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.     

The <Emphasis Type="Italic">angora</Emphasis> gene weakens the effect of interaction of the mutant genes <Emphasis Type="Italic">wellhaarig</Emphasis> and <Emphasis Type="Italic">waved alopecia</Emphasis> in mice

The interaction of the mutant genes wellhaarig (we) and waved alopecia (wal) in mice was earlier demonstrated in our laboratory. The we gene significantly accelerates the appearance of alopecia in double we/wewal/wal homozygotes as compared to that in single +/+wal/wal homozygotes. It has been found in this work that the mutant gene angora-Y (Fgf5 ^go-Y ) weakens the effect of interaction of the we and wal genes. The first signs of alopecia appear in mice of the we/wewal/wal genotype at the age of 14 days, in triple Fgf5 ^go-Y /Fgf5 ^go-Y we/wewal/wal homozygotes alopecia is observed seven days later, i. e., in 21-day-old animals. The progression of alopecia in triple homozygotes is expressed to a lesser degree than in double +/+we/wewal/wal homozygotes. A single dose of the Fgf5 ^go-Y gene also decreases the effect of interaction of the we and wal genes, but less than a double dose of this gene. The first signs of alopecia in mice of the +/Fgf5 ^go-Y we/wewal/wal genotype appear only three days later than in double +/+we/wewal/wal homozygotes. The data obtained demonstrate that the Fgf5 ^go-Y gene is a powerful modifier of mutant genes determining the process of alopecia.     

Gene angora enhances the effects of gene waved alopecia in mouse

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 for the 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/wal as 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 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.     

Interaction of mutant genes Fgf5go-Y, we, and wal changes the duration of hair growth cycles in mice

Mutant gene wallhaarig (wa) was acting as a modifier of the mutant gene waved alopecia (wal), substantially increasing hair loss rate in mice, as was previously shown in our laboratory. The current paper is devoted to a study of mutant gene angora-Y (Fgf5 ^go-Y ), which had extended anagen stage of the first and second generations hair growth cycles in triple heterozygotes (Fgf5 ^go-Y /Fgf5 ^go-Y we/we wal/wal). First generation guard hair in triple homozygotes had their anagen stage 4 days longer than the same stage in double homozygotes (+/+ we/we wal/wal). Hair loss started at a catagen stage in double homozygotes, while it started in triple homozygotes at the end of the same stage or even in a telogen. Such mutant gene interaction in hair follicle morphogenesis led to a partial recovery of a body hair coat in triple homozygotes.     

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.     

Gene <Emphasis Type="Italic">angora</Emphasis> as a modifier of the <Emphasis Type="Italic">hairless</Emphasis> gene in mouse

The interaction between mouse angora-Y (Fgf5 ^go-Y) and hairless (hr) genes have been studied. Homozygous mutant gene Fgf5 ^go-Y increases length of all hair types, while homozygotes for the h gene lose hair completely starting on day 14 after birth. We obtained mice with genotypes +/+ hr/hr F₂, +/Fgf5 ^go-Y hr/hr and Fgf5 ^go-Y/Fgf5 ^go-Y hr/hr. Both +/Fgf5 ^go-Y hr/hr and +/+ hr/hr mice began to loose hair from their heads on day 14. This further extended on the whole body. On day 21 the mice were completely deprived of hair. Therefore a single dose of gene Fgf5 ^go-Y does not modify alopecia in mice homozygous for hr. However in double homozygotes Fgf5 ^go-Y/Fgf5 ^go-Y hr/hr alopecia started 4 days later, namely on day 18. It usually finished 10–12 days after detection of first bald patches. On days 28–30 double homozygotes lose coat completely. Hair loss in double homozygous mice was 1.5-fold slower than in +/+ hr/hr mice. This resulted from a significant extension of anagen phase induced by a mutant homozygous gene Fgf5 ^go-Y in morphogenesis of the hair follicle. The hr gene was expressed at the transmission phase from anagen to catagen. Our data shows that the angora gene is a modifier of the hairless gene and this results in a strong repression of alopecia progression in double homozygous mice compared to +/+ hr/hr animals.     

Effects of the Mutant Gene wellhaarig in the Chimeric Mice

The mutant genewellhaarig(we) controls the formation of the waved coat in mice, which is most pronounced in homozygotes at 10 to 21 days of postnatal development. Abnormal hair growth and structure in the we/we mutant mice results from defective cell differentiation in the inner root sheath of a hair follicle. To localize the site of the we gene action, we obtained ten chimeric mice by aggregation of the early C57BL/6-2we/we and BALB/c embryos. The chimera coat was waved, shaggy, or almost normal depending on the percentage of the mutant component. In the we/we +/+ chimeric animals of the first generation (G1) aged 21 days, both mutant and normal hair phenotypes were observed, which was especially discernible in zigzag hair. Note that none of the chimeras exhibited the alternating patterns of transversely oriented stripes or patches of either mutant or normal hair; i.e., they had a mixed parental hair phenotype. We also did not observe the animals with an intermediate phenotype, which suggests a discontinuous hair formation in chimeras according to the all or nothing principle. The data obtained indicate that the dermal papilla cells of a hair follicle are the sites for the we gene action. During the embryonic development, dermal cells are strongly mixed, which accounts for the lack of the clear-cut transverse stripes of either mutant or normal hair. The mutant genewe is probably responsible for a disrupted induction signal from the dermal papilla towards ectodermal cells of a hair follicle.     

Interaction of mutant genes Fgf5(go-Y), we, and wal changes the duration of hair growth cycles in mice

Mutant gene wallhaarig (wa) was acting as a modifier of the mutant gene waved alopecia (wal), substantially increasing hair loss rate in mice, as was previously shown in our laboratory. The current paper is devoted to a study of mutant gene angora- Y(Fgf5(go-Y)), which had extended anagen stage of the first and second generations hair growth cycles in triple heterozygotes (Fgf5(go-Y)/Fgf5(go-Y) we/we wal/wal). First generation guard hair in triple homozygotes had their anagen stage 4 days longer than the same stage in double homozygotes (+/+ we/we wal/wal). Hair loss started at a catagen stage in double homozygotes, while it started in triple homozygotes at the end of the same stage or even in a telogen. Such mutant gene interaction in hair follicle morphogenesis led to a partial recovery of a body hair coat in triple homozygotes.     

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.     

Gene angora as a modifier of the mouse hairless gene

The interactions between mouse angora-Y (Fgf5go-Y) and hairless (hr) genes have been studied. Homozygous mutant gene Fgf5go-Y increases hair length starting on day 14 after birth. We obtained mice with genotypes +/+ hr/hr F2, +/Fgf5go-Y hr/hr and Fgf5go-Y/Fgf5go-Y hr/hr. Both +/Fgf5go-Y hr/hr and +/+ hr/hr mice began to loose hair from their heads on day 14. This further extended on the whole body. On day 21 the mice were completely deprived of hair. Therefore a single dose of gene Fgf5go-Y does not affect alopecia mice homozygous for hr. However in double homozygotes Fgf5go-Y/Fgf5gO-hr/hr alopecia started 4 days later, namely on day 18. It usually finished 10-12 days after detection of first bald patches. On days 28-30 double homozygotes have lost all the hair. Hair loss in double homozygous mice was 1,5-fold slower than in +/+ hr/hr mice. This resulted from a significant extension of anagen phase induced by a mutant homozygous gene Fgf5go-Y in morphogenesis of the hair follicle. In contrast, hr gene was expressed only at the transmission phase from anagen to catagen. Our data shows that the angora gene is a modifier of the hairless gene and this results in a strong repression of alopecia progression in double homozygous mice compared to +/+ hr/hr animals.     

Wal Mutant Mice Have a Mutation Associated with Autism Spectrum Disorders

Doklady Biological Sciences - The waved alopecia (wal) mutation arose spontaneously in mice. Phenotypically, the wal mutation in a homozygous recessive state is manifested by a wavy coat. Over...     

The Effects of Mutant Gene hairless in Chimeric Mice

The autosomal recessive gene hairless (hr) is responsible for the complete hairlessness in mice homozygous for this gene. Hair shedding that begins at the age of 10 days is caused by an abnormal cycle of hair follicle development disturbed at the catagen stage. This results in enhanced programmed cell death (apoptosis) and ultimately leads to the complete hair follicle destruction and shedding of all hairs by the age of three weeks. To study the phenotypic expression of the hr gene in a chimeric organism, we have obtained 12 chimeric mice hr/hr +/+ by means of aggregation of early embryos hr/hr and +/+. In chimeric mice, the hair shedding has begun two days later than in the hr/hr mice. By day 23 of postnatal development, hairless areas were present on the coat of chimeric mice or the latter were completely hairless depending on the percentage of the hr/hr mutant component. In four chimeras with high content of the mutant component (68–76%), the hair shedding process was similar to that in the hr/hr mice, though it was accomplished two days later. In three chimeras with 48–51% of the mutant component, alternating hairless and hair-covered bands were observed. These data suggest that the hr gene acts in epidermal cells of a hair follicle, because epidermal cell clones in embryonic skin migrate in the lateral–ventral direction coherently and without mixing. However, some chimeras displayed a pattern which was not so clear-cut: the band borders were illegible and hairs partly covered the hairless areas. In some chimeras, the uniform thinning of the coat was observed. Analysis of the effects of the hr mutant gene in chimeric mice differing in the ratio between mutant (hr/hr) and normal (+/+) components in tissues suggests that the hrgene acts in the epidermal cells of the hair follicle. The interactions between cells have an essential effect on the mode and degree of the hr gene expression, which leads to distortion of the ectodermal coat pattern in chimeras.     

Molecular Basis for the rhino (hr)Phenotype: A Nonsense Mutation in the MousehairlessGene

The hairless (hr) and rhino (hr^rh) mutations are autosomal recessive allelic mutations that map to mouse Chromosome 14. Both hairless and rhino mice have a number of skin and nail abnormalities and develop a striking form of total alopecia at approximately 3–4 weeks of age. The molecular basis of the hairless mouse phenotype was previously found to be the result of a murine leukemia proviral insertion in intron 6 of thehrgene that resulted in aberrant splicing. In this study, we report a 2-bp substitution in exon 4 of thehrgene in a second allele ofhr,rhino 8J (hr^rh-8J), leading to a nonsense mutation. These findings document the molecular basis of the rhino phenotype for the first time and suggest that rhino is a functional knock-out of thehrgene.     

Effects of the mutant gene wellhaarig in chimeric mice

The mutant gene wellhaaring (we) confers the waved coat in mice, which is most pronounced in homozygotes at 10 to 21 days of postnatal development. Abnormal hair growth and structure in the we/we mutant mice results from defective cell differentiation in the inner root sheath of a hair follicle. To localize the site of the we gene action, we obtained ten chimeric mice by aggregation of the early C57BL/6-2we/we and BALB/c embryos. The chimera coat was waved, shaggy, or almost normal depending on the percentage of the mutant component. In the we/we +/+ chimeric animals of the first generation (G1) aged 21 days, both mutant and normal hair phenotypes were observed, which was especially discernible in zigzag hair. Note that none of the chimeras exhibited the alternating patterns of transversely oriented stripes or patches of either mutant or normal hair; i.e., they had a mixed parental hair phenotype. We also did not observe the animals with an intermediate phenotype, which suggests a discontinuous hair formation in chimeras according to the "all or nothing" principle. The data obtained indicate that the dermal papilla cells of a hair follicle are the sites for the we gene action. During the embryonic development, dermal cells are strongly mixed, which accounts for the lack of the clear-cut transverse stripes of either mutant or normal hair. The mutant gene we is probably responsible for a disrupted induction signal from the dermal papilla towards ectodermal cells of a hair follicle.     

The interaction of the coloboma and aphakia mutant genes in mice

The eye development has been studied in the 12-day-old, 14-day-old embryos and in neonates of Cm/+ ak/ak genotype. The gene coloboma (Cm) in heterozygous state causes a typical coloboma of the iris and the gene aphakia (ak) blocks the lens development in the homozygotes. It has been shown that in Cm/+ ak/ak mice the eyes go through mainly the same abnormal development as that in +/+ ak/ak animals. In mice of both genotypes the lens morphogenesis blocking at the vesicle stage and the retinal fold in the dorsal half of the eye develops. However, the ventral retinal fold which is characteristic for the +/+ ak/ak mice does not form in the Cm/+ ak/ak animals that is the result of the interaction of Cm and ak genes in the eye morphogenesis. The Cm gene suppressing the growth of the retina ventral half inhibits the formation of its fold in Cm/+ ak/ak embryos. As a result of the gene interaction a certain normalization of the eye development compared to the +/+ ak/ak mice is observed in the Cm/+ ak/ak animals. The obtained data show that the Cm gene expresses in the cell clones of the retina ventral half.     

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.     

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.     

Antigen-induced acceleration of shedding and replacement of B cell antigen receptors requires mature T cells

To determine which early and intermediate events in the response of antigen-binding B cells to a T-dependent antigen (sheep erythrocytes [SRC]) require T help, the antigen-induced changes in receptor turnover and surface IgD loss in BALB/c athymic nu/nu mice were compared with that of nu/+ littermates and +/+ BALB/c mice. Nonimmune SRC antigen-binding spleen B cells (ABC) from +/+, nu/+, and nu/nu BALB/c mice coexpressed IgM and IgD, and 85 to 95% retained receptors well when incubated for 2.5 hr in 100 micrograms/ml cycloheximide (which prevents receptor replacement). Also they were able to regain their ability to bind antigen by 18 hr after pronase treatment, but not by 2 hr. However, 5 days after in vivo immunization, 1) the proportion of ABC expressing surface IgD declined from around 90% to less than 50% in +/+ mice and nu/+ mice but not in nu/nu mice; 2) substantial recovery of antigen-binding occurred by 2 hr after pronase treatment in +/+ and nu/+ ABC but not in nu/nu ABC; and 3) when spleen cells were incubated in cycloheximide, uncompensated receptor shedding reduced +/+ and nu/+ ABC by around 80% but produced only about a 10% reduction in nu/nu ABC. Thus, although the ABC in nonimmune nu/nu mice appeared normal with respect to their surface Ig turnover and expression, they failed to undergo the normal antigen-induced loss of IgD or acceleration of surface Ig shedding and replacement, suggesting that these intermediate activation events require interaction with mature T cells. To determine whether this interaction had to occur during B cell development, during the development of the immune response, or during receptor shedding or replacement itself, cell transfer experiments were carried our wherein nu/+ T cells were transferred i.v. to nu/nu littermates 1 day before immunization with SRC. In the transfer recipients, pronase-treated day 5 ABC were then able to replace and shed their receptors at the accelerated rate, like ABC from +/+ and nu/+ mice. In contrast, the co-incubation of 5-day immune nu/+ T cells with nu/nu B cells did not alter the rate of shedding or replacement.     

Response of murine epidermis to 2,3,7,8-tetrachlorodibenzo-p-dioxin: Interaction of the Ah and hr loci

2,3,7,8-Tetrachlorodibenzo-p-dioxin (TCDD) and related halogenated aromatic hydrocarbons produce epidermal hyperplasia, hyperkeratosis and sebaceous gland metaplasia in the skin of mice bearing the recessive mutation (hr/hr) hairless. This response is mediated through the cytosol receptor protein: the structure-activity relationship for receptor binding corresponds to that for production of the skin lesion, and these histopathological changes segregate with the genetic polymorphism at the Ah locus, the locus determining the cytosol receptor. In HRS/J mice, an inbred strain segregating for the hr locus, both hairless (hr/hr) and haired (hr/ +) mice possess the high-affinity cytosol receptor and respond to TCDD with the induction of epidermal aryl hydrocarbon hydroxylase activity, a receptor-mediated biochemical response; however, only hr/hr mice develop the proliferative/metaplastic skin response. We propose a genetic model for the interaction of the Ah and hr loci, to account for the differential response to TCDD observed in the skin of HRS/J hr/hr and hr/ + mice.