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First published online 14 May 2008
doi: 10.1242/dev.017459

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Activation of β-catenin signaling programs embryonic epidermis to hair follicle fate

¹ Departments of Dermatology and Cell and Developmental Biology, University of Pennsylvania School of Medicine, Philadelphia, PA 19104, USA.
² Department of Dermatology, University of Michigan, Ann Arbor, MI 48109, USA.
³ Department of Dermatology, University of Pennsylvania School of Medicine, Philadelphia, PA 19104, USA.
⁴ Bioinformatics Core, University of Pennsylvania, Philadelphia, PA 19104, USA.
⁵ Department of Histology, Microbiology and Medical Biotechnologies, Section of Histology and Embryology, University of Padua, 35121 Padua, Italy.
⁶ Max-Delbrück-Center for Molecular Medicine, Robert-Rössle-Strasse 10, 13092 Berlin, Germany.
⁷ Samuel Lunenfeld Research Institute, Mount Sinai Hospital, Toronto, Ontario, M5G 1X5, Canada.
⁸ Department of Pharmacology, Graduate School of Medicine, Kyoto University, Yoshida-Konoé-cho, Sakyo, Kyoto 606-8501, Japan.

^* Author for correspondence (e-mail: millars{at}mail.med.upenn.edu)

Accepted 24 April 2008

	SUMMARY

TOP SUMMARY INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
β-Catenin signaling is required for hair follicle development, but it is unknown whether its activation is sufficient to globally program embryonic epidermis to hair follicle fate. To address this, we mutated endogenous epithelial β-catenin to a dominant-active form in vivo. Hair follicle placodes were expanded and induced prematurely in activated β-catenin mutant embryos, but failed to invaginate or form multilayered structures. Eventually, the entire epidermis adopted hair follicle fate, broadly expressing hair shaft keratins in place of epidermal stratification proteins. Mutant embryonic skin was precociously innervated, and displayed prenatal pigmentation, a phenomenon never observed in wild-type controls. Thus, β-catenin signaling programs the epidermis towards placode and hair shaft fate at the expense of epidermal differentiation, and activates signals directing pigmentation and innervation. In transcript profiling experiments, we identified elevated expression of Sp5, a direct β-catenin target and transcriptional repressor. We show that Sp5 normally localizes to hair follicle placodes and can suppress epidermal differentiation gene expression. We identified the pigmentation regulators Foxn1, Adamts20 and Kitl, and the neural guidance genes Sema4c, Sema3c, Unc5b and Unc5c, as potential mediators of the effects of β-catenin signaling on pigmentation and innervation. Our data provide evidence for a new paradigm in which, in addition to promoting hair follicle placode and hair shaft fate, β-catenin signaling actively suppresses epidermal differentiation and directs pigmentation and nerve fiber growth. Controlled downregulation of β-catenin signaling is required for normal placode patterning within embryonic ectoderm, hair follicle downgrowth, and adoption of the full range of follicular fates.

Key words: Epidermis, Hair follicle, Mouse embryo, β-catenin, Wnt

	INTRODUCTION

TOP SUMMARY INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
The embryonic surface ectoderm stratifies to form the epidermis, providing an essential protective barrier. Subsets of surface ectodermal cells, rather than stratifying, develop into hair follicles and other ectodermal appendages (Mikkola and Millar, 2006). Hair follicle development is initiated by signaling from the dermis, which induces the formation of local thickenings, or placodes, in the overlying epithelium (Hardy, 1992). Although it is currently unclear whether the initiating dermal signal is uniform or whether it is generated by labile local dermal condensates, the final location of placodes appears to be influenced by reaction-diffusion mechanisms involving competing epithelial signals (Jiang et al., 2004). These interactions result in the formation of a hexagonal array of primary placodes that appears at approximately embryonic day (E) 14.5 in mouse embryos, and gives rise to the large guard over-hairs of the coat. Secondary placodes are initiated in several waves between E15.5 and birth, and develop into awl, auchene and zigzag hair follicles.

Signaling from placode epithelial cells causes condensation of mesenchymal cells that in turn stimulates proliferation and downgrowth of the placode (Hardy, 1992). Rapidly proliferating hair matrix cells surround the dermal condensate, hereafter referred to as a dermal papilla, and differentiate to form the hair shaft and inner root sheath (Fuchs, 2007; Millar, 2002). An outer root sheath surrounds the follicle and is contiguous with the basal epidermis. Incompletely characterized signals direct melanoblasts and nerve fibers to developing hair follicles (Jordan and Jackson, 2000; Peters et al., 2002).

Although the molecular nature of the primary dermal signal has not been established, several families of secreted signaling molecules participate in hair placode induction. These factors include the TNF family member ectodysplasin-A (EDA), which signals via its receptor EDAR and NFB to regulate primary placode formation; BMP family members, which negatively regulate placode formation and compete with EDA in establishing a regular patterned placodal array; and sonic hedgehog (SHH), which controls proliferation and downgrowth of hair follicle epithelium (reviewed by Fuchs, 2007; Millar, 2002; Schmidt-Ullrich and Paus, 2005). Stable primary placodes fail to form in EDA pathway mutants, but transient pre-placode structures can be detected, suggesting the existence of earlier patterned signals (Schmidt-Ullrich et al., 2006).

Wnt/β-catenin signaling regulates many aspects of development and disease. Signaling is activated by the binding of a secreted Wnt ligand to a frizzled (FZ) receptor and an LDL-related protein (LRP) 5/6 co-receptor, leading to the inactivation of a complex of proteins that phosphorylates cytoplasmic β-catenin and targets it for degradation. Cytoplasmic β-catenin accumulates, translocates to the nucleus, and complexes with LEF/TCF transcription factor family members to activate target gene transcription (Gordon and Nusse, 2006). Wnt/β-catenin signaling is required for hair follicle placode induction and the patterned expression of Edar (Andl et al., 2002). Wnt reporter transgene expression is elevated in epithelial and dermal condensate cells at early stages of follicular development, and is then downregulated in the epithelium until the onset of hair shaft differentiation when it appears in hair shaft precursor cells (DasGupta and Fuchs, 1999; Maretto et al., 2003). β-catenin/LEF complexes can directly regulate the expression of hair shaft keratin genes in vitro (Merrill et al., 2001), suggesting a key role for Wnt/β-catenin signaling in hair shaft differentiation.

Deletion of the intracellular Wnt/β-catenin pathway inhibitor Apc in skin epithelial cells results in the formation an increased number of embryonic hair follicles, and hair follicle abnormalities, but does not affect the development and stratification of interfollicular epidermis (Kuraguchi et al., 2006). Transgenic epidermal expression of stabilized β-catenin causes ectopic hair follicle induction in adult skin; however, alterations in embryonic skin or hair follicle development were not observed (Gat et al., 1998), or not reported (Lo Celso et al., 2004; Silva-Vargas et al., 2005). Thus, Wnt/β-catenin signaling is required for hair follicle placode induction, but it is not clear whether activation of this pathway in mammalian embryonic surface ectoderm is sufficient to globally program ectodermal cells to hair follicle fate. It is also not known whether Wnt/β-catenin signaling activates the factors that attract nerve fibers and melanoblasts to hair follicles, or whether it suppresses epidermal stratification to allow placode development. To address these questions, we mutated the endogenous β-catenin gene to a constitutively active form in vivo using an efficient KRT14-Cre transgenic line.

	MATERIALS AND METHODS

TOP SUMMARY INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
Generation and genotyping of mouse lines
KRT14-Cre Ctnnb1^(Ex3)fl/+ and KRT5-rtTA tetO-Dkk1 mice were generated as described previously (Chu et al., 2004; Liu et al., 2007). For tetracycline-inducible β-catenin mutation, mice carrying tetO-Cre (Mucenski et al., 2003) and KRT5-rtTA (Diamond et al., 2000) transgenes and Ctnnb1^(Ex3)fl (Harada et al., 1999) were placed on doxycycline chow (1 mg/kg, Bio-serv, Laurel, MD). To generate 4-hydroxytamoxifen-inducible β-catenin mutants, 50 µl of 4-hydroxytamoxifen in 95% ethanol (10 mg/ml, Sigma-Aldrich, St Louis, MO) or vehicle control was applied to dorsal back skin after hair clipping. Mice were genotyped by PCR analysis of tail biopsy DNA. All experiments were performed with approved animal protocols according to University of Pennsylvania and University of Michigan institutional guidelines.

Phenotypic analyses
Histological analysis, whole-mount and section in situ hybridization and immunostaining, TUNEL, X-gal staining, Oil Red O staining and transmission electron microscopy (TEM) were performed as described previously (Allen et al., 2003; Andl et al., 2004; Andl et al., 2006; Braun et al., 2003; Chu et al., 2004; Hutchin et al., 2005; Langbein et al., 2007; Liu et al., 2007). For epidermal barrier assays, methanol-fixed embryos were stained in 1% Toluidine Blue O solution (Sigma-Aldrich).

Semi-quantitative PCR and quantitative RT-PCR
Dissected dorsal skin was dispase treated (BD Bioscience, Sparks, MD) to separate epidermis and dermis. Wild-type, floxed and deleted-floxed Ctnnb1 alleles were detected by PCR of extracted genomic DNA. RNA was extracted using RNeasy Mini Kit (Qiagen, Valencia, CA). Primer pairs for qRT-PCR were purchased from Superarray Bioscience. Reactions were performed in triplicate using SYBR green on an MJ Opticon II thermocycler (Bio-Rad, Hercules, CA). Relative expression levels were standardized using β-actin as an internal control. Data were analyzed using the Opticon III program.

Chromatin immunoprecipitation (ChIP) assays
ChIP assays were performed using the Chromatin Immunoprecipitation Kit (Upstate, Charlottesville, VA). Epidermal cells were dissociated, fixed in 1% formaldehyde for 15 minutes at room temperature, sonicated and incubated with anti-β-catenin antibody (14, BD Bioscience, San Jose, CA) or control IgG overnight at 4°C, after which Protein A agarose beads were added. Purified DNA was subjected to semi-quantitative PCR with primers that amplify the Sp5 promoter, or Gapdh sequences.

Microarray analyses
Total RNA was subjected to one round of amplification/labeling to obtain biotinylated cRNA for hybridization to Affymetrix GeneChip Mouse Genome MOE430 2.0 oligonucleotide microarrays at the Microarray Core, University of Pennsylvania (Philadelphia, PA). Two entirely independent samples of each tested condition were used for data analyses. Scanned microarray images were imported into Gene Chip Operating Software (GCOS, Affymetrix, Santa Clara, CA) to generate signal values and present/absent calls for each probe set using the MAS 5.0 statistical expression algorithm. Data files were imported into GeneSpring 7.3.1 (Agilent, Santa Clara, CA), and replicate microarrays grouped and compared. Transcripts that were increased at least 2-fold in one population over the other and called present in both replicates were considered significant for further analysis.

Keratinocyte transfection
Full-length mouse Sp5 cDNA cloned into pCMV-3Tag (Stratagene, La Jolla, CA) or a pCMV-3Tag control plasmid were transfected into HaCAT cells using the Cell Line Nucleofector Kit V (Amaxz GmbH, Gaithersburg, MD). mRNA was extracted after 3 weeks of culture in 500 µg/ml G-418 and subjected to quantitative RT-PCR for Sp5, KRT10, involucrin and DLX3.

	RESULTS

TOP SUMMARY INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
Generation of a dominant stabilizing epithelial β-catenin mutant
To determine whether forced activation of Wnt/β-catenin signaling alters the fate of embryonic surface ectoderm, we stimulated β-catenin signaling in vivo by mutating the endogenous β-catenin gene (Ctnnb1) to a dominant-active form in epithelial cells. Ctnnb1^(Ex3)fl/fl mice, in which exon 3 of Ctnnb1, encoding all phosphorylation target serine/threonine residues, is flanked by loxP sequences that are targets for Cre-mediated recombination, were mated to KRT14-Cre line 43 transgenic mice expressing Cre recombinase under the control of a keratin 14 promoter (Liu et al., 2007). KRT14-Cre-mediated recombination of a ROSA26R Cre reporter gene (Soriano, 1999) was observed in surface epithelium by E11.5 (see Fig. S1 in the supplementary material).

KRT14-Cre Ctnnb1^(Ex3)fl/+ embryos died perinatally, and displayed limb and craniofacial defects. Their skin appeared grossly abnormal by E14.5, with multiple raised papules, and by birth was almost completely covered in large keratinized plaques (Fig. 1A-J). Precocious pigmentation was observed in embryonic ectoderm associated with keratinized plaques (Fig. 1J). Control mice displayed hair shaft pigmentation several days after birth, but control embryo skin was never pigmented (Fig. 1I).

Embryonic mutant skin showed elevated expression of β-catenin protein in the epithelium from E11.5 onwards, with many ectodermal cells exhibiting both cytoplasmic and nuclear localization of β-catenin (Fig. 1K,L). To determine the pattern of Wnt/β-catenin pathway activation in mutant skin, we generated KRT14-Cre Ctnnb1^(Ex3)fl/+ mice carrying two independent Wnt reporter genes, BATgal (Maretto et al., 2003) or Topgal (DasGupta and Fuchs, 1999). Expression of either reporter was significantly elevated and more widespread in mutant compared with littermate control skin, and the normal regular pattern of hair follicle placode formation was disturbed in the mutant (Fig. 1M-P).

Premature hair follicle placode development in stabilized β-catenin mutant embryos
Thickened epithelial structures expressing the placode marker Shh (St-Jacques et al., 1998) appeared in stabilized β-catenin mutant embryonic dorsal skin by E12.5, whereas hair follicle placodes were not apparent in control littermate embryos until E14.5 (Fig. 2A-F).

View larger version (85K): [in this window] [in a new window]   Fig. 1. Abnormal skin development and Wnt/β-catenin pathway activation in stabilized β-catenin mutant embryos. (A-H) Control littermate and KRT14-Cre Ctnnb1(Ex3)fl/+ (Act β-catenin) embryos at the stages indicated. Arrows indicate keratinized plaques in mutant embryos. (I,J) Higher magnification views of dorsal skin from G and H, respectively. Pigment (arrows) accumulates in mutant skin. (K,L) Immunohistochemistry for β-catenin at E15.5 showing elevated β-catenin levels in control placodes (K), and cytoplasmic and nuclear β-catenin throughout mutant ectoderm (L, arrows). (M-P) X-gal-stained control BATgal (M,O) and KRT14-Cre Ctnnb1(Ex3)fl/+ BATgal (Act β-catenin BATgal) (N,P) littermates at E13.5 (M,N) and E16.5 (O,P), showing increased BATgal expression and its irregular pattern in the mutant. Scale bar in L applies to K and L.

To visualize the global pattern of placode development, we carried out whole-mount in situ hybridization for the placode marker Wnt10b (St-Jacques et al., 1998). At E12.5, elevated Wnt10b expression localized specifically to mammary and vibrissa placodes in control embryos (Fig. 2I,K). Stabilized β-catenin mutant embryos displayed numerous placodes covering the trunk, head and limbs (Fig. 2J,L). At E13.5, mutant placodes were enlarged (Fig. 2M,N). Counting of the placodes in a defined area of head skin at E13.5 revealed a mean of 7±3 placodes in control embryos (n=3) and 33±9 placodes in mutant embryos (n=3; P=0.03). Wnt10b-positive placodes were observed in the footpads of E12.0 mutant embryos but not control embryos (see Fig. S2 in the supplementary material). Thus activated β-catenin can promote placode development even in normally hairless skin regions. Accelerated development of sweat glands was not observed in mutant footpads at later embryonic stages, suggesting that footpad placodes did not represent precocious sweat gland anlagen. Mammary glands developed in mutant female embryos, but exhibited histological abnormalities that will be described elsewhere.

The expression of Edar, assayed at E14.5, was elevated and more widespread in mutant than in littermate control skin (Fig. 2O,P). To determine whether EDAR signaling is activated in mutant placodes, we generated KRT14-Cre Ctnnb1^(Ex3)fl/+ mice carrying the NFB reporter gene (Ig)_3xcona-lacZ (Gal) (Schmidt-Ullrich et al., 1996). NF-B activity was detected in KRT14-Cre Ctnnb1^(Ex3)fl/+ Gal skin at E14.5 and E15.5, but failed to show its normal regular pattern (Fig. 2Q-T). NFB activity was not detected in mutant skin at earlier stages despite placodal expression of Wnt10b and Shh. Precociously initiated placodes may thus be more similar to secondary awl than primary hair follicle placodes, as development of the former, but not the latter, is independent of NFB signaling.

Impaired hair follicle development and broad adoption of hair follicle fate in activated β-catenin mutant surface ectoderm
Despite the formation of enlarged placodes in stabilized β-catenin mutant embryos at E14.5, hair follicles failed to extend into the dermis or to form multilayered structures (Fig. 3A-J). In some regions of the mutant embryos, large evaginations were noted that accumulated keratinized material and corresponded to the keratinized papules seen in whole mounts (Fig. 3B,D,J). Stratification of the epidermis appeared impaired, and fibroblasts in the upper dermis were more densely packed than were those in littermate controls (Fig. 3G,H).

To determine the molecular basis for these phenotypes, we examined the expression of hair follicle markers at E17.5. Shh is a specific marker for hair follicles within the skin (Chiang et al., 1999; St-Jacques et al., 1998), and, at this stage, its expression was confined to control hair follicle bulbs (Fig. 3K). In mutant embryos, expression of Shh was observed throughout the surface ectoderm, suggesting a widespread acquisition of hair follicle fate (Fig. 3L). Alkaline phosphatase activity marks the hair follicle dermal condensate and dermal papilla (Fig. 3M). Strikingly, in mutant embryos, alkaline phosphatase activity was detected broadly throughout most of the upper dermis (Fig. 3N). Together with the increased density of upper dermal fibroblasts, this abnormal staining indicated that upper dermal cells had broadly acquired at least some characteristics of the hair follicle dermal condensate. These data suggest that a secreted factor(s) expressed in response to cell-autonomous, stabilized epithelial β-catenin induced dermal condensation and alkaline phosphatase expression.

View larger version (81K): [in this window] [in a new window]   Fig. 2. Premature and expanded placode development in β-catenin mutant embryos. (A-D) Premature placode development at E12.5 indicated by Hematoxylin and Eosin (H&E) staining (A,B, arrows) and Shh mRNA expression (C,D; purple brown) in KRT14-Cre Ctnnb1(Ex3)fl/+ (Act β-catenin) embryos compared with controls. (E-H) Placodes are enlarged in the mutant at E14.5 (E,F) and immunofluorescence for PGP9.5 reveals precocious development of enlarged nerve fibers (G,H, arrows). (I-P) Whole-mount in situ hybridization for Wnt10b (I-N) or Edar (O,P) reveals accelerated formation of enlarged placodes in the mutants. (Q-T) Whole-mount X-gal staining of control Gal (Q,S) and KRT14-Cre Ctnnb1(Ex3)fl/+ Gal (R,T) embryos reveals an irregular pattern of NFB activity (arrows) in the mutants. Scale bars: bar in B applies to A,B; in D, to C,D; and in H, to E-H.

Consistent with hair shaft-like differentiation of mutant ectodermal cells, at E17.5 mutant dorsal skin displayed a mean of 10±3 Ki67-positive cells per field at 20x magnification compared with 29±5 in the equivalent region of control skin (n=3 embryos and two fields counted per embryo for each genotype; P=0.0024; Fig. 3U,V). The decreased proliferation observed in mutant ectoderm was largely due to the absence of defined hair follicle matrix cell populations. TUNEL-positive cells were detected broadly in mutant surface ectoderm, but in controls were mostly detected in terminally differentiating upper layers of the epidermis (Fig. 3W,X).

Induction of the stabilizing β-catenin mutation in embryonic surface epithelium after placode initiation causes defects in hair follicle development
Abnormal hair follicle development could be due to global alterations in the surface ectoderm prior to the stage when placodes are normally initiated, rather than to specific effects within developing follicles. To test this, we generated KRT5-rtTA tetO-Cre Ctnnb1^(Ex3)fl/+embryos, in which the mutation of β-catenin to a stabilized form can be induced in epithelial cells by dosage of the pregnant mother with oral doxycycline, and KRT5-rtTA tetO-Cre Ctnnb1^+/+ littermate controls. Untreated KRT5-rtTA tetO-Cre Ctnnb1^(Ex3)fl/+ embryos and adult mice lacked overt phenotypes. The induction of β-catenin mutation from E13.5, the stage at which primary placode initiation is just beginning, resulted in the formation of enlarged, abnormal placodes, and a failure of hair follicle downgrowth (Fig. 4A,B). Similarly, induction from E15.5, a stage after the formation of primary hair follicle placodes, blocked hair germ extension and resulted in defects in epidermal stratification (defects were assayed at birth; Fig. 4C-F). Pigment accumulation was noted in mutant but not control littermate skin at birth (Fig. 4G,H). Thus, the activated β-catenin mutation causes defective hair follicle development and abnormal pigmentation when induced after the onset of hair follicle placode formation.

Stabilized β-catenin mutants lack epidermal differentiation and barrier function
To analyze defects in epidermal stratification at the molecular level, we carried out immunofluorescence for specific markers for basal, spinous and granular epidermal layers at E17.5. Stabilized β-catenin mutants exhibited reduced levels of the basal layer marker KRT14 compared with littermate controls (Fig. 5A,B). Immunofluorescence for the spinous layer markers KRT1 and KRT10 and the granular layer markers filaggrin and loricrin, was prominent in control littermate embryos, but virtually undetectable in mutant surface ectoderm (Fig. 5C-H). Expression of the desmosomal components DSC1 and DSG1, which normally localize to suprabasal epidermal layers, was markedly reduced in mutant surface ectoderm (Fig. 5I-L). These data are consistent with a complete failure of epidermal differentiation and a global conversion of ectodermal cells to a hair follicle fate.

View larger version (61K): [in this window] [in a new window]   Fig. 3. Aberrant hair follicle development and global expression of placode and hair shaft markers in activated β-catenin mutant embryos. (A-J) Histological analysis of dorsal skin from control littermate and KRT14-Cre Ctnnb1(Ex3)fl/+ mutant embryos reveals the failure of hair follicle downgrowth in mutants. Mutant skin displays evaginations (B,D,J; arrows) and fails to stratify normally (H; arrow). (G,H) Higher magnification views of E and F, respectively. (K-X) The placode marker Shh (in situ hybridization, brown; K,L) and the dermal condensate marker alkaline phosphatase (AP; enzymatic assay, purple brown; M,N) are expressed broadly in the mutant. Expression of the inner root sheath marker GATA3 (O,P) and the outer root sheath marker SOX9 (Q,R; immunofluorescence, red) is reduced or absent, but hair shaft keratins (AE13 antibody, immunohistochemistry, brown) are ectopically expressed in mutant ectoderm (S,T). Proliferation is decreased (U,V; Ki67 immunofluorescence, red) and the pattern of apoptosis/terminal differentiation is altered (W,X; TUNEL staining, green) in mutant ectoderm. Arrows indicate expression; dashed lines mark dermal-epidermal boundaries. Samples were E17.5 (K-N,Q-X) or newborn (O,P). Scale bars: bar in F applies to A-F; in H, to G,H; in J, to I,J; in X, to K-X.

To determine the impact of these changes on skin ultrastructure, we subjected control and stabilized mutant skin to TEM at E16.5. Control epidermis displayed the expected stratifying structure, with readily identifiable basal cells, spinous cells characterized by dense networks of keratin filaments, and granular cells containing keratohyalin granules. By contrast, mutant surface ectoderm lacked the characteristics of suprabasal, spinous and granular cells (Fig. 5O,P). Pigment granules were noted in some regions of the mutant ectoderm (Fig. 5Q). Consistent with the unaffected expression of laminin 5 in mutant skin (Fig. 5M,N), the basement membrane was present in the mutant, and lamina lucida and lamina densa structures were similar to controls. However, hemidesmosomes were reduced in number compared with control skin (Fig. 5R,S). Notably, large spaces were apparent between mutant epithelial cells (Fig. 5P), suggesting defective cell-cell adhesion. Consistent with cell-adhesion defects, E-cadherin was downregulated in mutant basal cells; by contrast, P-cadherin localized intensely to control hair germs, but in mutants was strongly expressed throughout the surface epithelium (see Fig. S4 in the supplementary material).

Global changes in gene transcription patterns in activated β-catenin mutant skin
To begin to dissect the molecular mechanisms underlying the dramatic effects of stabilized β-catenin on embryonic surface ectodermal development, innervation and pigmentation, we used microarray analysis to obtain global transcript profiles of mutant and stabilized β-catenin mutant dorsal dermis and epidermis at E15.5, and of unseparated dorsal skin at E14.5 (GEO accession number GSE10733). We analyzed >18,000 transcripts that were flagged as present in at least two of four samples, representing >14,000 genes. Genespring software was used to normalize the raw data, and to identify genes with a Student's t-test P-value of less than 0.05 and a change in relative expression levels of at least 2-fold in KRT14-Cre Ctnnb1^(Ex3)fl/+compared with control samples.

View larger version (155K): [in this window] [in a new window]   Fig. 4. Mutation of β-catenin after placode initiation blocks hair follicle downgrowth and causes abnormal epidermal stratification and pigmentation. (A-F) H&E-stained sections of E16.5 (A,B) or P1 (C-F) dorsal skin from littermate control and KRT5-rtTA tetO-Cre Ctnnb1(Ex3)fl/+ embryos doxycycline treated from E13.5 (A,B) or E15.5 (C-F). (E,F) Higher magnification views of C,D. Placodes (arrows) are abnormal and expanded at E16.5 (A,B), but hair follicle downgrowth (arrows) fails (C,D). Epidermal stratification is abnormal in the mutants (blue arrows; E,F). (G,H) Precocious pigmentation (arrow) of newborn mutant induced from E15.5. Scale bars: bar in D applies to A-D; in F, to E,F.

The stem cell-associated genes Lrig1 (Jensen and Watt, 2006) and Krt15 (Morris et al., 2004) were downregulated in mutant ectoderm, consistent with the lack of expression of Sox9, which is required for establishing the hair follicle stem-cell compartment (Vidal et al., 2005), and with our observation that, in this developmental context, stabilized β-catenin promotes ectodermal differentiation towards hair shaft, rather that maintaining cells in an undifferentiated state.

An unexpected finding was that the transcription factor gene Sp5 and its relative Sp8 were substantially upregulated in mutant epidermis. Wnt regulates Sp8 expression in the developing limb (Kawakami et al., 2004). Sp5 is regulated by Wnt in diverse developmental and disease processes, and its proximal promoter region contains five evolutionarily conserved TCF/LEF-binding sites that mediate direct activation by canonical Wnt signaling (Fujimura et al., 2007; Takahashi et al., 2005; Weidinger et al., 2005). Differential expression of Sp5, Sp8 and selected additional genes from the microarray analyses was confirmed by quantitative RT-PCR (Fig. 6A). Sp5 expression localized to hair follicle placodes in wild-type embryos in a similar pattern to Topgal Wnt reporter activity (Fig. 6D,E), and was increased in gain of function β-catenin mutant ectoderm (Fig. 6F-I). Conversely, in ectoderm from embryos expressing the Dkk1 Wnt inhibitor under the control of a Krt5 promoter (Chu et al., 2004), Sp5 expression, analyzed by quantitative RT-PCR and in situ hybridization, was downregulated (Fig. 6J-L). We confirmed by ChIP analysis that Sp5 is a direct target of β-catenin in surface ectodermal cells in vivo (Fig. 6M).

Sp5 represses Krt10 and involucrin expression in keratinocytes
Sp5 can function as a transcriptional repressor (Fujimura et al., 2007), suggesting it as a candidate factor mediating the downregulation of epidermal differentiation genes in mutant β-catenin surface ectoderm. To test this, we transfected an expression vector for mouse Sp5 into the HaCAT human keratinocyte cell line under differentiating conditions. Sp5 suppressed the expression of mRNAs encoding the squamous differentiation markers KRT10 and involucrin relative to their levels in empty vector-transfected cells (Fig. 6N). Thus, Sp5 may mediate some of the effects of β-catenin in downregulating a subset of epidermal differentiation genes. Interestingly, the expression of DLX3, which is predominantly associated with hair shaft differentiation (Morasso et al., 1995), was increased by transfected Sp5.

View larger version (46K): [in this window] [in a new window]   Fig. 5. Epidermal differentiation fails in activated β-catenin mutants. (A-N) Expression of KRT14 (A,B), DSC1 (I,J) and DSG1 (K,L) is decreased, and expression of KRT10, filaggrin and loricrin (C-H) is absent in stabilized β-catenin mutants, but laminin 5 expression (M,N) indicates that the basement membrane remains intact. Scale bar in N applies to A-N. Arrows indicate expression. (O-S) TEM of E16.5 control (O,R) and mutant (P,Q,S) dorsal epidermis (O-Q) or epidermal-dermal junction region (R,S) reveals the presence of basal (Ba), spinous (Sp) and granular (Gr) layers in control epidermis (O), and their absence in the mutant (P). Pigment granules are present in mutant ectoderm (red arrows in Q). The basement membrane (BM) is intact in the mutant, but hemidesmosomes (red arrows in R) are reduced in number (S).

These data indicate that the stabilized β-catenin mutation produces distinct phenotypes in embryonic and adult skin (Fig. 7). Nuclear localized β-catenin was detected prominently in adult induced hair follicles (see Fig. S6D'-F' in the supplementary material), but was not as uniform as in induced embryonic ectoderm (Fig. 1L), possibly accounting in part for the different phenotypic outcomes. Semi-quantitative PCR analysis of floxed and recombined floxed Ctnnb1 alleles revealed that the efficiency of recombination in induced adult epidermis is similar to, or slightly greater than, that in embryonic surface ectoderm (see Fig. S5L in the supplementary material), suggesting that differential β-catenin accumulation is not primarily due to differences in recombination efficiency. Instead, stage and context dependent activation of the β-catenin promoter, positive feedback signaling in embryonic and hair follicle epithelium, and/or inhibitory effects in established, adult epidermis may affect β-catenin expression and function in different subsets of cells. Lack of an embryonic skin phenotype in previously described KRT14-Nβcat transgenic mice (Gat et al., 1998) could be due to β-catenin-mediated downregulation of the KRT14 promoter, in contrast to positive feedback regulation of epithelial β-catenin mRNA levels by stabilized β-catenin (Liu et al., 2007), or to subtle activity differences in the Nβcat and exon 3-deleted β-catenin mutant proteins.

	DISCUSSION

TOP SUMMARY INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
We have demonstrated here that an activating mutation in epithelial β-catenin had dramatic effects on embryonic surface ectoderm. Hair follicle placodes were expanded, but failed to develop normally, instead precociously expressing hair shaft keratins (Fig. 7). Mutant embryonic skin was prematurely pigmented and innervated, and epidermal stratification was disrupted, resulting in a total failure of epidermal barrier function. Our data support a model in which Wnt/β-catenin signaling plays multiple roles in the embryonic surface ectoderm, promoting placode and hair shaft fate, activating signals that attract nerve fibers and enhance pigmentation, and blocking squamous differentiation.

Although these experiments rely on a gain-of-function approach, many of the genes displaying differential expression in our microarray profiling experiments are known from previous studies to be expressed in developing hair follicles, and/or are suppressed in embryonic skin expressing the secreted Wnt inhibitor DKK1 or lacking β-catenin (Andl et al., 2002; Huelsken et al., 2001). Furthermore, we were able to verify placodal expression in wild-type embryos and decreased expression in Wnt-inhibited skin for Sp5, a gene not previously associated with embryonic hair follicle development.

Controlled β-catenin signaling is essential for periodic pattern formation in the surface ectoderm
Placode induction occurs at least two days earlier in gain-of-function β-catenin mutants than in wild-type ectoderm, indicating that stabilized β-catenin overrides the requirement for an initiating dermal message. Uncontrolled ectodermal β-catenin signaling induces the formation of a broadly condensed dermis associated with widespread acquisition of dermal condensate markers. Thus, dermal condensates can be either initiated, or stabilized and expanded, by signaling from the epithelium. These data suggest a model in which the final positioning of hair follicles is determined not by a fixed pattern of dermal condensates, but rather by the interplay of epithelial and dermal signals. Consistent with this model, stable dermal condensates are not observed in mice lacking epithelial Eda signaling (Schmidt-Ullrich et al., 2006).

Our results further indicate that controlled downregulation of β-catenin signaling is required to generate a regular array of placode and interplacode fate, consistent with a reaction-diffusion model for establishment of the placodal array (Jiang et al., 2004), involving Wnt/β-catenin as the primary placode promoting signal, and predicting an important function in placode spacing for secreted Wnt-inhibitory factors whose expression is promoted within placodes by β-catenin. Microarray analysis revealed increased expression in gain-of-function mutant β-catenin skin of several secreted Wnt inhibitors, including Dkk4, Dkk1 and Wif1, consistent with prior reports and mathematical modeling analyses (Bazzi et al., 2007; Maini et al., 2006; Sick et al., 2006; Stark et al., 2007). Secreted Wnt inhibitors act at the level of Wnt receptors and/or co-receptors, and so would be ineffective at modulating the activity of epithelial gain-of-function mutant β-catenin. Thus, the balance between activating and inhibitory signals is shifted in favor of placode formation in stabilized β-catenin mutant ectoderm, resulting in an expanded adoption of placode fate (Fig. 7).

The precocious development of placodes, the increase in their density, and their formation in normally hairless areas, suggests that the broad distribution of placodes in mutant embryos is due, at least in part, to a switch in fate of the embryonic surface ectoderm, rather than being wholly accounted for by an expansion of cells normally destined to adopt placode fate. Deletion of the intracellular Wnt pathway inhibitor Apc produces a milder phenotype (Kuraguchi et al., 2006), possibly due, in part, to the central, integrating role of β-catenin in the Wnt/β-catenin signaling pathway and to compensation of Apc functions by other pathway inhibitors.

View larger version (75K): [in this window] [in a new window]   Fig. 6. Verification of array data and identification of Sp5 as a direct β-catenin target capable of suppressing epidermal differentiation gene expression. (A) qRT-PCR assays for the indicated transcripts in epidermal extracts from control and activated β-catenin mutant E15.5 embryos. Average relative expression levels, measured in triplicate assays of two independent pairs of experimental and control samples, were normalized to levels of actin transcripts. (B,C) Immunohistochemistry for hair keratin KRT82 (brown) demonstrates its upregulation in activated mutant epithelium at E16.5. (D,E) Similar patterns of Topgal (whole-mount X-gal staining, blue) and Sp5 (whole-mount in situ hybridization, purple) expression (arrows) in wild-type primary hair follicle placodes at E16.0. The less-sensitive in situ hybridization assay does not detect Sp5 expression in all secondary hair follicles at this stage. D,E were photographed at the same magnification. (F-I) Expanded Sp5 expression in KRT14-Cre Ctnnb1(Ex3)fl/+ mutant embryos at E14.5 (F,G; yellow arrows) and E15.5 (H,I; yellow arrows), and its ectopic expression in mutant cornea (white arrow). (J) qRT-PCR shows decreased expression of Sp5 in epidermal extracts of KRT5-rtTA tetO-Dkk1 E14.5 embryos doxycycline treated from E0.5 compared with control littermates. (K,L) Absence of placodal Sp5 expression in Dkk1-expressing E15.5 embryos (L) compared with littermate controls (K). (M) ChIP assay for β-catenin binding to a region of the Sp5 promoter containing multiple conserved LEF/TCF-binding sites. Chromatin prepared from E15.5 control and KRT14-Cre Ctnnb1(Ex3)fl/+ epidermis was incubated with anti-β-catenin antibody (β-cat Ab) or control IgG. Semi-quantitative PCR detects β-catenin binding to the Sp5 promoter in control extracts and increased binding in KRT14-Cre Ctnnb1(Ex3)fl/+ extracts. β-catenin does not bind to Gapdh sequences (bottom panel). (N) qRT-PCR detects expression of transfected mouse Sp5, decreased levels of endogenous KRT10 and involucrin, and increased expression of endogenous DLX3 in Sp5-transfected HaCAT cells compared with empty vector-transfected controls. Average relative expression levels measured in triplicate assays of three independent transfection experiments are shown, normalized to levels of actin transcripts.

View larger version (42K): [in this window] [in a new window]   Fig. 7. Model of the effects of activated β-catenin on ectodermal differentiation. (A) Wnt/β-catenin signaling (blue) is weakly activated in subsets of wild-type epithelial cells in response to dermal signals. Positive-feedback signaling enhances pathway activity in placodes (Liu et al., 2008; Liu et al., 2007), activates secreted factors that promote dermal condensation and attract melanoblasts and nerve fibers, and induces expression of secreted Wnt inhibitors that block pathway activation in adjacent cells by a reaction-diffusion mechanism. Epithelial signaling reappears after birth in hair shaft precursor cells that attract pigment deposition. (B) In the constitutive mutant, elevated epithelial β-catenin overrides the requirement for a dermal message, and stimulates enhanced positive-feedback signaling, dermal condensation, and expression of secreted Wnt inhibitors that reduce Wnt/β-catenin signaling in dermal cells, but not in epithelial cells expressing activated mutant β-catenin. The imbalance between positive and negative signals leads to an expanded adoption of placode fate, broad suppression of epidermal differentiation, enhanced innervation, precocious pigmentation and differentiation towards hair shaft. (C) Induced mutation in embryonic epithelium after the placode stage blocks follicle downgrowth, stimulates hair shaft differentiation, and attracts pigment deposition and innervation. (D) Induced mutation in adult telogen skin induces abnormal growth of existing follicles, and the formation of ectopic follicles from outer root sheath and epidermis. Diagrams are not to scale.

Our results indicate that Sp5 is a direct transcriptional target of β-catenin in epithelial cells, and may suppress the expression of a subset of epidermal differentiation genes, including Krt10 and involucrin, contributing to the adoption of placode rather than stratified epidermal fate. Sp1-binding sequences in the involucrin promoter are required for normal expression levels in vivo (Crish et al., 2006), and Sp5 competitively suppresses Sp1 target genes in other developmental systems (Fujimura et al., 2007), providing a possible mechanism for its effects on involucrin expression. Sp5 is expressed in wild-type placodes, suggesting a role in normal placode development. Sp5-null mice show no overt phenotype (Harrison et al., 2000); however, we speculate that Sp5 may act redundantly with Sp8 or other related genes in the skin. Activated β-catenin appears to directly or indirectly inhibit Sp1 transcript accumulation (Fig. 6A), which could provide an additional mechanism by which epidermal differentiation gene expression is suppressed in placodes.

Although the activating β-catenin mutation promotes hair follicle fate in the skin, previous analyses of KRT14-Cre Ctnnb1^(Ex3)fl/+ mutant embryos revealed enhanced and accelerated development of fungiform taste papillae and taste buds in the tongue, and ectopic tooth development in the maxilla and mandible (Jarvinen et al., 2006; Liu et al., 2008; Liu et al., 2007). Thus, the effects of stabilized ectodermal β-catenin exhibit a remarkable regional specificity. These observations suggest the existence of pre-existing regional signals that differ between the skin, and the oral epithelia of the tongue and jaws, and that determine the precise nature of the cellular responses downstream of β-catenin.

Note added in proof
While this manuscript was under revision, Nähri et al. published data similar to those described here (Nähri et al., 2008).

Supplementary material
Supplementary material for this article is available at http://dev.biologists.org/cgi/content/full/135/12/2161/DC1

	ACKNOWLEDGMENTS

 
We thank Elaine Fuchs for Topgal reporter mice, Adam Glick for K5-rtTA mice, Don Baldwin for Affymetrix array analysis, Qian-Chun Yu for TEM, Jean Richa for transgenic mouse production, Henry Sun, Pierre Coulombe and Lutz Langbein for keratin antibodies, Leroy Ash and Tzvete Dentchev for histology, and Uri Gat and George Cotsarelis for helpful discussions. This work was supported by NIH grants RO1-AR47709, R01-DE015342, RO1-HD053829 (S.E.M.) and RO1-AR45973 (A.A.D.).

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