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.     

An analysis of the expression of the mutant angora-Y gene in the mouse

We studied the rate and duration of the growth of G1 and G3 hairs in mice homozygous for angora-Y mutant gene (goY). The follicular diameter of G3 hairs and the growth rate of G1 and G3 hairs in goY/goY mice do not differ from normal. However, the duration of growth period of all four studied types of hairs in goY/goY mice is longer than in the normal phenotype. Growth of the guard hairs G1 and G3 in mutants continues longer than in the normal phenotype by 7 and 3 days, respectively. For other hair types G1 and G3 (awl, auchene, zigzag) the duration of the growth period is approximately 3 days longer than in the control. As a result in goY/goY mice guard hairs G1 and G3 which have completed growth are 2 and 1.5 times longer than in +/+ mice. Other types of G1 hairs in mutants are longer by 50% and G3 hairs by 30% than in the wild type.     

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.     

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.     

The mutant gene wellhaarig disturbs the differentiation of hair follicle cells in the mouse]

First generation (G1) hairs in mice homozygous for the wellhaarig (we) gene are wavy and shorter than in normal mice; basal regions of the hairs are deformed. Follicles of G1 hairs in mid-dorsal region of 8-, 12- and 16-days old we/we mice were examined. Huxley cells of the inner root sheath (IRS) in apical region of hair follicles appeared to be hypertrophied. Cytoplasm of these cells was not stained by basic dyes and showed no birefringence. Cytoplasm of the IRS Henle cells was not stained by basic dyes either. These data indicate that keratinization of the IRS cells is disturbed in mutant homozygotes. The layer of outer root sheath in the we/we mice was thinner than in normal mice; this is probably due to hypertrophy of the IRS cells. The structure of differentiating cells of the hair shaft in normal and mutant mice was similar. The data obtained suggest that abnormal G1 hairs in we/we mice result from disturbance in IRS cells differentiation.     

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.     

Analysis of the effects of mutant hairless genes 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 hr gene 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.     

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.     

Morphological analysis of hair in the hr-2 mutant deer mouse (Peromyscus maniculatus)

Skin from 36 hairless deer mice (Peromyscus maniculatus) homozygous for the recessive hr-2 mutation were analyzed for structural defects in hair and hair loss. Comparison of mutant to wild-type hairs demonstrated characteristic abnormalities in cellular organization, hair shape, length, and fragility. Matings between mutants homozygous for the hr-2 gene and for a second mutation producing hairlessness in deer mice, hr-1, showed that these two genes were nonallelic. Structural abnormalities in hairs associated with the expression of this gene suggest that its primary effect may be on the epidermis.     

Kinky coat, a new autosomal recessive mutation in the musk shrew, Suncus murinus.

A kinky-coat mutant was discovered at the fifth generation of the BAN strain originating from wild musk shrews (Suncus murinus) in Bangladesh. Mating experiments indicated that the kinky-coat character is controlled by a single autosomal recessive gene designated kc (kinky coat), which is not allelic to the gene ch (curly hair) previously reported in the Tr strain derived from wild musk shrews on Taramajima Island, Japan. Because the kc/kc homozygotes were fully fertile and viable, the kc gene should be useful as a genetic marker in linkage studies. In external appearance, homozygotes were characterized by curly vibrissae, somewhat unkept coat hair, and wavy long hair on the tail. Both the length and width of coat hair did not differ significantly between homozygous and normal shrews. Light microscopic observations showed that shafts of the kc coat hair are wavy and often have small swellings with disorganization of the medullary structure. Scanning electron microscopic examinations further revealed that the shafts of the vibrissae, coat hair, and tail hair have abnormalities such as longitudinal fissures, twists, and hollows. It is clear that these modifications caused waviness or curling of the shafts of the three kinds of hairs observed.     

A histological study on the skin and hairs of PC (poor coat) mice

Light microscopic examinations were done on the skin and hairs of PC (poor coat) mice, maintained as an inbred strain at the National Institute of Health, Japan. The structures of the epidermis, dermis, hair root sheath and the sebaceous glands were normal. Hair bulbs and hair papillae were poorly developed at anagen stage of hair cycle. Having scanty medulla, the hairs were thin and short. The hair cuticle appeared normal. These findings suggest that the defective hair growth in PC mice is caused by deficiencies in cell differentiation and/or proliferation in the hair matrix.     

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.     

Hr突变体转基因小鼠的构建和表型分析

无毛基因（Hr）定位于8p12,在染色体上跨越14 kb,包含19个外显子。无毛基因的自发突变能引起人和动物毛发脱落及相关毛发疾病的产生。为深入研究Hr基因的功能,本文利用Gateway技术构建Hr表达载体,在该基因的3 427位引入点突变(G→A),通过显微注射建立转基因小鼠。采用PCR方法鉴定出阳性的转基因小鼠,确定首建鼠,通过与C57BL/6小鼠回交后互交数代建系。观察转基因小鼠毛发生长发育规律。结果表明,成功构建了pRP(Exp)-EF1A>mHairless mutant>IRES/EGFP真核表达载体,通过与野生型小鼠杂交获得阳性子代,进行同窝交配,第2代小鼠出生后14 d开始脱发,30 d左右脱落的毛发重新长出。取部分皮肤组织做石蜡切片,皮肤组织学观察发现,脱毛期无毛小鼠毛囊瓦解,真皮内形成大小不等的包囊,毛发重新生长时,真皮内见大量新生的毛囊。蛋白印迹实验表明,转基因小鼠脱发时HR蛋白表达量明显高于同龄阴性小鼠。本文成功建立稳定遗传的Hr突变的转基因小鼠品系,推测无毛基因突变引发转基因小鼠的脱发,为研究Hr基因的功能提供了良好的动物模型。     

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.     

AtCSLD3, a cellulose synthase-like gene important for root hair growth in arabidopsis

A member of the cellulose synthase-like (subfamily D) gene family of Arabidopsis, AtCSLD3, has been identified by T-DNA tagging. The analysis of the corresponding mutant, csld3-1, showed that the AtCSLD3 gene plays a role in root hair growth in plants. Root hairs grow in phases: First a bulge is formed and then the root hair elongates by polarized growth, the so-called "tip growth." In the mutant, root hairs were initiated at the correct position and grew into a bulge, but their elongation was severely reduced. The tips of the csld3-1 root hairs easily leaked cytoplasm, indicating that the tensile strength of the cell wall had changed at the site of the tip. Based on the mutant phenotype and the functional conservation between CSLD3 and the genuine cellulose synthase proteins, we hypothesized that the CSLD3 protein is essential for the synthesis of polymers for the fast-growing primary cell wall at the root hair tip. The distinct mutant phenotype and the ubiquitous expression pattern indicate that the CSLD3 gene product is only limiting at the zone of the root hair tip, suggesting particular physical properties of the cell wall at this specific site of the root hair cell.     

Annual changes in hair length of the Japanese monkey (Macaca fuscata fuscata)

The hair length of Japanese monkeys was investigated for a period of one year and the molting phenomenon was clarified. Nine monkeys were employed in the study. The molting of the Japanese monkey was found to be of a seasonal type and occurred once during the year. The molting continued for one to four months in each monkey. The hair of the Japanese monkeys was wholly replaced during the period from April to August. The hair length was thus short in summer, and long in winter. Hair replacement in pregnant females began after parturition and was generally later than that in other individuals. During molting, both new and old hairs could be observed simultaneously in the same region of the body. The hair replacement ended around summer when the hair became the shortest. The new hairs continued to grow after molting and became the longest towards autumn or winter. Thus, the summer coat and the winter coat were essentially the same in the Japanese monkey. Such annual changes in the hair of the Japanese monkey were considered to be suitable for the climate of Japan.     

Segmental Igfbp5 expression is specifically associated with the bent structure of zigzag hairs

The murine hair coat consists of four different hair types that are characterised by hair length, the number of medulla columns, and the presence and number of bends. The molecular mechanisms underlying the establishment and maintenance of distinct hair follicle fates are unknown. We identify Igfbp5 as the first molecular marker that distinguishes among different hair follicle types. High-resolution expression analysis revealed that its expression in the medulla of hair shafts is associated with the bend-forming zones of zigzag hairs. To directly examine the functional importance of segmental gene expression in the hair follicle, we have generated transgenic mice expressing Igfbp5 in differentiating keratinocytes of the medulla and inner root sheath. Ectopic expression of Igfbp5 resulted in the appearance of remarkable curvatures and thinning of hair shafts, two hallmarks of hair bends. Both effects and the natural bending process are under negative control of IGF signalling. Thus, our data identify Igfbp5 as a central regulator of hair shaft differentiation and hair type determination.     

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

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