Although maternal intake of folic acid (FA) prevents neural tube defects in 70% of the population, the exact mechanism of prevention has not been elucidated. We hypothesized that FA affects neural stem cell (NSC) proliferation and differentiation. This hypothesis was examined in a folate-responsive spina bifida mouse model, Splotch (Sp−/−), which has a homozygous loss-of-function mutation in the Pax3 gene. Neurospheres were generated with NSCs from the lower lumbar neural tube of E10.5 wild-type (WT) and Sp−/− embryos, in the presence and absence of FA. In the absence of FA, the number of neurospheres generated from Sp−/− embryos compared with WT was minimal (P<0.05). Addition of FA to Sp−/− cultures increased the expression of a Pax3 downstream target, fgfr4, and rescued NSC proliferative potential, as demonstrated by a significant increase in neurosphere formation (P<0.01). To ascertain if FA affected cell differentiation, FA-stimulated Sp−/− neurospheres were allowed to differentiate in the continued presence or absence of FA. Neurospheres from both conditions expressed multi-potent stem cell characteristics and the same differentiation potential as WT. Further, multiple neurospheres from both WT and FA-stimulated Sp−/− cell cultures formed extensive synaptic connections. On the whole, FA-mediated rescue of neural tube defects in Sp−/− embryos promotes NSC proliferation at an early embryonic stage. FA-stimulated Sp−/− neurospheres differentiate and form synaptic connections, comparable to WT.
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References
1.
U.S. Preventive Services Task Force. 2009. Folic acid for the prevention of neural tube defects: U.S. Preventive Services Task Force recommendation statement. Ann Intern Med, 150:626–631.
2.
De WalsP, TairouF, Van AllenMI, UhSH, LowryRB, SibbaldB, EvansJA, Van den HofMC, ZimmerPet al. 2007. Reduction in neural-tube defects after folic acid fortification in Canada. N Engl J Med, 357:135–142.
3.
MRC Vitamin Study Research Group. 1991. Prevention of neural tube defects: results of the Medical Research Council Vitamin Study. Lancet, 338:131–137.
ZhangX, LiuH, CongG, TianZ, RenD, WilsonJX, HuangG. 2008. Effects of folate on notch signaling and cell proliferation in neural stem cells of neonatal rats in vitro. J Nutr Sci Vitaminol (Tokyo), 54:353–356.
7.
BurrenKA, SaveryD, MassaV, KokRM, ScottJM, BlomHJ, CoppAJ, GreeneND. 2008. Gene-environment interactions in the causation of neural tube defects: folate deficiency increases susceptibility conferred by loss of Pax3 function. Hum Mol Genet, 17:3675–3685.
8.
HarrisMJ, JuriloffDM. 2007. Mouse mutants with neural tube closure defects and their role in understanding human neural tube defects. Birth Defects Res A Clin Mol Teratol, 79:187–210.
9.
EpsteinDJ, VoganKJ, TraslerDG, GrosP. 1993. A mutation within intron 3 of the Pax-3 gene produces aberrantly spliced mRNA transcripts in the splotch (Sp) mouse mutant. Proc Natl Acad Sci USA, 90:532–536.
10.
GefridesLA, BennettGD, FinnellRH. 2002. Effects of folate supplementation on the risk of spontaneous and induced neural tube defects in Splotch mice. Teratology, 65:63–69.
11.
NakazakiH, ReddyAC, Mania-FarnellBL, ShenYW, IchiS, McCabeC, GeorgeD, McLoneDG, TomitaT, MayanilCS. 2008. Key basic helix-loop-helix transcription factor genes Hes1 and Neurog2 are regulated by Pax3 during mouse embryonic development. Dev Biol, 316:510–523.
WuY, LiuY, ChesnutJD, RaoMS. 2008. Isolation of neural stem and precursor cells from rodent tissue. Methods Mol Biol, 438:39–53.
21.
SakaiY. 1989. Neurulation in the mouse: manner and timing of neural tube closure. Anat Rec, 223:194–203.
22.
MoriH, NinomiyaK, Kino-okaM, ShofudaT, IslamMO, YamasakiM, OkanoH, TayaM, KanemuraY. 2006. Effect of neurosphere size on the growth rate of human neural stem/progenitor cells. J Neurosci Res, 84:1682–1691.
23.
WatsonED, MattarP, SchuurmansC, CrossJC. 2009. Neural stem cell self-renewal requires the Mrj co-chaperone. Dev Dyn, 238:2564–2574.
24.
PeaseS, BraghettaP, GearingD, GrailD, WilliamsRL. 1990. Isolation of embryonic stem (ES) cells in media supplemented with recombinant leukemia inhibitory factor (LIF)Dev Biol, 141:344–352.
25.
SalicA, MitchisonTJ. 2008. A chemical method for fast and sensitive detection of DNA synthesis in vivo. Proc Natl Acad Sci USA, 105:2415–2420.
26.
BuckSB, BradfordJ, GeeKR, AgnewBJ, ClarkeST, SalicA. 2008. Detection of S-phase cell cycle progression using 5-ethynyl-2′-deoxyuridine incorporation with click chemistry, an alternative to using 5-bromo-2′-deoxyuridine antibodies. Biotechniques, 44:927–929.
27.
OhtsukaT, IshibashiM, GradwohlG, NakanishiS, GuillemotF, KageyamaR. 1999. Hes1 and Hes5 as notch effectors in mammalian neuronal differentiation. EMBO J, 18:2196–2207.
28.
LiuJ, SatoC, CerlettiM, WagersA. 2010. Ultradian oscillations in notch signaling regulate dynamic biological events. Curr Top Dev Biol, 92:367–409.
29.
KageyamaR, NiwaY, ShimojoH, KobayashiT, OhtsukaT. 2010. Ultradian oscillations in Notch signaling regulate dynamic biological events. Curr Top Dev Biol, 92:311–331.
30.
OishiK, OgawaY, GamohS, UchidaMK. 2002. Contractile responses of smooth muscle cells differentiated from rat neural stem cells. J Physiol, 540:139–152.
31.
GalliR, BorelloU, GrittiA, MinasiMG, BjornsonC, ColettaM, MoraM, De AngelisMG, FioccoR, CossuG, VescoviAL. 2000. Skeletal myogenic potential of human and mouse neural stem cells. Nat Neurosci, 3:986–991.
32.
DenhamM, HuynhT, DottoriM, AllenG, TrounsonA, MollardR. 2006. Neural stem cells express non-neural markers during embryoid body coculture. Stem Cells, 24:918–927.
EsnerM, MeilhacSM, RelaixF, NicolasJF, CossuG, BuckinghamME. 2006. Smooth muscle of the dorsal aorta shares a common clonal origin with skeletal muscle of the myotome. Development, 133:737–749.
35.
YokoyamaS, AsaharaH. 2011. The myogenic transcriptional network. Cell Mol Life Sci.10.1007/s00018-011-0629-2[Epub ahead of print].
36.
HitoshiS, AlexsonT, TropepeV, DonovielD, EliaAJ, NyeJS, ConlonRA, MakTW, BernsteinA, van der KooyD. 2002. Notch pathway molecules are essential for the maintenance, but not the generation, of mammalian neural stem cells. Genes Dev, 16:846–858.
37.
Keller-PeckCR, MullenRJ. 1997. Altered cell proliferation in the spinal cord of mouse neural tube mutants curly tail and Pax3 splotch-delayed. Dev Brain Res, 102:177–188.
PaniL, HoralM, LoekenMR. 2002. Rescue of neural tube defects in Pax-3-deficient embryos by p53 loss of function: implications for Pax-3-dependent development and tumorigenesis. Genes Dev, 16:676–680.
40.
JiaDY, LiuHJ, WangFW, LiuSM, LingEA, LiuK, HaoAJ. 2008. Folic acid supplementation affects apoptosis and differentiation of embryonic neural stem cells exposed to high glucose. Neurosci Lett, 440:27–31.
41.
AppellaE, AndersonCW. 2001. Post-translational modifications and activation of p53 by genotoixic stresses. Eur J Biochem, 268:2764–2772.
42.
BirdA. 2002. DNA methylation patterns and epigenetic memory. Genes Dev, 16:6–21.
43.
ZeiselSH. 2009. Importance of methyl donors during reproduction. Am J Clin Nutr, 89,suppl:673S–677S.
44.
BeaudinAE, AbarinovWV, NodenDM, PerryCA, ChuS, StablerSP, AllenRH, StoverPJ. 2011. Shmt1 and de novo thymidylate biosynthesis underlie folate-responsive neural tube defects in mice. Am J Clin Nutr, 93:789–798.
45.
RossEM. 2010. Gene-environment interactions, folate metabolism and the embryonic nervous system. Wiley Interdiscip Rev Syst Biol Med, 2:471–480.
46.
BurdgeGC, LillycropKA. 2010. Nutrition, epigenetics, and developmental plasticity: implications for understanding human disease. Annu Rev Nutr, 30:315–339.
47.
NamiharaM, KohyamaJ, AbematsuM, NakashimaK. 2008. Epigenetic mechanisms regulating fate specification of neural stem cells. Phil Trans R Soc B Biol Sci, 363:2099–2109.
48.
MarsitCJ, EddyK, KelseyKT. 2006. MicroRNA responses to cellular stress. Cancer Res, 66:10843–10848.
49.
SadlerTW. 2006. Third to eight weeks: The Embryonic period. Langman's Medical Embryology, 10thSadlerTW. Lippincott Williams & Wilkins: Philadelphia, 67–87.
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