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Abstract

Skeletal muscle stem cell (SMSC) transplantation has shown great therapeutical potential in repairing muscle loss and dysfunction, but the muscle acquisition is usually a traumatic procedure causing pain and morbidity to the donor. In this study, we investigated the feasibility of isolating SMSCs from human orbicularis oculi muscle (OOM), which is routinely removed and discarded during ophthalmic cosmetic surgeries. OOM fragments were harvested from 18 female healthy donors undergoing upper eyelid plasties. Plastic-adherent cells were isolated from the muscles using a two-step plating method combined with collagenase digestion. A total of 15 cell cultures were successfully established from the muscle samples. These adherent cells were positive for the specific markers of SMSCs and could be directed toward the osteogenic, adipogenic, chondrogenic, and myogenic phenotypes in the presence of lineage-specific inductive media. Moreover, after cultured in the myogenic inductive medium for 3 weeks, the muscle cells were injected into the tibialis anterior muscles of nude mice and the cell fate was detected using a DiI-labeling technique. In vivo myogenesis was evidenced by the expression of DiI fluorescence after cell transplantation. The donor cells could be found in the satellite cell position and incorporated into the host myofibers. Our results demonstrated that human OOM represents a novel source of myogenic precursors with stem cell-like properties, which may provide a foundation for the SMSC-based therapeutics of skeletal muscle diseases.

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References

Mizuno

, Zuk

P.A.

, Zhu

, Lorenz

H.P.

, Benhaim

, and Hedrick

M.H.

Myogenic differentiation by human processed lipoaspirate cells. Plast Reconstr Surg, 109, 199, 2002.

Qu-Petersen

, Deasy

, Jankowski

, et al. Identification of a novel population of muscle stem cells in mice: potential for muscle regeneration. J Cell Biol, 157, 851, 2002.

Usas

, and Huard

Muscle-derived stem cells for tissue engineering and regenerative therapy. Biomaterials, 28, 5401, 2007.

Asakura

, Komaki

, and Rudnicki

Muscle satellite cells are multipotential stem cells that exhibit myogenic, osteogenic, and adipogenic differentiation. Differentiation, 68, 245, 2001.

Alessandri

, Pagano

, Bez

, et al. Isolation and culture of human muscle-derived stem cells able to differentiate into myogenic and neurogenic cell lineages. Lancet, 364, 1872, 2004.

Péault

, Rudnicki

, Torrente

, et al. Stem and progenitor cells in skeletal muscle development, maintenance, and therapy. Mol Ther, 15, 867, 2007.

Lee

J.Y.

, Qu-Petersen

, Cao

, et al. Clonal isolation of muscle-derived cells capable of enhancing muscle regeneration and bone healing. J Cell Biol, 150, 1085, 2000.

Huard

, Yokoyama

, Pruchnic

, et al. Muscle-derived cell-mediated ex vivo gene therapy for urological dysfunction. Gene Ther, 9, 1617, 2002.

Wada

M.R.

, Inagawa-Ogashiwa

, Shimizu

, Yasumoto

, and Hashimoto

Generation of different fates from multipotent muscle stem cells. Development, 129, 2987, 2002.

10.

Huard

, Cao

, and Qu-Petersen

Muscle-derived stem cells: potential for muscle regeneration. Birth Defects Res C Embryo Today, 69, 230, 2003.

11.

Di Rocco

, Iachininoto

M.G.

, Tritarelli

, et al. Myogenic potential of adipose-tissue-derived cells. J Cell Sci, 119, 2945, 2006.

12.

Jackson

W.M.

, Lozito

T.P.

, Djouad

, Kuhn

N.Z.

, Nesti

L.J.

, and Tuan

R.S.

Differentiation and regeneration potential of mesenchymal progenitor cells derived from traumatized muscle tissue. J Cell Mol Med, 15, 2377, 2011.

13.

Jackson

W.M.

, Aragon

A.B.

, Djouad

, et al. Mesenchymal progenitor cells derived from traumatized human muscle. J Tissue Eng Regen Med, 3, 129, 2009.

14.

Costin

B.R.

, Plesec

T.P.

, Kopplin

L.J.

, et al. Regional variations in orbicularis oculi histology. Ophthalmic Plast Reconstr Surg, 31, 325, 2015.

15.

Sekulic-Jablanovic

, Ullrich

N.D.

, Goldblum

, Palmowski-Wolfe

, Zorzato

, and Treves

Functional characterization of orbicularis oculi and extraocular muscles. J Gen Physiol, 147, 395, 2016.

16.

, Liao

, Liu

, Xu

, Tan

, and Song

Age-related changes in the regenerative potential of adipose-derived stem cells isolated from the prominent fat pads in human lower eyelids. PLoS One, 11, e0166590, 2016.

17.

Bueno

D.F.

, Kerkis

, Costa

A.M.

, et al. New source of muscle-derived stem cells with potential for alveolar bone reconstruction in cleft lip and/or palate patients. Tissue Eng Part A, 15, 427, 2009.

18.

Chang

, Yoshimoto

, Umeda

, et al. Generation of transplantable, functional satellite-like cells from mouse embryonic stem cells. FASEB J, 23, 1907, 2009.

19.

Wang

, Cheung

, Zhou

, et al. An in vitro culture system that supports robust expansion and maintenance of in vivo engraftment capabilities for myogenic progenitor cells from adult mice. Biores Open Access, 3, 79, 2014.

20.

Sinanan

A.C.

, Hunt

N.P.

, and Lewis

M.P.

Human adult craniofacial muscle-derived cells: neural-cell adhesion-molecule (NCAM; CD56)-expressing cells appear to contain multipotential stem cells. Biotechnol Appl Biochem, 40, 25, 2004.

21.

Kitajima

, Ogawa

, and Ono

Visualizing the functional heterogeneity of muscle stem cells. Methods Mol Biol, 1516, 183, 2016.

22.

Sun

J.S.

, Wu

S.Y.

, and Lin

F.H.

The role of muscle-derived stem cells in bone tissue engineering. Biomaterials, 26, 3953, 2005.

23.

Levy

M.M.

, Joyner

C.J.

, Virdi

A.S.

, et al. Osteoprogenitor cells of mature human skeletal muscle tissue: an in vitro study. Bone, 29, 317, 2001.

24.

Bosch

, Musgrave

D.S.

, Lee

J.Y.

, et al. Osteoprogenitor cells within skeletal muscle. J Orthop Res, 18, 933, 2000.

25.

Webster

, Pavlath

G.K.

, Parks

D.R.

, Walsh

F.S.

, and Blau

H.M.

Isolation of human myoblasts with the fluorescence-activated cell sorter. Exp Cell Res, 174, 252, 1988.

26.

Skuk

, Goulet

, Roy

, et al. Dystrophin expression in muscles of duchenne muscular dystrophy patients after high-density injections of normal myogenic cells. J Neuropathol Exp Neurol, 65, 371, 2006.

27.

Tedesco

F.S.

, Dellavalle

, Diaz-Manera

, Messina

, and Cossu

Repairing skeletal muscle: regenerative potential of skeletal muscle stem cells. J Clin Invest, 120, 11, 2010.

28.

Tremblay

J.P.

, and Skuk

Another new “super muscle stem cell” leaves unaddressed the real problems of cell therapy for duchenne muscular dystrophy. Mol Ther, 16, 1907, 2008.

29.

Collin

J.R.O.

A Manual of Systematic Eyelid Surgery, 3rd Ed. London, United Kingdom: Elsevier, 2005.

Identification and Characterization of Skeletal Muscle Stem Cells from Human Orbicularis Oculi Muscle

Abstract

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