Scale induction in the chick amnionic ectoderm attached to tarsometatarsal skin dermis

Under the influence of tarsometatarsal dermis of 13-17-day chick embryos, 6.8-day amnionic ectoderm can form scales and express keratins specific for scales. In contrast, 10.5-day shank dermis can induce both feather filaments and scales in the amnionic ectoderm.     

Expression of Hex during feather bud development

We studied proline-rich divergent homeobox gene Hex/Prh expression in the dorsal skin of chick embryo during feather bud development. Hex mRNA expression was first observed in the dorsolateral ectoderm and mesenchyme at 5 days, then in the epithelium and the dermis of the dorsal skin before placode (primordium of feather bud) formation and then was restricted to the placode and the dermis under the placode. Afterward, Hex expression was seen in the epidermis and the dermis of the posterior region of short bud. In accordance with Hex mRNA expression in the placode, Hex protein was observed in the epidermis as well as in the dermis of the placode. Immunoelectron microscopic study indicated that the protein located both in the nuclei and cytoplasm of the epidermis and the dermis at the short bud stage. The Wnt signaling pathway plays an essential role in the early inductive events in hair (Wnt3a and 7a) and feather (Wnt7a) follicles. The pattern of Hex expression in the epidermis was similar to that of Wnt7a, while little, if any, expression of Wnt7a was detected in the dermis under the placode or the dermis of the short bud compared with that of Hex, suggesting that Hex plays an important role in the initiation of feather morphogenesis.     

Epidermal-dermal tissue interactions between mutant and normal embryonic back skin: site of mutant gene activity determining abnormal feathering is in the epidermis.

The site of the scaleless gene's activity in the development of abnormal feathers was determined by reciprocally recombining epidermis and dermis between normal and scaleless chick embryos and culturing the recombinants for seven days on the chorioallantoic membrane. When recombined with a common dermal source, feather development is enhanced by scaleless high line as compared to scaleless low line epidermis. Against a common responding tissue, 7-day normal back epidermis, significant differences were not found in feather inducing ability between normal, scaleless high line and scaleless low line dermis. It was concluded that, in relation to abnormal feathering, these tissue interactions reveal that the site of the scaleless gene's activity is the epidermis. A model of tissue interaction in the development of normal and abnormal feathers is presented. According to the model, the focus of the scaleless mutation and the genes accumulated by selection for high or low feather numbers is the epidermis, the effect being that the reactivity of the epidermis to dermal stimuli is altered. Subsequently, the epidermis controls the morphogenetic organization of the dermis. The scaleless dermis is presumed to contain normal positional information for the determination of feather structure and pattern.     

Differentiation of embryonic chick feather-forming and scale-forming tissues in transfilter cultures

The dermal-epidermal tissue interaction in the chick embryo, leading to the formation of feathers and scales, provides a good experimental system to study the transfer between tissues of signals which specify cell type. At certain times in development, the dermis controls whether the epidermis forms feathers or scales, each of which are characterized by the synthesis of specific beta-keratins. In our culture system, a dermal effect on epidermal differentiation can still be observed, even when the tissues are separated by a Nuclepore filter, although development is abnormal. Epidermal morphological and histological differentiation in transfilter cultures are distinct and recognizable, more closely resembling feather or scale development, depending on the regional origin of the dermis. Differentiation is more advanced when epidermis is cultured transfilter from scale dermis than from feather dermis, as assessed by morphology and histology, as well as the expression of the tissue-specific gene products, the beta-keratins. Two-dimensional polyacrylamide gel analysis of the beta-keratins reveals that scale dermis cultured transfilter from either presumptive scale or feather epidermis induces the production of 7 of the 9 scale-specific beta-keratins that we have identified. Feather dermis, although less effective in activating the feather gene program when cultured transfilter from either presumptive feather or scale epidermis, is able to turn on the synthesis of 3 to 6 of the 18 feather-specific beta-keratins that we have identified. However, scale epidermis in transfilter recombinants with feather dermis also continues to synthesize many of the scale-specific beta-keratins. Using transmission and scanning electron microscopy, we detect no cell contact between tissues separated by a 0.2-micron pore diameter Nuclepore filter, while 0.4-micron filters readily permit cell processes to traverse the filter. We find that epidermal differentiation is the same with either pore size filter. Furthermore, we do not detect a basement membrane in transfilter cultures, implying that neither direct cell contact between dermis and epidermis, nor a basement membrane between the tissues is required for the extent of epidermal differentiation that we observe.     

Chemical Analysis of Melanin Pigments in Feather Germs of Japanese Quail Bh (Black at Hatch) Mutants

Bh (black at hatch) is a mutation of Japanese quails which causes darkening or lightening of the plumage in heterozygotes or homozygotes, respectively. We chemically analyzed melanin pigments in feather germs of Bh mutant embryos and in feathers of adult animals. Dark brown dorsal feathers of wild-type adult animals had white barrings, but heterozygous ones lacked clear barrings. The feathers of wild-type and heterozygote animals contained both eumelanins and pheomelanins, the latter being more pheomelanic. On the dorsal skin of 10-day old wild-type embryos, longitudinal stripes from black and yellow rows of feather germs developed; two or three longitudinal rows of black feather germs and then two or three rows of yellow feather germs next to the short central feather germs. Heterozygous embryos appeared black in plumage pigmentation, due to the presence of‘gray’feather germs in rows of dorsal feather germs that corresponded to yellow rows in wild-type embryos. Homozygous dorsal feather germs did not develop the black and yellow longitudinal stripes, but were brown. Chemical analysis showed that embryos of each genotype contained both eumelanins and pheomelanins in the feather germs; however, the eumelanin content in ho-mozygous feather germs was very low. These results suggest that the Bh mutation causes pheomelanic changes in feathers of quails.     

Reconstitution of the epidermal basement membrane after enzymatic dermal-epidermal separation of embryonic mouse skin

Pieces of trypsin-isolated 14-day embryonic mouse epidermis were recombined with various living or non-living dermal or non-dermal substrates, in order to analyse the reconstruction of the dermal-epidermal junction. The constitution and ultrastructure of the epidermal basement membrane were characterized by immunolabelling of laminin, type IV collagen and bullous pemphigoid antigen, and by transmission electron microscopy. Trypsin treatment of dorsal skin followed by dermal-epidermal separation does not visibly damage the epidermal basement membrane, which remains attached to the lower face of epidermis. When freshly isolated epidermis is reassociated with dermis, the basement membrane is first degraded during the first 4 h of culture, then reconstituted within 24 h. When epidermis is cultured in isolation the basement membrane disappears within 4 h and is not reconstructed. Epidermis, precultured for 4 h and thus deprived of its basement membrane prior to reassociation, is able to reconstruct an antigenically and ultrastructurally normal basement membrane, when recombined with living or frozen-killed (-20 degrees C) dermis, with muscle tissue, or with a film of fibrous type I collagen. No basement membrane is reconstituted when the epidermis is recombined with heat (100 degrees C) killed dermis. It is concluded that, in the reconstituted epidermal basement membrane, laminin, type IV collagen, bullous pemphigoid antigen, and lamina densa are of exclusive epidermal origin.     

The specification of feather and scale protein synthesis in epidermal-dermal recombinations

Keratin proteins synthesized by dorsal or tarsometatarsal embryonic chick epidermis in heterotopic and heterospecific epidermal-dermal recombinants were analyzed by polyacrylamide gel electrophoresis and were compared to those produced by normal nondissociated dorsal and tarsometatarsal embryonic skin, as well as to those produced by control homotopic recombinants. Recombinant skins were grafted on the chick chorioallantoic membrane and grown for 8 or 11 days. Recombinants comprising dorsal feather-forming dermis formed feathers, irrespective of the origin of the epidermis. The electrophoretic band patterns of the keratins extracted from these feathers were of typical feather type. Conversely recombinants comprising tarsometatarsal scale-forming dermis formed scales, irrespective of the origin of the epidermis. The band patterns of the keratins extracted from the epidermis of these scales were of typical scale type. Heterospecific recombinants comprising chick dorsal feather-forming epidermis and mouse plantar dermis gave rise to six footpads arranged in a typical mouse pattern. In these recombinants, the chick epidermis produced keratins, the band pattern of which was of typical chick scale type. These results demonstrate that the dermis not only induces the formation of cutaneous appendages in confirmity with its regional origin, but also triggers off in the epidermis the biosynthesis of either of two different keratin types, in accordance with the regional type (feather, scale, or pad) of cutaneous appendages induced. The possible relationship between region-specific morphogenesis and cytodifferentiation is discussed in comparison with results obtained in other kinds of epithelial-mesenchymal interactions.     

Regional specification of cutaneous appendages in mammals

Summary The problem of the regional specification of snout vibrissae and dorsal pelage hairs has been analysed in mouse embryos. Reconstituted homo-and heterotopic skin explants, consisting of epidermis and dermis from both regions, were cultured on the chorioallantoic membrane of the chick embryo.Recombinants of 12.5-day upper lip dermis and 12.5-day dorsal epidermis developed a small number of large vibrissal type follicles arranged in a recognizable rectangular vibrissal pattern. The reverse combinations of 12.5- or 14.5-day dorsal dermis and 11- to 12.5-day upper lip epidermis formed a single population of numerous and small follicles arranged in a typical pelage hair pattern (trio groups) or gave rise to a mixed population of follicles with both whiskers and pelage hairs.It is concluded that the dermis is responsible for the regional specification of the cutaneous appendages and their distribution pattern. However, at the time it was isolated, the upper lip epidermis already possesses the information for the morphogenesis of vibrissae, but remains malleable and responsive to the dermal influence.This work was supported in part by DGRST and CNRS     

Epidermal-dermal tissue interactions between mutant foot skin and normal back skin: a comparison of the inductive capacities of scaleless low line and normal anterior foot dermis.

The inductive capacities of 9- to 16-day anterior foot dermis of scaleless low line and normal embryos were compared by recombining them with a common source of epidermis, i.e., 7-day normal back epidermis. Tissue recombinants were cultured as grafts to the chorioallantoic membrane (CAM). Both normal and scaleless low line dermis of 12 to 13 days of incubation began to lose their ability to elicit feather production in 7-day normal back epidermis. Normal foot dermis began to elicit scale production at 12 to 13 days, whereas scaleless low line anterior foot dermis maintained feather production at a low level. It is inferred that without being associated with scale placode formation, scaleless low line anterior foot dermis does not acquire specific inductive capacities related to the production of an outer scale surface in the overlying epidermis. Feather placodes do not function as surrogates of scale placodes. The difference between normal and scaleless low line anterior foot dermis in terms of specific inductive capacities related to scale production is interpreted as a secondary effect of the action of the scaleless allele in interfering with scale placode formation in the scaleless low line anterior foot epidermis.     

Characterization of three mouse monoclonal antibodies that react with high-molecular-mass glycopeptides isolated from F9 mouse teratocarcinoma cells

Three IgM mouse monoclonal antibodies, NL-9, Thy-22, and HL-5, which were produced primarily against human hematopoietic cells, were tested for their reactivity with various mouse cell lines and were found to react predominantly with mouse embryonal carcinoma cells. Thy-22 reacted with 2-cell-stage mouse embryos, whereas the other two antibodies were not reactive at this stage. All three antibodies, however, reacted with 8-cell-stage embryos. At the blastocyst stage, Thy-22 reacted with the entire surface of the trophectoderm cells, whereas the reactivity of NL-9 and HL-5 was weaker and was polarized on the mural trophectoderm. Immunohistological examination of 6th-day mouse embryos using anti-complement immunofluorescence demonstrated that the embryonic ectoderm was positive for all three antibodies: the reaction of NL-9 and Thy-22 was uniformly distributed over these cells, whereas HL-5 predominantly stained the luminal aspects of the cells lining the proamniotic cavity. Visceral-endoderm cells and trophoblastic cells were positive with all three monoclonal antibodies, whereas the parietal endoderm, extraembryonic ectoderm, and ectoplacental cone were negative. In 19th-day fetuses and adult tissues, certain epithelial cells were stained by these three antibodies. The biochemical nature of the antigens detected was also investigated. Farr's assay showed that both NL-9 and Thy-22 precipitated approximately 10% of the high-molecular-mass glycopeptides isolated from F9 cells, while HL-5 reacted with about 5% of these glycopeptides. The reactivity of the three antibodies against the glycopeptides was completely inhibited by the presence of X-hapten-conjugated silica.(ABSTRACT TRUNCATED AT 250 WORDS)     

Serological analysis of early mouse embryo with rat monoclonal antibodies produced against mouse teratocarcinoma cells

Rat-mouse hybridoma antibodies were produced against mouse teratocarcinoma F9 or PCC4 aza1 cells, and four clones were established. Both the F11 (IgM) and F20 (IgG2c) antibodies showed a similar specificity, reacting only with nullipotential teratocarcinoma cells. They were also found to agglutinate sheep red blood cells. Solid-phase enzyme-linked immunofluorescence assay showed that, among the neutral glycolipids studied, they only reacted with the Forssman antigen. P2 antibody (IgG2b) reacted with the undifferentiated-type and embryonal endodermtype teratocarcinoma cells. During the preimplantation stage, this antibody did not stain mouse embryos, but it reacted very weakly with the inner cell mass of blastocysts cultured in vitro. In the 5th-day embryo, the embryonic ectoderm as well as the visceral and parietal endoderm were positive, but the extraembryonic ectoderm was not. Mesoderm of the 7.5th-day embryo also reacted with this antibody. However, P2 antigen was not observed in the 16th-day embryo or in adult tissues. F2 antibody (IgG2a), which was reactive with all of the cultured cell lines tested, showed an immunoreaction with mouse embryos throughout the preimplantation stage. However, in the 7.5th-day embryo, the presence of F2 was limited to the cells forming the parietal endoderm. This antigen was present in some epithelial tissues of the 16th-day embryo and adult mouse. Of these antigens, P2 and F2 are probably novel differentiation antigens of the early mouse embryo. Together with the Forssman antigen, these will be important markers for analyzing cell-surface antigens of mouse teratocarcinoma cells as well as embryos.     

Particle purification, properties and epitope variability of Indian tomato leaf curl geminivirus

A whitefly-transmissible stock isolate of Indian tomato leaf curl geminivirus (ITmLCV) was cultured in graft-inoculated tomato plants and its particles purified from chloroform-clarified extracts in citrate buffer by precipitation with 70 g/litre polyethylene glycol, ultracentrifugation and sucrose density gradient centrifugation. Contaminating helical filaments were eliminated by banding in caesium sulphate gradients. ITmLCV particles had the shape typical for geminiviruses, measured c. 30 × 20 nm and contained a single major protein of estimated mol. wt c. 32 000. They reacted in immunosorbent electron microscopy with antisera to four other whitefly-transmitted geminiviruses. ITmLCV reacted with one out of 17 monoclonal antibodies specific for different epitopes in the particle protein of African cassava mosaic geminivirus and five or six out of 10 monoclonal antibodies to the particle protein of Indian cassava mosaic geminivirus. Virus isolates from tomato at nine locations in Karnataka State showed only slight differences in epitope profile, and isolates from four weed species in tomato fields were similar or identical to those from tomato.     

Use of retinoic acid for the analysis of dermal-epidermal interactions in the tarsometatarsal skin of the chick embryo

Feet of chicks are normally covered with scales. Injection of retinoic acid into the amniotic cavity of 10-day chick embryos causes the formation of feathers on the foot scales. To elucidate whether retinoic acid affects primarily the epidermis or the dermis, heterotypic dermal-epidermal recombinants of tarsometatarsal skin were tested as to their morphogenetic capacity, when grafted to the chick chorioallantoic membrane. Recombinants involving treated epidermis and untreated dermis formed feathered scales, while the reverse recombinants of untreated epidermis and treated dermis led to the formation of scales only. Likewise the association of treated tarsometatarsal dermis with untreated epidermis from a non-appendage-forming region (the midventral apterium) resulted in the formation of scales only. These results show that retinoic acid affects primarily the epidermis. Further insight into the mechanism of dermal-epidermal interaction was gained by heterotopic recombinations of early (8.5- and 10-day) untreated tarsometatarsal dermis with epidermis from the midventral apterium. These recombinants formed scales, proving that tarsometatarsal dermis is endowed with scale-forming properties as early as 8.5 days of incubation. Finally, it is concluded that retinoic acid acts on the chick foot epidermal cells by temporarily inhibiting their scale placode-forming properties, allowing their latent feather placode-forming properties to be expressed.     

Keratin filaments of epithelial and taste-bud cells in the circumvallate papillae of adult and developing mice

Summary Keratin filaments of epithelial- and taste-bud cells in the circumvallate papillae of adult and developing mice were studied by immunocytochemistry using monoclonal antikeratin antibodies (PKK2 and PKK3) and by conventional electron microscopy. Elongated cells (type-I,-II, and-III cells) of the taste buds were stained by PKK3 antibody, which reacts with 45-kdalton keratin, whereas basal cells of the taste buds and surrounding epithelial cells showed negative staining with PKK3. Such PKK3-reactive cells occurred at 0 day after birth, when taste-buds first appeared in the dorsal surface epithelium of the papillae. Thus 45-kdalton keratin seems to be an excellent immunocytochemical marker for identifying taste-bud cells. Epithelial cells in all layers of the trench wall and basal layer cells of the dorsal surface contained densely aggregated bundles of keratin filaments that reacted with PKK2 antibody, but not with PKK3. In contrast, taste-bud cells and spinous and granular layer cells of the dorsal surface possessed loose aggregated bundles of filaments that reacted with PKK3, but not with PKK2. These results suggest that the aggregation and distribution pattern of keratin filaments may reflect differences in the keratin subtypes that comprise these filaments.     

Screening of murine monoclonal antibodies against living schistosomula of Schistosoma mansoni by radioimmunoassay

A radioimmunoassay was developed to screen supernatants of murine monoclonal antibodies against surface antigens of living schistosomula of Schistosoma mansoni. Of 196 clones screened, 10% bound schistosomula. Of these, 74% bound only schistosomula. The remaining molecules also reacted with soluble adult worm antigens and soluble egg antigens as determined by enzyme-linked immunosorbent assay. Immunoblot analysis demonstrated that monoclonal antibody 204-3E4 reacted with a 68 kDa protein, a glycoprotein that induces substantial resistance against S. mansoni infection. Recognition of an 18 kDa antigen by 204-3F1 antibody was stage-specific with the antigen being expressed in cercariae, 3- and 24-h-old parasites but not 4-day, lung stage or adult worms. Monoclonal antibody 204-4E3 reacted with purified S. mansoni paramyosin. These data indicate that radioimmunoassay using living schistosomula is a rapid alternative method to identify murine hybridomas that secrete antibodies which react with surface antigens of S. mansoni.     

CROSS-REACTIVITY OF ANTIBODIES TO HUMAN ANTIGENS WITH TISSUES OF THE BOTTLENOSE DOLPHIN, TURSIOPS TRUNCATUS, USING IMMUNOPEROXIDASE TECHNIQUES

Cross-species reactivity of 53 antibodies developed against human antigens was evaluated in the bottlenose dolphin Tursiops truncatus , using immunoperoxidase techniques, Strong cross-reactivity was demonstrated with antibodies against intermediate filaments, most hormones, but few leukocyte antigens. S100, NSE, F8RA, Factor XIIIa, and lactalbumin antibodies reacted, while HMB45, EMA, PLAP, and PSA did not. Polyclonal antibodies are much more likely to cross-react than are monoclonal antibodies. Twenty-four of 30 (80%) of polyclonals cross-reacted, while only 10 of 23 (43.5%) monoclonals cross-reacted. Some antigens are demonstrated only after using a special technique to unmask the antigen.     

FGF signaling is required for initiation of feather placode development

Morphogenesis of hairs and feathers is initiated by an as yet unknown dermal signal that induces placode formation in the overlying ectoderm. To determine whether FGF signals are required for this process we over-expressed soluble versions of FGFR1 or FGFR2 in the skin of chicken embryos. This produced a complete failure of feather formation prior to any morphological or molecular signs of placode development. We further show that Fgf10 is expressed in the dermis of nascent feather primordia, and that anti-FGF10 antibodies block feather placode development in skin explants. In addition we show that FGF10 can induce expression of positive and negative regulators of feather development and can induce its own expression under conditions of low BMP signaling. Together these results demonstrate that FGF signaling is required for the initiation of feather placode development and implicate FGF10 as an early dermal signal involved in this process.     

Analysis of morphogenesis and keratinization in transfilter recombinants of feather-forming skin

The relationships between feather morphogenesis, histogenesis, and biochemical differentiation were examined by recombining backskin epidermis and dermis, from chick embryos (Hamburger-Hamilton stages 27-31), with an intervening Nucleopore filter (pore size of 0.4 micron). The filter inhibited normal feather morphogenesis and histogenesis of barb ridges, yet feather-like filaments, which were free of dermal cells, formed from the epidermal cells. Using indirect immunofluorescence, with antiserum against alpha- and beta-keratins, the biochemical differentiation of the feather-like filaments was compared to normal feathers. In the feather-like filaments resulting from tissues of stages 27-29, cells containing beta keratins were occasionally seen at the periphery of the filaments, yet cells containing alpha-keratins were inappropriately located throughout the filaments. In a few feather-like filaments on recombinants resulting from tissues of stages 29.5-31, cells positive for beta-keratins were found in the center of the filament, but again alpha-keratins were also found. Surrounding these cells there were several layers of cells, arranged circumferentially, resembling sheath cells. Some sheath-like cells contained beta-keratins. We conclude that although feather epidermal cells, which are separated from their dermis by a Nuclepore filter, can undergo limited morphogenesis and the production of alpha- and beta-keratins, normal feather morphogenesis, histogenesis, and biochemical differentiation require the intimate associations of epidermis and dermis.     

EPIDERMAL METAPLASIA OF THE CORNEAL ANTERIOR EPITHELIUM IN THE CHICK EMBRYO

The corneal anterior epithelium of younger chick embryos can be changed into a keratinized epidermis, when it is cultured in vitro combined with 6 1/2-day dorsal dermis. Even if a Millipore filter is inserted between the corneal anterior epithelium and underlying dorsal dermis, the epithelium undergoes similar metaplastic changes. In older embryos, however, the epithelium gradually loses the competence for the keratinization. Cultivation of cornea (anterior epithelium, stroma and endothelium) of 6 1/2- or 10-day embryos results in maintenance of its original pattern, and the epithelium fails to differentiate into a keratinized epidermis. The dermis isolated from 8 1/2-day dorsal or 12 1/2-day tarsometatarsal skin is not so effective in inducing the epidermal metaplasia. The mesenchyme of 5 1/2-day proventriculus or 5 1/2-day gizzard fails to bring about any endodermal metaplasia of the corneal epithelium. The corneal stroma, on the other hand, has no inhibitory action on the keratinization of the epidermis obtained from 6 1/2-day dorsal skin.     

Distribution of fast myosin heavy chain isoforms in thick filaments of developing chicken pectoral muscle

Colloidal gold-conjugated monoclonal antibodies were prepared to stage-specific fast myosin heavy chain (MHC) isoforms of developing chicken pectoralis major (PM). Native thick filaments from different stages of development were reacted with these antibodies and examined in the electron microscope to determine their myosin isoform composition. Filaments prepared from 12-d embryo, 10-d chick, and 1-yr chicken muscle specifically reacted with the embryonic (EB165), neonatal (2E9), and adult (AB8) antimyosin gold-conjugated monoclonal antibodies, respectively. The myosin isoform composition was more complex in thick filaments from stages of pectoral muscle where more than one isoform was simultaneously expressed. In 19-d embryo muscle where both embryonic and neonatal isoforms were present, three classes of filaments were found. One class of filaments reacted only with the embryonic antibody, a second class reacted only with the neonatal-specific antibody, and a third class of filaments were decorated by both antibodies. Similar results were obtained with filaments prepared from 44-d chicken PM where the neonatal and adult fast MHCs were expressed. These observations demonstrate that two myosin isoforms can exist in an individual thick filament in vivo. Immunoelectron microscopy was also used to determine the specific distribution of different fast MHC isoforms within individual filaments from different stages of development. The anti-embryonic and anti-adult antibodies uniformly decorated both homogeneous and heterogeneous thick filaments. The neonatal specific antibody uniformly decorated homogeneous filaments; however, it preferentially decorated the center of heterogeneous filaments. These observations suggest that neonatal MHC may play a specific role in fibrillogenesis.