Τρίτη 1 Αυγούστου 2017

Transcriptome-Wide Analyses of Human Neonatal Articular Cartilage and Human Mesenchymal Stem Cell-Derived Cartilage Provide a New Molecular Target for Evaluating Engineered Cartilage

Transcriptome-Wide Analyses of Human Neonatal Articular Cartilage and Human Mesenchymal Stem Cell-Derived Cartilage Provide a New Molecular Target for Evaluating Engineered Cartilage:

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Tissue Engineering Part A , Vol. 0, No. 0.



Tissue Engineering Part A

Transcriptome-Wide Analyses of Human Neonatal Articular Cartilage and Human Mesenchymal Stem Cell-Derived Cartilage Provide a New Molecular Target for Evaluating Engineered Cartilage

To cite this article:
Somoza Rodrigo A., Correa Diego, Labat Ivan, Sternberg Hal, Forrest Megan E., Khalil Ahmad M., West Michael D., Tesar Paul, and Caplan Arnold I.. Tissue Engineering Part A. July 2017, ahead of print.http://ift.tt/2tZm85k
Online Ahead of Print: July 28, 2017
Online Ahead of Editing: June 10, 2017

Author information

Rodrigo A. SomozaPhD,1,2 Diego CorreaMD, MSc, PhD,1,3 Ivan LabatPhD,4 Hal SternbergPhD,4 Megan E. ForrestBS,5 Ahmad M. KhalilPhD,2,5 Michael D. WestPhD,4 Paul TesarPhD,5 and Arnold I. CaplanPhD1,2
1Department of Biology, Skeletal Research Center, Case Western Reserve University, Cleveland, Ohio.
2CWRU Center for Multimodal Evaluation of Engineered Cartilage, Cleveland, Ohio.
3Division of Sports Medicine, Department of Orthopaedics, Diabetes Research Institute and Cell Transplant Center, University of Miami, Miller School of Medicine, Miami, Florida.
4BioTime, Inc., Alameda, California.
5Department of Genetics and Genome Sciences, School of Medicine, Case Western Reserve University, Cleveland, Ohio.
Address correspondence to:
Rodrigo A. Somoza, PhD
Department of Biology
Skeletal Research Center
Case Western Reserve University
2080 Adelbert Road
Millis Science Center, Room 114A
Cleveland, OH 44106
E-mail: 
Received: December 28, 2016
Accepted: May 12, 2017

ABSTRACT

Cellular differentiation comprises a progressive, multistep program that drives cells to fabricate a tissue with specific and site distinctive structural and functional properties. Cartilage constitutes one of the potential differentiation lineages that mesenchymal stem cells (MSCs) can follow under the guidance of specific bioactive agents. Single agents such as transforming growth factor beta (TGF-β) and bone morphogenetic protein 2 in unchanging culture conditions have been historically used to induce in vitro chondrogenic differentiation of MSCs. Despite the expression of traditional chondrogenic biomarkers such as type II collagen and aggrecan, the resulting tissue represents a transient cartilage rather than an in vivo articular cartilage (AC), differing significantly in structure, chemical composition, cellular phenotypes, and mechanical properties. Moreover, there have been no comprehensive, multicomponent parameters to define high-quality and functional engineered hyaline AC. To address these issues, we have taken an innovative approach based on the molecular interrogation of human neonatal articular cartilage (hNAC), dissected from the knees of 1-month-old cadaveric specimens. Subsequently, we compared hNAC-specific transcriptional regulatory elements and differentially expressed genes with adult human bone marrow (hBM) MSC-derived three-dimensional cartilage structures formed in vitro. Using microarray analysis, the transcriptome of hNAC was found to be globally distinct from the transient, cartilage-like tissue formed by hBM-MSCs in vitro. Specifically, over 500 genes that are highly expressed in hNAC were not expressed at any time point during in vitro human MSC chondrogenesis. The analysis also showed that the differences were less variant during the initial stages (first 7 days) of the in vitro chondrogenic differentiation program. These observations suggest that the endochondral fate of hBM-MSC-derived cartilage may be rerouted at earlier stages of the TGF-β-stimulated chondrogenic differentiation program. Based on these analyses, several key molecular differences (transcription factors and coded cartilage-related proteins) were identified in hNAC that will be useful as molecular inductors and identifiers of the in vivo AC phenotype. Our findings provide a new gold standard of a molecularly defined AC phenotype that will serve as a platform to generate novel approaches for AC tissue engineering.
 

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