BEN/DM-GRASP/SC1 expression during mouse facial development: differential expression and regulation in molars and incisors

The cell adhesion molecule BEN/DM-GRASP/SC1 is expressed in a variety of tissues during embryogenesis. Here, we studied the expression pattern of BEN/DM-GRASP/SC1 in different organs involved in facial mouse development, especially in the developing teeth. BEN/DM-GRASP/SC1 was expressed in nose, whisker, gland, and tongue epithelia, as well as in myogenic mesenchyme. In molars, BEN/DM-GRASP/SC1 was firstly expressed in the condensed mesenchyme and thereafter expression was confined to mesenchymal cells of the dental follicle. In contrast, in incisors, transient BEN/DM-GRASP/SC1 expression was restricted to epithelium. In tissue recombination experiments, BEN/DM-GRASP/SC1 expression in mesenchyme was activated by molar, but not incisor epithelium.     

A widely distributed antigen developmentally regulated in the nervous system

We have identified a glycoprotein (BEN) of 95-100 x 10(3) Mr using a monoclonal antibody. This protein is transiently expressed at the cell surface of the peripherally projecting neurons, i.e. motoneurons of the spinal cord and cranial nuclei, sensory neurons of the dorsal root and cranial sensory ganglia and sympathetic, parasympathetic and enteric neurons. In vitro cultures of dorsal root and sympathetic ganglia have shown that BEN is expressed on neurons but not on glial cells. On motor and sensory neurons, BEN first appears at the level of the cell body just after withdrawal from the cell cycle. Soon afterwards, expression of the antigen extends to the elongating axon. After a few days, BEN is no longer expressed by the motor and sensory neurons, disappearing first from the cell body and then progressively from the fibres. The loss of expression is concomitant with the onset of intense proliferation of satellite and Schwann cells. This modulated expression within the nervous system is unlike that of any surface glycoprotein so far described in vertebrates. Preliminary biochemical analysis indicates that, although it bears the adhesion-associated epitope HNK-1, BEN does not share characteristics with any previously described axonal glycoprotein. Consequently, we speculate that this glycoprotein might be a novel molecule implicated in selective adhesion phenomena, such as axonal fasciculation.     

Expression of the Intermediate Filament Keratin Gene,K15,in the Basal Cell Layers of Epithelia and the Hair Follicle

The intermediate filament keratin, K15, is present in variable abundance in stratified epithelia. In this study we have isolated and characterized the sheepK15gene, focusing on its expression in the follicles of sheep and mice. We show thatK15is expressed throughout the hair cycle in the basal layer of the outer root sheath that envelops the follicle. Strikingly, however, in large medullated wool follicles, a small group of basal outer root sheath cells located in the region thought to contain hair follicle stem cells areK15-negative. In the follicle bulbK15is expressed in cells situated next to the dermal papilla but not in the inner bulb cells. Elsewhere,K15is expressed at a low, variable level in the basal layer of the epidermis and sebaceous gland, often in a punctate pattern. In the esophagus of the sheepK15expression is restricted to the basal layer, in contrast to human esophagus where it is expressed throughout the epithelium. Transgenic mouse lines established with a 15-kb sheepK15gene construct exhibited faithful expression and showed no phenotypic consequences ofK15overexpression. An investigation of transgene expression showed thatK15is continuously expressed in outer root sheath cells during the hair cycle. Given its expression in the mitotically active basal cell layers of diverse epithelia and the follicle,K15expression appears to signal an early stage in the pathway of keratinocyte differentiation that precedes the decision of a cell to become epidermal or hair-like.     

Tissue, cellular and sub-cellular localization of the Vangl2 protein during embryonic development: effect of the Lp mutation

Loop-tail (Lp) mice show a very severe neural tube defect, craniorachischisis, which is caused by mis-sense mutations in the Vangl2 gene. The membrane protein Vangl2 belongs to a highly conserved group of proteins that regulate planar polarity in certain epithelia, and that are also important for convergent extension movements during gastrulation and neurulation. A specific anti-Vangl2 antiserum was produced and used to examine the tissue, cell type, and sub-cellular localization of Vangl2 during embryogenesis. Vangl2 protein is expressed at high levels in the neural tube and shows a dynamic expression profile during neurulation. After neural tube closure, robust Vangl2 staining is detected in several neural and neurosensory tissues, including cerebral cortex, dorsal root ganglia, olfactory epithelium, retina, mechanosensory hair cells of the cochlea, and optic nerve. Vangl2 is also expressed during organogenesis in a number of tubular epithelia, including the bronchial tree, intestinal crypt/villus axis, and renal tubular segments derived from ureteric bud and from metanephric mesenchyme. Examination of Vangl2 localization in the neural tubes and cochleas of the normal and Lp/Lp embryos shows disruption of normal membrane localization of Vangl2 in independent alleles at Lp (Lp, Lp(m1Jus)) as well as overall decrease in the expression level.     

Development and evolution of inner ear sensory epithelia and their innervation

The development and evolution of the inner ear sensory patches and their innervation is reviewed. Recent molecular developmental data suggest that development of these sensory patches is a developmental recapitulation of the evolutionary history. These data suggest that the ear generates multiple, functionally diverse sensory epithelia by dividing a single sensory primordium. Those epithelia will establish distinct identities through the overlapping expression of genes of which only a few are currently known. One of these distinctions is the unique pattern of hair cell polarity. A hypothesis is presented on how the hair cell polarity may relate to the progressive segregation of the six sensory epithelia. Besides being markers for sensory epithelia development, neurotrophins are also expressed in delaminating cells that migrate toward the developing vestibular and cochlear ganglia. These delaminating cells originate from multiple sites at or near the developing sensory epithelia and some also express neuronal markers such as NeuroD. The differential origin of precursors raises the possibility that some sensory neurons acquire positional information before they delaminate the ear. Such an identity of these delaminating sensory neurons may be used both to navigate their dendrites to the area they delaminated from, as well as to help them navigate to their central target. The navigational properties of sensory neurons as well as the acquisition of discrete sensory patch phenotypes implies a much more sophisticated subdivision of the developing otocyst than the few available gene expression studies suggest.     

BEN, a novel surface molecule of the immunoglobulin superfamily on avian hemopoietic progenitor cells shared with neural cells.

BEN is a novel molecule of the immunoglobulin superfamily that we previously identified by means of a monoclonal antibody on neural cell populations during avian development and epithelial cells of the bursa of Fabricius. In this paper, we describe the expression of BEN by hemopoietic cells during ontogeny. In the thymus, BEN is expressed as early as E9, and from E12 until just after hatching 30-60% of thymocytes are BEN positive. Thus the cells expressing BEN are immature thymocytes and not yet differentiated T cells. In the spleen, BEN expression parallels the myelopoietic activity. It is present on 75% of splenocytes during embryonic development and falls rapidly to 20% of cells during the first week after hatching when the spleen is becoming a secondary lymphoid organ. BEN is also found on a large proportion (about 80% positive cells) of bone marrow cells during ontogeny. Post hatching, BEN is present on 40-50% of bone marrow cells. The population of BEN-positive cells in the bone marrow includes myeloid and erythroid progenitor cells, identified by their ability to form colonies in vitro. BEN expression is lost as progenitor cells proliferate and differentiate to develop mature colonies in the clonal assay. Mature myeloid cells, such as macrophages, granulocytes, thrombocytes, and erythrocytes do not express the BEN antigen. Taken together, these data demonstrated that BEN is a stage-specific rather than a lineage-specific differentiation antigen expressed by immature hemopoietic cells.     

DM-GRASP, a novel immunoglobulin superfamily axonal surface protein that supports neurite extension

We have identified a 95 kd cell surface protein, DM-GRASP, that is expressed on a restricted population of axons. Its expression begins early in chick embryogenesis, and within the spinal cord it is localized to axons in the dorsal funiculus, midline floorplate cells, and motoneurons. Antibodies to DM-GRASP impair neurite extension on axons, and purified DM-GRASP supports neurite extension from chick sensory neurons. We have cloned and sequenced the cDNA corresponding to this protein and find that it is a new member of the immunoglobulin superfamily of adhesion molecules. Consequently we have named this protein DM-GRASP, since it is an immunoglobulin-like restricted axonal surface protein that is expressed in the dorsal funiculus and ventral midline of the chick spinal cord.     

Desmoglein 4 is expressed in highly differentiated keratinocytes and trichocytes in human epidermis and hair follicle

Desmosomes are critical for the tissue integrity of stratified epithelia and their appendages. Desmogleins (DSGs) and desmocollins (DSCs) are transmembrane desmosomal cadherins that interact extracellularly to link neighboring epithelial cells. We recently identified a new member of the DSG family, designated desmoglein 4, whose mutations cause hypotrichosis in human, mouse and rat. In this study, we analyzed in detail the expression domains of human desmoglein 4 protein (DSG4) in human skin relative to differentiation markers and other DSGs. Our results show that DSG4 protein is expressed in the more highly differentiated layers of the epidermis. This expression pattern in vivo is recapitulated in highly differentiated HaCaT human keratinocytes and normal human keratinocytes in vitro. In the human hair follicle, DSG4 is expressed specifically in the hair shaft cortex, the lower hair cuticle, and the upper inner root sheath (IRS) cuticle. Using a green fluorescent protein-tagged version of mouse or rat desmoglein 4 protein (Dsg4) and immuno-electron microscopy, we demonstrate that Dsg4 localizes to desmosomes both in vitro and in vivo. The highly specific expression pattern of DSG4 in the human hair follicle, combined with the phenotype of rodent models and human patients with desmoglein 4 mutations, underscores the importance of this adhesion molecule in the integrity of the hair shaft.     

OsCSLD1, a cellulose synthase-like D1 gene, is required for root hair morphogenesis in rice

Root hairs are long tubular outgrowths that form on the surface of specialized epidermal cells. They are required for nutrient and water uptake and interact with the soil microflora. Here we show that the Oryza sativa cellulose synthase-like D1 (OsCSLD1) gene is required for root hair development, as rice (Oryza sativa) mutants that lack OsCSLD1 function develop abnormal root hairs. In these mutants, while hair development is initiated normally, the hairs elongate less than the wild-type hairs and they have kinks and swellings along their length. Because the csld1 mutants develop the same density and number of root hairs along their seminal root as the wild-type plants, we propose that OsCSLD1 function is required for hair elongation but not initiation. Both gene trap expression pattern and in situ hybridization analyses indicate that OsCSLD1 is expressed in only root hair cells. Furthermore, OsCSLD1 is the only member of the four rice CSLD genes that shows root-specific expression. Given that the Arabidopsis (Arabidopsis thaliana) gene KOJAK/AtCSLD3 is required for root hair elongation and is expressed in the root hair, it appears that OsCSLD1 may be the functional ortholog of KOJAK/AtCSLD3 and that these two genes represent the root hair-specific members of this family of proteins. Thus, at least part of the mechanism of root hair morphogenesis in Arabidopsis is conserved in rice.     

An antigen expressed by avian neuronal cells is also expressed by activated T lymphocytes.

A monoclonal antibody, anti-BEN, initially characterized by its reactivity with an epitope present on the surface of avian bursa epithelial cells and neurons, also reacts with membrane molecules on some hemopoietic cells. In this study we examine BEN expression on lymphoid cells in thymus, spleen, and blood. We demonstrate that BEN is an activation antigen on mature T lymphocytes. It is not expressed on peripheral blood or splenic lymphocytes, but following mitogenic or allogeneic stimulation of blood lymphocytes it appears rapidly on a T cell subpopulation in parallel with the appearance of IL-2 receptors. BEN is also expressed on III-C5 cells, an avian IL-2-dependent permanent T cell line, and on immature CD4+CD8+ thymocytes. BEN is not expressed by resting or actively proliferating B cells. Biochemical analyses of the BEN protein on T lymphoblasts shows that the molecule is similar in size to the BEN molecules on bursa epithelial cells and on neurons. The physicochemical properties of the BEN protein and its tissue distribution differs from other known avian and mammalian T cell activation markers, differentiation antigens, and integrins. Thus BEN is a novel marker of activated T cells in birds.     

The retinoblastoma gene pathway regulates the postmitotic state of hair cells of the mouse inner ear

Precursors of cochlear and vestibular hair cells of the inner ear exit the cell cycle at midgestation. Hair cells are mitotically quiescent during late-embryonic differentiation stages and postnatally. We show here that the retinoblastoma gene Rb and the encoded protein pRb are expressed in differentiating and mature hair cells. In addition to Rb, the cyclin dependent kinase inhibitor (CKI) p21 is expressed in developing hair cells, suggesting that p21 is an upstream effector of pRb activity. p21 apparently cooperates with other CKIs, as p21-null mice exhibited an unaltered inner ear phenotype. By contrast, Rb inactivation led to aberrant hair cell proliferation, as analysed at birth in a loss-of-function/transgenic mouse model. Supernumerary hair cells expressed various cell type-specific differentiation markers, including components of stereocilia. The extent of alterations in stereociliary bundle morphology ranged from near-normal to severe disorganization. Apoptosis contributed to the mutant phenotype, but did not compensate for the production of supernumerary hair cells, resulting in hyperplastic sensory epithelia. The Rb-null-mediated proliferation led to a distinct pathological phenotype, including multinucleated and enlarged hair cells, and infiltration of hair cells into the mesenchyme. Our findings demonstrate that the pRb pathway is required for hair cell quiescence and that manipulation of the cell cycle machinery disrupts the coordinated development within the inner ear sensory epithelia.     

DM-GRASP/ALCAM/CD166 is required for cardiac morphogenesis and maintenance of cardiac identity in first heart field derived cells

Vertebrate heart development requires specification of cardiac precursor cells, migration of cardiac progenitors as well as coordinated cell movements during looping and septation. DM-GRASP/ALCAM/CD166 is a member of the neuronal immunoglobulin domain superfamily of cell adhesion molecules and was recently suggested to be a target gene of non-canonical Wnt signalling. Loss of DM-GRASP function did not affect specification of cardiac progenitor cells. Later during development, expression of cardiac marker genes in the first heart field of Xenopus laevis such as Tbx20 and TnIc was reduced, whereas expression of the second heart field marker genes Isl-1 and BMP-4 was unaffected. Furthermore, loss of DM-GRASP function resulted in defective cell adhesion and cardiac morphogenesis. Additionally, expression of DM-GRASP can rescue the phenotype that results from the loss of non-canonical Wnt11-R signalling suggesting that DM-GRASP and non-canonical Wnt signalling are functionally coupled during cardiac development.     

Matriptase Expression and Zymogen Activation in Human Pilosebaceous Unit

Studies of human genetic disorders and mouse models reveal the important roles of matriptase in hair growth. Here, we investigate matriptase expression and zymogen activation in hair follicles. We show: 1) layer-dependent distribution patterns, with much higher matriptase expression in cells of the outer root sheath and matrix cells of the hair bulb than in cells of the inner root sheath; 2) cycle-dependent expression patterns, with matriptase expressed in the anagen and catagen phases of the hair lifecycle, but not in the telogen phase; 3) reduced expression of the matriptase inhibitor, HAI-1, in the catagen phase, suggesting increased proteolytic activity in this phase; and 4) definitive matriptase zymogen activation patterns, with the highest matriptase activation observed in matrix cells and outer root sheath cells in the isthmus/bulge region. In sebaceous glands, matriptase is highly expressed in basal and ductal cells, with much lower expression in the differentiated, lipid-filled cells of the interior. We also show that matriptase potently activates hepatocyte growth factor (HGF) in vitro, and that the HGF receptor, c-Met, is co-expressed in those cells that express activated matriptase. Our observations suggest that the matriptase-HGF-c-MET pathway has the potential to be engaged, primarily in proliferative cells rather than terminally differentiated epithelial cells of the human pilosebaceous unit.     

Expression of nucleosomal protein HMGN1 in the cycling mouse hair follicle

Here we examine the expression pattern of HMGN1, a nucleosome binding protein that affects chromatin structure and activity, in the hair follicle and test whether loss of HMGN1 affects the development or cycling of the follicle. We find that at the onset of hair follicle development, HMGN1 protein is expressed in the epidermal placode and in aggregated dermal fibroblasts. In the adult hair follicle, HMGN1 is specifically expressed in the basal layer of epidermis, in the outer root sheath, in the hair bulb, but not in the inner root sheath and hair shaft. The expression pattern of HMGN1 is very similar to p63, suggesting a role for HMGN1 in the transiently amplifying cells. We also find HMGN1 expression in some, but not all hair follicle stem cells as detected by its colocalization with Nestin and with BrdU label-retaining cells. The appearance of the skin and hair follicle of Hmgn1^?/? mice was indistinguishable from that of their Hmgn1^+/+ littermates. We found that in the hair follicle the expression of HMGN2 is very similar to HMGN1 suggesting functional redundancy between these closely related HMGN variants.     

The zinc finger transcription factor Gfi1, implicated in lymphomagenesis,is required for inner ear hair cell differentiation and survival

Gfi1 was first identified as causing interleukin 2-independent growth in T cells and lymphomagenesis in mice. Much work has shown that Gfi1 and Gfi1b, a second mouse homolog, play pivotal roles in blood cell lineage differentiation. However, neither Gfi1 nor Gfi1b has been implicated in nervous system development, even though their invertebrate homologues, senseless in Drosophila and pag-3 in C. elegans are expressed and required in the nervous system. We show that Gfi1 mRNA is expressed in many areas that give rise to neuronal cells during embryonic development in mouse, and that Gfi1 protein has a more restricted expression pattern. By E12.5 Gfi1 mRNA is expressed in both the CNS and PNS as well as in many sensory epithelia including the developing inner ear epithelia. At later developmental stages, Gfi1 expression in the ear is refined to the hair cells and neurons throughout the inner ear. Gfi1 protein is expressed in a more restricted pattern in specialized sensory cells of the PNS, including the eye, presumptive Merkel cells, the lung and hair cells of the inner ear. Gfi1 mutant mice display behavioral defects that are consistent with inner ear anomalies, as they are ataxic, circle, display head tilting behavior and do not respond to noise. They have a unique inner ear phenotype in that the vestibular and cochlear hair cells are differentially affected. Although Gfi1-deficient mice initially specify inner ear hair cells, these hair cells are disorganized in both the vestibule and cochlea. The outer hair cells of the cochlea are improperly innervated and express neuronal markers that are not normally expressed in these cells. Furthermore, Gfi1 mutant mice lose all cochlear hair cells just prior to and soon after birth through apoptosis. Finally, by five months of age there is also a dramatic reduction in the number of cochlear neurons. Hence, Gfi1 is expressed in the developing nervous system, is required for inner ear hair cell differentiation, and its loss causes programmed cell death.