Investigating the molecular mechanisms controlling the in vivo developmental program postembryogenesis is challenging and time consuming. However, the developmental program can be partly recapitulated in vitro by the use of cultured embryonic stem cells (ESCs). Similar to the totipotent cells of the inner cell mass, gene expression and morphological changes in cultured ESCs occur hierarchically during their differentiation, with epiblast cells developing first, followed by germ layers and finally somatic cells. Combination of high throughput -omics technologies with murine ESCs offers an alternative approach for studying developmental processes toward organ-specific cell phenotypes. We have made an attempt to understand differentiation networks controlling embryogenesis in vivo using a time kinetic, by identifying molecules defining fundamental biological processes in the pluripotent state as well as in early and the late differentiation stages of ESCs. Our microarray data of the differentiation of the ESCs clearly demonstrate that the most critical early differentiation processes occur at days 2 and 3 of differentiation. Besides monitoring well-annotated markers pertinent to both self-renewal and potency (capacity to differentiate to different cell lineage), we have identified candidate molecules for relevant signaling pathways. These molecules can be further investigated in gain and loss-of-function studies to elucidate their role for pluripotency and differentiation. As an example, siRNA knockdown of MageB16, a gene highly expressed in the pluripotent state, has proven its influence in inducing differentiation when its function is repressed.
Get full access to this article
View all access options for this article.
References
1.
EvansMJ, KaufmanMH. 1981. Establishment in culture of pluripotential cells from mouse embryos. Nature, 292:154–156.
2.
NiwaH. 2007. How is pluripotency determined and maintained?Development, 134:635–646.
3.
LoebelDAF, WatsonCM, De YoungA, TamPPL. 2003. Lineage choice and differentiation in mouse embryos and embryonic stem cells. Dev Biol, 264:1–14.
4.
ChambersI, ColbyD, RobertsonM, NicholsJ, LeeS, TweedieS, SmithA. 2003. Functional expression cloning of Nanog, a pluripotency sustaining factor in embryonic stem cells. Cell, 113:643–655.
5.
AvilionAA, NicolisSK, PevnyLH, PerezL, VivianN, Lovell-BadgeR. 2003. Multipotent cell lineages in early mouse development depend on SOX2 function. Genes Dev, 17:126–140.
6.
NiwaH, MiyazakiJ, SmithAG. 2000. Quantitative expression of Oct-3/4 defines differentiation, dedifferentiation or self-renewal of ES cells. Nat Genet, 24:372–376.
7.
ScholerHR, RuppertS, SuzukiN, ChowdhuryK, GrussP. 1990. New type of pou domain in germ line-specific protein Oct-4. Nature, 344:435–439.
8.
OkitaK, YamanakaS. 2006. Intracellular signaling pathways regulating pluripotency of embryonic stem cells. Curr Stem Cell Res Ther, 1:103–111.
PepperSD, SaundersEK, EdwardsLE, WilsonCL, MillerCJ. 2007. The utility of MAS5 expression summary and detection call algorithms. BMC Bioinformatics, 8:273.
15.
SmythGK. 2004. Linear models and empirical bayes methods for assessing differential expression in microarray experiments. Stat Appl Genet Mol Biol, 3Article3.
16.
DossMX, ChenS, WinklerJ, Hippler-AltenburgR, OdenthalM, WickenhauserC, BalaramanS, SchulzH, HummelOet al.2007. Transcriptomic and phenotypic analysis of murine embryonic stem cell derived BMP2(+) lineage cells: an insight into mesodermal patterning. Genome Biol, 8:R184.
17.
DossMX, WaghV, SchulzH, KullM, KoldeR, PfannkucheK, NoldenT, HimmelbauerH, ViloJ, HeschelerJ, SachinidisA. 2010. Global transcriptomic analysis of murine embryonic stem cell-derived brachyury plus (T) cells. Genes Cells, 15:209–228.
ZhangZ, JonesA, SunCW, LiC, ChangCW, JooHY, DaiQA, MysliwiecMR, WuLCet al.2011. PRC2 complexes with JARID2, MTF2, and esPRC2p48 in ES cells to modulate ES cell pluripotency and somatic cell reprograming. Stem Cells, 29:229–240.
23.
HoriK, Cholewa-WaclawJ, NakadaY, GlasgowSM, MasuiT, HenkeRM, WildnerH, MartarelliB, BeresTMet al.2008. A nonclassical bHLH-Rbpj transcription factor complex is required for specification of GABAergic neurons independent of Notch signaling. Genes Dev, 22:166–178.
24.
MasonMJ, FanGP, PlathK, ZhouQ, HorvathS. 2009. Signed weighted gene co-expression network analysis of transcriptional regulation in murine embryonic stem cells. BMC Genomics, 10:327.
25.
GuoY, CostaR, RamseyH, StarnesT, VanceG, RobertsonK, KelleyM, ReinboldR, ScholerH, HromasR. 2002. The embryonic stem cell transcription factors Oct-4 and FoxD3 interact to regulate endodermal-specific promoter expression. Proc Natl Acad Sci U S A, 99:3663–3667.
26.
WalterJ. 2011. An epigenetic Tet a Tet with pluripotency. Cell Stem Cell, 8:121–122.
27.
PardoM, LangB, YuL, ProsserH, BradleyA, BabuMM, ChoudharyJ. 2010. An expanded Oct4 interaction network: implications for stem cell biology, development, and disease. Cell Stem Cell, 6:382–395.
Chotteau-LelievreA, MontesanoR, SorianoJ, SoulieP, DesbiensX, de LaunoitY. 2003. PEA3 transcription factors are expressed in tissues undergoing branching morphogenesis and promote formation of duct-like structures by mammary epithelial cells in vitro. Dev Biol, 259:241–257.
35.
BurgessR, RawlsA, BrownD, BradleyA, OlsonEN. 1996. Requirement of the paraxis gene for somite formation and musculoskeletal patterning. Nature, 384:570–573.
36.
MitsuiK, TokuzawaY, ItohH, SegawaK, MurakamiM, TakahashiK, MaruyamaM, MaedaM, YamanakaS. 2003. The homeoprotein Nanog is required for maintenance of pluripotency in mouse epiblast and ES cells. Cell, 113:631–642.
37.
WangL, ZhengA, YiL, XuCR, DingMX, DengHK. 2004. Identification of potential nuclear reprogramming and differentiation factors by a novel selection method for cloning chromatin-binding proteins. Biochem Biophys Res Commun, 325:302–307.
38.
VestergaardJ, Lind-ThomsenA, PedersenMW, JarmerHO, BakM, HasholtL, TommerupN, TumerZ, LarsenLA. 2008. GLI1 is involved in cell cycle regulation and proliferation of NT2 embryonal carcinoma stem cells. DNA Cell Biol, 27:251–256.
39.
ReinerR, Alfiya-MorN, Berrebi-DemmaM, WesolowskiD, AltmanS, JarrousN. 2011. RNA binding properties of conserved protein subunits of human RNase P. Nucleic Acids Res, 39:5704–5714.
40.
SessionDR, LeeGS, WolgemuthDJ. 2001. Characterization of D1Pas1, a mouse autosomal homologue of the human AZFa region DBY, as a nuclear protein in spermatogenic cells. Fertil Steril, 76:804–811.
41.
ScaldaferriML, FeraS, GrisantiL, SanchezM, StefaniniM, De FeliciM, ViciniE. 2011. Identification of side population cells in mouse primordial germ cells and prenatal testis. Int J Dev Biol, 55:209–214.
42.
InoueN, HessKD, MoreadithRW, RichardsonLL, HandelMA, WatsonML, ZinnAR. 1999. New gene family defined by MORC, a nuclear protein required for mouse spermatogenesis. Hum Mol Genet, 8:1201–1207.
43.
WatsonML, ZinnAR, InoueN, HessKD, CobbJ, HandelMA, HalabanR, DucheneCC, AlbrightGM, MoreadithRW. 1998. Identification of morc (microrchidia), a mutation that results in arrest of spermatogenesis at an early meiotic stage in the mouse. Proc Natl Acad Sci U S A, 95:14361–14366.
44.
YangGD, WuLY, BryanS, KhaperN, ManiS, WangR. 2010. Cystathionine gamma-lyase deficiency and overproliferation of smooth muscle cells. Cardiovasc Res, 86:487–495.
45.
GaoHJ, WuGY, SpencerTE, JohnsonGA, BazerFW. 2009. Select nutrients in the ovine uterine lumen. III. Cationic amino acid transporters in the ovine uterus and peri-implantation conceptuses. Biol Reprod, 80:602–609.
46.
YoshimaT, YuraT, YanagiH. 1998. Novel testis-specific protein that interacts with heat shock factor 2. Gene, 214:139–146.
47.
YoshimuraT, ToyodaS, Kuramochi-MiyagawaS, MiyazakiT, MiyazakiS, TashiroF, YamatoE, NakanoT, MiyazakiJ. 2009. Gtsf1/Cue110, a gene encoding a protein with two copies of a CHHC Zn-finger motif, is involved in spermatogenesis and retrotransposon suppression in murine testes. Dev Biol, 335:216–227.
48.
GascaS, HillDP, KlingensmithJ, RossantJ. 1995. Characterization of a gene trap insertion into a novel gene, cordon-bleu, expressed in axial structures of the gastrulating mouse embryo. Dev Genet, 17:141–154.
49.
WuC, OrozcoC, BoyerJ, LegliseM, GoodaleJ, BatalovS, HodgeCL, HaaseJ, JanesJ, HussJWIII, SuAI. 2009. BioGPS: an extensible and customizable portal for querying and organizing gene annotation resources. Genome Biol, 10:R130.
50.
TashiroF, Kanai-AzumaM, MiyazakiS, KatoM, TanakaT, ToyodaS, YamatoE, KawakamiH, MiyazakiT, MiyazakiJI. 2010. Maternal-effect gene Ces5/Ooep/Moep19/Floped is essential for oocyte cytoplasmic lattice formation and embryonic development at the maternal-zygotic stage transition. Genes Cells, 15:813–828.
51.
MhyreAJ, MarcondesAM, SpauldingEY, DeegHJ. 2009. Stroma-dependent apoptosis in clonal hematopoietic precursors correlates with expression of PYCARD. Blood, 113:649–658.
52.
OuyangZ, ZhouQ, WongWH. 2009. ChIP-Seq of transcription factors predicts absolute and differential gene expression in embryonic stem cells. Proc Natl Acad Sci U S A, 106:21521–21526.
53.
ChouKC, ShenHB. 2008. Cell-PLoc: a package of Web servers for predicting subcellular localization of proteins in various organisms. Nat Protoc, 3:153–162.
AngSL, RossantJ. 1994. Hnf-3-beta is essential for node and notochord formation in mouse development. Cell, 78:561–574.
56.
HongHK, NoveroskeJK, HeadonDJ, LiuT, SyMS, JusticeMJ, ChakravartiA. 2001. The winged helix/forkhead transcription factor Foxq1 regulates differentiation of hair in satin mice. Genesis, 29:163–171.
57.
SwiderskiRE, ReiterRS, NishimuraDY, AlwardWLM, KalenakJW, SearbyCS, StoneEM, SheffieldVC, LinJJC. 1999. Expression of the Mf1 gene in developing mouse hearts: implication in the development of human congenital heart defects. Dev Dyn, 216:16–27.
58.
WinnierGE, HargettL, HoganBLM. 1997. The winged helix transcription factor MFH1 is required for proliferation and patterning of paraxial mesoderm in the mouse embryo. Genes Dev, 11:926–940.
59.
HiemischH, MonaghanAP, SchutzG, KaestnerKH. 1998. Expression of the mouse Fkh1/Mf1 and Mfh1 genes in late gestation embryos is restricted to mesoderm derivatives. Mech Dev, 73:129–132.
60.
KumeT, DengKY, HoganBLM. 2000. Murine forkhead/winged helix genes Foxc1 (Mf1) and Foxc2 (Mfh1) are required for the early organogenesis of the kidney and urinary tract. Development, 127:1387–1395.
61.
ArenasE. 2008. Foxa2: the rise and fall of dopamine neurons. Cell Stem Cell, 2:110–112.
62.
LeeCS, FriedmanJR, FulmerJT, KaestnerKH. 2005. The initiation of liver development is dependent on Foxa transcription factors. Nature, 435:944–947.
HunterC, RhodesS. 2005. LIM-homeodomain genes in mammalian development and human disease. Mol Biol Rep, 32:67–77.
65.
WardleFC, PapaioannouVE. 2008. Teasing out T-box targets in early mesoderm. Curr Opin Genet Dev, 18:418–425.
66.
StuderM, LumsdenA, ArizaMcNaughtonL, BradleyA, KrumlaufR. 1996. Altered segmental identity and abnormal migration of motor neurons in mice lacking Hoxb-1. Nature, 384:630–634.
67.
StuderM, GavalasA, MarshallH, Ariza-McNaughtonL, RijliFM, ChambonP, KrumlaufR. 1998. Genetic interactions between Hoxa1 and Hoxb1 reveal new roles in regulation of early hindbrain patterning. Development, 125:1025–1036.
68.
BuckleyRR, KrumlaufR. 2007. Contribution of Hoxb1 to the development of the vertebrate skeleton. Dev Biol, 306:883–893.
69.
GoutiM, GavalasA. 2008. Hoxb1 controls cell fate specification and proliferative capacity of neural stem and progenitor cells. Stem Cells, 26:1985–1997.
WillcocksLC, SmithKGC, ClatworthyMR. 2009. Low-affinity Fc gamma receptors, autoimmunity and infection. Expert Rev Mol Med, 11:e24.
79.
GrewalT, EnrichC. 2009. Annexins—modulators of EGF receptor signalling and trafficking. Cell Signal, 21:847–858.
80.
PerrettiM, DalliJ. 2009. Exploiting the Annexin A1 pathway for the development of novel anti-inflammatory therapeutics. Br J Pharmacol, 158:936–946.
81.
YiM, SchnitzerJE. 2009. Impaired tumor growth, metastasis, angiogenesis and wound healing in annexin A1-null mice. Proc Natl Acad Sci U S A, 106:17886–17891.
Supplementary Material
Please find the following supplemental material available below.
For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.
For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.
