Patent Application
20090203574
Hair follicle morphogenesis involves a temporal series of reciprocal interactions between the ectoderm and its underlying mesenchyme (Hardy (1992) Trends Genet. 8:55; Millar (2002) J. Invest. Dermatol. 118:216; Schmidt-Ullrich and Paus (2005) Bioessays 27:247). During embryogenesis, the skin epidermis develops from a single uniform layer of multipotent cells, separated from the mesenchymally-derived dermis by a basement membrane of extracellular matrix. Cells of this proliferative basal layer can be committed into one of two major lineages. To serve its function as a protective barrier, cells directed towards the epidermal lineage begin a program of terminal differentiation by detaching from the basement membrane, moving outward toward the skin surface, and undergoing metabolic changes to create a keratinized, stratified squamous cell layer. Alternatively, cells of the basal layer can give rise to hair follicles. In response to inductive signals, embryonic hair morphogenesis begins with a localized thickening of epidermal cells and a subsequent bud-like down-growth into the dermis. Known as a hair placode or hair germ, these cells send a reciprocal signal back to the underlying mesenchymal cells to organize into a dermal condensate, the precursor of the dermal papilla. As the hair follicle continues to develop by growing further down into the dermis, a group of rapidly proliferating follicular cells called the matrix surrounds the dermal papilla, forming the hair bulb. Cells losing contact with the hair bulb become the outer root sheath, contiguous with the interfollicular epidermis. The close association between the matrix and dermal papilla within the hair bulb likely results in another set of epithelial-mesenchymal exchange of signals to begin terminal hair differentiation. Specific hair lineages are adopted by the matrix cells as they move upward in concentric rings of cells to form the different layers of the hair follicle, including the inner root sheath and hair shaft. At some point during this morphogenetic process, stem cells residing in the bulge are specified and set aside for the postnatal hair cycle and epidermal repair.
Some of the molecular events involved in hair follicle morphogenesis have been elucidated. In response to an inductive Wnt and an inhibitory Bmp signal (Noggin), small hair placodes bud from the epithelium, giving rise to larger hair germs (DasGupta and Fuchs (1999) Development 126:4557; Huelsken, et al. (2001) Cell 105:533; Botchkarev, et al. (1999) Nature Cell Biol. 1:158; Jamora, et al. (2003) Nature 422:317). In the presence of the mitogen Shh, these hair germs develop further and grow downwards to form a mature follicle that actively produces hair (Chiang, et al. (1999) Dev. Biol. 205:1; Oro and Higgins (2003) Dev. Biol. 255:238; St-Jacques, et al. (1998) Curr. Biol. 8:1058). Although the molecular details of bud formation are still being defined, the general features of this process are repeated at the start of each postnatal hair cycle when multipotent stem cells in the hair follicle bulge become activated to initiate a new round of hair growth. In addition, the early epithelial remodeling to form the hair germ shares many features with the development of other epithelial tissues and organs, including feathers, teeth, and mammary glands (Hogan (1999) Cell 96:225; Pispa and Thesleff (2003) Dev. Biol. 262:195; Yue, et al. (2005) Nature 438:1026). Understanding how tissues form buds which then progress along different lineages is predicated on elucidating the molecular mechanisms that funnel these early signaling pathways into a transcriptional program that drives morphogenesis.
The present invention is a method for modulating hair growth by regulating the expression or activity of Lhx2. The present invention also relates to the use of Lhx2 in a screening assay to identify an agent which modulates hair growth. The screening assay involves contacting a test cell expressing a reporter operably linked to an Lhx2 promoter with an agent and detecting expression of the reporter in the test cell, wherein a decrease in reporter expression is indicative of an agent which stimulates hair growth and an increase in reporter expression is indicative of an agent which inhibits hair growth.
It has now been found that Lhx2 is a transcription factor positioned downstream of signals necessary to specify hair follicle stem cells, but upstream from signals required to drive activated stem cells to terminally differentiate. Using gain and loss of function studies, Lhx2 was found to maintain the growth and undifferentiated properties of hair follicle progenitors. Accordingly, the present invention relates to the use of Lhx2 as a target for modulating hair growth. For example, by increasing the expression or activity of Lhx2, hair follicles can be maintained in a resting or quiescent state thereby preventing or reducing unwanted hair growth, whereas decreasing the expression or activity of Lhx2 can be employed in the stimulation or activation of follicle stem cell proliferation and therefore stimulation of hair growth. Thus, the present invention also embraces screening assays for identifying agents which modulate the expression or activity of Lhx2. Such agents can be identified in in vitro or in vivo screening assays which monitor the activity or expression of Lhx2 (e.g., via reporter protein expression). Agents which can be screened in accordance with the instant assays include the Lhx2 protein or fragments thereof, as well as agonistic or antagonistic anti-Lhx2 antibodies. Ribozymes, siRNA, antisense oligonucleotides and the like can be screened for inhibiting the expression of Lhx2 and small organic molecules can be identified which inhibit or stimulate the expression or activity of Lhx2.
Embryonic hair progenitors were isolated using mice doubly transgenic for a Keratin 14-GFP gene expressed in skin keratinocytes and the Wnt reporter gene TOPGAL, transcribed in hair placodes and germs where β-catenin/Lef1 complexes are active (DasGupta and Fuchs (1999) supra; Vaezi, et al. (2002) Dev. Cell 3:367). In these early hair progenitors, E-cadherin is down-regulated and P-cadherin is upregulated (Jamora, et al. (2003) supra). By embryonic day 17 (E17), dispase was used to separate the epidermis, including hair placodes and germs, from the underlying dermis, which harbored more mature hair pegs and follicles. Using fluorescence-activated cell sorting (FACS) on the epidermal fraction, the early “PCAD+” hair progenitors (K14-GFP+, α6-integrin+, P-cadherin+) were then separated from the “PCAD−” interfollicular epidermis (K14-GFP+, α6-integrin+, P-cadherin−) based on their differential surface P-cadherin expression. Characterization of these two cell populations confirmed their similarities in K5 and β4-integrin expression, but their distinct activities of TOPGAL and expression of known hair placode markers.
The gene expression profiles of purified PCAD+ hair progenitors and PCAD− interfollicular basal keratinocytes were further analyzed using oligonucleotide microarrays. Utilizing fold differences of known hair placode markers as a sensitivity gauge, a 2-fold cut-off was assigned as a genuine difference between the two populations. A total of 1394 probes (660 in PCAD+; 734 in PCAD−) were preferentially expressed greater than 2-fold in one population over the other (Table 1). The Mean Log2 Ratio of Table 1 was calculated for PCAD+ with respect to PCAD− signal values.
A short list of differentially expressed genes relevant to the present study is provided in Table 2. Genes designated with “#” were upregulated and genes designated with “*” were downregulated within the bulge stem cells of postnatal hair follicles compared against the total skin epithelial cell population (Blanpain, et al. (2004) Cell 118:6). A number of these genes have documented roles in either hair morphogenesis (PCAD+) or epidermal differentiation (PCAD−). The interfollicular epidermal population was typified by adhesive and cytoskeletal components, Notch signaling factors, C-myc, Kruppel-like factors, as well as Bmp-responsive transcription factors (Grainyhead-like, Ovol) previously implicated in epidermal differentiation (Fuchs and Raghavan (2002) Nature Rev. Genet. 3:199; Tao, et al. (2005) Development 132:1021; Ting, et al. (2005) Science 308:411; Arnold and Watt (2001) Curr. Biol. 11:558). In contrast, the hair germ signature featured Wnts, Shh, Bmps, Tgfβs, and tyrosine kinase receptor signaling morphogens, as well as a number of different transcription factors. Although some of these transcription factors have not been previously implicated in the specification of skin progenitor fates, others have previously been associated with postnatal genetic hair disorders, including Cutl1, Gli1, Hoxc13, Sox9, Trps1, and Vdr (Millar (2002) supra; Schmidt-Ullrich, et al. (2005) supra).
Unexpectedly, several of the uncharacterized transcription factors on this list were also found to be differentially expressed in the postnatal hair follicle bulge (Blanpain, et al. (2004) supra; Morris, et al. (2004) Nature Biotechnol. 22:411) (Table 2), indicating that the embryonic hair germ may exhibit functional properties similar to adult stem cells. Although the hair germ is committed to a follicular cell fate, it remains undifferentiated like bulge stem cells, yet capable of differentiating into all the lineages of the hair follicle, including the sebaceous gland (Ito, et al. (2005) Nature Med. 11:1351; Levy, et al. Dev. Cell 9:855).
To determine whether the early hair germs may reflect hair follicle stem cells and regulate key steps in progenitor cell differentiation, focus was placed on the transcription factors emanating from the screen that were known to govern developmental cell fate specification in other tissues and organs. Lim-homeodomain transcription factor Lhx2 was of interest since Lhx2 null mutant animals display defects in patterning and cell fate determination during brain development (Porter, et al. (1997) Development 124:2935; Bulchand, et al. (2001) Mech. Dev. 100:165; Hirota and Mombaerts (2004) Proc. Natl. Acad. Sci. USA 101:8751). In addition, they lack definitive erythropoeisis and conversely, hematopoetic progenitor cells can be maintained in vitro by forced expression of Lhx2 (Pinto do, et al. (2002) Blood 99:3939). Lhx2 null animals die between E15.5-E16.5, and a possible role for Lhx2 in skin has not been examined.
Lhx2 was upregulated 18-fold in the PCAD+ population relative to PCAD− population by microarray. Semi-quantitative RT-PCR and in situ hybridization confirmed this marked differential expression. By immunofluorescence, Lhx2 first appeared in early hair placodes, and as morphogenesis progressed, became prominent at the leading front of invaginating hair germs and pegs. As down-growth neared completion and hair differentiation began, Lhx2 concentrated in the upper outer root sheath (ORS) at a presumptive site (bulge) of the developing postnatal follicle stem cell compartment. Concomitantly, expression diminished at the base of the follicle, where highly proliferative matrix cells give rise to the differentiating inner root sheath and hair shaft. In adult follicles, Lhx2 concentrated in the bulge, and as the new hair cycle initiated, Lhx2 extended to the emerging secondary hair germs. Based upon these patterns, Lhx2 appeared to function in specifying the embryonic hair follicle progenitor cells that then persist as bulge stem cells in adult follicles.
To more precisely define Lhx2's role in hair follicle stem cell specification and/or maintenance, its status was examined in various genetic mutant embryos defective in different aspects of hair morphogenesis. In the complete absence of hair follicle induction or bulge maintenance, as reflected in β-catenin conditionally null (cKO) skin, Lhx2 was not expressed. In Shh knockout embryos, where hair germs are specified but unable to progress, Lhx2 expression was dramatically reduced. This positioned Lhx2 downstream of Wnt and Shh, where it could play a role in establishing or expanding the early progenitors necessary for hair follicle morphogenesis.
Bmp signaling is not required for hair follicle induction, even though Bmp ligands and receptors are expressed in embryonic hair germs and in postnatal follicle stem cells. Correspondingly, in BmpR1a cKO skin, Lhx2 was expressed in both embryonic hair germs and the presumptive bulge of developing follicles. Conversely, Bmp signaling is required for differentiation, and in the absence of BmpR1a, proliferating undifferentiated hair progenitor cells accumulate at the follicle base (Andl, et al. (2004) Development 131:2257; Kobielak, et al. (2003) J. Cell Biol. 163:609). Lhx2 was noticeably enhanced in these follicles, with strong staining throughout the ORS and matrix. These cells were also positive for Shh and Lef1. Thus, in the absence of terminal hair differentiation, cells accumulating in postnatal BmpR1a null follicles resembled early embryonic hair follicle progenitors.
If Lhx2 governs the gene expression program of undifferentiated follicle stem cells or their early progenitors, then misexpression of Lhx2 in interfollicular epidermis might result in an induction of hair follicle progenitor genes. Accordingly, K14-Lhx2 transgenic mice were generated to examine this possibility. Although more hair follicles were not induced, Lhx2 markedly suppressed morphological and biochemical signs of epidermal differentiation and failed to produce a functional lipid barrier. Most notable was the induction of Tcf3 and Sox9, two key transcription factors of adult hair follicle stem cells (Merrill, et al. (2001) Genes Dev. 15:1688; Vidal, et al. (2005) Curr. Biol. 15:1340). Lhx2 also suppressed differentiation in tongue epithelium. These findings indicate that Lhx2 can maintain cells in an undifferentiated state, further enforcing the link between Lhx2 and stemness.
If Lhx2 is required for follicle stem cell maintenance, then its absence could alter the ability of hair follicles to form. In support of this notion, E16 Lhx2 null embryos displayed an −40% reduction in overall density of P-cadherin positive hair follicles, with no noticeable defect in the epidermis or embryo size. Marked reduction in follicle density is a feature of other mouse mutants in key hair follicle morphogenetic genes. Although Lhx2 KO follicle density was reduced, Shh, Wnt10b, Bmp2, Bmp4 and Lef1 expression appeared unaffected in those hair placodes and germs that developed. In Lhx2 null skin engraftments, follicles appeared morphologically and biochemically indistinguishable from their wild-type counterparts. Taken together, the gain and loss of function studies indicate that Lhx2, reflecting its expression pattern, functions to specify and maintain hair follicle stem cells, but does not function in their differentiation.
If Lhx2 maintains the undifferentiated state of embryonic and adult follicle stem cells, then Lhx2 null follicles might exhibit alterations in the transition of stem cells from the resting (telogen) to the growing (anagen) phase of the postnatal hair cycle. Using skin grafts, the hair cycles of wild-type and Lhx2 KO follicles were compared. The initial morphogenetic and first postnatal Lhx2 KO hair cycles progressed similarly to wild-type and by 8 weeks, KO follicles had returned to telogen. By contrast, at 11 weeks when most wild-type follicles were still in this extended telogen, KO follicles had precociously entered the next hair cycle. Moreover, upon shaving at 8 weeks, most wild-type hairs remained in telogen while KO hairs consistently and uniformly grew back within 3 weeks, confirming their shortened resting phase.
Immunofluorescence and FACS analyses revealed that KO follicles exhibited diminished CD34, a surface marker of bulge stem cells (
Although CD34 marks adult stem cells, it is not found in embryonic skin progenitors, suggesting that its reduction could be an indication of enhanced proliferative activity within KO follicle stem cells. This was supported by bromodeoxyuridine (BrdU) pulse-chase experiments conducted prior to marked deviations in hair cycling (
The reduction in label retention was accompanied by enhanced proliferation within the KO bulge. After a 4-hour BrdU pulse during full anagen, the percentage of S-phase labeled bulge cells was 2× higher than normal (
By isolating and transcriptionally profiling embryonic hair placodes and interfollicular epidermis, genes implicated in hair development have been identified (Table 1) and novel differences have been uncovered that could be important in orchestrating lineage specification of multipotent skin progenitors. By way of illustration, Lhx2 studies revealed that it functions as a molecular brake in regulating the switch between hair follicle stem cell maintenance and activation. Although follicles can be specified embryonically without Lhx2, their overall numbers are reduced, and Lhx2 null follicles that do form are not proficient in maintaining the resting state and precociously activate. Once committed, cells no longer require or express Lhx2 and progress along a normal program of terminal differentiation.
Finally, Lhx2 is the first identified marker expressed specifically by both embryonic hair placodes and postnatal follicle stem cells of the bulge. Lhx2 now provides a segue to dissect the transcriptional mechanisms that underlie stem cell maintenance within the hair follicle and also serves as a target for modulating hair growth. Further, one or more of the genes identified as being involved in embryonic hair placodes and interfollicular epidermis (Table 1) can be used as a signature of the early hair germ that makes a follicle. Moreover, as with Lhx2, it is contemplated that one of more of the genes listed in Table 1 can be used as targets for modulating hair growth.
The invention is described in greater detail by the following non-limiting examples.
Lhx2−/−; Shh−/−; BmpR1afl/fl; Pcad−/−; β-cateninfl/fl are known in the art and were produced according to convention methods. TOPGAL and K14-GFPactin transgenic mice are also known in the art (DasGupta and Fuchs (1999) supra; Vaezi, et al. (2002) Dev. Cell 3:367). Lhx2 transgenic mice were generated by cloning full-length murine Lhx2 cDNA (GENBANK Accession No. NM_010710) into a vector driving expression from the human keratin 14 promoter faithfully expressed in the interfollicular epidermis and outer root sheath of hair follicles (Vasioukhin, et al. (1999) Proc. Natl. Acad. Sci. USA 96:8551).
Full thickness skins were removed from the torsos of sex-matched wild type and Lhx2 null E15.5 embryos, and placed onto the backs of anesthetized female nu/nu (Nude) recipient mice, with each recipient receiving a WT and KO graft. Grafts were secured by sterile gauze and cloth bandages, which were removed after healing (12-13 days). Hairs typically appeared within 1 week after grafting. A total of forty grafts were placed (20 wild-type and 20 KO), and each showed a consistent phenotype dependent on the presence or absence of Lhx2 in the donor skin. 5′-Bromo-2′-deoxyuridine (BrdU; Sigma-Aldrich, St. Louis, Mo.) pulse-chase experiments were performed as described. Intra-peritoneal injections (50 μg/g BrdU) were carried out twice a day for 3 days at day 26 to 28 post-graft and analyzed 4 weeks later for label retention. For cell cycle analysis, mice were injected once with 50 μg/g BrdU at day 40 postgraft and analyzed 4 hours later for BrdU incorporation. A minimum of 4 grafts (two wild-type and two Lhx2 KO) were used for each BrdU experiment. Since K14-Lhx2 transgenic mice died perinatally, newborn back skins were similarly grafted.
Tissues were embedded in OCT and frozen sections were fixed in 4% paraformaldehyde and subjected to immunofluorescence microscopy or hematoxylin/eosin staining. When applicable, the MOM basic kit (Vector laboratories) was used to prevent non-specific binding of mouse monoclonal antibodies (Abs). Antibodies and dilutions used: Lhx2 (rabbit, 1:2500); P- and E-cadherins (rat, 1:100); α6-integrin (rat, 1:100; Pharmingen); K5 (rabbit, 1:500); K1 (rabbit, 1:500); Filaggrin (rabbit, 1:500; Covance); β4-integrin (rat, 1:100; Pharmingen); CD34 (rat, 1:100; Pharmingen); Tenascin C (mouse, 1:500; IBL); S100A6 (rabbit, 1:100; Lab Vision); BrdU (rat, 1:500; Abcam); Tcf3 (guinea pig, 1:300); Sox9 (rabbit, 1:100; Santa Cruz); Lef1 (rabbit, 1:250); Gata3 (mouse, 1:100; Santa Cruz); K6 (rabbit, 1:500); AE13 and AE15 (mouse, 1:50); FITC (1:100; Jackson) or Alexa594 (1:1000; Molecular Probes) conjugated secondary Abs. Nuclei were stained using 4′6′-diamidino-2-phenylindole (DAPI). Imaging was performed using ZEISS AXIOSKOP and AXIOPHOT microscopes equipped with SPOT RT (Diagnostic Instruments) and AXIOCAM (ZEISS) digital cameras, respectively.
Back skins from E17.5 K14-GFP embryos were dissected and treated overnight with dispase (Gibco, 0.4 mg/mL) at 4° C., which selectively removed the epidermis, hair placodes, and hair germs from the rest of the skin. This epidermal fraction was treated with 10 mM EDTA, and neutralized cell suspensions were strained (40 μM pores; BD Bioscience). Single cells were resuspended in PBS containing CaCl2 and MgCl2 (GIBCO) with 5% FBS, and incubated with primary antibodies coupled to biotin for 30 minutes on ice. After washing with PBS, cells were stained with streptavidin and antibodies directly conjugated to specific fluorophors for 30 minutes on ice. Cells were washed in PBS and resuspended in 300 ng/mL propidium iodide for dead cell exclusion. Cell isolations were performed on FACSVANTAGE SE system equipped with FACS DIVA software (BD Biosciences). Epidermal cells were gated for single events and viability, then sorted according to their expression of K14-GFP, α6-integrin, and P-cadherin. Purity of sorted cells was determined by post-sort FACS analysis and typically exceeded 95%. For grafted skin, single cell suspensions of total skin were isolated by dissecting the graft, mincing into small pieces, and sequential treatment with collagenase (SIGMA) and trypsin (GIBCO) at 37° C. Cells were strained and stained as above. Flow cytometry was performed on FACSORT equipped with CELLQUEST (BD Biosciences). Primary antibodies used for FACS: P-cadherin conjugated to biotin (1:100); α6-integrin coupled to APC or PE (1:100; Pharmingen); β4-integrin (1:100; Pharmingen) coupled to APC; CD34 conjugated to biotin (1:50; Pharmingen). BrdU detection was performed using BrdU Flow Kit (Pharmingen). Cytospin analysis was performed with a Cytospin4 unit (Thermo/Shandon), and stained according to standard methods.
Total RNAs from FACS sorted cells were isolated and assessed for quality as described (Rendl, et al. (2005) PLOS Biol. 3:e331). Two rounds of amplification/labeling of 200 ng RNA was performed to obtain biotinylated cRNA for hybridization onto AFFYMETRIX GENECHIP Mouse Genome MOE430 2.0 oligonucleotide microarrays at the Genomics Core Laboratory of Memorial Sloan-Kettering Cancer Center (New York, USA). Two entirely independent samples were used for data analyses. Scanned microarray images were imported into Gene Chip Operating Software (GCOS, AFFYMETRIX) to generate signal values and present/absent calls for each probe set using the MAS 5.0 statistical expression algorithm. Each array was scaled to a target signal of 500 using default analysis parameters. Data files were imported into GENETRAFFIC 3.8 (Iobion Informatics), and replicate microarrays were grouped and compared using the Robust Multi-Chip Analysis algorithm. Genes represented with probe sets ≧2-fold increased in one population over the other and called present in both replicates were considered significant for further analysis.
Total RNA from FACS sorted cells was isolated as above, quantified with RIBOGREEN (Molecular Probes), and normalized RNA quantities were reverse transcribed with SUPERSCRIPT III using oligo-dT primers (INVITROGEN). PCR amplification of selected genes of interest was performed using primers designed to produce a product spanning exon/intron boundaries.
17B04Rik /// LOC38
indicates data missing or illegible when filed
This invention was made in the course of research sponsored by the National Institutes of Health (Grant No. R01-AR050452). The U.S. government may have certain rights in this invention.
| Filing Document | Filing Date | Country | Kind | 371c Date |
|---|---|---|---|---|
| PCT/US07/69936 | 5/30/2007 | WO | 00 | 11/5/2008 |
| Number | Date | Country | |
|---|---|---|---|
| 60810007 | May 2006 | US |
