Transcriptomic Analysis of a Diabetic Skin-Humanized Mouse Model Dissects Molecular Pathways Underlying the Delayed Wound Healing Response

Transcriptomic Analysis of a Diabetic Skin-Humanized Mouse Model Dissects Molecular Pathways Underlying the Delayed Wound Healing Response

Defective healing leading to cutaneous ulcer formation is one of the most feared complications of diabetes due to its consequences on patients’ quality of life and on the healthcare system. A more in-depth analysis of the underlying molecular pathophysiology is required to develop effective healing-...

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Main Authors: Carlos León, Francisco García-García, Sara Llames, Eva García-Pérez, Marta Carretero, María del Carmen Arriba, Joaquín Dopazo, Marcela del Río, María José Escámez, Lucía Martínez-Santamaría
Format: Article
Language:English
Published: MDPI AG 2021-12-01
Series:Genes
Subjects:
transcriptomics
wound healing
diabetes
skin-humanized mice
enrichment analysis
Online Access:https://www.mdpi.com/2073-4425/12/1/47
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spelling doaj-ee9fa49dfb4e49009e66fe4c95f1d7c32021-01-01T00:00:15ZengMDPI AGGenes2073-44252021-12-0112474710.3390/genes12010047Transcriptomic Analysis of a Diabetic Skin-Humanized Mouse Model Dissects Molecular Pathways Underlying the Delayed Wound Healing ResponseCarlos León0Francisco García-García1Sara Llames2Eva García-Pérez3Marta Carretero4María del Carmen Arriba5Joaquín Dopazo6Marcela del Río7María José Escámez8Lucía Martínez-Santamaría9Department of Bioengineering, Carlos III University, Av. de la Universidad, 30, Leganés, 28911 Madrid, SpainBioinformatics and Biostatistics Unit, Prince Felipe Research Center (CIPF), C/Eduardo Primo Yúfera, 3, 46012 Valencia, SpainNetwork Research on Rare Diseases (CIBERER), U714, C/Melchor Fernández Almagro, 3, 28029 Madrid, SpainTissue Engineering Unit, Blood and Tissue Community Center of Asturias (CCST), C/Emilio Rodríguez Vigil s/n, 33006 Oviedo, SpainNetwork Research on Rare Diseases (CIBERER), U714, C/Melchor Fernández Almagro, 3, 28029 Madrid, SpainDepartment of Bioengineering, Carlos III University, Av. de la Universidad, 30, Leganés, 28911 Madrid, SpainClinical Bioinformatics Research Area, Progress and Health Foundation (FPS), CDCA, Hospital Virgen del Rocío, Av. Manuel Siurot s/n, 41013 Sevilla, SpainDepartment of Bioengineering, Carlos III University, Av. de la Universidad, 30, Leganés, 28911 Madrid, SpainDepartment of Bioengineering, Carlos III University, Av. de la Universidad, 30, Leganés, 28911 Madrid, SpainDepartment of Bioengineering, Carlos III University, Av. de la Universidad, 30, Leganés, 28911 Madrid, SpainDefective healing leading to cutaneous ulcer formation is one of the most feared complications of diabetes due to its consequences on patients’ quality of life and on the healthcare system. A more in-depth analysis of the underlying molecular pathophysiology is required to develop effective healing-promoting therapies for those patients. Major architectural and functional differences with human epidermis limit extrapolation of results coming from rodents and other small mammal-healing models. Therefore, the search for reliable humanized models has become mandatory. Previously, we developed a diabetes-induced delayed humanized wound healing model that faithfully recapitulated the major histological features of such skin repair-deficient condition. Herein, we present the results of a transcriptomic and functional enrichment analysis followed by a mechanistic analysis performed in such humanized wound healing model. The deregulation of genes implicated in functions such as angiogenesis, apoptosis, and inflammatory signaling processes were evidenced, confirming published data in diabetic patients that in fact might also underlie some of the histological features previously reported in the delayed skin-humanized healing model. Altogether, these molecular findings support the utility of such preclinical model as a valuable tool to gain insight into the molecular basis of the delayed diabetic healing with potential impact in the translational medicine field.https://www.mdpi.com/2073-4425/12/1/47transcriptomicswound healingdiabetesskin-humanized miceenrichment analysis
collection DOAJ
language English
format Article
sources DOAJ
author Carlos León
Francisco García-García
Sara Llames
Eva García-Pérez
Marta Carretero
María del Carmen Arriba
Joaquín Dopazo
Marcela del Río
María José Escámez
Lucía Martínez-Santamaría
spellingShingle Carlos León
Francisco García-García
Sara Llames
Eva García-Pérez
Marta Carretero
María del Carmen Arriba
Joaquín Dopazo
Marcela del Río
María José Escámez
Lucía Martínez-Santamaría
Transcriptomic Analysis of a Diabetic Skin-Humanized Mouse Model Dissects Molecular Pathways Underlying the Delayed Wound Healing Response
Genes
transcriptomics
wound healing
diabetes
skin-humanized mice
enrichment analysis
author_facet Carlos León
Francisco García-García
Sara Llames
Eva García-Pérez
Marta Carretero
María del Carmen Arriba
Joaquín Dopazo
Marcela del Río
María José Escámez
Lucía Martínez-Santamaría
author_sort Carlos León
title Transcriptomic Analysis of a Diabetic Skin-Humanized Mouse Model Dissects Molecular Pathways Underlying the Delayed Wound Healing Response
title_short Transcriptomic Analysis of a Diabetic Skin-Humanized Mouse Model Dissects Molecular Pathways Underlying the Delayed Wound Healing Response
title_full Transcriptomic Analysis of a Diabetic Skin-Humanized Mouse Model Dissects Molecular Pathways Underlying the Delayed Wound Healing Response
title_fullStr Transcriptomic Analysis of a Diabetic Skin-Humanized Mouse Model Dissects Molecular Pathways Underlying the Delayed Wound Healing Response
title_full_unstemmed Transcriptomic Analysis of a Diabetic Skin-Humanized Mouse Model Dissects Molecular Pathways Underlying the Delayed Wound Healing Response
title_sort transcriptomic analysis of a diabetic skin-humanized mouse model dissects molecular pathways underlying the delayed wound healing response
publisher MDPI AG
series Genes
issn 2073-4425
publishDate 2021-12-01
description Defective healing leading to cutaneous ulcer formation is one of the most feared complications of diabetes due to its consequences on patients’ quality of life and on the healthcare system. A more in-depth analysis of the underlying molecular pathophysiology is required to develop effective healing-promoting therapies for those patients. Major architectural and functional differences with human epidermis limit extrapolation of results coming from rodents and other small mammal-healing models. Therefore, the search for reliable humanized models has become mandatory. Previously, we developed a diabetes-induced delayed humanized wound healing model that faithfully recapitulated the major histological features of such skin repair-deficient condition. Herein, we present the results of a transcriptomic and functional enrichment analysis followed by a mechanistic analysis performed in such humanized wound healing model. The deregulation of genes implicated in functions such as angiogenesis, apoptosis, and inflammatory signaling processes were evidenced, confirming published data in diabetic patients that in fact might also underlie some of the histological features previously reported in the delayed skin-humanized healing model. Altogether, these molecular findings support the utility of such preclinical model as a valuable tool to gain insight into the molecular basis of the delayed diabetic healing with potential impact in the translational medicine field.
topic transcriptomics
wound healing
diabetes
skin-humanized mice
enrichment analysis
url https://www.mdpi.com/2073-4425/12/1/47
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