Maki Masuda scite author profile

The differentiation potential of skeletal muscle-derived stem cells (MDSCs) after in vitro culture and in vivo transplantation has been extensively studied. However, the clonal multipotency of MDSCs has yet to be fully determined. Here, we show that single skeletal muscle-derived CD34 STEM CELLS 2007;25: 2283-2290 Disclosure of potential conflicts of interest is found at the end of this article.

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Synchronized reconstitution of muscle fibers, peripheral nerves and blood vessels by murine skeletal muscle-derived CD34−/45− cells

Tamaki

Okada

Uchiyama

et al. 2007

Histochem Cell Biol

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In order to establish the practical isolation and usage of skeletal muscle-derived stem cells (MDSCs), we determined reconstitution capacity of CD34(-)/CD45(-) (Sk-DN) cells as a candidate somatic stem cell source for transplantation. Sk-DN cells were enzymatically isolated from GFP transgenic mice (C57/BL6N) skeletal muscle and sorted using fluorescence activated cell sorting (FACS), and expanded by collagen gel-based cell culture with bFGF and EGF. The number of Sk-DN cells was small after sorting (2-8 x 10(4)); however, the number increased 10-20 fold (2-16 x 10(5)) after 6 days of expansion culture, and the cells maintained immature state and multipotency, expressing mRNAs for mesodermal and ectodermal cell lineages. Transplantation of expanded Sk-DN cells into the severe muscle damage model (C57/BL6N wild-type) resulted in the synchronized reconstitution of blood vessels, peripheral nerves and muscle fibers following significant recovery of total muscle mass (57%) and contractile function (55%), whereas the non-cell-transplanted control group showed around 20% recovery in both factors. These reconstitution capacities were supported by the intrinsic plasticity of Sk-DN cells that can differentiate into muscular (skeletal muscle), vascular (pericyte, endothelial cell and smooth muscle) and peripheral nerve (Schwann cells and perineurium) cell lineages that was revealed by transplantation to non-muscle tissue (beneath renal capsule) and fluorescence in situ hybridization (FISH) analysis.

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Skeletal Muscle–Derived CD34⁺/45^-and CD34^-/45^-Stem Cells Are Situated Hierarchically Upstream of Pax7⁺Cells

Tamaki

Okada²,

Uchiyama³

et al. 2008

Stem Cells and Development

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The hierarchical relationship of skeletal muscle-derived multipotent stem cells sorted as CD34(+)/CD45(-) (Sk-34) and CD34(-)/CD45(-) (Sk-DN) cells, which have synchronized reconstitution capacities for blood vessels, peripheral nerves, and muscle fibers, was examined. Expression of Sca-1 and CD34 (typical state of freshly isolated Sk-34 cells) in Sk-DN cells was examined using in vitro culture and in vivo cell implantation. Sk-DN cells sequentially expressed Sca-1 and CD34 during cell culture showing self-maintenance and/or self-renewal-like behavior, and are thus considered hierarchically upstream of Sk-34 cells in the same lineage. Sk-34 and Sk-DN cells were further divided into small and large cell fractions by cell sorting. Immunocytochemistry using anti-Pax7 was performed at the time of isolation (before culture) and revealed that only 1% of cells in the large Sk-DN cell fraction were positive for Pax7, while Sk-34 cells and 99% of Sk-DN cells were negative for Pax7. Therefore, putative satellite cells were possibly present in the large Sk-DN cell fraction. However, serial analysis of Pax7 expression by RT-PCR and immunocytochemistry for single and 2 to >40 clonally proliferated Sk-34 and Sk-DN cells revealed that both cell types expressed Pax7 after several asymmetric cellular divisions during clonal-cell culture. In addition, production of satellite cells was seen after muscle fiber formation following Sk-34 or Sk-DN cell transplantation into damaged muscle, and even in the nonmuscle tissue environment (beneath the renal capsule). Thus, Sk-DN cells are situated upstream of Sk-34 cells and both cells can produce Pax7+ cells (putative satellite cells) after cellular division.

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3D Reconstitution of Nerve–Blood Vessel Networks Using Skeletal Muscle-Derived Multipotent Stem Cell Sheet Pellets

Tamaki¹,

Soeda²,

Hashimoto³

et al. 2013

Regen. Med.

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Reconstitution of Experimental Neurogenic Bladder Dysfunction Using Skeletal Muscle-Derived Multipotent Stem Cells

Nitta

Tamaki²,

Tono³

et al. 2010

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Maki Masuda

Clonal Multipotency of Skeletal Muscle-Derived Stem Cells Between Mesodermal and Ectodermal Lineage

Synchronized reconstitution of muscle fibers, peripheral nerves and blood vessels by murine skeletal muscle-derived CD34−/45− cells

Skeletal Muscle–Derived CD34⁺/45^-and CD34^-/45^-Stem Cells Are Situated Hierarchically Upstream of Pax7⁺Cells

3D Reconstitution of Nerve–Blood Vessel Networks Using Skeletal Muscle-Derived Multipotent Stem Cell Sheet Pellets

Reconstitution of Experimental Neurogenic Bladder Dysfunction Using Skeletal Muscle-Derived Multipotent Stem Cells

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Maki Masuda

Clonal Multipotency of Skeletal Muscle-Derived Stem Cells Between Mesodermal and Ectodermal Lineage

Synchronized reconstitution of muscle fibers, peripheral nerves and blood vessels by murine skeletal muscle-derived CD34−/45− cells

Skeletal Muscle–Derived CD34+/45-and CD34-/45-Stem Cells Are Situated Hierarchically Upstream of Pax7+Cells

3D Reconstitution of Nerve–Blood Vessel Networks Using Skeletal Muscle-Derived Multipotent Stem Cell Sheet Pellets

Reconstitution of Experimental Neurogenic Bladder Dysfunction Using Skeletal Muscle-Derived Multipotent Stem Cells

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Skeletal Muscle–Derived CD34⁺/45^-and CD34^-/45^-Stem Cells Are Situated Hierarchically Upstream of Pax7⁺Cells