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Abstract

In this study, we demonstrate that a small population of pluripotent stem cells, termed adipose multilineage-differentiating stress-enduring (adipose-Muse) cells, exist in adult human adipose tissue and adipose-derived mesenchymal stem cells (adipose-MSCs). They can be identified as cells positive for both MSC markers (CD105 and CD90) and human pluripotent stem cell marker SSEA-3. They intrinsically retain lineage plasticity and the ability to self-renew. They spontaneously generate cells representative of all three germ layers from a single cell and successfully differentiate into targeted cells by cytokine induction. Cells other than adipose-Muse cells exist in adipose-MSCs, however, do not exhibit these properties and are unable to cross the boundaries from mesodermal to ectodermal or endodermal lineages even under cytokine inductions. Importantly, adipose-Muse cells demonstrate low telomerase activity and transplants do not promote teratogenesis in vivo. When compared with bone marrow (BM)– and dermal-Muse cells, adipose-Muse cells have the tendency to exhibit higher expression in mesodermal lineage markers, while BM- and dermal-Muse cells were generally higher in those of ectodermal and endodermal lineages. Adipose-Muse cells distinguish themselves as both easily obtainable and versatile in their capacity for differentiation, while low telomerase activity and lack of teratoma formation make these cells a practical cell source for potential stem cell therapies. Further, they will promote the effectiveness of currently performed adipose-MSC transplantation, particularly for ectodermal and endodermal tissues where transplanted cells need to differentiate across the lineage from mesodermal to ectodermal or endodermal in order to replenish lost cells for tissue repair.

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References

Zuk

, Zhu

, Ashjian

, De Ugarte

, Huang

, et al. (2002). Human adipose tissue is a source of multipotent stem cells. Mol Biol Cell, 13:4279–4295.

Cho

, Lee

, Park

, Kim

, Yoo

, et al. (2013). Autologous adipose tissue-derived stem cells for the treatment of Crohn's fistula: a phase I clinical study. Cell Transplant, 22:279–285.

Tzouvelekis

, Paspaliaris

, Koliakos

, Ntolios

, Bouros

, et al. (2013). A prospective, non-randomized, no placebo-controlled, phase Ib clinical trial to study the safety of the adipose derived stromal cells-stromal vascular fraction in idiopathic pulmonary fibrosis. J Transl Med, 11:171

Gimble

, Katz

and Bunnell

. (2007). Adipose-derived stem cells for regenerative medicine. Circ Res, 100:1249–1260.

Ikegame

, Yamashita

, Hayashi

, Mizuno

, Tawada

, et al. (2011). Comparison of mesenchymal stem cells from adipose tissue and bone marrow for ischemic stroke therapy. Cytotherapy, 13:675–685.

Boulland

, Mastrangelopoulou

, Boquest

, Jakobsen

, Noer

, et al. (2013). Epigenetic regulation of nestin expression during neurogenic differentiation of adipose tissue stem cells. Stem Cells Dev, 22:1042–1052.

Kingham

, Kalbermatten

, Mahay

, Armstrong

, Wiberg

, et al. (2007). Adipose-derived stem cells differentiate into a Schwann cell phenotype and promote neurite outgrowth in vitro . Exp Neurol, 207:267–274.

Chandra

, Swetha

, Muthyala

, Jaiswal

, Bellare

, et al. (2011). Islet-like cell aggregates generated from human adipose tissue derived stem cells ameliorate experimental diabetes in mice. PLoS One, 6: e20615.

Banas

, Teratani

, Yamamoto

, Tokuhara

, Takeshita

, et al. (2007). Adipose tissue-derived mesenchymal stem cells as a source of human hepatocytes. Hepatology, 46:219–228.

10.

Ruiz

, Ludlow

, Sherwood

, Yu

, Wu

, et al. (2010). Differentiated human adipose-derived stem cells exhibit hepatogenic capability in vitro and in vivo . J Cell Physiol, 225:429–436.

11.

Aurich

, Sgodda

, Kaltwasser

, Vetter

, Weise

, et al. (2009). Hepatocyte differentiation of mesenchymal stem cells from human adipose tissue in vitro promotes hepatic integration in vivo . Gut, 58:570–581.

12.

Okura

, Saga

, Fumimoto

, Soeda

, Moriyama

, et al. (2011). Transplantation of human adipose tissue-derived multilineage progenitor cells reduces serum cholesterol in hyperlipidemic Watanabe rabbits. Tissue Eng Part C Methods, 17:145–154.

13.

Chen

, Tang

, Liu

, Hu

, Liu

, et al. (2012). Transplantation of adipose-derived stem cells is associated with neural differentiation and functional improvement in a rat model of intracerebral hemorrhage. CNS Neurosci Ther, 18:847–854.

14.

Lee

and Yoon

. (2008). Intracerebral transplantation of human adipose tissue stromal cells after middle cerebral artery occlusion in rats. J Clin Neurosci, 15:907–912.

15.

Valina

, Pinkernell

, Song

, Bai

, Sadat

, et al. (2007). Intracoronary administration of autologous adipose tissue-derived stem cells improves left ventricular function, perfusion, and remodelling after acute myocardial infarction. Eur Heart J, 28:2667–2677.

16.

Kuroda

, Kitada

, Wakao

, Nishikawa

, Tanimura

, et al. (2010). Unique multipotent cells in adult human mesenchymal cell populations. Proc Natl Acad Sci USA, 107:8639–8643.

17.

Wakao

, Kitada

, Kuroda

, Shigemoto

, Matsuse

, et al. (2011). Multilineage-differentiating stress-enduring (Muse) cells are a primary source of induced pluripotent stem cells in human fibroblasts. Proc Natl Acad Sci USA, 108:9875–9880.

18.

Pittenger

, Mackay

, Beck

, Jaiswal

, Douglas

, et al. (1999). Multilineage potential of adult human mesenchymal stem cells. Science, 284:143–147.

19.

Dezawa

, Kanno

, Hoshino

, Cho

, Matsumoto

, et al. (2004). Specific induction of neuronal cells from bone marrow stromal cells and application for autologous transplantation. J Clin Invest, 113:1701–1710.

20.

Estes

, Diekman

, Gimble

and Guilak

. (2010). Isolation of adipose-derived stem cells and their induction to a chondrogenic phenotype. Nat Protoc, 5:1294–1311.

21.

Kuroda

, Wakao

, Kitada

, Murakami

, Nojima

, et al. (2013). Isolation, culture and evaluation of multilineage-differentiating stress-enduring (Muse) cells. Nat Protoc, 8:1391–1415.

22.

Livak

and Schmittgen

. (2001). Analysis of relative gene expression data using real-time quantitative PCR and the 2(-Delta Delta C(T)) Method. Methods, 25:402–408.

23.

Gimble

and Guilak

. (2003). Adipose-derived adult stem cells: isolation, characterization, and differentiation potential. Cytotherapy, 5:362–369.

24.

Venkataramana

, Kumar

, Balaraju

, Radhakrishnan

, Bansal

, et al. (2010). Open-labeled study of unilateral autologous bone-marrow-derived mesenchymal stem cell transplantation in Parkinson's disease. Transl Res, 155:62–70.

25.

Ren

, Chen

, Dong

, Li

, Ren

, et al. (2012). Concise review: mesenchymal stem cells and translational medicine: emerging issues. Stem Cells Transl Med, 1:51–58.

26.

Heneidi

, Simerman

, Keller

, Singh

, Li

, et al. (2013). Awakened by cellular stress: isolation and characterization of a novel population of pluripotent stem cells derived from human adipose tissue. PLoS One, 8: e64752.

27.

Greene

, Pitts

, McCarville

, Wang

, Newport

, et al. (2000). PPARgamma: observations in the hematopoietic system. Prostaglandins Other Lipid Mediat, 62:45–73.

28.

Eferl

and Wagner

. (2003). AP-1: a double-edged sword in tumorigenesis. Nat Rev Cancer, 3:859–868.

29.

Ceteci

, Ceteci

, Karreman

, Kramer

, Asan

, et al. (2007). Disruption of tumor cell adhesion promotes angiogenic switch and progression to micrometastasis in RAF-driven murine lung cancer. Cancer Cell, 12:145–159.

30.

Ali

, Dawson

, Blows

, Provenzano

, Pharoah

, et al. (2011). Cancer stem cell markers in breast cancer: pathological, clinical and prognostic significance. Breast Cancer Res, 13: R118.

31.

Thornton

and Gregory

. (2012). How does Lin28 let-7 control development and disease?. Trends Cell Biol, 22:474–482.

32.

Pang

, Yang

, Vierbuchen

, Ostermeier

, Fuentes

, et al. (2011). Induction of human neuronal cells by defined transcription factors. Nature, 476:220–223.

33.

Nakashima

, Zhou

, Kunkel

, Zhang

, Deng

, et al. (2002). The novel zinc finger-containing transcription factor osterix is required for osteoblast differentiation and bone formation. Cell, 108:17–29.

34.

Kadi

, Schjerling

, Andersen

, Charifi

, Madsen

, et al. (2004). The effects of heavy resistance training and detraining on satellite cells in human skeletal muscles. J Physiol, 558:1005–1012.

35.

Relaix

, Rocancourt

, Mansouri

and Buckingham

. (2005). A Pax3/Pax7-dependent population of skeletal muscle progenitor cells. Nature, 435:948–953.

36.

Cohen

, Cali

, Jelinek

, Mehrabian

, Sparkes

, et al. (1992). Cloning of the human cholesterol 7 alpha-hydroxylase gene (CYP7) and localization to chromosome 8q11-q12. Genomics, 14:153–161.

37.

Ambasudhan

, Talantova

, Coleman

, Yuan

, Zhu

, et al. (2011). Direct reprogramming of adult human fibroblasts to functional neurons under defined conditions. Cell Stem Cell, 9:113–118.

38.

Roy

, Gascard

, Dumont

, Zhao

, Pan

, et al. (2013). Rare somatic cells from human breast tissue exhibit extensive lineage plasticity. Proc Natl Acad Sci USA, 110:4598–4603.

39.

Abeysinghe

, Cao

, Xu

, Pollock

, Veyberman

, et al. (2003). THY1 expression is associated with tumor suppression of human ovarian cancer. Cancer Genet Cytogenet, 143:125–132.

40.

, Liu

, Zhu

, Dimeco

, et al. (2012). CD90 is identified as a candidate marker for cancer stem cells in primary high-grade gliomas using tissue microarrays. Mol Cell Proteomics 11: M111. 010744.

41.

Drukala

, Paczkowska

, Kucia

, Mlynska

, Krajewski

, et al. (2012). Stem cells, including a population of very small embryonic-like stem cells, are mobilized into peripheral blood in patients after skin burn injury. Stem Cell Rev, 8:184–194.

42.

Kassmer

, Jin

, Zhang

, Bruscia

, Heydari

, et al. (2013). Very small embryonic-like stem cells from the murine bone marrow differentiate into epithelial cells of the lung. Stem Cells. [Epub ahead of print]; DOI: 10.1002/stem.1413.

43.

Miyanishi

, Mori

, Seita

, Chen

, Karten

, et al. (2013). Do pluripotent stem cells exist in adult mice as very small embryonic stem cells?. Stem Cell Rep, 1:198–208.

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Human Adipose Tissue Possesses a Unique Population of Pluripotent Stem Cells with Nontumorigenic and Low Telomerase Activities: Potential Implications in Regenerative Medicine

Abstract

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