The production of chimeric rats and their use in the analysis of the hooded pigmentation pattern

New, improved media and procedures for making rat chimeric embryos and culturing them in vitro have been developed. We have produced 27 rat chimeras: 20 males and 7 females. This ratio of males to females is consistent with that seen in mouse chimeras, suggesting that rat sex chimeras develop as phenotypic males. By aggregating embryos containing appropriate genetic markers for pigment cell differentiation, it is possible to produce chimeras that elucidate the site of action of the hooded gene. The coat color patterns of black ? black hooded chimeras display a white belly spot. In black ? albino hooded chimeras, small patches of white hair appear on the head and a large white spot occurs on the belly. Black ? agouti hooded chimeras display both agouti and nonagouti pigmentation over the entire surface of the chimera. These animals are fully pigmented with no white spots. In black ? albino non-hooded chimeras, rather small irregular patches of black and white hairs are distributed throughout the pelage. Histological examination of sections of hair follicles obtained from the white areas in the head of black ? albino hooded chimeras revealed amelanotic melanocytes. On the other hand, hair bulbs from the white belly spots do not contain any such melanocytes. Thus the white hairs of the head are due to the presence of albino melanocytes, but the white hairs of the belly are due to the total absence of melanocytes. All these observations are consistent with the conclusion that the hooded gene acts within melanoblasts, probably to retard their migration from the neural crest and/or to prevent their entrance into the hair follicles of the white areas of hooded rats.     

Mutant gene expression in mouse aggregation chimeras. 8. The effect of the white gene on coat pigmentation

Aggregation of mouse embryos produced 11 chimaeras Miwh/+C/C----+/+c/c and 8 chimaeras +/+C/C----+/+c/c (control). Chimaerism was detected by mosaicism of coat retinal pigment epithelium and by electrophoretic pattern of glucose phosphate isomerase. All chimaeras showed a common pattern of pigmented and unpigmented hair regions that alternated as stripes of different length and width and extended from spine in lateral-ventral direction. However, white coat color predominated in Miwh/+C/C----+/+c/c chimaeras due to a higher proportion of unpigmented zones as well as to weakening of hair color in pigmented areas. Besides, distal regions of limbs were always unpigmented in Miwh/+C/C----+/+c/c chimaeras and completely or partially pigmented in +/+C/C----+/+c/c chimaeras. Pigmented hair regions are often located on the ventral trunk surface where the Miwh/+ heterozygotes usually had an unpigmented spot. The examination of hairs, taken from the same regions of gray coloration, revealed the presence of pigmented, unpigmented and mosaic hairs. The proportion of unpigmented hairs was much higher in Miwh/+C/C----+/+c/c chimaeras than in +/+C/C----+/+c/c chimaeras. The data obtained indicate that a single Miwh gene dose reduced proliferative activity of melanoblasts which resulted in weakening of coat pigmentation.     

Influence of Donor Age on Establishing Well-Differentiated Clonal Cultures from Embryonic Chicken Retinal Pigmented Epithelium

Retinal pigmented epithelia (RPE) isolated from chicken embryos of various developmental stages were dissociated into single cells, and their ability to re-express defferentiated characteristics in clonal culture was investigated. The lighty pigmented, columnar cells isolated from stage 25 to 29 embryos dissociated more easily than the heavily pigmeted, cuboidal cells from embryos of stages 30 to 34. The yield of RPE cells per embryo increased with donor age, paralleling the growth of the epithelium in vivo . However, the potential these cells to attach, to proliferate, and to form typical, welldifferentiated RPE colonies declined with donor age. Cells from stage 25 embryos developed exclusively into large, typical epithelial colonies which expressed all stages of differentiation from flat, unpigmented cells at the margin to cuboidal, pigmented cells in the centre. At the other end of the spectrum, cells from stage 34 embryos frequently formed small, atypical colonies of unpigmented cells, in addition to typical but relatively small colonies. The plating efficiency (calculated on the basis of pigmented colonies formed within 3 weeks) dropped from more than 2% at stage 25 to 0.01% at stage 34.     

Possible demonstration of multipotential nature of embryonic neural retina by clonal cell culture.

The possible multipotential nature of the neural retina of early chick embryos was examined by the technique of clonal cell culture. Cultures were prepared from cells dissociated from freshly excised neural retinas of 3.5-day-old chick embryos or from cells harvested from primary highdensity cultures. The following four colony types were obtained: colonies differentiating into “lentoid bodies”; colonies with pigment cells; colonies with both “lentoid bodies” and pigment cells; and colonies comprised entirely of unidentifiable cells. Neuronal differentiation occurred frequently in the early stages of culture (up to about 10 days). In some of these neuronal colonies, “lentoid bodies” and, rarely, both “lentoid bodies” and pigment cells differentiated after a further culture period of up to 30 days. Secondary colonies established from primary colonies after 9–10 days demonstrated that these original colonies fell into four different categories: those giving rise to secondary colonies containing only “lentoid bodies,” those giving rise to pigmented colonies only, those developing both lentoid and pigmented colonies, and finally those which gave rise to secondary colonies of all three types, lentoid, pigmented, and mixed colonies. When primary pigmented colonies were recloned at about 30 days after inoculation, the differentiated pigment cells transdifferentiated into lens. Whether multispecific colonies were really of clonal origin or not is discussed. The possible presence of a multipotent progenitor cell able to give rise to multispecific clones in the neural retina of 3.5-day-old chick embryos is suggested. A sequence of differentiation starting from multipotent neural retinal cells to be terminated with lens through the differentiation of neuronal and pigment cells is hypothetically proposed.     

Morphological changes in hair melanosomes by aging

Various changes appear in hair by aging, and graying is the most remarkable one. Changes in melanocytes have been well studied as the cause; however, little is known about the change in melanosomes which have a role of carrying melanin pigments into hair shafts. Using pigmented hairs of Japanese females from their age of 4–75, I isolated melanosomes and observed them. As a result, I found a significant change in the morphology of hair melanosomes with age. They were ellipsoidal on the whole and there was no age dependence in the major axis, while the minor axis significantly increased and its frequency distribution broadened with age. The anticipated volume of the melanosome of the oldest person hairs was about twice larger than that of child hairs. This enlargement of melanosome seems to be a cause of the age‐related color change in pigmented hairs from brown to black.     

Pigmentation Patterns of Mouse Chimaeras following Injection of Embryonic Cells into Postimplantation Embryos In Utero

Chimaeric mice were produced by introducing dissociated embryonic cells of C57BL/6N mice into the embryos of Jcl: ICR albino mice at mid-gestation in utero . The patterns and the existence of pigmented areas were investigated over the long term. The pigmentation of the chimaeras was observed in several locational patterns; mainly in the head and the breast, rarely in the tail, the abdomen, the anterior and posterior trunk. During long-term observation, the pigmentation became faint in 6 of 7 chimaeras and completely disappeared in 2 of 7 chimaeras 6 months after birth, as was true in our previous observation in rat/mouse chimaeras. The reason for this discoloration, however, is unknown at present; melanocytes derived from donor cells may have failed to function or have been eliminated. To examine the entry routes of injected cells into the embryos, pollen particles, similar to embronic cells in size, were injected as a donor material. The particles were localized mainly on the mid-dorsal line in the head, and breast near fore-limb buds 48 hr after injection. These patterns were similar to those of areas where the pigmentation were observed in the chimaeras. The results suggested that the cells were passively incorporated into embryos on the dorsal midline and the abdomen through the neural tube and somatopleure closure, respectively.     

The ret oncogene can induce melanogenesis and melanocyte development in Wv/Wv mice.

We recently reported the establishment of transgenic mouse lines carrying the mouse metallothionein/ret fusion gene in which severe melanosis and melanocytic tumors developed. In the present study, we demonstrate that a significant number of pigmented hairs developed in Wv/Wv mice crossed to one of the transgenic mouse lines. The pigmented hair of Wv/Wv mice carrying the ret oncogene did not lose color during aging and reappeared after shaving, indicating that the melanocytes in the hair follicle function. The melanocytic tumors also developed in these mice, although the incidence was lower than that in the wild transgenic mice. Furthermore, the neutral tube culture of mouse embryos indicated that neural crest cells of the transgenic mice gave rise to a cell population that autonomously produced melanin even in the absence of melanocyte stimulating hormone. These results strongly suggested that the introduced ret oncogene could compensate for the defect of c-kit in Wv mice during both embryogenesis and postnatal life and induce a high level of melanin synthesis in the process of melanocyte development.     

Partial restriction in the developmental potential of late emigrating avian neural crest cells.

Trunk neural crest cells migrate along two major pathways: a ventral pathway through the somites whose cells form neuronal derivatives and dorsolateral pathway underneath the ectoderm whose cells become pigmented. In avian embryos, the latest emigrating neural crest cells move only along the dorsolateral pathway. To test whether late emigrating neural crest cells are more restricted in developmental potential than early migrating cells, cultures were prepared from the neural tubes of embryos at various stages of neural crest cell migration. "Early" and "middle" aged neural crest cells differentiated into many derivatives including pigmented cells, neurofilament-immunoreactive cells, and adrenergic cells. In contrast, "late" neural crest cells differentiated into pigment cells and neurofilament-immunoreactive cells, but not into adrenergic cells even after 10-14 days. To further challenge the developmental potential of early and late emigrating neural crest cells, they were transplanted into embryos during the early phases of neural crest cell migration, known to be permissive for adrenergic neuronal differentiation. The cells were labeled with the vital dye, DiI, and injected onto the ventral pathway at stages 14-17. Two and three days after injection, some early neural crest cells were found to express catecholamines, suggesting they were adrenergic neuroblasts. In contrast, DiI-labeled late neural crest cells never became catecholamine-positive. These results suggest that the late emigrating neural crest cell population has a more restricted developmental potential than the early migrating neural crest cell population.     

Enhancement of expression of lens phenotype in cultures of pigmented epithelial cells by hyaluronidase in the presence of phenylthiourea

Pigmented epithelial cells isolated from 8-9-day-old chick embryos can transdifferentiate into lens-like cells at the terminal period of the third generation of culture. However, efficiency of this transdifferentiation is usually rather low. Phenylthiourea, a potent inhibitor of melanin synthesis, effectively enhances transdifferentiation of pigmented epithelial cells into lens-like cells in vitro. Lentoid bodies began to appear in the multilayered region of primary cultures of pigmented epithelial cells maintained in medium containing phenylthiourea at concentrations between 0.5 and 1.0 mM. Furthermore, the enhancing effect of phenylthiourea can be amplified with testicular hyaluronidase. Under these conditions, pigmented epithelial cells grow vigorously and lose their differentiative properties, efficiently switching their phenotype into lens-like cells some 20 days after initiation of culture in the presence of both substances. Semiquantitative analysis revealed that testicular hyaluronidase amplified the effect of phenylthiourea more than 100-fold. It has been suggested that phenotypic expression of pigmented epithelial cells during transdifferentiation can be regulated by manipulating the microenvironment in which these cells reside.     

Establishment of the scleral cartilage in the chick.

This study was undertaken to investigate the establishment of the scleral cartilage in the chick embryo. Johnston et al. (1974) has demonstrated that most of the cells of the scleral cartilage originate in the cranial neural crest. By means of a series of chorioallantoic grafts of pigmented retina, and its adherent periocular mesenchyme from stage 11 to 25, the present experiments show that the cranial neural crest cells arrive at the eye in sufficient numbers to form cartilage by stage 14. Pigmented retina, denuded of mesenchyme, from stage 16 embryos implanted into the head of stage 13 embryos induces cartilage formation in head mesenchyme. However, neither pigmented retina nor spinal cord could induce cartilage formation in chorioallantoic mesenchyme. Combination grafts of cranial neural crest and presumptive optic vesicle developed neural tissue, pigmented retina, and in some cases sclera-like cartilage. Thus, periorbital mesenchyme, derived largely from cranial neural crest, at about stage 14 develops the scleral cartilage in response to induction by the pigmented retina.     

Neural crest cells: temperature-dependent transformation by Rous sarcoma virus.

Cranial neural crest cells from chick embryos, when cultured under appropriate conditions, differentiate after approx. 1 week into pigmented cells. Neurol crest cells were infested with a mutant (RSV-BH-Ta) of the Bryan 'high titer' strain of Rous sarcoma virus on the second day of culture before the cells were morphologically differentiated, or later after they became pigmented. Cells infected and maintained at the temperature permissive for transformation (37 degrees C) proliferated rapidly compared to uninfected cells are produced extensive cytoplasmic vacuoles in a fashion similar to other types of cells transformed with RSV-BH-Ta at 37 degrees C. Cells infected and maintained at the non-permissive temperature for transformation (41 degrees C) also proliferated rapidly but did not become morphologically transformed. Transformation occurred reversibly following a shift of temperature. Infection of morphologically undifferentiated neural crest cells at either temperature prevented their differentiation into pigment cells, and infection of pigmented neural crest cells at either temperature led to a gradual loss of pigmentation. These results suggest that even at the non-permissive temperature the virus may regulate the state of differentiation of certain types of cells.     

Enhancement of differentiation of lens and pigment cells by ascorbic acid in cultures of neural retinal cells of chick embryos.

When dissociated cells of neural retinae of 9-day-old chick embryos were cultured in Eagle's minimum essential medium supplemented with dialyzed fetal calf serum, both the proliferation and differentiation of the neural retinal cells were inhibited. These cells remained quiescent and flattened. When ascorbic acid was added to such a medium, the cells started to grow and differentiated into lentoid bodies and pigmented cells after about 10 days.     

Antioxidant enzymatic systems in pigment tissue of amphibia

Superoxide dismutase, catalase, glutathione peroxidase, and glutathione reductase activities in pigmented and unpigmented liver tissues of frog and albino rat, respectively, were studied. Our results show that pigmented tissue is lacking in manganese superoxide dismutase activity and that the main enzymatic activity utilized in the cytosol by pigmented cells to reduce the hydrogen peroxide to water is represented by catalase; on the contrary, for the same reaction, the cells of albino rat liver primarily utilize the glutathione peroxidase activity. Both a low glutathione peroxidase activity and a low glutathione reductase activity were found in pigmented tissue of frog liver when compared with unpigmented tissue of rat liver. In light of our results, we also report a hypothetical interrelationship between melanin and reduced glutathione: We believe that in pigmented cells the melanin could act as a reducing physiological agent replacing the glutathione in the reduction of hydrogen peroxide. This reducing action of melanin could cause a diminished need for GSH and therefore could provoke the low glutathione peroxidase and reductase activities in pigmented tissue.     

Sexing of rat embryos with antisera specific for male rats.

Male-specific antigenicity (H-Y antigen) of rat embryos has been examined, and the feasibility of sexing rat embryos by use of H-Y antibodies has been studied. Rat H-Y antisera were produced by immunization of female Wistar rats with a homogenate of testes from male Wistar neonates. Male specificity of the antiserum (H-Y antibody) was determined by retention of cytotoxicity to male epidermal cells after absorption with female cells. After cultivation of rat embryos for 5 to 6 hr in the presence of antibody, half of the embryos were arrested at the morula stage. However, these embryos developed into blastocysts after removal of the antiserum, and then they grew into male young in recipient foster mothers. Eighty percent of the embryos that developed to blastocysts in the presence of the antiserum grew into female young.     

The patchwork mouse phenotype: implication for melanocyte replacement in the hair follicle.

Mice homozygous for the recessive patchwork (pwk) mutation are characterized by a variegated pigment pattern with a mixture of unpigmented and normally pigmented hairs. The pigmented hair bulbs contain functional melanocytes. By contrast, the unpigmented hair bulbs contain no melanocytes. This lack results from the death of melanoblasts in the hair follicle at the end of embryogenesis. Here, we report that melanoblasts and melanocytes are found in the epidermis of pwk/pwk mice. Furthermore, these epidermal pigment cells are able to colonize new hair follicles after skin wounding. Despite the presence of epidermal pigment cells with a colonization potential, a follicle that had produced an unpigmented hair produces a new unpigmented hair during the successive hair growth cycles. This hair color continuity is also true for the pigmented hair follicles. Thus, in normal conditions, the hair acts as an independent functional unit as regards its pigment cells population.     

Properties of cells from inverted embryos ofXenopus laevis investigated by scanning electron microscopy

Summary Xenopus embryos held inverted from the one cell stage show a partial reversal of the pattern of cleavage: the blastocoel forms towards the new upper pole, and the non-pigmented cells forming the blastocoel roof are smaller than normal endoderm cells. Two properties of the cells from inverted embryos have been studied: their capacity to form cilia when cultured for 48 h, normally a property of ectoderm cells; and their scanning electron microscopical appearance when isolated and cultured for shorter periods, which differs for normal ectoderm and endoderm cells. Groups of the upper, non-pigmented cells from inverted embryos do not form cilia in a longerterm culture, whereas groups of the lower, pigmented cells do. In contrast, the scanning electron microscopical appearance of the upper, non-pigmented cells of inverted embryos is more like that of normal ectoderm cells; the appearance of lower, pigmented cells is more like that of normal endoderm. Thus the determination to form cilia is not reversed by inversion, whereas the control of cell morphology is.     

Clonal origins of cells in the pigmented retina of the zebrafish eye

Mosaic analysis has been used to study the clonal basis of the development of the pigmented retina of the zebrafish, Brachydanio rerio. Zebrafish embryos heterozygous for a recessive mutation at the gol-1 locus were exposed to gamma-irradiation at various developmental stages to create mosaic individuals consisting of wild-type pigmented cells and a clone of pigmentless (golden) cells in the eye. The contribution of individual embryonic cells to the pigmented retina was measured and the total number of cells in the embryo that contributed descendants to this tissue was determined. Until the 32-cell stage, almost every blastomere has some descendants that participate in the formation of the pigmented retina of the zebrafish. During subsequent cell divisions, up to the several thousand-cell stage, the number of ancestral cells is constant: approximately 40 cells are present that will give rise to progeny in the pigmented retina. Analysis of the size of clones in the pigmented retina indicates that the cells of this tissue do not arise through a rigid series of cell divisions originating in the early embryo. The findings that each cleavage stage cell contributes to the pigmented retina and yet the contribution of such cells is highly variable are consistent with the interpretation that clonal descendants of different blastomeres normally intermix extensively prior to formation of the pigmented retina.     

The Patchwork Mouse Phenotype: Implication for Melanocyte Replacement in the Hair Follicle

Mice homozygous for the recessive patchwork (pwk) mutation are characterized by a variegated pigment pattern with a mixture of unpigmented and normally pigmented hairs. The pigmented hair bulbs contain functional melanocytes. By contrast, the unpigmented hair bulbs contain no melanocytes. This lack results from the death of melanoblasts in the hair follicle at the end of embryogenesis. Here, we report that melanoblasts and melanocytes are found in the epidermis of pwk/pwk mice. Furthermore, these epidermal pigment cells are able to colonize new hair follicles after skin wounding. Despite the presence of epidermal pigment cells with a colonization potential, a follicle that had produced an unpigmented hair produces a new unpigmented hair during the successive hair growth cycles. This hair color continuity is also true for the pigmented hair follicles. Thus, in normal conditions, the hair acts as an independent functional unit as regards its pigment cells population.     

Studies of Sl/Sld in equilibrium with +/+ mouse aggregation chimaeras. I. Different distribution patterns between melanocytes and mast cells in the skin

In spite of their different origin, both melanocytes and mast cells are deficient in the skin of mutant mice of the Sl/Sld genotype. Since the neural crest and the liver of Sl/Sld embryos contain normal precursors of melanocytes and mast cells, respectively, the deficiency is attributed to a defect in tissue environment necessary for migration and/or differentiation of precursor cells. We investigated whether the tissue environment used for differentiation of melanocytes and mast cells was identical by producing aggregation chimaeras from Sl/Sld and +/+ embryos. Chimaeric mice with apparent pigmented and nonpigmented stripes were obtained. In the nonpigmented stripes of these Sl/Sld in equilibrium with +/+ chimaeras, melanocytes were not detectable in hair follicles but were detectable in the dermis. In contrast, melanocytes were detectable neither in hair follicles nor in the dermis of nonchimaeric Sl/Sld mice. Concentrations of mast cells were comparable in the pigmented and nonpigmented stripes of Sl/Sld in equilibrium with +/+ chimaeras, but the average concentration of mast cells significantly varied in the chimaeras (from 8% to 74% of the value observed in control +/+ mice). The present result suggests that mesodermal cells that support the migration and differentiation of both melanocyte precursors and mast-cell precursors mix homogeneously in the dermis and that ectodermal cells that influence the invasion of differentiating melanocytes into hair follicles make discrete patches.     

Transdifferentiation of "lentoid" structures in cultures derived from pigmented epithelium was inhibited by collagen.

Cells from pigmented retina of 8- to 9-day-old chick embryos were cultured under two different conditions: on noncoated (NS) or collagen-coated (CS) substrates. Although cells on CS seemed to start dividing 2 to 3 days earlier than those on NS, their early growth rates were basically similar. Cells on CS stopped growing after attaining confluency and formed a monolayer, while cells on NS continued to grow after confluency and overlapped each other. In early growth phase, cells on both substrates became depigmented. Cells became repigmented earlier on CS than on NS. The average melanin content of cells in confluent cultures on CS was two to three times higher than that of cells on NS. By Day 30 “lentoid bodies” were formed only in cultures on NS. Immunoelectrophoretic tests showed the presence of all crystallins (α-, β-, and δ) in cultures on NS but not in cultures on CS. It is concluded that a collagen substrate inhibits “transdifferentiation” of pigmented retinal cells into lens during cell culture.