The molecular features of chronic lung allograft dysfunction in lung transplant airway mucosa

Kieran Halloran; Martina Mackova; Michael D. Parkes; Alim Hirji; Justin Weinkauf; Irina L. Timofte; Greg I. Snell; Glen P. Westall; Robert Lischke; Andrea Zajacova; Jan Havlin; Ramsey Hachem; Daniel Kreisel; Deborah Levine; Bartosz Kubisa; Maria Piotrowska; Stephen Juvet; Shaf Keshavjee; Peter Jaksch; Walter Klepetko; Philip F. Halloran

doi:10.1016/j.healun.2022.08.014

The molecular features of chronic lung allograft dysfunction in lung transplant airway mucosa

Kieran Halloran, Martina Mackova, Michael D. Parkes, Alim Hirji, Justin Weinkauf, Irina L. Timofte, Greg I. Snell, Glen P. Westall, Robert Lischke, Andrea Zajacova, Jan Havlin, Ramsey Hachem, Daniel Kreisel, Deborah Levine, Bartosz Kubisa, Maria Piotrowska, Stephen Juvet, Shaf Keshavjee, Peter Jaksch, Walter KlepetkoPhilip F. Halloran

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

2 Scopus citations

Abstract

Background: Many lung transplants fail due to chronic lung allograft dysfunction (CLAD). We recently showed that transbronchial biopsies (TBBs) from CLAD patients manifest severe parenchymal injury and dedifferentiation, distinct from time-dependent changes. The present study explored time-selective and CLAD-selective transcripts in mucosal biopsies from the third bronchial bifurcation (3BMBs), compared to those in TBBs. Methods: We used genome-wide microarray measurements in 324 3BMBs to identify CLAD-selective changes as well as time-dependent changes and develop a CLAD classifier. CLAD-selective transcripts were identified with linear models for microarray data (limma) and were used to build an ensemble of 12 classifiers to predict CLAD. Hazard models and random forests were then used to predict the risk of graft loss using the CLAD classifier, transcript sets associated with rejection, injury, and time. Results: T cell-mediated rejection and donor-specific antibody were increased in CLAD 3BMBs but most had no rejection. Like TBBs, 3BMBs showed a time-dependent increase in transcripts expressed in inflammatory cells that was not associated with CLAD or survival. Also like TBBs, the CLAD-selective transcripts in 3BMBs reflected severe parenchymal injury and dedifferentiation, not inflammation or rejection. While 3BMBs and TBBs did not overlap in their top 20 CLAD-selective transcripts, many CLAD-selective transcripts were significantly increased in both for example LOXL1, an enzyme controlling matrix remodeling. In Cox models for one-year survival, the 3BMB CLAD-selective transcripts and CLAD classifier predicted graft loss and correlated with CLAD stage. Many 3BMB CLAD-selective transcripts were also increased by injury in kidney transplants and correlated with decreased kidney survival, including LOXL1. Conclusions: Mucosal and transbronchial biopsies from CLAD patients reveal a diffuse molecular injury and dedifferentiation state that impacts prognosis and correlates with the physiologic disturbances. CLAD state in lung transplants shares features with failing kidney transplants, indicating elements shared by the injury responses of distressed organs.

Original language	English (US)
Pages (from-to)	1689-1699
Number of pages	11
Journal	Journal of Heart and Lung Transplantation
Volume	41
Issue number	12
DOIs	https://doi.org/10.1016/j.healun.2022.08.014
State	Published - Dec 2022
Externally published	Yes

Keywords

airway
chronic lung allograft dysfunction
gene expression
injury

ASJC Scopus subject areas

Surgery
Pulmonary and Respiratory Medicine
Cardiology and Cardiovascular Medicine
Transplantation

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10.1016/j.healun.2022.08.014

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Halloran, K., Mackova, M., Parkes, M. D., Hirji, A., Weinkauf, J., Timofte, I. L., Snell, G. I., Westall, G. P., Lischke, R., Zajacova, A., Havlin, J., Hachem, R., Kreisel, D., Levine, D., Kubisa, B., Piotrowska, M., Juvet, S., Keshavjee, S., Jaksch, P., ... Halloran, P. F. (2022). The molecular features of chronic lung allograft dysfunction in lung transplant airway mucosa. Journal of Heart and Lung Transplantation, 41(12), 1689-1699. https://doi.org/10.1016/j.healun.2022.08.014

Halloran, K, Mackova, M, Parkes, MD, Hirji, A, Weinkauf, J, Timofte, IL, Snell, GI, Westall, GP, Lischke, R, Zajacova, A, Havlin, J, Hachem, R, Kreisel, D, Levine, D, Kubisa, B, Piotrowska, M, Juvet, S, Keshavjee, S, Jaksch, P, Klepetko, W & Halloran, PF 2022, 'The molecular features of chronic lung allograft dysfunction in lung transplant airway mucosa', Journal of Heart and Lung Transplantation, vol. 41, no. 12, pp. 1689-1699. https://doi.org/10.1016/j.healun.2022.08.014

@article{51e9065ed064467ab432782e4d716667,

title = "The molecular features of chronic lung allograft dysfunction in lung transplant airway mucosa",

abstract = "Background: Many lung transplants fail due to chronic lung allograft dysfunction (CLAD). We recently showed that transbronchial biopsies (TBBs) from CLAD patients manifest severe parenchymal injury and dedifferentiation, distinct from time-dependent changes. The present study explored time-selective and CLAD-selective transcripts in mucosal biopsies from the third bronchial bifurcation (3BMBs), compared to those in TBBs. Methods: We used genome-wide microarray measurements in 324 3BMBs to identify CLAD-selective changes as well as time-dependent changes and develop a CLAD classifier. CLAD-selective transcripts were identified with linear models for microarray data (limma) and were used to build an ensemble of 12 classifiers to predict CLAD. Hazard models and random forests were then used to predict the risk of graft loss using the CLAD classifier, transcript sets associated with rejection, injury, and time. Results: T cell-mediated rejection and donor-specific antibody were increased in CLAD 3BMBs but most had no rejection. Like TBBs, 3BMBs showed a time-dependent increase in transcripts expressed in inflammatory cells that was not associated with CLAD or survival. Also like TBBs, the CLAD-selective transcripts in 3BMBs reflected severe parenchymal injury and dedifferentiation, not inflammation or rejection. While 3BMBs and TBBs did not overlap in their top 20 CLAD-selective transcripts, many CLAD-selective transcripts were significantly increased in both for example LOXL1, an enzyme controlling matrix remodeling. In Cox models for one-year survival, the 3BMB CLAD-selective transcripts and CLAD classifier predicted graft loss and correlated with CLAD stage. Many 3BMB CLAD-selective transcripts were also increased by injury in kidney transplants and correlated with decreased kidney survival, including LOXL1. Conclusions: Mucosal and transbronchial biopsies from CLAD patients reveal a diffuse molecular injury and dedifferentiation state that impacts prognosis and correlates with the physiologic disturbances. CLAD state in lung transplants shares features with failing kidney transplants, indicating elements shared by the injury responses of distressed organs.",

keywords = "airway, chronic lung allograft dysfunction, gene expression, injury",

author = "Kieran Halloran and Martina Mackova and Parkes, {Michael D.} and Alim Hirji and Justin Weinkauf and Timofte, {Irina L.} and Snell, {Greg I.} and Westall, {Glen P.} and Robert Lischke and Andrea Zajacova and Jan Havlin and Ramsey Hachem and Daniel Kreisel and Deborah Levine and Bartosz Kubisa and Maria Piotrowska and Stephen Juvet and Shaf Keshavjee and Peter Jaksch and Walter Klepetko and Halloran, {Philip F.}",

note = "Funding Information: This research has been supported by grants from Genome Canada, Canada Foundation for Innovation, the University of Alberta Hospital Foundation, the Alberta Ministry of Advanced Education and Technology, the Mendez National Institute of Transplantation Foundation, and Industrial Research Assistance Program. Partial support was also provided by funding from a licensing agreement with the One Lambda Inc. division of Thermo Fisher Scientific. Dr. Halloran held a Canada Research Chair in Transplant Immunology until 2008 and currently holds the Muttart Chair in Clinical Immunology. Funding Information: Disclosure statement P F Halloran holds shares in Transcriptome Sciences Inc (TSI), a University of Alberta research company dedicated to developing molecular diagnostics, supported in part by a licensing agreement between TSI and Thermo Fisher Scientific, and by a research grant from Natera Inc.. P F Halloran is a consultant to Natera Inc.. The other authors have declared no conflict of interest exists. Publisher Copyright: {\textcopyright} 2022 International Society for Heart and Lung Transplantation",

year = "2022",

month = dec,

doi = "10.1016/j.healun.2022.08.014",

language = "English (US)",

volume = "41",

pages = "1689--1699",

journal = "Journal of Heart and Lung Transplantation",

issn = "1053-2498",

publisher = "Elsevier USA",

number = "12",

}

TY - JOUR

T1 - The molecular features of chronic lung allograft dysfunction in lung transplant airway mucosa

AU - Halloran, Kieran

AU - Mackova, Martina

AU - Parkes, Michael D.

AU - Hirji, Alim

AU - Weinkauf, Justin

AU - Timofte, Irina L.

AU - Snell, Greg I.

AU - Westall, Glen P.

AU - Lischke, Robert

AU - Zajacova, Andrea

AU - Havlin, Jan

AU - Hachem, Ramsey

AU - Kreisel, Daniel

AU - Levine, Deborah

AU - Kubisa, Bartosz

AU - Piotrowska, Maria

AU - Juvet, Stephen

AU - Keshavjee, Shaf

AU - Jaksch, Peter

AU - Klepetko, Walter

AU - Halloran, Philip F.

N1 - Funding Information: This research has been supported by grants from Genome Canada, Canada Foundation for Innovation, the University of Alberta Hospital Foundation, the Alberta Ministry of Advanced Education and Technology, the Mendez National Institute of Transplantation Foundation, and Industrial Research Assistance Program. Partial support was also provided by funding from a licensing agreement with the One Lambda Inc. division of Thermo Fisher Scientific. Dr. Halloran held a Canada Research Chair in Transplant Immunology until 2008 and currently holds the Muttart Chair in Clinical Immunology. Funding Information: Disclosure statement P F Halloran holds shares in Transcriptome Sciences Inc (TSI), a University of Alberta research company dedicated to developing molecular diagnostics, supported in part by a licensing agreement between TSI and Thermo Fisher Scientific, and by a research grant from Natera Inc.. P F Halloran is a consultant to Natera Inc.. The other authors have declared no conflict of interest exists. Publisher Copyright: © 2022 International Society for Heart and Lung Transplantation

PY - 2022/12

Y1 - 2022/12

N2 - Background: Many lung transplants fail due to chronic lung allograft dysfunction (CLAD). We recently showed that transbronchial biopsies (TBBs) from CLAD patients manifest severe parenchymal injury and dedifferentiation, distinct from time-dependent changes. The present study explored time-selective and CLAD-selective transcripts in mucosal biopsies from the third bronchial bifurcation (3BMBs), compared to those in TBBs. Methods: We used genome-wide microarray measurements in 324 3BMBs to identify CLAD-selective changes as well as time-dependent changes and develop a CLAD classifier. CLAD-selective transcripts were identified with linear models for microarray data (limma) and were used to build an ensemble of 12 classifiers to predict CLAD. Hazard models and random forests were then used to predict the risk of graft loss using the CLAD classifier, transcript sets associated with rejection, injury, and time. Results: T cell-mediated rejection and donor-specific antibody were increased in CLAD 3BMBs but most had no rejection. Like TBBs, 3BMBs showed a time-dependent increase in transcripts expressed in inflammatory cells that was not associated with CLAD or survival. Also like TBBs, the CLAD-selective transcripts in 3BMBs reflected severe parenchymal injury and dedifferentiation, not inflammation or rejection. While 3BMBs and TBBs did not overlap in their top 20 CLAD-selective transcripts, many CLAD-selective transcripts were significantly increased in both for example LOXL1, an enzyme controlling matrix remodeling. In Cox models for one-year survival, the 3BMB CLAD-selective transcripts and CLAD classifier predicted graft loss and correlated with CLAD stage. Many 3BMB CLAD-selective transcripts were also increased by injury in kidney transplants and correlated with decreased kidney survival, including LOXL1. Conclusions: Mucosal and transbronchial biopsies from CLAD patients reveal a diffuse molecular injury and dedifferentiation state that impacts prognosis and correlates with the physiologic disturbances. CLAD state in lung transplants shares features with failing kidney transplants, indicating elements shared by the injury responses of distressed organs.

AB - Background: Many lung transplants fail due to chronic lung allograft dysfunction (CLAD). We recently showed that transbronchial biopsies (TBBs) from CLAD patients manifest severe parenchymal injury and dedifferentiation, distinct from time-dependent changes. The present study explored time-selective and CLAD-selective transcripts in mucosal biopsies from the third bronchial bifurcation (3BMBs), compared to those in TBBs. Methods: We used genome-wide microarray measurements in 324 3BMBs to identify CLAD-selective changes as well as time-dependent changes and develop a CLAD classifier. CLAD-selective transcripts were identified with linear models for microarray data (limma) and were used to build an ensemble of 12 classifiers to predict CLAD. Hazard models and random forests were then used to predict the risk of graft loss using the CLAD classifier, transcript sets associated with rejection, injury, and time. Results: T cell-mediated rejection and donor-specific antibody were increased in CLAD 3BMBs but most had no rejection. Like TBBs, 3BMBs showed a time-dependent increase in transcripts expressed in inflammatory cells that was not associated with CLAD or survival. Also like TBBs, the CLAD-selective transcripts in 3BMBs reflected severe parenchymal injury and dedifferentiation, not inflammation or rejection. While 3BMBs and TBBs did not overlap in their top 20 CLAD-selective transcripts, many CLAD-selective transcripts were significantly increased in both for example LOXL1, an enzyme controlling matrix remodeling. In Cox models for one-year survival, the 3BMB CLAD-selective transcripts and CLAD classifier predicted graft loss and correlated with CLAD stage. Many 3BMB CLAD-selective transcripts were also increased by injury in kidney transplants and correlated with decreased kidney survival, including LOXL1. Conclusions: Mucosal and transbronchial biopsies from CLAD patients reveal a diffuse molecular injury and dedifferentiation state that impacts prognosis and correlates with the physiologic disturbances. CLAD state in lung transplants shares features with failing kidney transplants, indicating elements shared by the injury responses of distressed organs.

KW - airway

KW - chronic lung allograft dysfunction

KW - gene expression

KW - injury

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The molecular features of chronic lung allograft dysfunction in lung transplant airway mucosa

Abstract

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