Project description:Mesenchymal stromal cells (MSCs) are of high relevance for the regeneration of mesenchymal tissues such as bone and cartilage. The promising role of MSCs in cell-based therapies and tissue engineering appears to be limited due to a decline of their regenerative potential with increasing donor age, their limited availability in human tissues and the need of in vitro expansion prior to treatment. We therefore aimed to determine to which degree in vitro aging and chronological aging may be similar processes or if in vitro culture-related changes at the cellular and molecular level are at least altered as a function of donor age. For that purpose we established MSCs cultures from young (yMSCs) and aged (aMSCs) rats that were cultured for more than 100 passages. These long-term MSCs cultures were non-tumorigenic and exhibited similar surface marker patterns as primary MSCs of passage 2. During in vitro expansion, but not during chronological aging, MSCs progressively lose their progenitor characteristics, e.g., complete loss of osteogenic differentiation potential, diminished adipogenic differentiation, altered cell morphology and increased susceptibility towards senescence. Transcriptome analysis revealed that long-term in vitro MSCs cultivation leads to down-regulation of genes involved in cell differentiation, focal adhesion organization, cytoskeleton turnover and mitochondria function. Accordingly, functional analysis demonstrated altered mitochondrial morphology, decreased antioxidant capacities and elevated ROS levels in long-term cultivated yMSCs as well as aMSCs. Notably, only the MSC migration potential and their antioxidative capacity were altered by in vitro as well as chronological aging. Based on specific differences observed between the impact of chronological and in vitro MSC aging we conclude that both are distinct processes. Total mRNA obtained from MSCs from 12 month and three week old Sprague Dawley rats of passage 2, 30 and 100. Total RNA was isolated using Trizol® (Invitrogen) reagent as describes previously and purified using Qiagen RNeasy® mini kit (Qiagen, Germany, www.qiagen.com) according to manufacturers instruction. Illumina® BeadChip hybridization: Biotinylated cRNA was produced from 500ng total RNA using llumina® TotalPrep™ RNA amplification kit (Invitrogen). Illumina® RatRef-12 Expression BeadChips hybridization, washing, Cy3 streptavidin staining, and scanning were performed using Illumina® BeadStation 500 platform.

Project description:To explore the biological diiference following MSC proliferation, we isolated MSCs from three umbilical cord tissues obtained from three donors, hereinafter referred to C56, C59 and C60. MSCs from each donor were then cultured and harvested at passage 2, 6 and 10 respectively (hereinafter referred to P2, P6 and P10). We next conducted global transcriptomics studies.

Project description:Mesenchymal stromal cells (MSCs) are of high relevance for the regeneration of mesenchymal tissues such as bone and cartilage. The promising role of MSCs in cell-based therapies and tissue engineering appears to be limited due to a decline of their regenerative potential with increasing donor age, their limited availability in human tissues and the need of in vitro expansion prior to treatment. We therefore aimed to determine to which degree in vitro aging and chronological aging may be similar processes or if in vitro culture-related changes at the cellular and molecular level are at least altered as a function of donor age. For that purpose we established MSCs cultures from young (yMSCs) and aged (aMSCs) rats that were cultured for more than 100 passages. These long-term MSCs cultures were non-tumorigenic and exhibited similar surface marker patterns as primary MSCs of passage 2. During in vitro expansion, but not during chronological aging, MSCs progressively lose their progenitor characteristics, e.g., complete loss of osteogenic differentiation potential, diminished adipogenic differentiation, altered cell morphology and increased susceptibility towards senescence. Transcriptome analysis revealed that long-term in vitro MSCs cultivation leads to down-regulation of genes involved in cell differentiation, focal adhesion organization, cytoskeleton turnover and mitochondria function. Accordingly, functional analysis demonstrated altered mitochondrial morphology, decreased antioxidant capacities and elevated ROS levels in long-term cultivated yMSCs as well as aMSCs. Notably, only the MSC migration potential and their antioxidative capacity were altered by in vitro as well as chronological aging. Based on specific differences observed between the impact of chronological and in vitro MSC aging we conclude that both are distinct processes.

Project description:Gene Markers of Cellular Aging in Human Multipotent Stromal Cells in Culture Identifying gene markers of cellular aging as determined by cellular passaging of human multipotent stromal cells (MSCs) derived from bone marrow Repeated Measures Experiment; MSC from 6 different donors at 3 passages (passages 3, 5, & 7) with 3 technical replicates at each passage; a total of 54 microarrays

Project description:The properties of MSCs can be affected by long term culture, therefore casting doubt over the ability of late passage MSCs to accurately recapitulate their biology. Additionally, assumption within the scientific community is often made that early passage MSCs are still representative of the primary MSC population, however, little research has been done to support this. We compared the transcriptomic profiles of murine MSCs freshly isolated from the long bones to MSCs that had been expanded in culture for 10 days. Interestingly, we identified that a single passage in culture induced extensive alterations to MSC molecular signatures associated with cell cycling, differentiation and immune response.

Project description:To determine gene expression changes during in vitro senescence of MSC we have analyzed differential expression of the corresponding early passage (P2) and senescent passage (PX). There were global changes in the gene expression profile that were reproducible in three independent donor samples. Experiment Overall Design: Mesenchymal Stem Cells (MSC) were isolated from human bone marrow (BM) as described before (Wagner et al., 2005, Exp Hematol, 33, 1402-1416; Wagner et al., Exp Hematol, 34, 536-548). Cells were always replated when grown to confluency. A sample for RNA isolation was taken at every passage until the cells finally became senescent: they became much larger with irregular and flat shape. The nucleus became more circumscribed in phase contrast microscopy. The cytoplasm began to be granular with many inclusions and there was more cell debris. Global gene expression profiles were analyzed to determine molecular changes between corresponding early passage (P2) and senescent passage (PX) in three donor samples. In addition we have analyzed different passages of donor 1 (P2, P3, P4, P5, P6, P7, P8, P10, and P11) to determine changes in the course of cellular aging. Data were median normalized and compared to P2 of the corresponding donor sample.

Project description:Multipotent stromal cells (MSCs) are known for their distinctive ability to differentiate into different cell lineages such as adipocytes, chondrocytes and osteocytes. They can be isolated from numerous tissue sources including bone marrow, adipose tissue, skeletal muscle and others. Because of their differentiation potential and their secretion of growth factors, MSCs are believed to have an inherent quality of regeneration and immune suppression, which are considered advantageous in treating multiple disorders such as graft-versus-host disease. Since the number of MSCs derived from a tissue source is low, cellular expansion is necessary to obtain sufficient numbers for a desired cell therapy. However, after several rounds of passaging, our previous results have shown that MSCs exhibit reduced capacity for proliferation and differentiation. In this study, gene markers of MSC proliferation were identified and evaluated for their ability to predict the cell population proliferative quality. Microarray data of human bone marrow-derived MSCs were correlated with two proliferation assays. A collection of 24 genes were observed to significantly correlate with both proliferation assays (|r| > 0.70) for 8 MSC donors at multiple passages. These 24 identified genes were then confirmed using an additional set of MSCs from 8 new donors using RT-qPCR. The proliferative potential of the second set of MSCs was measured for each donor/passage by three proliferation assays for confluency fraction, fraction of EdU+ cells and population doubling time. The second set of MSCs exhibited a greater proliferative potential at passage 4 in comparison to passage 8, which was distinguishable by 15 genes; however, only 7 of the genes (BIRC5, CCNA2, CDC20, CDK1, PBK, PLK1, SPC25) demonstrated significant correlation (FDR: q < 0.05 and |r| > 0.62) with MSC proliferation regardless of passage. These 7 genes and the proliferative capacity of different non-MSC cell lines were assessed for comparison. Our analyses revealed that correlation between gene expression and proliferation was consistently reduced with the introduction of non-MSC cell lines; therefore this set of 7 genes may be more strongly associated with MSC proliferative quality. These correlative methods may be further used to identify additional markers that exhibit strong correlation with a particular MSC quality such as differentiation or immune suppression potential. Our results pave the way toward the identification of specific gene markers that could rapidly determine the quality of an MSC population for a particular cellular therapy in lieu of an extended in vitro or in vivo assay.

Project description:Multipotent stromal cells (MSCs) are known for their distinctive ability to differentiate into different cell lineages such as adipocytes, chondrocytes and osteocytes. They can be isolated from numerous tissue sources including bone marrow, adipose tissue, skeletal muscle and others. Because of their differentiation potential and their secretion of growth factors, MSCs are believed to have an inherent quality of regeneration and immune suppression, which are considered advantageous in treating multiple disorders such as graft-versus-host disease. Since the number of MSCs derived from a tissue source is low, cellular expansion is necessary to obtain sufficient numbers for a desired cell therapy. However, after several rounds of passaging, our previous results have shown that MSCs exhibit reduced capacity for proliferation and differentiation. In this study, gene markers of MSC proliferation were identified and evaluated for their ability to predict the cell population proliferative quality. Microarray data of human bone marrow-derived MSCs were correlated with two proliferation assays. A collection of 24 genes were observed to significantly correlate with both proliferation assays (|r| > 0.70) for 8 MSC donors at multiple passages. These 24 identified genes were then confirmed using an additional set of MSCs from 8 new donors using RT-qPCR. The proliferative potential of the second set of MSCs was measured for each donor/passage by three proliferation assays for confluency fraction, fraction of EdU+ cells and population doubling time. The second set of MSCs exhibited a greater proliferative potential at passage 4 in comparison to passage 8, which was distinguishable by 15 genes; however, only 7 of the genes (BIRC5, CCNA2, CDC20, CDK1, PBK, PLK1, SPC25) demonstrated significant correlation (FDR: q < 0.05 and |r| > 0.62) with MSC proliferation regardless of passage. These 7 genes and the proliferative capacity of different non-MSC cell lines were assessed for comparison. Our analyses revealed that correlation between gene expression and proliferation was consistently reduced with the introduction of non-MSC cell lines; therefore this set of 7 genes may be more strongly associated with MSC proliferative quality. These correlative methods may be further used to identify additional markers that exhibit strong correlation with a particular MSC quality such as differentiation or immune suppression potential. Our results pave the way toward the identification of specific gene markers that could rapidly determine the quality of an MSC population for a particular cellular therapy in lieu of an extended in vitro or in vivo assay. Microarray gene expression analysis with confirmation of genes by RT-qPCR

Project description:Intro: Donor age has been widely demonstrated to affect the characteristic of multipotent mesenchymal stem cells derived from bone marrow (BM-MSCs). The cellular features including decrease in cell proliferation, differentiation capacity and telomere length as well as increase of senescence may reduce the yield and clinical application for cell therapy. Methods: Expansion of BM-MSCs from young and aged donors under prolonged passage (P15) and hypoxic (5% O2) platforms was performed and the biological, cellular and miRNA profiles were assessed using Next Generation Sequencing. Results: miRNA sequencing revealed differential expression of hypoxia-inducible miRNAs when young donor MSC was cultured under hypoxia.Here, we demonstrate for the first time the link between age, hypoxia and microRNA expression and conclude that MSC isolated from both young and aged donors have a greater expansion potential when cultured under hypoxic condition.

Project description:Human mesenchymal stem cells or multipotent stromal cells (MSCs) are of interest for clinical therapy, in part because of their capacity for proliferation and differentiation. However, results from clinical trials and in vitro models have been variable, possibly due to MSC heterogeneity and a lack of standardization between MSC in vitro expansion protocols. Here we defined changes in MSCs during expansion in vitro. In low density cultures, MSCs expand through distinct lag, exponential growth and stationary phases. We assayed cultures of passage 2 human MSCs from three donors at low density (50 cells/cm2) at about 5% confluence on Day 2 and after the cultures had expanded to about 70% confluence on Day 7. On Day 2 genes involved in cell division were up-regulated. On Day 7 genes for cell development were up-regulated. The variations between three donors were less than the variation within the expansion of MSCs from a single donor. The microarray data for selected genes were confirmed by real-time PCR, ELISA and FACScan. About 50% of cells at Day 2 were in S-phase compared to 10% at Day 7. The results demonstrated major differences in early and late stage cultures of MSCs that should be considered in using the cells in experiments and clinical applications. Experiment Overall Design: We assayed cultures of passage 2 human MSCs from three donors at low density (50 cells/cm2) at about 5% confluence on Day 2 and after the cultures had expanded to about 70% confluence on Day 7.