Localisation of members of the notch system and the differentiation of vibrissa hair follicles: receptors, ligands, and fringe modulators.

Hair vibrissa follicle morphogenesis involves several cell segregation phases, in the dermis as well as in the epidermis. The expression of Notch-related genes, which are well established mediators of multiple cell segregation events in Drosophila development, was studied by in situ hybridisation during embryonic mouse vibrissa follicle morphogenesis and the first adult hair cycle. The results show that two receptors, Notch1 and -2, three ligands, Delta1, Serrate1, and -2, and the three Fringe regulators, Lunatic, Manic, and Radical, are expressed in different locations and morphogenetic stages. First, the appearance of hair vibrissa primordia involves the expression of complementary patterns of Notch2, Delta1, and Lunatic Fringe in the dermis and of Notch1, Serrate2, and Lunatic Fringe in the epidermis. Second, this expression pattern is no longer found after stage 3 in the dermis. Meanwhile, in the epidermis, the expression of Notch1, Serrate2, and Lunatic Fringe before the formation of the placode may be involved in determining two populations of epidermal cells in the developing follicle. Third, complementary expression patterns for Notch1, Manic, and Lunatic Fringe, as well as Serrate1 and -2 as previously shown (Powell et al., 1998), are progressively established from stage 4 of embryonic development both in the outer root sheath and in the hair matrix. These patterns are consistent with the one found in the adult anagen phase. During the hair vibrissa cycle, Notch1 and Manic Fringe display temporal and spatial changes of expression, suggesting that they may intervene as modulators of trichocyte activities.

Differential expression pattern of the three Fringe genes is associated with epidermal differentiation.

Epidermal differentiation, as keratinocytes go through different layers to the skin surface, may imply a differential activation of Notch transmembrane proteins. In mouse, as recently shown in Drosophila, Notch activation by its ligands may be modulated by Fringe secreted proteins. Therefore, we cloned the mouse homolog of Radical-fng, synthesized riboprobes for Lunatic-fng, Manic-fng, and Radical-fng, and examined their expression during epidermal differentiation. Expression of all three genes is differentially activated during embryonic epidermal stratification. Manic-fng and Lunatic-fng are expressed in the basal layer, whereas Lunatic-fng is expressed in the granular layer and Radical-fng is restricted to the most differentiated nucleated layer. This expression decreases by a few days postnatally and can be reactivated by retinoic acid treatment, which triggers a new distribution of Fringe transcripts and a thickening of the granular layer. Therefore, Manic, Lunatic, and Radical Fringe by modulating the Notch pathway may play a key role in defining the different steps of keratinocyte differentiation.

Chick Delta-1 gene expression and the formation of the feather primordia.

The chick dermis is known to control the formation of feathers and interfeathery skin in a hexagonal pattern. The evidence that the segregation of two types of fibroblasts involves Delta/Notch signalling is based on three facts. Rings of C-Delta-1-expressing fibroblasts precede and delimit the forming feather primordia. C-Delta-1 is uniformly expressed in the dermis of the scaleless mutant, which is almost entirely devoid of feathers. Feather development is inhibited by overexpression of C-Delta-1 in wild type dermis using a retroviral construct. We also show that the distribution of C-Delta-1 in the mutant dermis can be rescued by its association with a wild type epidermis, which acts as a permissive inducer, or by epidermal secreted proteins like FGF2.

Differential expression of two different homeobox gene families during mouse tegument morphogenesis.

The expression of six genes belonging to two different homeobox gene families was studied during the embryonic and postnatal morphogenesis of head and body regions of the mouse integument. The first family included the Otx1 and Otx2 genes, both related to the orthodenticle Drosophila gene and the second was represented by four members of the Antennapedia class HOX genes: Hoxc8 and three Hoxd genes, d9, d11 and d13. In situ hybridizations with 35S labeled antisense RNA probes were performed on head serial frontonasal sections, as well as entire embryo and postnatal tail longitudinal sections. The expression of these genes shows a differential spatiotemporal pattern along the cephalo-caudal axis. In 12.5-day and 15.5-day embryos, the Otx2 gene expression is restricted to the nasal epithelium and its associated glands, while the Otx1 transcripts are present in both nasal and facial integuments, including nasal glands and hair vibrissa follicles. The Hoxc8 expression first appears in skin at 14.5 days of gestation in the sternal region and is extended at 16.5 days to the thoracic ventral and lumbar dorsal regions. The Hoxd9 and Hoxd11 genes are only expressed in the caudal skin from 14.5 days of gestation. The Hoxd13 transcripts are the last to appear, 2 days after birth, and are limited to the last epidermal cells to differentiate, i.e. those of the hair matrix of the caudal pelage hair follicles. Taken together, these observations strengthen the hypothesis that different homeobox gene families specify the regional identity of the skin in the cephalic and body regions.

Retinoic acid and mouse skin morphogenesis. II. Role of epidermal competence in hair glandular metaplasia.

Retinoic acid (RA) has marked effects on mouse upper-lip skin morphogenesis, leading to the development of glomerular gland instead of hair vibrissa follicle, but does not apparently change the dorsal pelage hair developmental program. In order to test the hypothesis that an up-regulation of the beta retinoic acid nuclear receptor (RAR beta) may be implicated in the alteration of the dermal-epidermal interactions which occur during cutaneous appendage development, RA-treated and untreated skin explants, controls as well as heterotopic recombinants, were made among nasal, upper-lip, and dorsal mouse embryonic tissues. They were analyzed by in situ hybridization with RAR beta 35S-labeled probe after 48 hr of in vitro culture as well as by identification of the morphological phenotype of cutaneous appendages after 6 additional days of culture on the chick chorioallantoic membrane. The results show that only mesenchyme from the facial region can express the RAR beta gene either normally or after RA treatment, depending on its nasal or upper-lip origin. However, the RAR beta up-regulation is unrelated to hair glandular metaplasia, which depends both on a glandular bias of the upper-lip epidermis and on the weakening of hair follicle-inducing dermal properties. The latter occurs in both the upper-lip and dorsal dermis as a consequence of RA treatment.

Retinoic acid and mouse skin morphogenesis. I. Expression pattern of retinoic acid receptor genes during hair vibrissa follicle, plantar, and nasal gland development.

The spatial and temporal expression of the nuclear retinoic acid receptors alpha, beta, and gamma (RAR-alpha, beta, and gamma) was compared by in situ hybridization during hair vibrissa follicle and nasal and plantar eccrine gland morphogenesis in mouse embryo. The RAR-alpha and RAR-gamma transcripts are abundant in the dermal papilla cells of the hair vibrissa when these cells elicit epidermal hair placode (12.5-d embryos) and hair follicle (13.5-d embryos) formation. Both these transcripts are also abundant in the dermal cells of the plantar foot pad at the initiation stage (17.5-d embryos) of glandular morphogenesis. In epidermal cells, the distribution of RAR-gamma transcripts increases in parallel with hair vibrissa follicle and sweat gland differentiation, and thus may be part of the epidermal response to the dermal instructions. The RAR-beta signal is barely above control level during both hair vibrissa and plantar gland morphogenesis. By contrast, during nasal gland formation (12.5- to 15.5-d embryos), the RAR-beta signal reaches a high level in mesenchymal cells, whereas the RAR-alpha-transcripts are present in both epithelial and mesenchymal cells. These results suggest a role for RAR-alpha and RAR-gamma in the epidermal-dermal interactions that lead to hair follicle and plantar gland morphogenesis, whereas the nasal gland development implies RAR-alpha and RAR-beta gene expression. This should be correlated with the expression of the RAR-beta gene that was previously shown to be linked to the RA-induced glandular metaplasia of hair vibrissa follicles.

Retinoic acid-induced glandular metaplasia in mouse skin is linked to the dermal expression of retinoic acid receptor beta mRNA.

The distribution of transcripts of nuclear (RAR alpha, RAR beta, and RAR gamma) and cytosolic (CRABP) retinoic acid receptors was analyzed in 13.5-day mouse embryo upper-lip skin, cultured in vitro for 48 hr with or without added retinoic acid. The results show a significant up-regulation of the transcription of the RAR beta gene concomitant with the initiation of an alteration of hair vibrissae follicle development, leading, after transfer for 8 days to the chick embryo chorioallantoic membrane, to an exocrine-type gland morphogenesis.