Notch signaling is required for the maintenance of enteric neural crest progenitors

doi:10.1242/dev.022319

QUICK SEARCH:

[advanced]

	Author:		Keyword(s):

Home Help Feedback Subscriptions Archive Search Table of Contents

First published online 2 October 2008
doi: 10.1242/dev.022319

Development 135, 3555-3565 (2008)
Published by The Company of Biologists 2008

This Article

	Summary
	Figures Only
	Full Text (PDF)
	Supplementary Material
	All Versions of this Article: dev.022319v1 135/21/3555 most recent
	Alert me when this article is cited
	Alert me if a correction is posted

Services

	Email this article to a friend
	Similar articles in this journal
	Similar articles in PubMed
	Alert me to new issues of the journal
	Download to citation manager


Citing Articles

	Citing Articles via HighWire
	Citing Articles via Google Scholar

Google Scholar

	Articles by Okamura, Y.
	Articles by Saga, Y.
	Search for Related Content

PubMed

	PubMed Citation
	Articles by Okamura, Y.
	Articles by Saga, Y.


Social Bookmarking

	What's this?

Notch signaling is required for the maintenance of enteric neural crest progenitors

Yoshiaki Okamura¹ and Yumiko Saga¹^,2^,*

¹ Department of Genetics, SOKENDAI, 1111 Yata, Mishima, Shizuoka 411-8540, Japan.
² Division of Mammalian Development, National Institute of Genetics, Yata 1111, Mishima 411-8540, Japan.

^* Author for correspondence (e-mail: ysaga{at}lab.nig.ac.jp)

Accepted 8 September 2008

SUMMARY

TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Notch signaling is involved in neurogenesis, including thatof the peripheral nervous system as derived from neural crestcells (NCCs). However, it remains unclear which step is regulatedby this signaling. To address this question, we took advantageof the Cre-loxP system to specifically eliminate the proteinO-fucosyltransferase 1 (Pofut1) gene, which is a core componentof Notch signaling, in NCCs. NCC-specific Pofut1-knockout micedied within 1 day of birth, accompanied by a defect of entericnervous system (ENS) development. These embryos showed a reductionin enteric neural crest cells (ENCCs) resulting from premature neurogenesis.We found that Sox10 expression, which is normally maintainedin ENCC progenitors, was decreased in Pofut1-null ENCCs. Bycontrast, the number of ENCCs that expressed Mash1, a potentrepressor of Sox10, was increased in the Pofut1-null mouse.Given that Mash1 is suppressed via the Notch signaling pathway,we propose a model in which ENCCs have a cell-autonomous differentiatingprogram for neurons as reflected in the expression of Mash1,and in which Notch signaling is required for the maintenanceof ENS progenitors by attenuating this cell-autonomous programvia the suppression of Mash1.

Key words: Neural crest cells, Pofut1, Sox10, Mash1 (Ascl1), Wnt1-Cre

INTRODUCTION

TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The neural crest is a pluripotent cell population derived fromthe neural plate during the early stages of embryogenesis. Neuralcrest cells (NCCs) disperse from the dorsal surface of the neuraltube and migrate extensively throughout the embryo. This givesrise to a wide variety of differentiated cell types, includingneurons, glial cells, pigment cells, facial cartilage and bone,and connective tissues (Le Douarin et al., 2004). The fate ofindividual NCCs largely depends upon the locations to whichthey migrate. Some NCCs contribute to the enteric nervous system(ENS), which yields neurons and glial cells. The ENS arises fromvagal and sacral NCCs.

At E8.5, the vagal NCCs detach from the dorsal neural tube atsomite level 1-7, colonize the foregut at E9.5, then migratein a caudal direction and reach the rectum by E14 (Young etal., 1998). Sacral NCCs are delaminated from the neural tubethat is posterior to somite 28. Some of these cells give riseto pelvic ganglia, whereas others contribute to the ENS by colonizingthe hindgut in a caudal-rostral migratory path (Druckenbrod andEpstein, 2005; Kapur, 2000).

The ENS constitutes a part of the autonomic nervous system thatregulates peristalsis, secretion, blood supply and the immuneresponse in the intestinal tract. Defects in neural crest developmentare a significant cause of Hirschsprung disease in humans, whichis characterized by distal intestinal aganglionosis and whichoccurs about once in every 5000 live births (Swenson, 2002).Many genes, including Edn3, Ednrb, Sox10, Ret, Gfra1 and Gdnf,have been implicated in the pathogenesis of congenital megacolon,and these genes control the development of the ENS through theircoordinated activities (Barlow et al., 2003; Baynash et al.,1994; Enomoto et al., 1998; Herbarth et al., 1998; Hosoda etal., 1994; Schuchardt et al., 1994; Stanchina et al., 2006). Duringthe development of the ENS, the transcriptional regulator Sox10is essential for the maintenance of neural crest progenitors (Paratoreet al., 2002). The expression of Sox10, a member of the SRY-likeHMG-box family of transcription factors, is initiated in NCCswhen they detach from the neural tube and is maintained duringNCC migration. Eventually, Sox10 expression is turned off in theNCC derivatives, except for the glial and melanocyte lineages (Kuhlbrodtet al., 1998; Pusch et al., 1998). Two mutations of Sox10 havebeen examined in mice: a null mutation generated by targetedinsertion of lacZ (Sox10^lacZ), and a spontaneous mutation referredto as Dominant megacolon (Sox10^Dom) (Britsch et al., 2001; Herbarthet al., 1998; Southard-Smith et al., 1998). In the heterozygousstate, both mutants lack enteric ganglia in a variable lengthof the colon and exhibit pigmentation defects. Homozygous mutants displaysevere deficits in several neural crest derivatives, including completeabsence of the ENS (Britsch et al., 2001; Kapur, 1999). By contrast,the overexpression of Sox10 in neural crest stem cells (NCSCs)preserves both glial and neuronal differentiation potentials(Kim et al., 2003).

In addition to these mutants, it is known that Mash1 (Ascl1- Mouse Genome Informatics) mutant mice also show defects in ENSdevelopment. Mash1 encodes a member of the basic helix-loop-helix familyof transcriptional regulators and is a mammalian homolog ofthe Drosophila proneural genes of the achaete-scute complex; Mash1is expressed in both the central nervous system (CNS) and the peripheralnervous system and is induced by bone morphogenetic protein2 (Bmp2) in NCSCs (Shah et al., 1996). Mash1 mutant mice showdefects in the development of olfactory and peripheral autonomicneurons and a loss of part of the enteric neuron lineages (Blaugrundet al., 1996; Guillemot et al., 1993).

Notch is one of the transmembrane receptors activated by thejuxtacrine interactions of specific ligands with Notch receptors (Artavanis-Tsakonaset al., 1999). Once activated, the Notch receptors then undergoa series of proteolytic cleavages, resulting in the releaseof the Notch intracellular domain (NICD) (Mumm et al., 2000).Subsequently, the NICD translocates into the nucleus, associateswith the transcription factor RBP-J ${kappa}$ (Rbpj - Mouse Genome Informatics)to generate the transactivation complex, and thereby initiates thetranscription of target genes such as Hes1 (Kageyama et al.,2000). In addition to the four Notch receptors (Notch1-4) andfive ligands (delta-like 1, 3, 4 and jagged 1, 2) that havebeen identified in vertebrates, there are many auxiliary factorsthrough which Notch signaling is tightly regulated (Bray, 2006).One of these, protein O-fucosyltransferase 1 (Pofut1), whichtransfers O-fucose to Notch EGF repeats, is an essential componentof Notch signaling and functions upstream of NICD, where itregulates Notch-Delta interactions and trafficking of the Notchreceptor (Okajima and Irvine, 2002; Okajima et al., 2003; Okajimaet al., 2005; Okamura and Saga, 2008; Sasamura et al., 2007; Sasamuraet al., 2003; Shi and Stanley, 2003). Although Pofut1 is ubiquitouslyexpressed in the mouse, its removal leads to global Notch signalingdefects similar to those associated with the loss of RBP-Jk,the common mediator of Notch signaling in mice (Oka et al.,1995). This indicates that Pofut1 functions are largely restrictedto the Notch signaling pathway.

Notch signaling is involved in various aspects of neurogenesis.In the CNS it is essential for the maintenance of neural stemcells (Hitoshi et al., 2002). Transient activation of Notchsignaling is not sufficient to maintain NCSCs. Rather, it actspositively to promote switching from neurogenesis to gliogenesisin vitro (Morrison et al., 2000) and in vivo (Wakamatsu et al.,2000). In addition, Notch signaling regulates sympathetic neurondevelopment (Tsarovina et al., 2008), cardiac neural crest differentiation (Highet al., 2007), melanocyte development (Moriyama et al., 2006)and mesencephalic neural crest differentiation (Ijuin et al.,2008). However, little is known regarding the role of Notchsignaling in enteric neural crest development in vivo.

Here, we have examined the role of Notch signaling in the ENSby specifically eliminating the Pofut1 gene in NCCs. These Pofut1conditional knockout (cKO) embryos showed a reduction in entericneural crest cells (ENCCs) and premature neurogenesis, and thiswas accompanied by the loss of Sox10 expression and by an increasein the number of Mash1-positive ENCCs. These results suggestthat Notch signaling is necessary for the maintenance of entericneural crest progenitors via the regulation of Sox10 and Mash1expression.

MATERIALS AND METHODS

TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Mice and genotyping
The generation of a conditional allele of the Pofut1 locus has recentlybeen described (Okamura and Saga, 2008). The generation of CAG-CAT-EGFP,Wnt1-Cre and R26R reporter mice has also been reported (Ahmedet al., 2002; Chai et al., 2000; Jiang et al., 2000; Soriano,1999). Mouse tail or embryo yolk sac DNA was used for genotyping.Tissue samples were heated at 95°C for 5 minutes and thenincubated in 100 mM Tris (pH 8), 5 mM EDTA, 300 µg/mlproteinase K at 55°C overnight. After heat denaturationat 95°C for 5 minutes, tissue suspensions were used as PCRtemplates. PCR primers used for genotyping were as follows:Pofut1 mice, LA-4.9 (5'-CCATTGTGCGGTGCATTGTG-3'), cprb-L1 (5'-GCACTCTGGGGCTCTGCCGT-3')and SA-R0.01 (5'-CTGTACCCAGGCAAGTAGGG-3'); Wnt1-Cre mice, Cre1 (5'-GGACATGTTCAGGGATCGCCAGGCG-3')and Cre2 (5'-GCATAACCAGTGAAACAGCATTGCTG-3'); Rosa26 reporter,Rosa-2 (5'-GCGAAGAGTTTGTCCTCAACC-3'), Rosa-3 (5'-GGAGCGGGAGAAATGGATATG-3'),Rosa-4 (5'-AAAGTCGCTCTGAGTTGTTAT-3'); CAG-CAT-EGFP mice, CAT2 (5'-CAGTCAGTTGCTCAATGTACC-3'),CAT3 (5'-ACTGGTGAAACTCACCCA-3').

Histological analyses
Whole-mount X-Gal staining of embryos was as described (Sagaet al., 1992). The number of X-Gal-positive ENCCs was countedand quantified as the number per unit area (100 µm²).Whole-mount immunostaining using monoclonal anti-neurofilamentantibody 2H3 (Developmental Studies Hybridoma Bank) was performedas described previously (Matsuo et al., 1995). For section immunohistochemistry,embryos were fixed in 4% paraformaldehyde (PFA) in PBS at 4°C,cryoprotected in 30% sucrose in PBS at 4°C, embedded inOCT compound (Tissue-Tek) and sectioned (7 µm). The sectionswere blocked in PBS containing 10% normal donkey serum (Chemicon)for 1 hour at room temperature, then incubated overnight at4°C in a mixture of the following primary antibodies inblocking solution: anti-GFP (Nacalai Tesque), anti-activatedcaspase 3 (Cell Signaling Technology), anti-β-tubulin isotypeIII (TuJ1) (Sigma), anti-BFABP (a gift from T. Müller,Max-Delbruck Center, Berlin, Germany), anti-Sox10 (Santa CruzBiotechnology), anti-Hes1 (a gift from N. Brown, Cincinnati Children'sHospital Medical Center, Cincinnati, OH) and anti-Mash1 (BD Pharmingen).After washing, these were incubated with a mixture of AlexaFluor 488- and 594- (Molecular Probes) or Cy3- (Jackson Laboratories)conjugated secondary antibodies.

For BrdU labeling, pregnant mice were injected intraperitoneallywith BrdU (Sigma) at 10 mg/kg body weight and sacrificed 2 hourslater. Embryos were handled as described above and sectioned(7 µm). After blocking, these sections were incubatedovernight at 4°C in anti-GFP or anti-Sox10 antibody in blockingsolution. After washing, the samples were further incubatedwith Alexa Fluor 488-conjugated secondary antibody, washed inPBS and fixed in 4% PFA in PBS at 4°C. The specimens werethen placed in 2M HCl for 30 minutes at 37°C, then washedin PBS. After blocking, the sections were incubated with anti-BrdUantibody (Sigma), washed in PBS and incubated with Cy3-conjugatedsecondary antibody.

For double staining using immunohistochemistry and in situ hybridization, frozensections (12 µm) were incubated with anti-p75^NTR primary antibody(1:200, Promega) for the detection of ENCCs, followed by a biotinylatedgoat anti-rabbit IgG secondary antibody (1:200, Vector Laboratories).These sections were then hybridized with digoxigenin (DIG)-labeledantisense cRNA probes (Roche). The hybridized probes were detectedusing horseradish peroxidase-conjugated anti-DIG sheep antibody (Roche)and Cyanine 3-Tyramid Signal Detection Reagent (Perkin Elmer). p75^NTRwas detected using horseradish peroxidase-conjugated Streptavidin(Roche) and fluorescein isothiocyanate-conjugated Tyramid signal detection(Perkin Elmer). Sections were counterstained with 0.5 µg/ml 4',6-diamino-2-phenylindole(DAPI) for 10 minutes and examined using a scanning-laser confocalimaging system (Zeiss LSM510) or with an Olympus BX61 fluorescencemicroscope system with an ORCA-ER digital camera (Hamamatsu Photo).Subsequent analysis was performed using MetaMorph software (Universal Imaging).More than six sections from the stomach or intestine regionsof three different embryos were counted in each experiment.Statistical analysis was performed using a Student's t-test.Differences were considered to be significant if the P-valuewas less than 0.05.

RESULTS

TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Targeted disruption of the Pofut1 gene in mouse neural crest cells
To achieve a conditional deletion of the Pofut1 locus in NCCs,we employed Wnt1-Cre transgenic mice that express Cre recombinaseunder the control of the Wnt1 promoter. The Cre recombinaseis active in the early migratory neural crest population ofthese mice at all axial levels (Chai et al., 2000; Jiang etal., 2000). We also utilized the Rosa26 reporter (R26R) andCAG-CAT-EGFP, which mark the Cre-expressed cell lineages viaβ-galactosidase and EGFP expression, respectively, afterCre-mediated excision of a floxed PGK-neo or CAT cassette. Togenerate a Pofut1 deficiency in mouse NCCs, we crossed Pofut1^+/-;Wnt1-Cre mice with Pofut1^flox/flox mice harboring a R26R or CAG-CAT-EGFPallele. From this cross, we obtained two genotypes: Pofut1^+/^flox;Wnt1-Cre (R26R or CAG-CAT-EGFP), referred to hereafter as control;and Pofut1^-/^flox; Wnt1-Cre (R26R or CAG-CAT-EGFP), referredto as Pofut1 cKO.

The Pofut1 cKO mice died within 1 day of birth, but showed no obviousmorphological abnormalities other than a relatively small bodysize (Fig. 1A). However, 18/20 newborn Pofut1 cKO mice had nomilk in their stomachs (Fig. 1A, arrowheads). Since NCCs contributeto the formation of the ENS, we speculated that this phenotype mightbe due to defective ENS development. We examined enteric neuronal developmentin the gastrointestinal tract using anti-neurofilament antibody 2H3,which labels both extrinsic and intrinsic nerve fibers. Theganglion structure of the ENS was disrupted and dispersed andthe nerve bundles in the Pofut1 cKO embryos were relativelythick by comparison with the dense reticulate pattern of theenteric ganglia in the control embryos (Fig. 1B-E). These results suggestthat Notch signaling participates in ENS development.

View larger version (92K):
[in this window]
[in a new window]

Fig. 1. Defects of the NCC-specific Pofut1-knockout mouse. (A) External morphology of control and Pofut1 cKO mice at postnatal day 1 (P1). The Pofut1 cKO mouse is relatively small, but otherwise shows no apparent morphological defects. Arrowheads indicate the stomach. (B-E) Immunostaining of the gastrointestinal tract at E16.5 in control (B,C) and Pofut1 cKO (D,E) embryos with the anti-neurofilament antibody 2H3.

View larger version (80K):
[in this window]
[in a new window]

Fig. 2. Lineage analysis of ENCCs. Enteric neural crest lineages were traced using β-galactosidase activity from E10.5 to E13.5 in control (A-D) and Pofut1cKO (E-H) mouse embryos by crossing Pofut1^+/-;Wnt1-Cre and Pofut1^flox^/^flox;R26R mice. The gastrointestinal tracts are outlined (dashed lines). Arrowheads (A,E) indicate migratory wavefront of ENCCs. st, stomach; ca, cecum.

Embryos lacking Pofut1 in NCCs show a reduction in post-migratory enteric neural crest cells
We examined enteric neural crest development by lineage tracingwith lacZ in R26R reporter mice (Fig. 2). In control;R26R embryos,the ENCCs migrated to and colonized the foregut at around E9.5,then continued to migrate through the gut mesenchyme in a caudaldirection, completing their migration at around E14 (Fig. 2A-D).Similar to control;R26R embryos, the ENCCs in Pofut1 cKO;R26R embryoscolonized the foregut and migrated to the hindgut by E11.5 (Fig. 2E,F).However, the number of ENCCs in these embryos was greatly reducedafter E12.5 (Fig. 2G,H). Compared with control embryos, thenumber of ENCCs at E12.5 was estimated to be reduced to $~$ 53%in the stomach, $~$ 47% in the foregut and $~$ 49% in the midgut andhindgut. Interestingly, specific regions in Pofut1 cKO;R26Rembryos showed a slightly elevated number of ENCCs as comparedwith other regions (see Fig. S1 in the supplementary material).In spite of their reduction in Pofut1 cKO;R26R embryos, the ENCCsmigrated on a normal timetable and contributed throughout the gastrointestinaltract by E14 (Fig. 2E-H), indicating that ENCC migration isnot overtly disrupted by the loss of Pofut1. Hence, Pofut1 cKOembryos exhibited an abnormal ENS network, for which a reductionin the number of ENCCs appeared responsible.

The decreased proliferation of ENCCs is partly responsible for their reduced number in Pofut1 cKO embryos
To determine the underlying cause of the reduction of ENCCsin Pofut1 cKO embryos, we examined the apoptotic and proliferation statusof these cells (Fig. 3). For this analysis, we used a CAG-CAT-EGFPreporter to facilitate the immunohistological detection of ENCCsamong other molecular markers. Apoptotic cells were not observedin control or Pofut1 cKO ENCCs at E11.5 and E12.5 (Fig. 3A-H).This indicates that the loss of ENCCs in Pofut1 cKO embryosis not due to an increase in apoptosis. However, our data donot exclude the possibility that non-apoptotic cell death contributesto the loss of ENCCs, as it has recently been shown that theconditional ablation of Gfra1 in mouse induces a loss of entericNCCs via a caspase-independent mechanism (Uesaka et al., 2007).

View larger version (115K):
[in this window]
[in a new window]

Fig. 3. Detection of apoptosis and proliferation in ENCCs. (A-H) Immunohistological analysis of control (A-D) and Pofut1 cKO (E-H) mouse embryos using anti-caspase 3 (red) and anti-GFP (green) antibodies to visualize apoptotic cells and ENCCs, respectively, at E11.5 (A,B,E,F) and E12.5 (C,D,G,H). (I-P) Immunohistological analysis of control (I-L) and Pofut1 cKO (M-P) embryos using anti-BrdU (red) and anti-GFP (green) antibodies to visualize proliferating cells and ENCCs, respectively, at E11.5 (I,J,,M,N) and E12 (K,L,O,P). Arrowheads indicate proliferating ENCCs. (Q,R) Quantitation of ENCC proliferation at E11.5 (Q) and E12.5 (R). Average percentages of BrdU-incorporating ENCCs are shown with s.d. ns, not significant.

We next examined proliferating cells in the gastrointestinaltract by BrdU-incorporation analyses at E11.5 and E12.5. Theproliferation rate of ENCCs in Pofut1 cKO embryos was foundto be significantly reduced in the intestinal tract at E12.5(Fig. 3I-R). Interestingly, consistent with the observationthat slightly increased numbers of ENCCs exist in the stomachand cecum (see Fig. S1 in the supplementary material), the proliferatingENCCs in Pofut1 cKO embryos at E12.5 were mainly located inthe stomach and in the vicinity of the cecum, whereas thesecells were uniformly detected throughout the gastrointestinaltract in control embryos (Fig. 3K,L,O,P; see Fig. S2 in thesupplementary material). These regions are known to be sourcesof Gdnf and Edn3 (Burns and Thapar, 2006

). Gdnf is known topromote the proliferation of ENS progenitors (Chalazonitis etal., 1998

; Hearn et al., 1998

; Heuckeroth et al., 1998

; Taraviraset al., 1999

), although the role of Edn3/Ednrb signaling remainscontroversial (Bondurand et al., 2006

; Kruger et al., 2003

).In either case, the localized proliferation we observed in Pofut1cKO embryos might well be influenced by such factors. Furthermore,despite their significant reduction in number, NCCs still contributedto development throughout the gastrointestinal tract in Pofut1cKO embryos. This is likely to be due to the presence of a fewproliferating ENCCs. Our results thus suggest that the lossof ENCCs in Pofut1 cKO embryos might be partially, althoughnot solely, due to a decrease in their proliferation.

ENCCs lacking Pofut1 show premature neurogenesis and a decrease in the number of glial progenitors
Since the decreased number of ENCCs in Pofut1 cKO embryos could alsobe explained by premature differentiation, we examined the differentiationstatus of ENCCs in these embryos using the post-mitotic neuron markerTuJ1 (Tubb3 - Mouse Genome Informatics) (Fig. 4). It has beenreported that ENCCs produce neurons and glia during their migration.About 10-15% of the ENCC population commences differentiationinto neurons at E10.5, and this gradually increases to $~$ 25% byE12.5 (Young et al., 2002). As reported previously, differentiationwas already detected at E10.5 (8% in the intestine), and increasedto $~$ 37% by E11.5 in our control embryos (Fig. 4A-C,I,J). By contrast, althoughthe proportion of Tuj1-positive cells in the Pofut1 cKO embryoswas not significantly different from that of control embryosat E10.5 (Fig. 4D,I), differentiation was strongly induced thereafterin $~$ 77% of the ENCCs in the Pofut1 cKO embryos at E12.5 (Fig. 4F).Premature neurogenesis could already be observed at E11.5 (Fig. 4E,J),which is before a reduction in the number of these cells wasdetectable (Fig. 2C,G).

View larger version (58K):
[in this window]
[in a new window]

Fig. 4. Neuronal and glial differentiation of ENCCs. Immunohistochemical analysis of control (A-C,G) and Pofut1 cKO (D-F,H) mouse embryos with anti-TuJ1 (red) and anti-GFP (green) antibodies to visualize neuronal cells and ENCCs, respectively, at E10.5-12.5 (A-F), or with anti-BFABP (magenta) and anti-GFP (green) antibodies to visualize glial progenitors and ENCCs, respectively, at E11.5 (G,H). Arrowheads (G,H) indicate BFABP-positive ENCCs. (I,J) Quantitation of neuronal differentiation at E10.5 (I) and E11.5 (J). Average percentages of TuJ1-positive ENCCs are shown with s.d. (K) Quantitation of glial differentiation at E11.5. Average percentages of BFABP-positive ENCCs are shown with s.d.

In addition to neural differentiation, glial differentiationwas examined using an anti-BFABP (Fabp7 - Mouse Genome Informatics)antibody (Fig, 4G,H,K), which is a marker for glial progenitors.Glial differentiation is initiated around E11.5 (Young et al.,2003

). In Pofut1 cKO embryos, however, the generation of glialprogenitors was reduced at E11.5 (Fig. 4H,K). Therefore, prematureneuronal differentiation is likely to be the major reason forthe observed reduction in the ENCC number in the Pofut1 cKO embryos.Hence, we speculated that this premature differentiation mightbe due to a defect in the maintenance of progenitor cells, whichwould indicate that Notch signaling is required for the maintenanceof ENS progenitors.

Notch signaling is required for the maintenance of Sox10 expression in ENCCs
We next addressed the question of how Notch signaling regulatesthe pluripotency of ENS progenitors by analyzing the expressionof Sox10, which is essential for the maintenance of neural crestprogenitors during ENS development (Bondurand et al., 2006;Paratore et al., 2002). The Sox10 expression profile did notdiffer significantly between control and Pofut1 cKO embryosat E10.5 (Fig. 5A,B,E,F,I). However, the number of ENCCs expressingSox10 was significantly reduced, to $~$ 22% of the total population(in the intestine), in Pofut1 cKO embryos at E11.5 (Fig. 5G,H,J).By contrast, Sox10 expression was observed in 62% of ENCCs (inthe intestine) in control embryos (Fig. 5C,D). After E12.5,however, virtually no ENCCs expressed Sox10 in Pofut1 cKO embryos(data not shown). This suggests that Notch signaling is necessaryfor the maintenance of Sox10 expression in ENCCs after E11.5.

To investigate the relationship between the decrease in Sox10expression and the proliferative ability of ENCCs, we examinedthe proliferation rate of Sox10-positive ENCCs. At E11.5, thisdid not differ significantly between Pofut1 cKO (11% in thestomach and the intestine) and control (10% in the stomach,14% in the intestine) embryos (Fig. 5K). The proliferation rateof Sox10-negative ENCCs, estimated from that of total ENCCsand Sox10-positive ENCCs (Fig. 3Q and Fig. 5J), was $~$ 26% in thestomach and $~$ 30% in the intestine of control embryos, but only $~$ 14%in the stomach and $~$ 16% in the intestine of Pofut1 cKO embryos.Although these are only estimates of the proliferation rate,the rate for Sox10-negative ENCCs was nonetheless significantlyreduced in Pofut1 cKO embryos. Since Sox10-negative ENCCs mayrepresent cells committed to the neural lineage, these resultssuggest that proliferation defects are indeed secondary to thepremature appearance of cells committed to the neural lineage.Hence, the decreased proliferation and premature neurogenesisobserved in Pofut1 cKO embryos are likely to be a consequenceof the downregulation of Sox10 expression, which could thenlead to a diminished progenitor population that eventually resultsin the loss of NCCs after E12.5. However, it was reported recentlythat Edn/Ednrb signaling is also required for the maintenanceof ENS progenitors (Bondurand et al., 2006) and that the expressionof Ednrb in ENCCs is regulated by Sox10 (Zhu et al., 2004).In this context, it is noteworthy that we observed impairedEdnrb expression in Pofut1 cKO embryos (see Fig. S3 in the supplementary material), whichis consistent with the downregulation of Sox10 expression inthese embryos. Hence, the progenitor maintenance defect in thePofut1 cKO embryo might also be due to the loss of Edn/Ednrbsignaling.

View larger version (60K):
[in this window]
[in a new window]

Fig. 5. Downregulation of Sox10 in Pofut1-null ENCCs. (A-H) Immunohistological detection of Sox10 (red) expression within ENCCs (green) in control (A-D) and Pofut1 cKO (E-H) mouse embryos at E10.5 (A,B,E,F) and E11.5 (C,D,G,H). (I,J) Quantitation of Sox10-positive cells at E10.5 (I) and E11.5 (J). Average percentages of Sox10-positive ENCC cells are shown with s.d. (K) Quantification of the proliferation rate in Sox10-positive ENCCs at E11.5. Average percentages of BrdU incorporation in proliferating Sox10-positive ENCC cells are shown with s.d. ns, not significant.

Expression patterns of Notch receptors and ligands in ENCCs
Since the downregulation of Sox10 expression was observed atE11.5 in Pofut1 cKO embryos, we speculated that Notch signalingmight be activated at around E11.5. However, there have beenno previous reports regarding the involvement of Notch ligandsor their receptors in ENCC development. We examined the expressionof all the known Notch receptors and ligands (Notch1-4, Dll1,Dll3, Dll4, Jag1 and Jag2) by in situ hybridization (Fig. 6). Theexpression of these factors in ENCCs was confirmed by immunohistochemistry withthe NCC marker p75^NTR (Ngfr - Mouse Genome Informatics) concomitantwith in situ hybridization analysis (see Materials and methods). Notch1,Notch4, Dll1, Dll3, Dll4 and Jag1 were found to be expressedin the gastrointestinal tract. A number of ENCCs expressed Notch1,Dll1 and Dll3, but only a few expressed Notch4, Dll4 and Jag1(Fig. 6; see Fig. S4 in the supplementary material).

Since ENCCs are known to migrate within the gut mesenchyme aschains of cells (Druckenbrod and Epstein, 2005; Young et al., 2004),we speculated that Notch signaling might be activated throughcell-cell contact among NCCs. This idea might be supported byour current finding that both Notch receptors and ligands areexpressed in ENCCs. However, some other cell types neighboringthe ENCCs were also found to express Dll4 and Jag1 (Fig. 6;see Fig. S4 in the supplementary material) and the activationof Notch signaling through neighboring cells might thereforealso occur. To investigate ligand redundancy and Notch activationthrough neighboring cells, we examined Sox10 expression in Dll1mutant embryos. Dll1 mutant embryos did not show clear downregulationof Sox10 expression in post-migratory ENCCs at E11.5 (see Fig.S5 in the supplementary material), indicating that other ligandsmight also be functional during the maintenance of ENS progenitors.

Regulatory mechanism of Sox10 maintenance
A question that arises from our current data is how Notch signaling regulatesSox10 expression. We speculated that Sox10 might be a directtarget of Notch signaling. However, it has been shown that asubset of NCCs expressing Sox10 induces Mash1, which in turnrepresses Sox10 (Kim et al., 2003). In addition to this negative-feedbackmechanism, Mash1 is known to be repressed by Hes1, one of thetargets of Notch signaling in the CNS (Chen et al., 1997). These relationshipsgive rise to the possibility that Sox10 expression is maintained bythe repression of Mash1 through Notch signaling. This likelihoodcan be further evaluated by examining Hes1 and Mash1 expression.

If Notch signaling directly activates Sox10 expression, we predictedthat Mash1 expression would not be altered or downregulatedin Pofut1 cKO embryos. However, if Notch signaling maintainsSox10 expression by suppressing Mash1 via Hes1, then Hes1 expressionwould be expected to be downregulated and Mash1 expression tobe upregulated in the Pofut1 cKO mice. We examined these expressionpatterns in the ENS at E10.5, before premature neurogenesisoccurs, in Pofut1 cKO embryos (Fig. 7). In control embryos, Hes1expression was observed in $~$ 16% of ENCCs in the intestine andalso in other non-ENCCs (Fig. 7A-C). By contrast, Hes1 expressionin ENCCs was found to be downregulated to $~$ 7% of the total populationin the intestine of Pofut1 cKO embryos (Fig. 7D-F,M). Mash1expression is restricted in ENCCs and $~$ 48% of ENCCs were indeedfound to be Mash1-positive in the intestine of control embryosat this stage (Fig. 7G-I). However, Mash1-positive ENCCs weresignificantly increased in Pofut1 cKO embryos (up to $~$ 70% ofthe intestinal population) (Fig. 7J-L,N), indicating that Notchsignaling indirectly regulates Sox10 expression through thesuppression of Mash1.

View larger version (116K):
[in this window]
[in a new window]

Fig. 6. Expression of Notch signaling genes in the mouse gastrointestinal tract. In situ hybridizations were performed using RNA probes against Notch1, Notch4, Dll1, Dll3, Dll4 and Jag1 (magenta), together with the immunohistological detection of NCCs using an anti-p75^NTR antibody (green) in E11.5 stomach and intestine. Open arrowheads indicate expression in ENCCs, and solid arrowheads indicate expression in neighboring cells. The boxed regions are shown at high magnification in the right-hand panel of each pair.

To confirm this scenario, we performed double-immunostainingexperiments for Sox10 and Mash1 (Fig. 8) and from their expressionpatterns the ENCCs were classified into three populations: Sox10or Mash1 single-positive, and Sox10/Mash1 double-positive. Incontrol embryos, the Sox10/Mash1 double-positive ENCCs (58%of the population in the intestine) were observed from E10.5and continually thereafter during embryogenesis (data not shown),but the proportion of Mash1 single-positive cells was low (12%in the intestine) compared with that of Sox10 single-positivecells (30% in the intestine) (Fig. 8C). As expected, however,in Pofut1 cKO embryos, the abundance of Mash1 single-positiveENCCs was increased (28% in the intestine) and Sox10 single-positiveENCCs were decreased (13% in the intestine) (Fig. 8F,G). Theproportion of Sox10/Mash1 double-positive progenitor cells wasnot significantly different between the control (58% in theintestine) and Pofut1 cKO (59% in the intestine) embryos (Fig. 8G), indicatingthat Notch signaling may not participate in the induction ofMash1 expression itself. Hence, Notch signaling appears to regulatethe population of Mash1 single-positive ENCCs and be requiredfor the maintenance of enteric neural crest progenitors viathe regulation of a Sox10/Mash1 expression balance. Importantly,the balance of transcription factor expression in Pofut1 cKOembryos was found to have shifted at E10.5, which is prior tothe occurrence of the premature differentiation observed onlyafter E11.5. This may indicate that the decrease in the proliferationrate in Pofut1 cKO embryos is secondary to the premature appearanceof ENCCs that are committed to the neuronal lineage. In otherwords, altering the balance of expressed transcription factorsat E10.5, which results in the upregulation of Mash1, may causepremature differentiation and a decrease in proliferation atE11.5 and, eventually, a reduction in the number of ENCCs at E12.5.

View larger version (88K):
[in this window]
[in a new window]

Fig. 7. ENCCs expressing Hes1 are decreased, whereas those expressing Mash1 are increased, in the Pofut1 cKO embryo. Immunohistological analysis of control (A-C,G-I) and Pofut1 cKO (D-F,J-L) mouse embryos at E10.5 using antibodies against Hes1 (A,C,D,E, magenta), Mash1 (G,I,J,L, magenta) and GFP (B,C,E,F,H,I,K,L, green). Arrowheads indicate Hes1-positive or Mash1-positive ENCCs in control (C,I) and Pofut1 cKO (F,L) embryos. (M,N) Quantification of Hes1-positive ENCCs (M) and Mash1-positive ENCCs (N) at E10.5. Average percentages of the total ENCC cell population expressing each gene are shown with s.d.

	DISCUSSION

TOP SUMMARY INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

We performed a comprehensive series of expression analyses inthe Pofut1 cKO mouse in combination with a lineage tracer anddemonstrate that Notch signaling plays a crucial role duringENS development in vivo. In general, this strategy can addressthe function of Notch signaling in all neural crest derivatives.Mice lacking Pofut1 in NCCs had a slightly smaller body sizethan their control littermates. This was probably caused bya defect in a subset of the neural crest derivatives in whichNotch signaling plays some role. However, the Pofut1 cKO embryosdid not exhibit obvious abnormalities in regions such as thecraniofacial structures and heart arteries. Hence, the smallerbody size might be a secondary effect of Notch signaling impairmentin neural crest derivatives that were not included in our currentanalysis.

Phenotypic variation in mutants showing defective ENS development
Mice lacking Pofut1 in their NCCs showed a reduction in ENCCsat E12.5, although these cells retained their capacity to contributeto development throughout the gastrointestinal tract. This phenotypeappears to be different from the defects observed in mouse modelsof human congenital megacolon (Hirschsprung disease), includingSox10, Edn3, Ednr, Gdnf, Ret and Gfra1 knockout mice (Enomotoet al., 1998; Herbarth et al., 1998; Schuchardt et al., 1994;Southard-Smith et al., 1998; Stanchina et al., 2006). Each ofthese mutant mice shows a complete loss of enteric neurons inthe gut region that is distal to the stomach. In addition, someof them, including Gdnf, Ret and Gfra1 knockout mice, show milk intheir esophagus but die within 1 day of birth.

View larger version (79K):
[in this window]
[in a new window]

Fig. 8. Comparative analysis of ENCCs expressing Mash1 and Sox10. Immunohistological analysis of control (A-C) and Pofut1 cKO (D-F) mouse embryos at E10.5 using antibodies against Mash1 (A,C,D,F, green) and Sox10 (B,C,E,F, red). Arrowheads indicate Mash1 single-positive ENCCs, and arrows indicate Sox10 single-positive ENCCs. (G) Statistical analyses of Mash1-single positive, Sox10-single positive or Mash1/Sox10 double-positive cells at E10.5. Average percentages of the ENCC progenitor population expressing Mash1 or Sox10 are shown with s.d.

It has been reported that Mash1-null mutants also die within1 day of birth but without milk in their stomachs (Guillemotet al., 1993

). Interestingly, Mash1 mutants lack neurons inthe esophagus but possess these cells in the stomach and intestine.There might be a correlation, therefore, between milk in thestomach and the presence of neurons in the esophagus. However,Pofut1 cKO embryos, in which neurons are present in the esophagus,but are reduced in number in the stomach and intestine, hadno milk in their stomach. The reason for this is currently unknown.

Relationship between Notch signaling and glial development in the ENS
Recently, experiments that are similar to those of our currentstudy were conducted using RBP-Jk^flox and Wnt1-Cre mice. The authorsof this earlier study concluded that Notch signaling promotes gliogenesisin the ENS, based upon their finding that neurogenesis was less affected,but gliogenesis severely affected, by the gene knockout (Tayloret al., 2007). This apparent inconsistency with our currentdata might be due to differences in the methods used and inthe time windows analyzed, as we obtained results similar tothose reported here when we performed comparable experimentsusing RBP-Jk^flox and Wnt1-Cre mice (data not shown). We alsoemployed a linage tracer to analyze specific gene expressionpatterns in ENCCs, and this might have affected the interpretationof results even though similar probes were used. In our lineageanalysis, we observed a clear reduction in the number of ENCCsat E12.5 in Pofut1 cKO embryos (Fig. 2). However, Taylor et al.(Taylor et al., 2007) counted differentiated ENCCs in RBP-JkcKO embryos at E10.5, E14.5 and E18.5, by which time decreasedproliferation and any premature neurogenesis occurring at E11.5could have been missed. Since Sox10 is expressed not only inthe ENS progenitors, but also in the glial cell lineage, thedownregulation of Sox10 expression observed in the Pofut1 cKO embryoat E11.5 must lead to the loss of glial progenitors thereafter.Hence, we support the notion that both the maintenance of ENSprogenitors and the formation of glial progenitors are accountedfor by the maintenance of Sox10 expression. Taken together,we conclude from the available data, including our current results,that Notch signaling is required for the maintenance of ENS progenitorsrather than for the promotion of glial cell differentiation.

A model for the mechanism underlying the maintenance of ENS progenitors
The ENCCs in Pofut1 cKO embryos exhibited premature differentiationwithout increased apoptosis and with a slight decrease in proliferationduring ENS development. These results suggest that Notch signalingis necessary for the maintenance of ENS progenitors. Since this findingis consistent with a role for Notch signaling in the CNS, itmay well reflect a common role for Notch during neurogenesis.

View larger version (22K):
[in this window]
[in a new window]

Fig. 9. A hypothetical model for the function of Notch signaling during mouse ENS development. The NCCs begin to express Sox10 when they detach from the neural tube at around E8.5. After arriving at the foregut (E9.5), a subset of the NCCs begins to express Mash1. In turn, Mash1 suppresses Sox10 expression, and Mash1-positive cells then eventually produce neurons. The remaining NCCs continue to express Sox10 to maintain the pool of ENS progenitors. Notch signaling might be required for the continuous expression of Sox10 by suppressing Mash1. TC cells, transient catecholaminergic cells (see Discussion).

Previous studies have shown that the lack of some progenitorsor neurons is simply explained by the lack of particular transcriptionfactors, which include the maintenance of NCC progenitors bySox10 and the induction of some of the enteric neuron lineagesby Mash1. However, our current study demonstrates for the firsttime that progenitor maintenance and the subsequent differentiationof ENCCs are regulated by the balance of Sox10 and Mash1 expression,which might enable a continuous derivation of mature neuronswhile maintaining a constant progenitor population. We alsodemonstrate herein that Notch signaling plays a crucial rolein maintaining this balance by suppressing Mash1 expression(Fig. 9).

Further interesting aspects of Mash1-expressing cells have emergedfrom previous studies. In the developing gut, catecholaminergic(TC) cells have been transiently detected and are thought tobe the precursors of a subset of enteric neurons as they showproliferative ability (Baetge et al., 1990). Both the selectiveelimination of TC cells and a Mash1-null mutation prevent thegeneration of a subset of enteric neurons. However, the remainingENCCs can still produce another class of enteric neurons (Blaugrundet al., 1996). From this observation, it has been proposed thatthe ENS comprises two progenitor populations. One comprisesthe TC cells that give rise to early-born enteric neurons viaa Mash1-dependent pathway, and the other contains a populationof non-TC cells that generate late-born enteric neurons viaa Mash1-independent pathway (Blaugrund et al., 1996). Sincethe ENCCs that express Sox10 are a cell population that is distinctfrom TC cells (Young et al., 2002), this suggests that non-TCcells can be formed by a Sox10-dependent pathway. In addition,Sox10/Mash1 double-positive ENCCs were observed in control embryosthroughout embryogenesis (Fig. 8 and data not shown). Hence,it is intuitive that the expression of these transcription factorsmust be balanced in ENCCs, even though one of the functionsof Mash1 is to suppress Sox10 expression. We speculate thatNotch signaling is involved in regulating the balance betweenSox10 and Mash1 expression, which may in turn generate two progenitorpopulations, one Mash1-dependent and the other Sox10-dependent (Fig. 9).

Although many genes involved in ENS development have been identifiedin recent years, their regulatory mechanisms and the relationshipsbetween the different gene functions remain poorly understood.Our current study provides new insights into these pathwaysby demonstrating that the cellular properties of ENCCs are regulatedby a cell-cell communication mechanism that is mediated by Notchsignaling. Further analyses of the molecular mechanisms underlying thiscell-cell communication might provide a more precise understandingof the developmental processes within the ENS that might beapplied in future therapeutic strategies against Hirschsprungdisease.

Supplementary material
Supplementary material for this article is available at http://dev.biologists.org/cgi/content/full/135/21/3555/DC1

ACKNOWLEDGMENTS

We thank A. McMahon for providing the Wnt1-Cre mice; T. Müllerand N. Brown for generously donating the antibodies againstBFABP and Hes1, respectively; and our colleagues who providedcDNA probes, including R. A. Conlon (Notch1), T. A. Mitsiadis(Jag1), T. Gridley (Notch4, Jag2) and M. Hirashima (Dll4). Thiswork was supported in part by Grants-in-Aid for Scientific Researchon Priority Areas, Dynamics of Extracellular Environments, andfor the National BioResource Project from the Ministry of Education,Culture, Sports, Science and Technology, Japan.

REFERENCES

TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Ahmed, F., Wyckoff, J., Lin, E. Y., Wang, W., Wang, Y., Hennighausen, L., Miyazaki, J., Jones, J., Pollard, J. W., Condeelis, J. S. et al. (2002). GFP expression in the mammary gland for imaging of mammary tumor cells in transgenic mice. Cancer Res. 62,7166 -7169.[Abstract/Free Full Text]
Artavanis-Tsakonas, S., Rand, M. D. and Lake, R. J. (1999). Notch signaling: cell fate control and signal integration in development. Science 284,770 -776.[Abstract/Free Full Text]
Baetge, G., Schneider, K. A. and Gershon, M. D. (1990). Development and persistence of catecholaminergic neurons in cultured explants of fetal murine vagus nerves and bowel. Development 110,689 -701.[Abstract/Free Full Text]
Barlow, A., de Graaff, E. and Pachnis, V. (2003). Enteric nervous system progenitors are coordinately controlled by the G protein-coupled receptor EDNRB and the receptor tyrosine kinase RET. Neuron 40,905 -916.[CrossRef][Medline]
Baynash, A. G., Hosoda, K., Giaid, A., Richardson, J. A., Emoto, N., Hammer, R. E. and Yanagisawa, M. (1994). Interaction of endothelin-3 with endothelin-B receptor is essential for development of epidermal melanocytes and enteric neurons. Cell 79,1277 -1285.[CrossRef][Medline]
Blaugrund, E., Pham, T. D., Tennyson, V. M., Lo, L., Sommer, L., Anderson, D. J. and Gershon, M. D. (1996). Distinct subpopulations of enteric neuronal progenitors defined by time of development, sympathoadrenal lineage markers and Mash-1-dependence. Development 122,309 -320.[Abstract]
Bondurand, N., Natarajan, D., Barlow, A., Thapar, N. and Pachnis, V. (2006). Maintenance of mammalian enteric nervous system progenitors by SOX10 and endothelin 3 signalling. Development 133,2075 -2086.[Abstract/Free Full Text]
Bray, S. J. (2006). Notch signalling: a simple pathway becomes complex. Nat. Rev. Mol. Cell Biol. 7, 678-689.[CrossRef][Medline]
Britsch, S., Goerich, D. E., Riethmacher, D., Peirano, R. I., Rossner, M., Nave, K. A., Birchmeier, C. and Wegner, M. (2001). The transcription factor Sox10 is a key regulator of peripheral glial development. Genes Dev. 15, 66-78.[Abstract/Free Full Text]
Burns, A. J. and Thapar, N. (2006). Advances in ontogeny of the enteric nervous system. Neurogastroenterol. Motil. 18,876 -887.[CrossRef][Medline]
Chai, Y., Jiang, X., Ito, Y., Bringas, P., Jr, Han, J., Rowitch, D. H., Soriano, P., McMahon, A. P. and Sucov, H. M. (2000). Fate of the mammalian cranial neural crest during tooth and mandibular morphogenesis. Development 127,1671 -1679.[Abstract]
Chalazonitis, A., Rothman, T. P., Chen, J. and Gershon, M. D. (1998). Age-dependent differences in the effects of GDNF and NT-3 on the development of neurons and glia from neural crest-derived precursors immunoselected from the fetal rat gut: expression of GFRalpha-1 in vitro and in vivo. Dev. Biol.. 204,385 -406.[CrossRef][Medline]
Chen, H., Thiagalingam, A., Chopra, H., Borges, M. W., Feder, J. N., Nelkin, B. D., Baylin, S. B. and Ball, D. W. (1997). Conservation of the Drosophila lateral inhibition pathway in human lung cancer: a hairy-related protein (HES-1) directly represses achaete-scute homolog-1 expression. Proc. Natl. Acad. Sci. USA 94,5355 -5360.[Abstract/Free Full Text]
Druckenbrod, N. R. and Epstein, M. L. (2005). The pattern of neural crest advance in the cecum and colon. Dev. Biol. 287,125 -133.[CrossRef][Medline]
Enomoto, H., Araki, T., Jackman, A., Heuckeroth, R. O., Snider, W. D., Johnson, E. M., Jr and Milbrandt, J. (1998). GFR alpha1-deficient mice have deficits in the enteric nervous system and kidneys. Neuron 21,317 -324.[CrossRef][Medline]
Guillemot, F., Lo, L. C., Johnson, J. E., Auerbach, A., Anderson, D. J. and Joyner, A. L. (1993). Mammalian achaete-scute homolog 1 is required for the early development of olfactory and autonomic neurons. Cell 75,463 -476.[CrossRef][Medline]
Hearn, C. J., Murphy, M. and Newgreen, D. (1998). GDNF and ET-3 differentially modulate the numbers of avian enteric neural crest cells and enteric neurons in vitro. Dev. Biol.. 197,93 -105.
Herbarth, B., Pingault, V., Bondurand, N., Kuhlbrodt, K., Hermans-Borgmeyer, I., Puliti, A., Lemort, N., Goossens, M. and Wegner, M. (1998). Mutation of the Sry-related Sox10 gene in Dominant megacolon, a mouse model for human Hirschsprung disease. Proc. Natl. Acad. Sci. USA 95,5161 -5165.[Abstract/Free Full Text]
Heuckeroth, R. O., Lampe, P. A., Johnson, E. M. and Milbrandt, J. (1998). Neurturin and GDNF promote proliferation and survival of enteric neuron and glial progenitors in vitro. Dev. Biol.. 200,116 -129.
High, F. A., Zhang, M., Proweller, A., Tu, L., Parmacek, M. S., Pear, W. S. and Epstein, J. A. (2007). An essential role for Notch in neural crest during cardiovascular development and smooth muscle differentiation. J. Clin. Invest. 117,353 -363.[CrossRef][Medline]
Hitoshi, S., Alexson, T., Tropepe, V., Donoviel, D., Elia, A. J., Nye, J. S., Conlon, R. A., Mak, T. W., Bernstein, A. and van der Kooy, D. (2002). Notch pathway molecules are essential for the maintenance, but not the generation, of mammalian neural stem cells. Genes Dev. 16,846 -858.[Abstract/Free Full Text]
Hosoda, K., Hammer, R. E., Richardson, J. A., Baynash, A. G., Cheung, J. C., Giaid, A. and Yanagisawa, M. (1994). Targeted and natural (piebald-lethal) mutations of endothelin-B receptor gene produce megacolon associated with spotted coat color in mice. Cell 79,1267 -1276.[CrossRef][Medline]
Ijuin, K., Nakanishi, K. and Ito, K. (2008). Different downstream pathways for Notch signaling are required for gliogenic and chondrogenic specification of mouse mesencephalic neural crest cells. Mech. Dev. 125,462 -474.[CrossRef][Medline]
Jiang, X., Rowitch, D. H., Soriano, P., McMahon, A. P. and Sucov, H. M. (2000). Fate of the mammalian cardiac neural crest. Development 127,1607 -1616.[Abstract]
Kageyama, R., Ohtsuka, T. and Tomita, K. (2000). The bHLH gene Hes1 regulates differentiation of multiple cell types. Mol. Cells 10, 1-7.[CrossRef][Medline]
Kapur, R. P. (1999). Early death of neural crest cells is responsible for total enteric aganglionosis in Sox10(Dom)/Sox10(Dom) mouse embryos. Pediatr. Dev. Pathol. 2,559 -569.[CrossRef][Medline]
Kapur, R. P. (2000). Colonization of the murine hindgut by sacral crest-derived neural precursors: experimental support for an evolutionarily conserved model. Dev. Biol. 227,146 -155.[CrossRef][Medline]
Kim, J., Lo, L., Dormand, E. and Anderson, D. J. (2003). SOX10 maintains multipotency and inhibits neuronal differentiation of neural crest stem cells. Neuron 38, 17-31.[CrossRef][Medline]
Kruger, G. M., Mosher, J. T., Tsai, Y. H., Yeager, K. J., Iwashita, T., Gariepy, C. E. and Morrison, S. J. (2003). Temporally distinct requirements for endothelin receptor B in the generation and migration of gut neural crest stem cells. Neuron 40,917 -929.[CrossRef][Medline]
Kuhlbrodt, K., Herbarth, B., Sock, E., Hermans-Borgmeyer, I. and Wegner, M. (1998). Sox10, a novel transcriptional modulator in glial cells. J. Neurosci. 18,237 -250.[Abstract/Free Full Text]
Le Douarin, N. M., Creuzet, S., Couly, G. and Dupin, E. (2004). Neural crest cell plasticity and its limits. Development 131,4637 -4650.[Abstract/Free Full Text]
Matsuo, I., Kuratani, S., Kimura, C., Takeda, N. and Aizawa, S. (1995). Mouse Otx2 functions in the formation and patterning of rostral head. Genes Dev. 9,2646 -2658.[Abstract/Free Full Text]
Moriyama, M., Osawa, M., Mak, S. S., Ohtsuka, T., Yamamoto, N., Han, H., Delmas, V., Kageyama, R., Beermann, F., Larue, L. et al. (2006). Notch signaling via Hes1 transcription factor maintains survival of melanoblasts and melanocyte stem cells. J. Cell Biol. 173,333 -339.[Abstract/Free Full Text]
Morrison, S. J., Perez, S. E., Qiao, Z., Verdi, J. M., Hicks, C., Weinmaster, G. and Anderson, D. J. (2000). Transient Notch activation initiates an irreversible switch from neurogenesis to gliogenesis by neural crest stem cells. Cell 101,499 -510.[CrossRef][Medline]
Mumm, J. S., Schroeter, E. H., Saxena, M. T., Griesemer, A., Tian, X., Pan, D. J., Ray, W. J. and Kopan, R. (2000). A ligand-induced extracellular cleavage regulates gamma-secretase-like proteolytic activation of Notch1. Mol. Cell 5, 197-206.[CrossRef][Medline]
Oka, C., Nakano, T., Wakeham, A., de la Pompa, J. L., Mori, C., Sakai, T., Okazaki, S., Kawaichi, M., Shiota, K., Mak, T. W. et al. (1995). Disruption of the mouse RBP-J kappa gene results in early embryonic death. Development 121,3291 -3301.[Abstract]
Okajima, T. and Irvine, K. D. (2002). Regulation of notch signaling by o-linked fucose. Cell 111,893 -904.[CrossRef][Medline]
Okajima, T., Xu, A. and Irvine, K. D. (2003). Modulation of notch-ligand binding by protein O-fucosyltransferase 1 and fringe. J. Biol. Chem. 278,42340 -42345.[Abstract/Free Full Text]
Okajima, T., Xu, A., Lei, L. and Irvine, K. D. (2005). Chaperone activity of protein O-fucosyltransferase 1 promotes notch receptor folding. Science 307,1599 -1603.[Abstract/Free Full Text]
Okamura, Y. and Saga, Y. (2008). Pofut1 is required for the proper localization of the Notch receptor during mouse development. Mech. Dev. 125,663 -673.[CrossRef][Medline]
Paratore, C., Eichenberger, C., Suter, U. and Sommer, L. (2002). Sox10 haploinsufficiency affects maintenance of progenitor cells in a mouse model of Hirschsprung disease. Hum. Mol. Genet. 11,3075 -3085.[Abstract/Free Full Text]
Pusch, C., Hustert, E., Pfeifer, D., Sudbeck, P., Kist, R., Roe, B., Wang, Z., Balling, R., Blin, N. and Scherer, G. (1998). The SOX10/Sox10 gene from human and mouse: sequence, expression, and transactivation by the encoded HMG domain transcription factor. Hum. Genet. 103,115 -123.[CrossRef][Medline]
Saga, Y., Yagi, T., Ikawa, Y., Sakakura, T. and Aizawa, S. (1992). Mice develop normally without tenascin. Genes Dev. 6,1821 -1831.[Abstract/Free Full Text]
Sasamura, T., Sasaki, N., Miyashita, F., Nakao, S., Ishikawa, H. O., Ito, M., Kitagawa, M., Harigaya, K., Spana, E., Bilder, D. et al. (2003). neurotic, a novel maternal neurogenic gene, encodes an O-fucosyltransferase that is essential for Notch-Delta interactions. Development 130,4785 -4795.[Abstract/Free Full Text]
Sasamura, T., Ishikawa, H. O., Sasaki, N., Higashi, S., Kanai, M., Nakao, S., Ayukawa, T., Aigaki, T., Noda, K., Miyoshi, E. et al. (2007). The O-fucosyltransferase O-fut1 is an extracellular component that is essential for the constitutive endocytic trafficking of Notch in Drosophila. Development 134,1347 -1356.[Abstract/Free Full Text]
Schuchardt, A., D'Agati, V., Larsson-Blomberg, L., Costantini, F. and Pachnis, V. (1994). Defects in the kidney and enteric nervous system of mice lacking the tyrosine kinase receptor Ret. Nature 367,380 -383.[CrossRef][Medline]
Shah, N. M., Groves, A. K. and Anderson, D. J. (1996). Alternative neural crest cell fates are instructively promoted by TGFbeta superfamily members. Cell 85,331 -343.[CrossRef][Medline]
Shi, S. and Stanley, P. (2003). Protein O-fucosyltransferase 1 is an essential component of Notch signaling pathways. Proc. Natl. Acad. Sci. USA 100,5234 -5239.[Abstract/Free Full Text]
Soriano, P. (1999). Generalized lacZ expression with the ROSA26 Cre reporter strain. Nat. Genet. 21, 70-71.[CrossRef][Medline]
Southard-Smith, E. M., Kos, L. and Pavan, W. J. (1998). Sox10 mutation disrupts neural crest development in Dom Hirschsprung mouse model. Nat. Genet. 18, 60-64.[CrossRef][Medline]
Stanchina, L., Baral, V., Robert, F., Pingault, V., Lemort, N., Pachnis, V., Goossens, M. and Bondurand, N. (2006). Interactions between Sox10, Edn3 and Ednrb during enteric nervous system and melanocyte development. Dev. Biol. 295,232 -249.[CrossRef][Medline]
Swenson, O. (2002). Hirschsprung's disease: a review. Pediatrics 109,914 -918.[Free Full Text]
Taraviras, S., Marcos-Gutierrez, C. V., Durbec, P., Jani, H., Grigoriou, M., Sukumaran, M., Wang, L. C., Hynes, M., Raisman, G. and Pachnis, V. (1999). Signalling by the RET receptor tyrosine kinase and its role in the development of the mammalian enteric nervous system. Development 126,2785 -2797.[Abstract]
Taylor, M. K., Yeager, K. and Morrison, S. J. (2007). Physiological Notch signaling promotes gliogenesis in the developing peripheral and central nervous systems. Development 134,2435 -2447.[Abstract/Free Full Text]
Tsarovina, K., Schellenberger, J., Schneider, C. and Rohrer, H. (2008). Progenitor cell maintenance and neurogenesis in sympathetic ganglia involves Notch signaling. Mol. Cell. Neurosci. 37,20 -31.[CrossRef][Medline]
Uesaka, T., Jain, S., Yonemura, S., Uchiyama, Y., Milbrandt, J. and Enomoto, H. (2007). Conditional ablation of GFRalpha1 in postmigratory enteric neurons triggers unconventional neuronal death in the colon and causes a Hirschsprung's disease phenotype. Development 134,2171 -2181.[Abstract/Free Full Text]
Wakamatsu, Y., Maynard, T. M. and Weston, J. A. (2000). Fate determination of neural crest cells by NOTCH-mediated lateral inhibition and asymmetrical cell division during gangliogenesis. Development 127,2811 -2821.[Abstract]
Young, H. M., Hearn, C. J., Ciampoli, D., Southwell, B. R., Brunet, J. F. and Newgreen, D. F. (1998). A single rostrocaudal colonization of the rodent intestine by enteric neuron precursors is revealed by the expression of Phox2b, Ret, and p75 and by explants grown under the kidney capsule or in organ culture. Dev. Biol. 202,67 -84.[CrossRef][Medline]
Young, H. M., Jones, B. R. and McKeown, S. J. (2002). The projections of early enteric neurons are influenced by the direction of neural crest cell migration. J. Neurosci. 22,6005 -6018.[Abstract/Free Full Text]
Young, H. M., Bergner, A. J. and Muller, T. (2003). Acquisition of neuronal and glial markers by neural crest-derived cells in the mouse intestine. J. Comp. Neurol. 456,1 -11.[CrossRef][Medline]
Young, H. M., Bergner, A. J., Anderson, R. B., Enomoto, H., Milbrandt, J., Newgreen, D. F. and Whitington, P. M. (2004). Dynamics of neural crest-derived cell migration in the embryonic mouse gut. Dev. Biol. 270,455 -473.[CrossRef][Medline]
Zhu, L., Lee, H. O., Jordan, C. S., Cantrell, V. A., Southard-Smith, E. M. and Shin, M. K. (2004). Spatiotemporal regulation of endothelin receptor-B by SOX10 in neural crest-derived enteric neuron precursors. Nat. Genet. 36,732 -737.[CrossRef][Medline]

CiteULike

Complore

Connotea

Del.icio.us Add to Digg

Digg

Technorati

Twitter What's this?

This article has been cited by other articles:

P.-N. Tsao, M. Vasconcelos, K. I. Izvolsky, J. Qian, J. Lu, and W. V. Cardoso
Notch signaling controls the balance of ciliated and secretory cell fates in developing airways
Development, July 1, 2009; 136(13): 2297 - 2307.
[Abstract] [Full Text] [PDF]

This Article

Summary

Figures Only

Full Text (PDF)

Supplementary Material

All Versions of this Article:
dev.022319v1
135/21/3555 most recent

Alert me when this article is cited

Alert me if a correction is posted

Services

Email this article to a friend

Similar articles in this journal

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via HighWire

Citing Articles via Google Scholar

Google Scholar

Articles by Okamura, Y.

Articles by Saga, Y.

Search for Related Content

PubMed

PubMed Citation

Articles by Okamura, Y.

Articles by Saga, Y.

Social Bookmarking

What's this?