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Abstract

Human embryonic stem cells (hESCs) have long been considered as a promising source for cell replacement therapy. However, one major obstacle for the use of these cells is immune compatibility. Histocompatible human parthenogenetic ESCs have been reported as a new method for generating human leukocyte antigen (HLA)-matched hESCs. To further investigate the possibility of obtaining histocompatible stem cells from uniparental embryos, we tried to produce androgenetic haploid human embryos by injecting a single spermatozoon into enucleated human oocyte, and establish human androgenetic embryonic stem (hAGES) cell lines from androgenetic embryos. In the present study, a diploid hAGES cell line has been established, which exhibits typical features of human ESCs, including the expression of pluripotency markers, having differentiation potential in vitro and in vivo, and stable propagation in an undifferentiated state (>P40). Bisulfite sequencing of the H19, Snrpn, Meg3, and Kv imprinting control regions suggested that hAGES cells maintained to a certain extent a sperm methylation pattern. Genome-wide single nucleotide polymorphism, short tandem repeat, and HLA analyses revealed that the hAGES cell genome was highly homozygous. These results suggest that hAGES cells from spermatozoon could serve as a useful tool for studying the mechanisms underlying genomic imprinting in humans. It might also be used as a potential resource for cell replacement therapy as parthenogenetic stem cells.

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References

McGrath

and Solter

. (1984). Completion of mouse embryogenesis requires both the maternal and paternal genomes. Cell, 37:179–183.

Surani

and Barton

. (1983). Development of gynogenetic eggs in the mouse: implications for parthenogenetic embryos. Science, 222:1034–1036.

Hirasawa

and Feil

. (2010). Genomic imprinting and human disease. Essays Biochem, 48:187–200.

Surani

, Barton

and Norris

. (1984). Development of reconstituted mouse eggs suggests imprinting of the genome during gametogenesis. Nature, 308:548–550.

Linder

, McCaw

and Hecht

. (1975). Parthenogenic origin of benign ovarian teratomas. N Engl J Med, 292:63–66.

Padilla

, Boldt

and McDonough

. (1987). Possible parthenogenesis with in vitro fertilization subsequent to ovarian cystic teratomas. Am J Obstet Gynecol, 156:1127–1129.

Deveault

, Qian

, Chebaro

, Ao

, Gilbert

, Mehio

, Khan

, Tan

, Wischmeijer

, et al. (2009). NLRP7 mutations in women with diploid androgenetic and triploid moles: a proposed mechanism for mole formation. Hum Mol Genet, 8:888–897.

Nguyen

and Slim

. (2014). Genetics and epigenetics of recurrent hydatidiform moles: basic science and genetic counselling. Curr Obstet Gynecol Rep, 3:55–64.

Robertson

, Evans

and Kaufman

. (1983). X-chromosome instability in pluripotential stem cell lines derived from parthenogenetic embryos. J Embryol Exp Morphol, 74:297–309.

10.

Mai

, Yu

, Li

, Wang

, Chen

, Huang

, Zhou

and Zhou

. (2007). Derivation of human embryonic stem cell lines from parthenogenetic blastocysts. Cell Res, 17:1008–1019.

11.

Mann

, Gadi

, Harbison

, Abbondanzo

and Stewart

. (1990). Androgenetic mouse embryonic stem cells are pluripotent and cause skeletal defects in chimeras: implications for genetic imprinting. Cell, 62:251–260.

12.

Revazova

, Turovets

, Kochetkova

, Kindarova

, Kuzmichev

, Janus

and Pryzhkova

. (2007). Patient-specific stem cell lines derived from human parthenogenetic blastocysts. Cloning Stem Cells, 9:432–449.

13.

, Shuai

, Wan

, Dong

, Wang

, Sang

, Feng

, Luo

, Li

, et al. (2012). Androgenetic haploid embryonic stem cells produce live transgenic mice. Nature, 490:407–411.

14.

Keller

. (2005). Embryonic stem cell differentiation: emergence of a new era in biology and medicine. Genes Dev, 19:1129–1155.

15.

Bradley

, Bolton

and Pedersen

. (2002). Stem cell medicine encounters the immune system. Nat Rev Immunol, 2:859–871.

16.

Tachibana

, Amato

, Sparman

, Gutierrez

, Tippner-Hedges

, Ma

, Kang

, Fulati

, Lee

, et al. (2013). Human embryonic stem cells derived by somatic cell nuclear transfer. Cell, 153:1228–1238.

17.

Takahashi

and Yamanaka

. (2006). Induction of pluripotent stem cells from mouse embryonic and adult fibroblast cultures by defined factors. Cell, 126:663–676.

18.

Taylor

, Bolton

, Pocock

, Sharples

, Pedersen

and Bradley

. (2005). Banking on human embryonic stem cells: estimating the number of donor cell lines needed for HLA matching. Lancet, 366:2019–2025.

19.

Kim

, Lerou

, Yabuuchi

, Lengerke

, Ng

, West

, Kirby

, Daly

and Daley

. (2007). Histocompatible embryonic stem cells by parthenogenesis. Science, 315:482–486.

20.

Paull

, Emmanuele

, Weiss

, Treff

, Stewart

, Hua

, Zimmer

, Kahler

, Goland

, et al. (2003). Nuclear genome transfer in human oocytes eliminates mitochondrial DNA variants. Nature, 493:632–637.

21.

Nakajima

, Tokunaga

and Nakatsuji

. (2007). Human leukocyte antigen matching estimations in a hypothetical bank of human embryonic stem cell lines in the Japanese population for use in cell transplantation therapy. Stem Cells, 25:983–985.

22.

Gonzalez

, Garitaonandia

, Abramihina

, Wambua

, Ostrowska

, Brock

, Noskov

, Boscolo

, Craw

, et al. (2013). Deriving dopaminergic neurons for clinical use. A practical approach. Sci Rep, 3:1463.

23.

Mann

and Stewart

. (1991). Development to term of mouse androgenetic aggregation chimeras. Development, 113:1325–1333.

24.

Morris

. (1968). The XO and Oy chromosome constitutions in the mouse. Genet Res, 12:125–137.

25.

Fan

, Li

, Huang

, Yu

and Qiao

. (2013). Diploid, but not haploid, human embryonic stem cells can be derived from microsurgically repaired tripronuclear human zygotes. Cell Cycle, 12:02–11.

26.

Latham

, Akutsu

, Patel

and Yanagimachi

. (2002). Comparison of gene expression during preimplantation development between diploid and haploid mouse embryos. Biol Reprod, 67:386–392.

27.

Kono

, Sotomaru

, Sato

and Nakahara

. (1993). Development of androgenetic mouse embryos produced by in vitro fertilization of enucleated oocytes. Mol Reprod Dev, 34:43–46.

28.

Lagutina

, Lazzari

, Duchi

and Galli

. (2004). Developmental potential of bovine androgenetic and parthenogenetic embryos: a comparative study. Biol Reprod, 70:400–405.

29.

Wolf

and Lage

. (1995). Genetic analysis of gestational trophoblastic disease: a review. Semin Oncol, 22:113–120.

30.

Slim

and Mehio

. (2007). The genetics of hydatidiform moles: new lights on an ancient disease. Clin Genet, 71:25–34.

31.

Eckardt

, Leu

, Bradley

, Kato

, Bunting

and McLaughlin

. (2007). Hematopoietic reconstitution with androgenetic and gynogenetic stem cells. Genes Dev, 21:409–419.

32.

Dinger

, Eckardt

, Choi

, Camarero

, Kurosaka

, Hornich

, McLaughlin

and Müller

. (2008). Androgenetic embryonic stem cells form neural progenitor cells in vivo and in vitro. Stem Cells, 26:1474–1483.

33.

Gourraud

, Gilson

, Girard

and Peschanski

. (2012). The role of human leukocyte antigen matching in the development of multiethnic “haplobank”. of induced pluripotent stem cell lines. Stem Cells, 30:180–186.

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Derivation of a Homozygous Human Androgenetic Embryonic Stem Cell Line

Abstract

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