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Abstract

Embryonic stem cells (ESCs) with their abilities for extensive proliferation and multi-lineage differentiation can serve as a renewable source of cellular material in regenerative medicine. However, the development of processes for large-scale generation of human ESCs (hESCs) or their progeny will be necessary before hESC-based therapies become a reality. We hypothesized that microcarrier stirred-suspension bioreactors characterized by scalability, straightforward operation, and tight control of the culture environment can be used for hESC culture and directed differentiation. Under appropriate conditions, the concentration of hESCs cultured in a microcarrier bioreactor increased 34- to 45-fold over 8 days. The cells retained the expression of pluripotency markers such as OCT3/4A, NANOG, and SSEA4, as assessed by quantitative PCR, immunocytochemistry, and flow cytometry. We further hypothesized that hESCs on microcarriers can be induced to definitive endoderm (DE) when incubated with physiologically relevant factors. In contrast to embryoid body cultures, all hESCs on microcarriers are exposed to soluble stimuli in the bulk medium facilitating efficient transition to DE. After reaching a peak concentration, hESCs in microcarrier cultures were incubated in medium containing activin A, Wnt3a, and low concentration of serum. More than 80% of differentiated hESCs coexpressed FOXA2 and SOX17 in addition to other DE markers, whereas the expression of non-DE genes was either absent or minimal. We also demonstrate that the hESC-to-DE induction in microcarrier cultures is scalable. Our findings support the use of microcarrier bioreactors for the generation of endoderm progeny from hESCs including pancreatic islets and liver cells in therapeutically useful quantities.

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References

Ryan

E.A.

, Paty

B.W.

, Senior

P.A.

, Bigam

, Alfadhli

, Kneteman

N.M.

, Lakey

J.R.

, Shapiro

A.M.

Five-year follow-up after clinical islet transplantation. Diabetes, 54:2060. 2005.

D'Amour

K.A.

, Bang

A.G.

, Eliazer

, Kelly

O.G.

, Agulnick

A.D.

, Smart

N.G.

, Moorman

M.A.

, Kroon

, Carpenter

M.K.

, Baetge

E.E.

Production of pancreatic hormone-expressing endocrine cells from human embryonic stem cells. Nat Biotechnol, 24:1392. 2006.

Jiang

, Au

, Lu

, Eshpeter

, Korbutt

, Fisk

, Majumdar

A.S.

Generation of insulin-producing islet-like clusters from human embryonic stem cells. Stem Cells, 25:1940. 2007.

Kroon

, Martinson

L.A.

, Kadoya

, Bang

A.G.

, Kelly

O.G.

, Eliazer

, Young

, Richardson

, Smart

N.G.

, Cunningham

, Agulnick

A.D.

, D'Amour

K.A.

, Carpenter

M.K.

, Baetge

E.E.

Pancreatic endoderm derived from human embryonic stem cells generates glucose-responsive insulin-secreting cells in vivo. Nat Biotechnol, 26:443. 2008.

Fong

W.J.

, Tan

H.L.

, Choo

, Oh

S.K.

Perfusion cultures of human embryonic stem cells. Bioprocess Biosyst Eng, 27:381. 2005.

Cameron

C.M.

, Hu

W.S.

, Kaufman

D.S.

Improved development of human embryonic stem cell-derived embryoid bodies by stirred vessel cultivation. Biotechnol Bioeng, 94:938. 2006.

Gerecht-Nir

, Cohen

, Itskovitz-Eldor

Bioreactor cultivation enhances the efficiency of human embryoid body (hEB) formation and differentiation. Biotechnol Bioeng, 86:493. 2004.

D'Amour

K.A.

, Agulnick

A.D.

, Eliazer

, Kelly

O.G.

, Kroon

, Baetge

E.E.

Efficient differentiation of human embryonic stem cells to definitive endoderm. Nat Biotechnol, 23:1534. 2005.

Abranches

, Bekman

, Henrique

, Cabral

J.M.

Expansion of mouse embryonic stem cells on microcarriers. Biotechnol Bioeng, 96:1211. 2007.

10.

Fok

E.Y.

, Zandstra

P.W.

Shear-controlled single-step mouse embryonic stem cell expansion and embryoid body-based differentiation. Stem Cells, 23:1333. 2005.

11.

R.H.

, Peck

R.M.

, Li

D.S.

, Feng

, Ludwig

, Thomson

J.A.

Basic FGF and suppression of BMP signaling sustain undifferentiated proliferation of human ES cells. Nat Methods, 2:185. 2005.

12.

Livak

K.J.

, Schmittgen

T.D.

Analysis of relative gene expression data using real-time quantitative PCR and the 2(-Delta Delta C(T)) method. Methods (San Diego, Calif ), 25:402. 2001.

13.

Cauffman

, Liebaers

, van Steirteghem

, van de Velde

POU5F1 isoforms show different expression patterns in human embryonic stem cells and preimplantation embryos. Stem Cells, 24:2685. 2006.

14.

Lee

, Kim

H.K.

, Rho

J.Y.

, Han

Y.M.

, Kim

The human OCT-4 isoforms differ in their ability to confer self-renewal. J Biol Chem, 281:33554. 2006.

15.

Kotoula

, Papamichos

S.I.

, Lambropoulos

A.F.

Revisiting OCT4 expression in peripheral blood mononuclear cells. Stem Cells, 26:290. 2008.

16.

McLean

A.B.

, D'Amour

K.A.

, Jones

K.L.

, Krishnamoorthy

, Kulik

M.J.

, Reynolds

D.M.

, Sheppard

A.M.

, Liu

, Xu

, Baetge

E.E.

, Dalton

Activin a efficiently specifies definitive endoderm from human embryonic stem cells only when phosphatidylinositol 3-kinase signaling is suppressed. Stem Cells, 25:29. 2007.

17.

Ang

S.L.

, Wierda

, Wong

, Stevens

K.A.

, Cascio

, Rossant

, Zaret

K.S.

The formation and maintenance of the definitive endoderm lineage in the mouse: involvement of HNF3/forkhead proteins. Development, 119:1301. 1993.

18.

Sasaki

, Hogan

B.L.

Differential expression of multiple fork head related genes during gastrulation and axial pattern formation in the mouse embryo. Development, 118:47. 1993.

19.

Kanai-Azuma

, Kanai

, Gad

J.M.

, Tajima

, Taya

, Kurohmaru

, Sanai

, Yonekawa

, Yazaki

, Tam

P.P.

, Hayashi

Depletion of definitive gut endoderm in Sox17-null mutant mice. Development, 129:2367. 2002.

20.

Blum

, Gaunt

S.J.

, Cho

K.W.

, Steinbeisser

, Blumberg

, Bittner

, de Robertis

E.M.

Gastrulation in the mouse: the role of the homeobox gene goosecoid. Cell, 69:1097. 1992.

21.

Belo

J.A.

, Bouwmeester

, Leyns

, Kertesz

, Gallo

, Follettie

, de Robertis

E.M.

Cerberus-like is a secreted factor with neutralizing activity expressed in the anterior primitive endoderm of the mouse gastrula. Mech Dev, 68:45. 1997.

22.

Biben

, Stanley

, Fabri

, Kotecha

, Rhinn

, Drinkwater

, Lah

, Wang

C.C.

, Nash

, Hilton

, Ang

S.L.

, Mohun

, Harvey

R.P.

Murine cerberus homologue mCer-1: a candidate anterior patterning molecule. Dev Biol, 194:135. 1998.

23.

Pearce

J.J.

, Penny

, Rossant

A mouse cerberus/Dan-related gene family. Dev Biol, 209:98. 1999.

24.

Pevny

L.H.

, Sockanathan

, Placzek

, Lovell-Badge

A role for SOX1 in neural determination. Development, 125:1967. 1998.

25.

Nagai

, Aruga

, Takada

, Gunther

, Sporle

, Schughart

, Mikoshiba

The expression of the mouse Zic1, Zic2, and Zic3 gene suggests an essential role for Zic genes in body pattern formation. Dev Biol, 182:299. 1997.

26.

Meyer

B.I.

, Gruss

Mouse Cdx-1 expression during gastrulation. Development, 117:191. 1993.

27.

Komuro

, Izumo

Csx: a murine homeobox-containing gene specifically expressed in the developing heart. Proc Natl Acad Sci USA, 90:8145. 1993.

28.

Osafune

, Caron

, Borowiak

, Martinez

R.J.

, Fitz-Gerald

C.S.

, Sato

, Cowan

C.A.

, Chien

K.R.

, Melton

D.A.

Marked differences in differentiation propensity among human embryonic stem cell lines. Nat Biotechnol, 26:313. 2008.

29.

Kubo

, Shinozaki

, Shannon

J.M.

, Kouskoff

, Kennedy

, Woo

, Fehling

H.J.

, Keller

Development of definitive endoderm from embryonic stem cells in culture. Development, 131:1651. 2004.

30.

Tada

, Era

, Furusawa

, Sakurai

, Nishikawa

, Kinoshita

, Nakao

, Chiba

, Nishikawa

Characterization of mesendoderm: a diverging point of the definitive endoderm and mesoderm in embryonic stem cell differentiation culture. Development, 132:4363. 2005.

31.

Yasunaga

, Tada

, Torikai-Nishikawa

, Nakano

, Okada

, Jakt

L.M.

, Nishikawa

, Chiba

, Era

, Nishikawa

Induction and monitoring of definitive and visceral endoderm differentiation of mouse ES cells. Nat Biotechnol, 23:1542. 2005.

32.

Dang

S.M.

, Gerecht-Nir

, Chen

, Itskovitz-Eldor

, Zandstra

P.W.

Controlled, scalable embryonic stem cell differentiation culture. Stem Cells, 22:275. 2004.

33.

Zandstra

P.W.

, Bauwens

, Yin

, Liu

, Schiller

, Zweigerdt

, Pasumarthi

K.B.

, Field

L.J.

Scalable production of embryonic stem cell-derived cardiomyocytes. Tissue Eng, 9:767. 2003.

34.

S.K.W.

, Choo

A.B.H.

Human embryonic stem cell technology: large scale cell amplification and differentiation. Cytotechnology, 50:181. 2006.

35.

Fernandes

A.M.

, Fernandes

T.G.

, Diogo

M.M.

, da Silva

C.L.

, Henrique

, Cabral

J.M.

Mouse embryonic stem cell expansion in a microcarrier-based stirred culture system. J Biotechnol, 132:227. 2007.

36.

Kato

, Takeuchi

, Sakurai

, Furukawa

, Mizokami

, Sakata

, Hirayama

, Kunitake

The design of polymer microcarrier surfaces for enhanced cell growth. Biomaterials, 24:4253. 2003.

37.

Varani

, Inman

D.R.

, Fligiel

S.E.

, Hillegas

W.J.

Use of recombinant and synthetic peptides as attachment factors for cells on microcarriers. Cytotechnology, 13:89. 1993.

38.

, Inokuma

M.S.

, Denham

, Golds

, Kundu

, Gold

J.D.

, Carpenter

M.K.

Feeder-free growth of undifferentiated human embryonic stem cells. Nat Biotechnol, 19:971. 2001.

39.

Billig

, Clark

J.M.

, Ewell

A.J.

, Carter

C.M.

, Gebb

The separation of harvested cells from microcarriers: a comparison of methods. Dev Biol Stand, 55:67. 1983.

40.

Tao

T.-Y.

, Ji

G.-Y.

, Hu

W.S.

Serial propagation of mammalian cells on gelatin-coated microcarriers. Biotechnol Bioeng, 32:1037. 1988.

41.

Papoutsakis

E.T.

Fluid-mechanical damage of animal cells in bioreactors. Trends Biotechnol, 9:427. 1991.

42.

Zur Nieden

N.I.

, Cormier

J.T.

, Rancourt

D.E.

, Kallos

M.S.

Embryonic stem cells remain highly pluripotent following long term expansion as aggregates in suspension bioreactors. J Biotechnol, 129:421. 2007.

43.

Perea-Gomez

, Shawlot

, Sasaki

, Behringer

R.R.

, Ang

HNF3beta and Lim1 interact in the visceral endoderm to regulate primitive streak formation and anterior-posterior polarity in the mouse embryo. Development, 126:4499. 1999.

44.

Gadue

, Huber

T.L.

, Paddison

P.J.

, Keller

G.M.

Wnt and TGF-beta signaling are required for the induction of an in vitro model of primitive streak formation using embryonic stem cells. Proc Natl Acad Sci USA, 103:16806. 2006.

45.

Park

, Afrikanova

, Chung

Y.S.

, Zhang

W.J.

, Arentson

, Fong Gh

, Rosendahl

, Choi

A hierarchical order of factors in the generation of FLK1- and SCL-expressing hematopoietic and endothelial progenitors from embryonic stem cells. Development, 131:2749. 2004.

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Expansion and Differentiation of Human Embryonic Stem Cells to Endoderm Progeny in a Microcarrier Stirred-Suspension Culture

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