03115nas a2200493 4500008004100000022001400041245014400055210006900199260001500268490000700283520148700290653001201777653003601789653003001825653003101855653001801886653001101904653003601915653000901951653001501960653002401975653003401999653003302033653002402066653000902090653002502099653001502124653001702139653002302156653001802179653003402197653001802231100001802249700002902267700001702296700002402313700002102337700003102358700002002389700002102409700002602430700003402456856013102490 2020 eng d a2073-442500aTranscriptomic Analysis of a Diabetic Skin-Humanized Mouse Model Dissects Molecular Pathways Underlying the Delayed Wound Healing Response.0 aTranscriptomic Analysis of a Diabetic SkinHumanized Mouse Model c2020 12 310 v123 a
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.
10aAnimals10aDiabetes Mellitus, Experimental10aGene Expression Profiling10aGene Expression Regulation10aGene ontology10aHumans10aMetabolic Networks and Pathways10aMice10aMice, Nude10aMicroarray Analysis10aMolecular Sequence Annotation10aPrincipal Component Analysis10aSignal Transduction10aSkin10aSkin Transplantation10aSkin Ulcer10aStreptozocin10aTissue Engineering10aTranscriptome10aTransplantation, Heterologous10aWound Healing1 aLeón, Carlos1 aGarcia-Garcia, Francisco1 aLlames, Sara1 aGarcía-Pérez, Eva1 aCarretero, Marta1 aArriba, María, Del Carmen1 aDopazo, Joaquin1 aDel Rio, Marcela1 aEscamez, Maria, José1 aMartínez-Santamaría, Lucía uhttps://www.clinbioinfosspa.es/content/transcriptomic-analysis-diabetic-skin-humanized-mouse-model-dissects-molecular-pathways