Fibroblast-derived osteoglycin promotes epithelial cell repair

Luke van der Koog; Manon Woest; Iris Gorter; Vicky Verschut; Robin Elferink; Annet Zuidhof; Maunick Lefin Koloko Ngassie; I. Sophie T. Bos; Deepesh Dhakad; Justina Clarinda Wolters; Peter Horvatovich; Y S Prakash; Wim Timens; Ali Onder Yildirim; Corry-Anke Brandsma; H.W. Frijlink; Anika Nagelkerke; Reinoud Gosens

Fibroblast-derived osteoglycin promotes epithelial cell repair

Luke van der Koog, Manon Woest, Iris Gorter, Vicky Verschut, Robin Elferink, Annet Zuidhof, Maunick Lefin Koloko Ngassie, I. Sophie T. Bos, Deepesh Dhakad, Justina Clarinda Wolters, Peter Horvatovich, Y S Prakash, Wim Timens, Ali Onder Yildirim, Corry-Anke Brandsma, H.W. Frijlink, Anika Nagelkerke, Reinoud Gosens^*

^*Corresponding author for this work

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

Abstract

There is an urgent need for innovative therapies targeting defective epithelial repair in chronic diseases like COPD. The mesenchymal niche is a critical regulator in epithelial stem cell activation, suggesting that their secreted factors are possible potent drug targets. Utilizing a proteomics-guided drug discovery strategy, we explored the lung fibroblast secretome to uncover impactful drug targets. Our lung organoid assays identified several regenerative ligands, with osteoglycin (OGN) showing the most profound effects. Transcriptomic analyses revealed that OGN enhances alveolar progenitor differentiation, detoxifies reactive oxygen species, and strengthens fibroblast-epithelial crosstalk. OGN expression was diminished in COPD patients and smoke-exposed mice. An active fragment of OGN (leucine-rich repeat regions 4–7) replicated full-length OGN’s regenerative effects, significantly ameliorating elastase-induced lung injury in lung slices and improving lung function in vivo. These findings highlight OGN as a pivotal secreted protein for alveolar epithelial repair, positioning its active fragment as a promising therapeutic for COPD.

Original language	English
Journal	npj Regenerative Medicine
Volume	10
Issue number	16
Publication status	Accepted/In press - 25-Mar-2025

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van der Koog, L., Woest, M., Gorter, I., Verschut, V., Elferink, R., Zuidhof, A., Koloko Ngassie, M. L., Bos, I. S. T., Dhakad, D., Wolters, J. C., Horvatovich, P., Prakash, Y. S., Timens, W., Yildirim, A. O., Brandsma, C.-A., Frijlink, H. W., Nagelkerke, A., & Gosens, R. (Accepted/In press). Fibroblast-derived osteoglycin promotes epithelial cell repair. npj Regenerative Medicine, 10(16).

@article{309821d685ea4b2c833896b1caff0300,

title = "Fibroblast-derived osteoglycin promotes epithelial cell repair",

abstract = "There is an urgent need for innovative therapies targeting defective epithelial repair in chronic diseases like COPD. The mesenchymal niche is a critical regulator in epithelial stem cell activation, suggesting that their secreted factors are possible potent drug targets. Utilizing a proteomics-guided drug discovery strategy, we explored the lung fibroblast secretome to uncover impactful drug targets. Our lung organoid assays identified several regenerative ligands, with osteoglycin (OGN) showing the most profound effects. Transcriptomic analyses revealed that OGN enhances alveolar progenitor differentiation, detoxifies reactive oxygen species, and strengthens fibroblast-epithelial crosstalk. OGN expression was diminished in COPD patients and smoke-exposed mice. An active fragment of OGN (leucine-rich repeat regions 4–7) replicated full-length OGN{\textquoteright}s regenerative effects, significantly ameliorating elastase-induced lung injury in lung slices and improving lung function in vivo. These findings highlight OGN as a pivotal secreted protein for alveolar epithelial repair, positioning its active fragment as a promising therapeutic for COPD.",

author = "{van der Koog}, Luke and Manon Woest and Iris Gorter and Vicky Verschut and Robin Elferink and Annet Zuidhof and {Koloko Ngassie}, {Maunick Lefin} and Bos, {I. Sophie T.} and Deepesh Dhakad and Wolters, {Justina Clarinda} and Peter Horvatovich and Prakash, {Y S} and Wim Timens and Yildirim, {Ali Onder} and Corry-Anke Brandsma and H.W. Frijlink and Anika Nagelkerke and Reinoud Gosens",

year = "2025",

month = mar,

day = "25",

language = "English",

volume = "10",

journal = "npj Regenerative Medicine",

issn = "2057-3995",

publisher = "Nature Publishing Group",

number = "16",

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TY - JOUR

T1 - Fibroblast-derived osteoglycin promotes epithelial cell repair

AU - van der Koog, Luke

AU - Woest, Manon

AU - Gorter, Iris

AU - Verschut, Vicky

AU - Elferink, Robin

AU - Zuidhof, Annet

AU - Koloko Ngassie, Maunick Lefin

AU - Bos, I. Sophie T.

AU - Dhakad, Deepesh

AU - Wolters, Justina Clarinda

AU - Horvatovich, Peter

AU - Prakash, Y S

AU - Timens, Wim

AU - Yildirim, Ali Onder

AU - Brandsma, Corry-Anke

AU - Frijlink, H.W.

AU - Nagelkerke, Anika

AU - Gosens, Reinoud

PY - 2025/3/25

Y1 - 2025/3/25

N2 - There is an urgent need for innovative therapies targeting defective epithelial repair in chronic diseases like COPD. The mesenchymal niche is a critical regulator in epithelial stem cell activation, suggesting that their secreted factors are possible potent drug targets. Utilizing a proteomics-guided drug discovery strategy, we explored the lung fibroblast secretome to uncover impactful drug targets. Our lung organoid assays identified several regenerative ligands, with osteoglycin (OGN) showing the most profound effects. Transcriptomic analyses revealed that OGN enhances alveolar progenitor differentiation, detoxifies reactive oxygen species, and strengthens fibroblast-epithelial crosstalk. OGN expression was diminished in COPD patients and smoke-exposed mice. An active fragment of OGN (leucine-rich repeat regions 4–7) replicated full-length OGN’s regenerative effects, significantly ameliorating elastase-induced lung injury in lung slices and improving lung function in vivo. These findings highlight OGN as a pivotal secreted protein for alveolar epithelial repair, positioning its active fragment as a promising therapeutic for COPD.

AB - There is an urgent need for innovative therapies targeting defective epithelial repair in chronic diseases like COPD. The mesenchymal niche is a critical regulator in epithelial stem cell activation, suggesting that their secreted factors are possible potent drug targets. Utilizing a proteomics-guided drug discovery strategy, we explored the lung fibroblast secretome to uncover impactful drug targets. Our lung organoid assays identified several regenerative ligands, with osteoglycin (OGN) showing the most profound effects. Transcriptomic analyses revealed that OGN enhances alveolar progenitor differentiation, detoxifies reactive oxygen species, and strengthens fibroblast-epithelial crosstalk. OGN expression was diminished in COPD patients and smoke-exposed mice. An active fragment of OGN (leucine-rich repeat regions 4–7) replicated full-length OGN’s regenerative effects, significantly ameliorating elastase-induced lung injury in lung slices and improving lung function in vivo. These findings highlight OGN as a pivotal secreted protein for alveolar epithelial repair, positioning its active fragment as a promising therapeutic for COPD.

M3 - Article

SN - 2057-3995

VL - 10

JO - npj Regenerative Medicine

JF - npj Regenerative Medicine

IS - 16

ER -

Fibroblast-derived osteoglycin promotes epithelial cell repair

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