The microenvironment plays an important role in the homing in and differentiation of stem cells to repair injured tissue. Infrapatellar fat pad stromal cells (IFPSCs) are a promising source of such cells for the repair of articular injury-induced degeneration. This study investigated the chemotaxis of IFPSCs to chondrocytes and the effect of hyaluronan (HA) on the biological and regenerative properties of IFPSCs. The IFPSCs were obtained from patients undergoing arthroscopy and cultured via a standard 2-week culture protocol that yielded more than 10 million cells on passage 3. The results showed that the IFPSCs had a higher capacity for chondrogenic differentiation than mesenchymal cells from body fat, bone marrow, and Wharton's jelly of the umbilical cord. The IFPSCs cultured on 25% or 50% HA showed better osteogenic and adipogenic capabilities than those without HA or with 75% HA (p < 0.001). Cultures of the IFPSCs on 25% HA had a fourfold increase in chondrogenic differentiation compared to cultures without HA, which was better than with 50% and 75% HA (p < 0.05). Cell proliferation was not affected by the presence of HA. In conclusion, IFPSCs have a strong potential for chondrogenic regeneration, which can even be augmented in a 25% HA microenvironment.
Mesenchymal stem cells (MSCs) and especially those derived from fetal tissues exert a potent immunosuppressive effect that can be enhanced under inflammatory conditions. This study aimed to explore the immunosuppressive properties of human umbilical cord mesenchymal stem cells (HUCMSCs). We found that HLA-G, the nonclassical HLA allele with strong immune-inhibitory properties, was much more expressed on the HUCMSCs than on MSCs of other origins. Flow cytometry revealed that 90.8% of the HUCMSCs expressed HLA-G. RT-PCR revealed expression of HLA-G1, HLA-G5, and HLA-G7 in all of four HUCMSC lines. In a mixed lymphocyte reaction assay, the HUCMSCs inhibited the proliferation of lymphocytes by 35 ± 3% and could be reversed by treatment with an HLA-G blocking antibody. Upon coculture with the HUCMSCs, peripheral blood mononuclear cells expressed lower levels of proinflammatory mediators such as IL-6, TNF-a, and VEGF-a. This immunosuppressive effect was enhanced when the HUCMSCs were pretreated with IFN-g, such that the expression of HLA-G was highly activated and HLA-DR diminished. The same phenomenon was not observed in MSCs derived from bone marrow or the placenta. In a xenograft rejection assay, the HUCMSCs survived in immunocompetent mice, whereas primary fibroblasts did not survive. This study confirms the HLA-G-related immunosuppressive property of HUCMSCs, which is more potent than MSCs of other origin. A good tolerance of this mesenchymal stem cell in allogeneic transplantation can thus be anticipated.
BackgroundAlthough donor age-related effects of characteristics of mesenchymal stem cells (MSC), such as a decrease in the proliferation and differentiation capacity and an increase of senescence and apoptosis, are evident, such effects are generally less prominent in adipose-derived stem cells (ASC). Using a hormone and growth factor rich medium (KFSM), this study cultured ASC from abdominal subcutaneous fat of 27 adult females in three age groups: 30-39 y, 40-49 y and 50-60 y, and investigated the growth and differentiation characteristics.ResultsThe derived ASC had an immunophenotype similar to that of bone marrow derived MSC (BMSC). They could be stably expanded with an average population doubling time of 21.5 ± 2.3 h. Other than a higher pre-adipogenic commitment and a lower adipogenic differentiation capability in ASC derived from the old age group, other characteristics including proliferation rate, doubling time, telomere length, as well as the osteogenic and chondrogenic differentiation capacity were the same regardless of the donor’s age.ConclusionsThe study demonstrates a promising proliferation and differentiation capabilities of ASC regardless of the donor’s age. The compromised adipogenic potential in the older donors could be a benefit for their application in regeneration therapy.
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