. Candidate MDM selection was based on receiver operating characteristic (ROC) discrimination, methylation fold change, and low background methylation among controls. Blinded biological validation was performed using methylated specific PCR on DNA extracted from independent OC and FTE FFPE tissues. MDMs were tested using Target Enrichment Long-probe Quantitative Amplified Signal (TELQAS) assays in pre-treatment plasma from women newly diagnosed with OC and population-sampled healthy women. A random forest modeling analysis was performed to generate predictive probability of disease; results were 500-fold in silico cross-validated. Results: Thirty-three MDMs showed marked methylation fold changes (10 to >1000) across all OC subtypes vs FTE. Eleven MDMs (GPRIN1, CDO1, SRC, SIM2, AGRN, FAIM2, CELF2, RIPPLY3, GYPC, CAPN2, BCAT1) were tested on plasma from 91 women with OC (73 (80%) high-grade serous (HGS)) and 91 without OC; the cross-validated 11-MDM panel highly discriminated OC from controls (96% (95% CI, 89–99%) specificity; 79% (69–87%) sensitivity, and AUC 0.91 (0.86–0.96)). Among the 5 stage I/II HGS OCs included, all were correctly identified. Conclusions: Whole methylome sequencing, stringent filtering criteria, and biological validation yielded candidate MDMs for OC that performed with high sensitivity and specificity in plasma. Larger plasma-based OC MDM studies, including testing of pre-diagnostic specimens, are warranted.

Original language	English (US)
Pages (from-to)	568-576
Number of pages	9
Journal	Gynecologic oncology
Volume	165
Issue number	3
DOIs	https://doi.org/10.1016/j.ygyno.2022.03.018
State	Published - Jun 2022

Keywords

Carcinoma, ovarian epithelial/prevention & control
Cell-free nucleic acids
DNA methylation
Liquid biopsy
Ovarian neoplasm/diagnosis

ASJC Scopus subject areas

Oncology
Obstetrics and Gynecology

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10.1016/j.ygyno.2022.03.018

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Marinelli, L. M., Kisiel, J. B., Slettedahl, S. W., Mahoney, D. W., Lemens, M. A., Shridhar, V., Taylor, W. R., Staub, J. K., Cao, X., Foote, P. H., Burger, K. N., Berger, C. K., O'Connell, M. C., Doering, K. A., Giakoumopoulos, M., Berg, H., Volkmann, C., Solsrud, A., Allawi, H. T., ... Bakkum-Gamez, J. N. (2022). Methylated DNA markers for plasma detection of ovarian cancer: Discovery, validation, and clinical feasibility. Gynecologic oncology, 165(3), 568-576. https://doi.org/10.1016/j.ygyno.2022.03.018

Marinelli, LM, Kisiel, JB, Slettedahl, SW, Mahoney, DW, Lemens, MA, Shridhar, V, Taylor, WR, Staub, JK, Cao, X, Foote, PH, Burger, KN, Berger, CK, O'Connell, MC, Doering, KA, Giakoumopoulos, M, Berg, H, Volkmann, C, Solsrud, A, Allawi, HT, Kaiser, M, Vaccaro, AM, Albright Crawford, C, Moehlenkamp, C, Shea, G, Deist, MS, Schoolmeester, JK, Kerr, SE, Sherman, ME & Bakkum-Gamez, JN 2022, 'Methylated DNA markers for plasma detection of ovarian cancer: Discovery, validation, and clinical feasibility', Gynecologic oncology, vol. 165, no. 3, pp. 568-576. https://doi.org/10.1016/j.ygyno.2022.03.018

@article{436c34af46e34919ab748dfb9e977f93,

title = "Methylated DNA markers for plasma detection of ovarian cancer: Discovery, validation, and clinical feasibility",

abstract = "Objective: Aberrant DNA methylation is an early event in carcinogenesis which could be leveraged to detect ovarian cancer (OC) in plasma. Methods: DNA from frozen OC tissues, benign fallopian tube epithelium (FTE), and buffy coats from cancer-free women underwent reduced representation bisulfite sequencing (RRBS) to identify OC MDMs. Candidate MDM selection was based on receiver operating characteristic (ROC) discrimination, methylation fold change, and low background methylation among controls. Blinded biological validation was performed using methylated specific PCR on DNA extracted from independent OC and FTE FFPE tissues. MDMs were tested using Target Enrichment Long-probe Quantitative Amplified Signal (TELQAS) assays in pre-treatment plasma from women newly diagnosed with OC and population-sampled healthy women. A random forest modeling analysis was performed to generate predictive probability of disease; results were 500-fold in silico cross-validated. Results: Thirty-three MDMs showed marked methylation fold changes (10 to >1000) across all OC subtypes vs FTE. Eleven MDMs (GPRIN1, CDO1, SRC, SIM2, AGRN, FAIM2, CELF2, RIPPLY3, GYPC, CAPN2, BCAT1) were tested on plasma from 91 women with OC (73 (80%) high-grade serous (HGS)) and 91 without OC; the cross-validated 11-MDM panel highly discriminated OC from controls (96% (95% CI, 89–99%) specificity; 79% (69–87%) sensitivity, and AUC 0.91 (0.86–0.96)). Among the 5 stage I/II HGS OCs included, all were correctly identified. Conclusions: Whole methylome sequencing, stringent filtering criteria, and biological validation yielded candidate MDMs for OC that performed with high sensitivity and specificity in plasma. Larger plasma-based OC MDM studies, including testing of pre-diagnostic specimens, are warranted.",

keywords = "Carcinoma, ovarian epithelial/prevention & control, Cell-free nucleic acids, DNA methylation, Liquid biopsy, Ovarian neoplasm/diagnosis",

author = "Marinelli, {Lisa M.} and Kisiel, {John B.} and Slettedahl, {Seth W.} and Mahoney, {Douglas W.} and Lemens, {Maureen A.} and Vijayalakshmi Shridhar and Taylor, {William R.} and Staub, {Julie K.} and Xiaoming Cao and Foote, {Patrick H.} and Burger, {Kelli N.} and Berger, {Calise K.} and O'Connell, {Maria C.} and Doering, {Karen A.} and Maria Giakoumopoulos and Hannah Berg and Carla Volkmann and Adam Solsrud and Allawi, {Hatim T.} and Michael Kaiser and Vaccaro, {Abram M.} and {Albright Crawford}, Catherine and Cynthia Moehlenkamp and Gracie Shea and Deist, {Melissa S.} and Schoolmeester, {J. Kenneth} and Kerr, {Sarah E.} and Sherman, {Mark E.} and Bakkum-Gamez, {Jamie N.}",

note = "Funding Information: This research was supported by Mayo Clinic Comprehensive Cancer Center Support Grant (CA15083), funded by the National Cancer Institute ; the Mayo Clinic Specialized Program of Research Excellence (SPORE) in Ovarian Cancer ( CA136393 ) funded by the National Institutes of Health and CA214679 (to John Kisiel). Reagents and TELQAS assays were provided by Exact Sciences (Madison WI). The Medical Genome Facility, Genome Analysis Cor e (GAC) is supported, in part, by the Center for Individualized Medicine and the Mayo Clinic Comprehensive Cancer Center Grant ( CA15083 ). Funding Information: John B. Kisiel, Jamie N. Bakkum-Gamez, Douglas W. Mahoney, and William R. Taylor are inventors of Mayo Clinic intellectual property which is licensed to Exact Sciences (Madison WI) and may receive royalties, paid to Mayo Clinic. Seth W. Slettedahl, Xiaoming Cao, Patrick H. Foote, Kelli N. Burger, Calise K. Berger, Maria C. McGlinch, and Karen A. Doering are supported under a contract between Mayo Clinic and Exact Sciences. Maria Giakoumopoulos, Hannah Berg, Carla Volkmann, Adam Solsrud, Hatim T. Allawi, Michael Kaiser, Abram Vaccaro, Catherine Albright Crawford, Cynthia Moehlenkamp, Gracie Shea, and Melissa Deist are employees of Exact Sciences. Dr. Sherman has received collaborative research funding supported by Exact Sciences . Publisher Copyright: {\textcopyright} 2022 Elsevier Inc.",

year = "2022",

month = jun,

doi = "10.1016/j.ygyno.2022.03.018",

language = "English (US)",

volume = "165",

pages = "568--576",

journal = "Gynecologic Oncology",

issn = "0090-8258",

publisher = "Academic Press Inc.",

number = "3",

}

TY - JOUR

T1 - Methylated DNA markers for plasma detection of ovarian cancer

T2 - Discovery, validation, and clinical feasibility

AU - Marinelli, Lisa M.

AU - Kisiel, John B.

AU - Slettedahl, Seth W.

AU - Mahoney, Douglas W.

AU - Lemens, Maureen A.

AU - Shridhar, Vijayalakshmi

AU - Taylor, William R.

AU - Staub, Julie K.

AU - Cao, Xiaoming

AU - Foote, Patrick H.

AU - Burger, Kelli N.

AU - Berger, Calise K.

AU - O'Connell, Maria C.

AU - Doering, Karen A.

AU - Giakoumopoulos, Maria

AU - Berg, Hannah

AU - Volkmann, Carla

AU - Solsrud, Adam

AU - Allawi, Hatim T.

AU - Kaiser, Michael

AU - Vaccaro, Abram M.

AU - Albright Crawford, Catherine

AU - Moehlenkamp, Cynthia

AU - Shea, Gracie

AU - Deist, Melissa S.

AU - Schoolmeester, J. Kenneth

AU - Kerr, Sarah E.

AU - Sherman, Mark E.

AU - Bakkum-Gamez, Jamie N.

N1 - Funding Information: This research was supported by Mayo Clinic Comprehensive Cancer Center Support Grant (CA15083), funded by the National Cancer Institute ; the Mayo Clinic Specialized Program of Research Excellence (SPORE) in Ovarian Cancer ( CA136393 ) funded by the National Institutes of Health and CA214679 (to John Kisiel). Reagents and TELQAS assays were provided by Exact Sciences (Madison WI). The Medical Genome Facility, Genome Analysis Cor e (GAC) is supported, in part, by the Center for Individualized Medicine and the Mayo Clinic Comprehensive Cancer Center Grant ( CA15083 ). Funding Information: John B. Kisiel, Jamie N. Bakkum-Gamez, Douglas W. Mahoney, and William R. Taylor are inventors of Mayo Clinic intellectual property which is licensed to Exact Sciences (Madison WI) and may receive royalties, paid to Mayo Clinic. Seth W. Slettedahl, Xiaoming Cao, Patrick H. Foote, Kelli N. Burger, Calise K. Berger, Maria C. McGlinch, and Karen A. Doering are supported under a contract between Mayo Clinic and Exact Sciences. Maria Giakoumopoulos, Hannah Berg, Carla Volkmann, Adam Solsrud, Hatim T. Allawi, Michael Kaiser, Abram Vaccaro, Catherine Albright Crawford, Cynthia Moehlenkamp, Gracie Shea, and Melissa Deist are employees of Exact Sciences. Dr. Sherman has received collaborative research funding supported by Exact Sciences . Publisher Copyright: © 2022 Elsevier Inc.

PY - 2022/6

Y1 - 2022/6

N2 - Objective: Aberrant DNA methylation is an early event in carcinogenesis which could be leveraged to detect ovarian cancer (OC) in plasma. Methods: DNA from frozen OC tissues, benign fallopian tube epithelium (FTE), and buffy coats from cancer-free women underwent reduced representation bisulfite sequencing (RRBS) to identify OC MDMs. Candidate MDM selection was based on receiver operating characteristic (ROC) discrimination, methylation fold change, and low background methylation among controls. Blinded biological validation was performed using methylated specific PCR on DNA extracted from independent OC and FTE FFPE tissues. MDMs were tested using Target Enrichment Long-probe Quantitative Amplified Signal (TELQAS) assays in pre-treatment plasma from women newly diagnosed with OC and population-sampled healthy women. A random forest modeling analysis was performed to generate predictive probability of disease; results were 500-fold in silico cross-validated. Results: Thirty-three MDMs showed marked methylation fold changes (10 to >1000) across all OC subtypes vs FTE. Eleven MDMs (GPRIN1, CDO1, SRC, SIM2, AGRN, FAIM2, CELF2, RIPPLY3, GYPC, CAPN2, BCAT1) were tested on plasma from 91 women with OC (73 (80%) high-grade serous (HGS)) and 91 without OC; the cross-validated 11-MDM panel highly discriminated OC from controls (96% (95% CI, 89–99%) specificity; 79% (69–87%) sensitivity, and AUC 0.91 (0.86–0.96)). Among the 5 stage I/II HGS OCs included, all were correctly identified. Conclusions: Whole methylome sequencing, stringent filtering criteria, and biological validation yielded candidate MDMs for OC that performed with high sensitivity and specificity in plasma. Larger plasma-based OC MDM studies, including testing of pre-diagnostic specimens, are warranted.

AB - Objective: Aberrant DNA methylation is an early event in carcinogenesis which could be leveraged to detect ovarian cancer (OC) in plasma. Methods: DNA from frozen OC tissues, benign fallopian tube epithelium (FTE), and buffy coats from cancer-free women underwent reduced representation bisulfite sequencing (RRBS) to identify OC MDMs. Candidate MDM selection was based on receiver operating characteristic (ROC) discrimination, methylation fold change, and low background methylation among controls. Blinded biological validation was performed using methylated specific PCR on DNA extracted from independent OC and FTE FFPE tissues. MDMs were tested using Target Enrichment Long-probe Quantitative Amplified Signal (TELQAS) assays in pre-treatment plasma from women newly diagnosed with OC and population-sampled healthy women. A random forest modeling analysis was performed to generate predictive probability of disease; results were 500-fold in silico cross-validated. Results: Thirty-three MDMs showed marked methylation fold changes (10 to >1000) across all OC subtypes vs FTE. Eleven MDMs (GPRIN1, CDO1, SRC, SIM2, AGRN, FAIM2, CELF2, RIPPLY3, GYPC, CAPN2, BCAT1) were tested on plasma from 91 women with OC (73 (80%) high-grade serous (HGS)) and 91 without OC; the cross-validated 11-MDM panel highly discriminated OC from controls (96% (95% CI, 89–99%) specificity; 79% (69–87%) sensitivity, and AUC 0.91 (0.86–0.96)). Among the 5 stage I/II HGS OCs included, all were correctly identified. Conclusions: Whole methylome sequencing, stringent filtering criteria, and biological validation yielded candidate MDMs for OC that performed with high sensitivity and specificity in plasma. Larger plasma-based OC MDM studies, including testing of pre-diagnostic specimens, are warranted.

KW - Carcinoma, ovarian epithelial/prevention & control

KW - Cell-free nucleic acids

KW - DNA methylation

KW - Liquid biopsy

KW - Ovarian neoplasm/diagnosis

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UR - http://www.scopus.com/inward/citedby.url?scp=85127336231&partnerID=8YFLogxK

U2 - 10.1016/j.ygyno.2022.03.018

DO - 10.1016/j.ygyno.2022.03.018

M3 - Article

C2 - 35370009

AN - SCOPUS:85127336231

SN - 0090-8258

VL - 165

SP - 568

EP - 576

JO - Gynecologic Oncology

JF - Gynecologic Oncology

IS - 3

ER -

Methylated DNA markers for plasma detection of ovarian cancer: Discovery, validation, and clinical feasibility

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