The site of the action of the angora-Y gene and its interaction with the fuzzy-Y gene in the mouse

The site of action of the goY mutant gene was determined in the aggregation chimaeras C57BL-goY/goY----DBA (+/+). Chimerism was detected by mosaicism of coat pigmentation and electrophoretic pattern of glucose phosphate isomerase. In 28-day-old chimaeras the regions of light-brown coat alternated black coat, stripes of short hairs alternated those of long hairs. These stripes of different length and width extended from spine in lateral-ventral direction. The hairs plucked from long hairs stripes had a similar length that those of goY/goY mice of same age, but the hairs plucked from short hair stripes corresponded to the hair length of +/+ mice. These data show that the goY gene acts in epidermal cells of hair follicles and its expression is autonomous. It has been established that in double homozygotes goY/goYfzY/fzY both mutant genes are expressed: the considerable increase of hair length as compared to norm--the effect of the goY gene and curly coat--the effect of the fzY gene. In goY/goYfzY/fzY mice during the formation of G1 guard hairs the incomplete expression of the goY gene is observed that is due to the suppression of hair growth by the fzY mutant gene. The fzY gene does not suppress the growth of G2 hairs and therefore the full expression of the goY gene occurs in goY/goYfzY/fzY adult mice.     

Mutant gene expression in mouse aggregation chimeras. 6. An analysis of the effects of the white gene using a histochemical marker

The Miwh expression was studied using a genetical marker, acid beta-galactosidase, in 20 day old chimeric mice Miwh/Miwh Bglb/Bglb C/C in equilibrium +/+ Bgld/Bgld C/Ca and Miwh/Miwh Bglb/Bglb C/C in equilibrium +/+ Bgld/Bgld c/c. Three phenotypically new types of the retinal pigment epithelium (RPE) regions were found in the chimeras, which were absent in the RPE of the parental strains. The presence in the chimeras of the RPE regions consisting of pigmented and normally differentiated cells with a high activity of the enzyme suggests the normalization of differentiation of the Miwh/Miwh RPE cells, due, apparently, to the inducing influence of the normal (+/+ C/C) mesenchyme cells. In addition, the presence of nonpigmented, both hyperplasied and nonhyperplasied, RPE regions (+/+ C/C) suggests an insufficient growth-inhibiting influence and the absence of melanogenesis-stimulating activity of defective Miwh/Miwh ectomesenchyme. The histochemical and cytological analysis of the RPE in the obtained chimeras has, thus, shown that the Miwh gene primarily affects ectomesenchyme, which does not exert melanogenesis-stimulating and growth-inhibiting influence on the RPE ensuring its hyperplasia and the absence of pigmentation.     

Mutant gene expression in murine aggregation chimeras. 5. The ocular retardation and fidget genes

Analysis of ocular retardation (or) and fidget (fi) genes expression in 18 day old embryos, 10 and 20 day old or/or C/C----+/+ c/c and fi/fi or/or C/C----+/+ +/+ c/c mice has shown that genes or and fi are active in developing retina and suppress cell proliferation. Structural defects of retina and decrease in the eye size in the chimaeras, compared to the normal embryos, were observed already in the presence of 13-16% of mutant cells. As the fraction of mutant cells increased, the degree of eye disturbances increased as well. In the fi/fi or/or----+/+ +/+ chimaeras structural defects of retina and decrease in the eye size are more pronounced than in the or/or----+/+ chimaeras, due to the synergetical effect of both mutant genes in the fi/fi or/or cell clones. In the ontogenesis of the or/or----+/+ chimaeras the development of the retinal photoreceptor layer is normalized due to the substitution of mutant cells for actively proliferating normal cells. No metabolic cooperation between the mutant and normal cells was observed in the developing retina of chimaeras.     

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.     

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.     

Mutant gene expression in murine aggregation chimeras. 7. The effect of the aphakia gene--disorder in the formation of the crystalline capsule

An analysis of aphakia (ak) gene expression in 16 day ak/ak C/C----+/+ c/c chimaeric embryos has shown, that ak gene, acting in developing lens, blocks lens cell differentiation and disturbs the formation by these cells of the extracellular matrix composing the lens capsule material. The dependence of capsule structure in chimaeras on the genotype of underlying cells indicates that lens cells are responsible for the formation of lens capsule.     

The mutant gene "wal" is active in cells of mouse hair follicles

In order to determine the place of action of the mutant gene waved alopecia (wal), we have obtained chimeric wal/wal c/c Gpi-1aa<-->+/+ C/C Gpi-1bb animals by aggregation of eight-cellular embryos of BALB/c-wal/wal mice and CBA (+/+) mice. The presence or absence of the chimeric structure was determined from the mosaic nature of fur color and hair structure, as well as on the basis of the presence of electrophoretically distinct variants of glucosephosphate isomerase in blood. Chimeras had alternating transverse patches of different lengths and widths consisting of curly (genotype wal/wal) or straight (genotype +/+) hairs. The percentage of cells with wal/wal mutant genotype in chimeras established on the basis of glucosephosphate isomerase isozymes varied from 10 to 80%. A higher percentage of the parental wal/wal component in chimeras correlated with the number of patches having wavy hairs. Analysis of the fur pattern represented by the alternation of transverse patches of wavy or straight hairs in chimeric wal/wal (+/+ mice has shown that mutant gene wal acts in ectodermal cells of hair follicles.     

The we gene is a modifier of the wal gene in mice

Interaction of gene wellhaarig (we) with genes waved alopecia (wal) and hairless (hr) was studied in mice. The mutant gene we is responsible for the development of a specific waved coat in homozygotes. Homozygous mice carrying mutant gene wal also have a wavy coat, though a partial alopecia develops with time in these animals. In homozygotes for the hr gene, hair loss is observed beginning from the age of ten days. A series of crosses we/we and wal/wal yielded animals with we/+wal/wal and we/we wal/wal genotypes. In mice we/+wal/wal carrying gene we at a single dose, alopecia is accelerated significantly as compared to the single-dose homozygotes +/+wal/wal. In we/we wal/wal mice, alopecia starts earlier than in we/+wal/wal mice; by the age of one month, the double homozygotes are almost hairless except for small body areas covered with a sparse coat. In addition, curliness of the first-generation hair in mice we/we wal/wal is much more expressed than in +/+wal/wal and we/we+/+ mice. The obtained evidence suggests that the we gene is a modifier of the wal gene because the former enhances the effects of the wal gene, which is confirmed by the earlier onset of alopecia and progression of the latter in mice having the we/+wal/wal genotype and especially in we/we wal/wal animals. The we/we hr/+ mice do not differ in coat from we/we+/+ mice; in both cases, the coat is wavy. The coat of double homozygotes we/we hr/hr, is similar to that of we/we+/+ mice until ten days of age, when the signs of alopecia appear. By the age of 21 days, mice we/we hr/hr have lost their coat completely like mice +/+ hr/hr. Hence, the we gene is a modifier of the wal gene though it does not interact with hr gene during the coat formation.     

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.     

Phenotypic reversions at the W/Kit locus mediated by mitotic recombination in mice.

The mouse W locus encodes Kit, the receptor tyrosine kinase for stem cell factor (SCF). Kit is required for several developmental processes, including the proliferation and survival of melanoblasts. Because of the nearly complete failure of Wrio/+ melanoblasts to colonize the skin, the costs of Wrio/+ mice are characterized by a majority of white hairs interspersed among pigmented hairs, giving a roan effect. However, 3.6% of Wrio/+ mice exhibit phenotypic reversions, i.e., spots of wild-type color on their coats with an otherwise mutant phenotype. Melanocyte cell lines were derived from each of six independent reversion spots on the skin of (C57BL/6 x DBA/2)F1 Wrio/+ mice. All six melanocyte cell lines exhibited the general characteristics common to normal, nonimmortal mouse melanocytes. Of these, three revertant cell lines had lost the dominant-negative Wrio allele following mitotic recombination between the centromere and the W locus. One of the cell lines remained Wrio/+ but showed (i) stimulation in response to SCF and (ii) increased Kit expression, suggesting that the Wrio mutation can be rescued by increased endogenous expression of the c-kit proto-oncogene. Finally, two cell lines showed no detectable genetic change at the W/Kit locus and failed to respond to SCF stimulation in vitro. These results demonstrate that mitotic recombination can create large patches of wild-type hair on the coats of Wrio/+ mutant mice. This shows that mitotic recombination occurs spontaneously in normal healthy tissue in vivo. Moreover, these experiments confirm that other mechanisms, not associated with loss of heterozygosity, may account for the coat color reversion phenotype.     

An analysis of the distribution of clone cells in the retinal pigment epithelium from chimeric mice

The quantity of pigmented and unpigmented cells was estimated in the retinal pigment epithelium (RPE) in ten newborn and five 20-days old aggregated chimaeric mice C/C----c/c. A strong correlation was shown in the proportion of cells of the paternal genotypes either in the whole RPE of right and left eyes or in its separate regions, i.e. dorsal, central, ventral. Random distribution was revealed in these RPE cells clones. A high correlation was shown between the number of RPE pigmented cells and percentage of coat pigmentation.     

Effect of coat color genes on the hair pigmentation morphology in the American mink (Mustela vison Schr. L.)

The morphological patterns of hair pigmentation (the size and shape of pigment granules and their distribution among layers) have been studied in four compound coat color forms of the American mink: moil-sapphire also known as violet (genotype m/m a/a p/p); moil-silver or sage (genotype m/m p/p); the color form determined by genotype m/+ a/a; and platinum leopard (S(k)/+ a/+ p/p). The hair pigmentation pattern specific for each coat color form and its difference from the standard coat color of the American mink (genotype +/+) has been determined. The possible mechanisms of the phenotypic expression of the nonallelic genes contributing to the described compound color forms are discussed.     

Thymus differentiation and T-cell specificity in nu/nu +/+ mouse aggregation chimaeras

Thymus development and T cell differentiation were studied in mouse chimaeras produced by aggregating pre-implantation embryos of thymus-deficient nude BALB/c (nu/nu) and wild-type C57BL/6 (+/+) mice and vice versa. Chimaeras showed mosaic distribution of skin and coat pigmentation, of hair follicles, of glucosephosphate isomerase within all tested organs and of lymphocytes expressing the different major transplantation antigens (H-2). When tested for their capacity to generate vaccinia virus-specific and self-H-2 specific cytotoxic T cells, all chimaeras of BALB/c (nu/nu) H-2d in equilibrium C57BL/6 (+/+) H-2b type generated T cells of one or both parental origins that were specific for virus and for self-H-2 of the +/+ (H-2b) type only. In contrast, some BALB/c (+/+) H-2d in equilibrium C57BL/6 (nu/nu) H-2b chimaeras generated vaccinia virus-specific cytotoxic T cells specific for either H-2d (+/+) type or for H-2b (nu/nu) type. These asymmetrical results can be interpreted to indicate the following: (i) The +/+ thymus part alone is functional, but because of asymmetrical cross-reactivities of anti-self-H-2 specificities, the observed T cell restriction phenotypes differ. (ii) Both nu/nu and +/+ thymus parts are functional but immune response defects may be exaggerated in such chimaeras producing unexpected non-responsiveness to vaccinia virus linked to H-2d in H-2b (+/+) in equilibrium H-2d (nu/nu).     

The effect of methyl-containing supplements during pregnancy on the phenotypic modification of offspring hair color in rats

The effect of methyl supplements to the diet of pregnant homozygous (AAHH) female rats with agouti coat color mated with homozygous (aahh) males on the phenotypic modification of the coat color of their heterozygous offspring (AaHh) has been studied. Comparative morphological analysis of the main parameters of hair that determine coat color, including the total length of hairs of different types and the length of the upper black (eumelanin) and light (pheomelanin) parts of awn hairs has been performed. The pattern of pigment granule distribution among hair layers has been analyzed. The melanin content of the hair has been determined using electron spin resonance (ESR). Although all offspring have a typical agouti coat color (alternating black and light portions of hair), 39% of them have a darker coat color than control and other experimental rats have. The main differences between the offspring with darkened and standard coat colors are accounted for by the ratio between the eumelanin and pheomelanin portions of awn hairs. In darkened offspring, this ratio is significantly higher than in control rats. The possible mechanisms of the phenotypic modification of agouti coat color in experimental animals are discussed.     

SCF/c-kit signaling is required for cyclic regeneration of the hair pigmentation unit.

Hair graying, an age-associated process of unknown etiology, is characterized by a reduced number and activity of hair follicle (HF) melanocytes. Stem cell factor (SCF) and its receptor c-kit are important for melanocyte survival during development, and mutations in these genes result in unpigmented hairs. Here we show that during cyclic HF regeneration in C57BL/6 mice, proliferating, differentiating, and melanin-producing melanocytes express c-kit, whereas presumptive melanocyte precursors do not. SCF overexpression in HF epithelium significantly increases the number and proliferative activity of melanocytes. During the induced hair cycle in C57BL/6 mice, administration of anti-c-kit antibody dose-dependently decreases hair pigmentation and leads to partially depigmented (gray) or fully depigmented (white) hairs, associated with significant decreases in melanocyte proliferation and differentiation, as determined by immunostaining and confocal microscopy. However, in the next hair cycle, the previously treated animals grow fully pigmented hairs with the normal number and distribution of melanocytes. This suggests that melanocyte stem cells are not dependent on SCF/c-kit and when appropriately stimulated can generate melanogenically active melanocytes. Therefore, the blockade of c-kit signaling offers a fully reversible model for hair depigmentation, which might be used for the studies of hair pigmentation disorders.     

Expression of mutant genes in mouse aggregation chimeras. 4. The aphakia gene

Analysis of aphakia (ak) gene expression in ak/ak C/C in equilibrium +/+ c/c experimental chimaeras has shown that the ak gene acts in the lens rudiment cells blocking it differentiation. In the lens of 12 day old ak/ak C/C in equilibrium +/+ c/c chimaeric embryos undifferentiated ak/ak cells were present among the normally differentiating fibres. In 14 and 18 day old chimaeric embryos and 20 day old chimaeric mice ak/ak cells are located under the lens epithelium and the capsule of posterior lens half. In the locations of ak/ak cells on the posterior lens surface capsule breaks resulted in the extrusion of lens material into the secondary eye cavity. In all studied chimaeric embryos the lens structure is more similar to that in the normal embryos, than in ak/ak embryos. This suggests that in the developing chimaeric lens ak/ak cells are sorted out as the development proceeds. The proliferation rate of +/+ cells appears to be higher than that of ak/ak cells.     

The effect of methyl supplements during pregnancy on the phenotypic modification of offspring agouti coat color in rats

The effect of methyl supplements to the diet of pregnant homozygous (AAHH) female rats with agouti coat color mated with homozygous (aahh) males on the phenotypic modification of the coat color of their heterozygous offspring (AaHh) has been studied. Comparative morphological analysis of the main parameters of hair that determine coat color, including the total length of hairs of different types and the length of the upper black (eumelanin) and light (pheomelanin) parts of awn hairs has been performed. The pattern of pigment granule distribution among hair layers has been analyzed. The melanin content of the hair has been determined using electron spin resonance (ESR). Although all offspring have a typical agouti coat color (alternating black and light portions of hair), 39% of them have a darker coat color than control and other experimental rats have. The main differences between the offspring with darkened and standard coat colors are accounted for by the ratio between the eumelanin and pheomelanin portions of awn hairs. In darkened offspring, this ratio is significantly higher than in control rats. The possible mechanisms of the phenotypic modification of agouti coat color in experimental animals are discussed.     

Evidence for Mitotic Recombination in W(ei)/+ Heterozygous Mice

A number of alleles at coat color loci of the house mouse give rise to areas of wild-type pigmentation on the coats of otherwise mutant animals. Such unstable alleles include both recessive and dominant mutations. Among the latter are several alleles at the W locus. In this report, phenotypic reversions of the Wei allele at the W locus were studied Mice heterozygous in repulsion for both Wei and buff (bf) [i.e. Wei+/+bf] were examined for the occurrence of phenotypic reversion events. Buff (bf) is a recessive mutation, which lies 21 cM from W on the telomeric side of chromosome 5 and is responsible for the khaki colored coat of nonagouti buff homozygotes (a/a; bf/bf). Two kinds of fully pigmented reversion spots were recovered on the coats of a/a; Wei+/+bf mice: either solid black or khaki colored. Furthermore phenotypic reversions of Wei/+ were enhanced significantly following X-irradiation of 9.25-day-old Wei/+ embryos (P less than 0.04). These observations are consistent with the suggestion of a role for mitotic recombination in the origin of these phenotypic reversions. In addition these results rise the intriguing possibility that some W mutations may enhance mitotic recombination in the house mouse.     

Gene angora enhances the effects of gene waved alopecia in mice

Interaction between the mutant gene angora-Y (Fgf5(go-Y)) and the mutant gene waved alopecia (wal) in mice has been studied. Gene Fgf5(go-Y) in a homozygous state increases the length of hair of all types, whereas the homozygotes at wal gene display a waved hair with subsequent development of partial alopecia. Crosses between Fgf5(go-Y)/Fgf5(go-Y) and wal/wal mice gave the animals displaying the genotypes +/Fgf5(go-Y) wal/wal and Fgf5(go-Y)/Fgf5(go-Y) wal/walas well as F2 +/+ wal/wal mice. The first signs of alopecia in F2 +/+ wal/wal appear at the same time as in the mutant wal/wal BALB/c mice. This demonstrates that the genetic background has no effect on the expression of mutant gene wal. A single dose of gene Fgf5(go-Y) in +/Fgf5(go-Y) wal/wal mice causes a considerably earlier appearance of the first signs of alopecia compared with the +/+ wal/wal single homozygotes. The signs of alopecia in double homozygotes Fgf5(go-Y)/Fgf5(go-Y) wal/wal appear even earlier than in the mice +/Fgf5(go-Y) wal/wal. By the end of the first month after birth, the majority of double homozygotes have a virtually bold back with preserved scarce long hairs, guard hairs. Alopecia covers also the sides and belly. However, the head retains its hair and the regions of thinned long hairs remain on the limbs and near the tail base. The data obtained demonstrate that gene Fgf5(go-Y) is a modifier of gene wal, as it enhances considerably the effect of gene wal. This appears in an earlier development of alopecia and its more pronounced progress in the mice with genotypes +/Fgf5(go-Y) wal/wal and, particularly, Fgf5(go-Y)/Fgf5(go-Y) wal/wal.     

Maternal methyl supplements affect the phenotypic variation of the <Emphasis Type="Italic">agouti</Emphasis> gene in the offspring of rats with different behavioral types

The effects of selection of agouti rats (with genotype AAHH) on the tame and aggressive behavior and dietary methyl given to females from the eighth day of pregnancy to the fifth day after the birth of the offspring on the intensity of the agouti coat color in the offspring have been studied. The morphometric parameters of hair determining the darkness of the agouti color (the total length of guard hairs, the lengths of their eumelanin end and pheomelanin band, the ratio between the lengths of the eumelanin and pheomelanin portions of the hair, the total length of the awn hairs, and the relative length of their widened “lanceolate” upper end) have been compared. It has been found that selection of agouti rats for aggressive behavior is accompanied by darkening of the coat color compared to tame rats due to an increase in the ratio of the length of the black eumelanin end of the guard hairs to the length of the yellow pheomelanin band. Methyl-containing additives to the diet of females affect the intensity of the agouti coat color in the offsprings with both types of behavior, but to different extents. Aggressive offspring is more sensitive to the mother’s methyl-containing diet: the percentage of animals that are darker than control rats is higher among aggressive animals than among tame ones due to a greater increase in the ratio between dark and light portions of hairs. The possible mechanisms of differences in the phenotypic modifications of coat color in control and experimental agouti rats with different types of behavior are discussed.