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Abstract

The deficiency of X-inactive specific transcript (XIST) on the inactive X chromosome affects the behavior of female human embryonic stem cells (hESCs) and human induced pluripotent stem cells (hiPSCs), and further chromosomal erosion can occur with continued passaging of these cells. However, X chromosome instability has not been identified in other species. In the present study, we investigated three female rabbit ESC (rbESC) lines and found that two of them expressed Xist normally and obtained both Xist RNA coating and H3K27me3 foci, thus defined as Xi^XistXa. Interestingly, the third female rbESC line lacked Xist expression during ESC maintenance and differentiation. This line showed H3K27me3 foci but no Xist RNA coating in the early passages and was thus defined as Xi^w/oXistXa. Similar to Xi^w/oXistXa hESCs or hiPSCs, Xi^w/oXistXa rbESCs lose H3K27me3 and undergo Xi erosion (Xe) with passaging. Moreover, Xist-deficient rbESCs also exhibit impaired differentiation ability and upregulation of cancer-related genes. By overexpressing OCT4, SOX2, KLF4, and c-MYC in Xist-deficient rbESCs under optimized culture conditions, we successfully obtained mouse ESC-like (mESC-like) cells. The mESC-like rbESCs displayed dome-shaped colony morphology, activation of the LIF/STAT3-dependent pathway, and conversion of disordered X chromosome. Importantly, the defective differentiation potential was also greatly improved. Our data demonstrate that variations in X chromosome inactivation occur in early passage of rbESCs; thus, Xi disorders are conserved across species and are reversible using the proper epigenetic reprogramming and culture conditions. These findings may be very useful for future efforts toward deriving fully pluripotent rbESCs or rabbit iPSCs (rbiPSCs).

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References

Weekers

, Van Herck

, Coopmans

, Michalaki

, Bowers

, Veldhuis

and Van den Berghe

. (2002). A novel in vivo rabbit model of hypercatabolic critical illness reveals a biphasic neuroendocrine stress response. Endocrinology, 143:764–774.

Peh

, Middleton

, Christensen

, Nicholls

, Egawa

, Sotlar

, Brandsma

, Percival

, Lewis

, Liu

and Doorbar

. (2002). Life cycle heterogeneity in animal models of human papillomavirus-associated disease. J Virol, 76:10401–10416.

Fan

and Watanabe

. (2003). Transgenic rabbits as therapeutic protein bioreactors and human disease models. Pharmacol Ther, 99:261–282.

Shiomi

, Ito

, Yamada

, Kawashima

and Fan

. (2004). Correlation of vulnerable coronary plaques to sudden cardiac events. Lessons from a myocardial infarction-prone animal model (the WHHLMI rabbit). J Atheroscler Thromb, 11:184–189.

Fang

, Gai

, Huang

, Li

, Chen

, Shi

, Wu

, Liu

, Xu

and Sheng

. (2006). Rabbit embryonic stem cell lines derived from fertilized, parthenogenetic or somatic cell nuclear transfer embryos. Exp Cell Res, 312:3669–3682.

Honda

, Hirose

, Hatori

, Matoba

, Miyoshi

, Inoue

and Ogura

. (2010). Generation of induced pluripotent stem cells in rabbits: potential experimental models for human regenerative medicine. J Biol Chem, 285:31362–31369.

Honda

, Hirose

and Ogura

. (2009). Basic FGF and Activin/Nodal but not LIF signaling sustain undifferentiated status of rabbit embryonic stem cells. Exp Cell Res, 315:2033–2042.

Intawicha

, Ou

, Lo

, Zhang

, Chen

, Lin

, Su

, Guu

, Chen

, et al. (2009). Characterization of embryonic stem cell lines derived from New Zealand white rabbit embryos. Cloning Stem Cells, 11:27–38.

Wang

, Shen

, Yuan

, Chen

, Guo

, Chen

, Niu

, Li

, Xu

, et al. (2008). Dissecting signaling pathways that govern self-renewal of rabbit embryonic stem cells. J Biol Chem, 283:35929–35940.

10.

Wang

, Tang

, Niu

, Chen

, Li

, Zhang

, Hu

, Zhou

and Ji

. (2007). Generation and characterization of rabbit embryonic stem cells. Stem Cells, 25:481–489.

11.

Zakhartchenko

, Flisikowska

, Li

, Richter

, Wieland

, Durkovic

, Rottmann

, Kessler

, Gungor

, et al. (2010). Cell-mediated transgenesis in rabbits: chimeric and nuclear transfer animals. Biol Reprod, 84:229–237.

12.

Tesar

, Chenoweth

, Brook

, Davies

, Evans

, Mack

, Gardner

and McKay

. (2007). New cell lines from mouse epiblast share defining features with human embryonic stem cells. Nature, 448:196–199.

13.

Brons

, Smithers

, Trotter

, Rugg-Gunn

, Sun

, Chuva de Sousa Lopes

, Howlett

, Clarkson

, Ahrlund-Richter

, Pedersen

and Vallier

. (2007). Derivation of pluripotent epiblast stem cells from mammalian embryos. Nature, 448:191–195.

14.

Nichols

and Smith

. (2009). Naive and primed pluripotent states. Cell Stem Cell, 4:487–492.

15.

Dvash

, Lavon

and Fan

. (2010). Variations of X chromosome inactivation occur in early passages of female human embryonic stem cells. PLoS One, 5:e11330

16.

Anguera

, Sadreyev

, Zhang

, Szanto

, Payer

, Sheridan

, Kwok

, Haggarty

, Sur

, et al. (2012). Molecular signatures of human induced pluripotent stem cells highlight sex differences and cancer genes. Cell Stem Cell, 11:75–90.

17.

Silva

, Rowntree

, Mekhoubad

and Lee

. (2008). X-chromosome inactivation and epigenetic fluidity in human embryonic stem cells. Proc Natl Acad Sci U S A, 105:4820–4825.

18.

Papp

and Plath

. (2013). Epigenetics of reprogramming to induced pluripotency. Cell, 152:1324–1343.

19.

Nazor

, Altun

, Lynch

, Tran

, Harness

, Slavin

, Garitaonandia

, Muller

, Wang

, et al. (2012). Recurrent variations in DNA methylation in human pluripotent stem cells and their differentiated derivatives. Cell Stem Cell, 10:620–634.

20.

Hanna

, Cheng

, Saha

, Kim

, Lengner

, Soldner

, Cassady

, Muffat

, Carey

and Jaenisch

. (2010). Human embryonic stem cells with biological and epigenetic characteristics similar to those of mouse ESCs. Proc Natl Acad Sci U S A, 107:9222–9227.

21.

Buecker

, Chen

, Polo

, Daheron

, Bu

, Barakat

, Okwieka

, Porter

, Gribnau

, Hochedlinger

and Geijsen

. (2010). A murine ESC-like state facilitates transgenesis and homologous recombination in human pluripotent stem cells. Cell Stem Cell, 6:535–546.

22.

Bao

, Tang

, Li

, Hayashi

, Gillich

, Lao

and Surani

. (2009). Epigenetic reversion of post-implantation epiblast to pluripotent embryonic stem cells. Nature, 461:1292–1295.

23.

Guo

, Yang

, Nichols

, Hall

, Eyres

, Mansfield

and Smith

. (2009). Klf4 reverts developmentally programmed restriction of ground state pluripotency. Development, 136:1063–1069.

24.

Erwin

and Lee

. (2010). Characterization of X-chromosome inactivation status in human pluripotent stem cells. Curr Protoc Stem Cell Biol Chapter 1:Unit 1B. 6.

25.

Soldner

, Hockemeyer

, Beard

, Gao

, Bell

, Cook

, Hargus

, Blak

, Cooper

, et al. (2009). Parkinson's disease patient-derived induced pluripotent stem cells free of viral reprogramming factors. Cell, 136:964–977.

26.

Kim

. (1995). Estimating doubling time of cells in vitro. In Vitro Cell Dev Biol Anim, 31:419–420.

27.

Mekhoubad

, Bock

, de Boer

, Kiskinis

, Meissner

and Eggan

. (2012). Erosion of dosage compensation impacts human iPSC disease modeling. Cell Stem Cell, 10:595–609.

28.

Hall

, Byron

, Butler

, Becker

, Nelson

, Amit

, Itskovitz-Eldor

, Stein

, Ware

and Lawrence

. (2008). X-inactivation reveals epigenetic anomalies in most hESC but identifies sublines that initiate as expected. J Cell Physiol, 216:445–452.

29.

Tchieu

, Kuoy

, Chin

, Trinh

, Patterson

, Sherman

, Aimiuwu

, Lindgren

, Hakimian

, et al. (2010). Female human iPSCs retain an inactive X chromosome. Cell Stem Cell, 7:329–342.

30.

Shen

, Matsuno

, Fouse

, Rao

, Root

, Xu

, Pellegrini

, Riggs

and Fan

. (2008). X-inactivation in female human embryonic stem cells is in a nonrandom pattern and prone to epigenetic alterations. Proc Natl Acad Sci U S A, 105:4709–4714.

31.

Okamoto

, Patrat

, Thepot

, Peynot

, Fauque

, Daniel

, Diabangouaya

, Wolf

, Renard

, Duranthon

and Heard

. (2011). Eutherian mammals use diverse strategies to initiate X-chromosome inactivation during development. Nature, 472:370–374.

32.

Buehr

, Meek

, Blair

, Yang

, Ure

, Silva

, McLay

, Hall

, Ying

and Smith

. (2008). Capture of authentic embryonic stem cells from rat blastocysts. Cell, 135:1287–1298.

33.

, Tong

, Mehrian-Shai

, Jia

, Wu

, Yan

, Maxson

, Schulze

, Song

, et al. (2008). Germline competent embryonic stem cells derived from rat blastocysts. Cell, 135:1299–1310.

34.

Tong

, Li

, Wu

, Yan

and Ying

. (2010). Production of p53 gene knockout rats by homologous recombination in embryonic stem cells. Nature, 467:211–213.

35.

Hou

, Li

, Zhang

, Liu

, Guan

, Li

, Zhao

, Ye

, Yang

, et al. (2013). Pluripotent stem cells induced from mouse somatic cells by small-molecule compounds. Science, 341:651–654.

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Xist Deficiency and Disorders of X-Inactivation in Rabbit Embryonic Stem Cells Can Be Rescued by Transcription-Factor-Mediated Conversion

Abstract

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Supplementary Material