Cosimo De Bari scite author profile

In many adult tissues, mesenchymal stem cells (MSCs) are closely associated with perivascular niches and coexpress many markers in common with pericytes. The ability of pericytes to act as MSCs, however, remains controversial. By using genetic lineage tracing, we show that some pericytes differentiate into specialized tooth mesenchyme-derived cells—odontoblasts—during tooth growth and in response to damage in vivo. As the pericyte-derived mesenchymal cell contribution to odontoblast differentiation does not account for all cell differentiation, we identify an additional source of cells with MSC-like properties that are stimulated to migrate toward areas of tissue damage and differentiate into odontoblasts. Thus, although pericytes are capable of acting as a source of MSCs and differentiating into cells of mesenchymal origin, they do so alongside other MSCs of a nonpericyte origin. This study identifies a dual origin of MSCs in a single tissue and suggests that the pericyte contribution to MSC-derived mesenchymal cells in any given tissue is variable and possibly dependent on the extent of the vascularity.

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Mesenchymal multipotency of adult human periosteal cells demonstrated by single‐cell lineage analysis

Bari¹,

Dell’Accio²,

Vanlauwe³

et al. 2006

Arthritis & Rheumatism

379

321

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Objective. To investigate whether periosteal cells from adult humans have features of multipotent mesenchymal stem cells (MSCs) at the single-cell level.Methods. Cell populations were enzymatically released from the periosteum of the proximal tibia obtained from adult human donors and then expanded in monolayer. Single-cell-derived clonal populations were obtained by limiting dilution. Culture-expanded periosteal cell populations were tested for their growth potential and for expression of conventional markers of MSCs and were subjected to in vitro assays to investigate their multilineage potential. To assess their multipotency in vivo, periosteal cells were injected into a regenerating mouse tibialis anterior muscle for skeletal myogenesis or were either seeded into an osteoinductive matrix and implanted subcutaneously into nude mice for osteogenesis or implanted in a joint surface defect under a periosteal flap into goats for chondrogenesis. Cell phenotypes were analyzed by histochemistry and immunohistochemistry and by reverse transcriptionpolymerase chain reaction for the expression of lineagerelated marker genes.Results. Regardless of donor age, periosteal cells were clonogenic and could be expanded extensively in monolayer, maintaining linear growth curves over at least 30 population doublings. They displayed long telomeres and expressed markers of MSCs. Under specific conditions, both parental and single-cellderived clonal cell populations differentiated to the chondrocyte, osteoblast, adipocyte, and skeletal myocyte lineages in vitro and in vivo.Conclusion. Our study demonstrates that, regardless of donor age, the adult human periosteum contains cells that, upon enzymatic release and culture expansion, are multipotent MSCs at the single-cell level.

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Skeletal muscle repair by adult human mesenchymal stem cells from synovial membrane

et al. 2003

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We have demonstrated previously that adult human synovial membrane-derived mesenchymal stem cells (hSM-MSCs) have myogenic potential in vitro (De Bari, C., F. Dell'Accio, P. Tylzanowski, and F.P. Luyten. 2001. Arthritis Rheum. 44:1928–1942). In the present study, we have characterized their myogenic differentiation in a nude mouse model of skeletal muscle regeneration and provide proof of principle of their potential use for muscle repair in the mdx mouse model of Duchenne muscular dystrophy. When implanted into regenerating nude mouse muscle, hSM-MSCs contributed to myofibers and to long term persisting functional satellite cells. No nuclear fusion hybrids were observed between donor human cells and host mouse muscle cells. Myogenic differentiation proceeded through a molecular cascade resembling embryonic muscle development. Differentiation was sensitive to environmental cues, since hSM-MSCs injected into the bloodstream engrafted in several tissues, but acquired the muscle phenotype only within skeletal muscle. When administered into dystrophic muscles of immunosuppressed mdx mice, hSM-MSCs restored sarcolemmal expression of dystrophin, reduced central nucleation, and rescued the expression of mouse mechano growth factor.

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Human periosteum-derived cells maintain phenotypic stability and chondrogenic potential throughout expansion regardless of donor age

Bari¹,

Dell’Accio²,

Luyten³

2001

Arthritis & Rheumatism

333

243

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Objective To assess the in vitro chondrogenic potential of adult human periosteum‐derived cells (PDCs) with regard to the number of cell passages and the age of the donor. Methods Cells were enzymatically released from the periosteum of the proximal tibia obtained from adult human donors and expanded in monolayer. PDCs were harvested at multiple passages for total RNA extraction and semiquantitative reverse transcription–polymerase chain reaction (RT‐PCR) gene expression analysis. For the chondrogenesis assay, cells were plated in micromass and treated with transforming growth factor β1 (TGFβ1) in a chemically defined medium. At different time points, micromasses were either harvested for RT‐PCR analysis for cartilage and bone markers or fixed, paraffin‐embedded, and stained for cartilage matrix, and immunostained for type II collagen. Results At the first 2 passages, human PDCs from young donors formed chondrogenic nodules. This spontaneous chondrogenic activity was lost upon passaging, and it was not observed in donors older than 30 years. Using a panel of marker genes, PDCs were shown to be phenotypically stable during cell expansion. Regardless of donor age or cell passage, chondrogenesis could be induced consistently by combining micromass culture and TGFβ1 treatment. Histochemical and immunohistochemical analyses demonstrated the hyaline‐like cartilage phenotype of the tissue generated in vitro. Other TGFβ superfamily members, such as growth differentiation factor 5/cartilage‐derived morphogenetic protein 1, and bone morphogenetic proteins 2, 4, and 7, were poorly chondrogenic under the same culture conditions. Conclusion Adult human PDCs have the potential to differentiate toward the chondrocytic lineage in vitro, retaining this property even after extensive subculture. Human PDCs are easily accessible, expandable, and maintain their chondrogenic potential, and are therefore promising progenitor cells for use in the repair of joint surface defects.

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Cosimo De Bari

Multipotent mesenchymal stem cells from adult human synovial membrane

Dual origin of mesenchymal stem cells contributing to organ growth and repair

Mesenchymal multipotency of adult human periosteal cells demonstrated by single‐cell lineage analysis

Skeletal muscle repair by adult human mesenchymal stem cells from synovial membrane

Human periosteum-derived cells maintain phenotypic stability and chondrogenic potential throughout expansion regardless of donor age

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