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Extracellular Matrix Analysis of Human Renal Arteries in Both Quiescent and Active Vascular State

In vascular tissue engineering strategies, the addition of vascular-specific extracellular matrix (ECM) components may better mimic the in vivo microenvironment and potentially enhance cell–matrix interactions and subsequent tissue growth. For this purpose, the exact composition of the human vascula...

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Autores principales: van Dijk, Christian G.M., Louzao-Martinez, Laura, van Mulligen, Elise, Boermans, Bart, Demmers, Jeroen A.A., van den Bosch, Thierry P.P., Goumans, Marie-José, Duncker, Dirk J., Verhaar, Marianne C., Cheng, Caroline
Formato: Online Artículo Texto
Lenguaje:English
Publicado: MDPI 2020
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7313045/
https://www.ncbi.nlm.nih.gov/pubmed/32486169
http://dx.doi.org/10.3390/ijms21113905
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author van Dijk, Christian G.M.
Louzao-Martinez, Laura
van Mulligen, Elise
Boermans, Bart
Demmers, Jeroen A.A.
van den Bosch, Thierry P.P.
Goumans, Marie-José
Duncker, Dirk J.
Verhaar, Marianne C.
Cheng, Caroline
author_facet van Dijk, Christian G.M.
Louzao-Martinez, Laura
van Mulligen, Elise
Boermans, Bart
Demmers, Jeroen A.A.
van den Bosch, Thierry P.P.
Goumans, Marie-José
Duncker, Dirk J.
Verhaar, Marianne C.
Cheng, Caroline
author_sort van Dijk, Christian G.M.
collection PubMed
description In vascular tissue engineering strategies, the addition of vascular-specific extracellular matrix (ECM) components may better mimic the in vivo microenvironment and potentially enhance cell–matrix interactions and subsequent tissue growth. For this purpose, the exact composition of the human vascular ECM first needs to be fully characterized. Most research has focused on characterizing ECM components in mature vascular tissue; however, the developing fetal ECM matches the active environment required in vascular tissue engineering more closely. Consequently, we characterized the ECM protein composition of active (fetal) and quiescent (mature) renal arteries using a proteome analysis of decellularized tissue. The obtained human fetal renal artery ECM proteome dataset contains higher levels of 15 ECM proteins versus the mature renal artery ECM proteome, whereas 16 ECM proteins showed higher levels in the mature tissue compared to fetal. Elastic ECM proteins EMILIN1 and FBN1 are significantly enriched in fetal renal arteries and are mainly produced by cells of mesenchymal origin. We functionally tested the role of EMILIN1 and FBN1 by anchoring the ECM secreted by vascular smooth muscle cells (SMCs) to glass coverslips. This ECM layer was depleted from either EMILIN1 or FBN1 by using siRNA targeting of the SMCs. Cultured endothelial cells (ECs) on this modified ECM layer showed alterations on the transcriptome level of multiple pathways, especially the Rho GTPase controlled pathways. However, no significant alterations in adhesion, migration or proliferation were observed when ECs were cultured on EMILIN1- or FNB1-deficient ECM. To conclude, the proteome analysis identified unique ECM proteins involved in the embryonic development of renal arteries. Alterations in transcriptome levels of ECs cultured on EMILIN1- or FBN1-deficient ECM showed that these candidate proteins could affect the endothelial (regenerative) response.
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spelling pubmed-73130452020-06-29 Extracellular Matrix Analysis of Human Renal Arteries in Both Quiescent and Active Vascular State van Dijk, Christian G.M. Louzao-Martinez, Laura van Mulligen, Elise Boermans, Bart Demmers, Jeroen A.A. van den Bosch, Thierry P.P. Goumans, Marie-José Duncker, Dirk J. Verhaar, Marianne C. Cheng, Caroline Int J Mol Sci Article In vascular tissue engineering strategies, the addition of vascular-specific extracellular matrix (ECM) components may better mimic the in vivo microenvironment and potentially enhance cell–matrix interactions and subsequent tissue growth. For this purpose, the exact composition of the human vascular ECM first needs to be fully characterized. Most research has focused on characterizing ECM components in mature vascular tissue; however, the developing fetal ECM matches the active environment required in vascular tissue engineering more closely. Consequently, we characterized the ECM protein composition of active (fetal) and quiescent (mature) renal arteries using a proteome analysis of decellularized tissue. The obtained human fetal renal artery ECM proteome dataset contains higher levels of 15 ECM proteins versus the mature renal artery ECM proteome, whereas 16 ECM proteins showed higher levels in the mature tissue compared to fetal. Elastic ECM proteins EMILIN1 and FBN1 are significantly enriched in fetal renal arteries and are mainly produced by cells of mesenchymal origin. We functionally tested the role of EMILIN1 and FBN1 by anchoring the ECM secreted by vascular smooth muscle cells (SMCs) to glass coverslips. This ECM layer was depleted from either EMILIN1 or FBN1 by using siRNA targeting of the SMCs. Cultured endothelial cells (ECs) on this modified ECM layer showed alterations on the transcriptome level of multiple pathways, especially the Rho GTPase controlled pathways. However, no significant alterations in adhesion, migration or proliferation were observed when ECs were cultured on EMILIN1- or FNB1-deficient ECM. To conclude, the proteome analysis identified unique ECM proteins involved in the embryonic development of renal arteries. Alterations in transcriptome levels of ECs cultured on EMILIN1- or FBN1-deficient ECM showed that these candidate proteins could affect the endothelial (regenerative) response. MDPI 2020-05-30 /pmc/articles/PMC7313045/ /pubmed/32486169 http://dx.doi.org/10.3390/ijms21113905 Text en © 2020 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (http://creativecommons.org/licenses/by/4.0/).
spellingShingle Article
van Dijk, Christian G.M.
Louzao-Martinez, Laura
van Mulligen, Elise
Boermans, Bart
Demmers, Jeroen A.A.
van den Bosch, Thierry P.P.
Goumans, Marie-José
Duncker, Dirk J.
Verhaar, Marianne C.
Cheng, Caroline
Extracellular Matrix Analysis of Human Renal Arteries in Both Quiescent and Active Vascular State
title Extracellular Matrix Analysis of Human Renal Arteries in Both Quiescent and Active Vascular State
title_full Extracellular Matrix Analysis of Human Renal Arteries in Both Quiescent and Active Vascular State
title_fullStr Extracellular Matrix Analysis of Human Renal Arteries in Both Quiescent and Active Vascular State
title_full_unstemmed Extracellular Matrix Analysis of Human Renal Arteries in Both Quiescent and Active Vascular State
title_short Extracellular Matrix Analysis of Human Renal Arteries in Both Quiescent and Active Vascular State
title_sort extracellular matrix analysis of human renal arteries in both quiescent and active vascular state
topic Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7313045/
https://www.ncbi.nlm.nih.gov/pubmed/32486169
http://dx.doi.org/10.3390/ijms21113905
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