The angora locus (go) in the mouse: hair morphology, duration of growth cycle and site of action

Pamela R. Pennycuik; Kathryn A. Raphael

doi:10.1017/S0016672300026525

Summary

Core share and HTML view are not available for this content. However, as you have access to this content, a full PDF is available via the ‘Save PDF’ action button.

All four coat hair types were longer in mice homozygous for angora (go / go) than in wild-type mice ( + / +). This increase in hair length in mutant animals was due to an increase in the duration of the phase of hair growth (anagen VI). When skin recombinants incorporating mutant or wild-type epidermis and dermis were grafted to a nude host, the activity of the mutant was found to be confined to the epidermis.

References

REFERENCES

Burns, M. & Fraser, M. N. (1966). Genetics of the Dog. The Basis of Successful Breeding 230 pp. Oliver & Boyd: Edinburgh, London.Google Scholar

Chase, H. B., Rauch, H. & Smith, V. (1951). Critical stages of hair development and pigmentation in the mouse. Physiological Zoology 24, 1–8.Google Scholar

Crary, D. D. & Sawin, P. B. (1953). Some factors influencing the growth potential of the skin in the domestic rabbit. Journal of Experimental Zoology 124, 31–62.Google Scholar

Dickie, M. N. (1963). New mutations: 1. Angora. Mouse News Letter 29, 39.Google Scholar

Fraser, A. S. (1953). A note on the growth of the rex and angora coats. Journal of Genetics 51, 237–242.Google Scholar

Fraser, A. S. & Nay, T. (1955). Growth of the mouse coat. IV. Comparison of naked and normal mice. Australian Journal of Biological Sciences 8, 420–427.Google Scholar

Green, M. C. (Ed.) (1981) Genetic Variants and Strains of the Laboratory Mouse, 476 pp. Fischer: Stuttgart, New York.Google Scholar

Hale, P. A. & Ebling, F. J. (1975). The effects of epilation and hormones on the activity of rat hair follicles. Journal of Experimental Zoology 191, 49–62.Google Scholar

Kindred, B. (1967). Some observations on the skin and hair of tabby mice. Journal of Heredity 58, 197–199.Google Scholar

Lauvergne, J. J. & Howell, W. E. (1978). Un premier inventaire génétique de la chèvre Corse (gènes à effets visibles). Ethnozootechnie 22, 86–92.Google Scholar

Pennycuik, P. R. & Raphael, K. A. (1984). The tabby locus (Ta) in the mouse: its site of action in tail and body skin. Genetical Research 43, 51–64.Google Scholar

Raphael, K. A. & Pennycuik, P. R. (1980). The site of action of the naked locus (N) in the mouse as determined by dermal-epidermal recombinations. Journal of Embryology and Experimental Morphology 57, 143–153.Google Scholar

Robinson, R. (1977). Genetics for Cat Breeders, 2nd edition202 pp. Pergamon: Oxford, New York, Toronto, Sydney, Paris, Frankfurt.Google Scholar

Slee, J. (1957). The morphology and development of ‘Ragged’ a mutant affecting the skin and hair of the house mouse. 1. Adult morphology. Journal of Genetics 55, 100–121.CrossRef Google Scholar

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Pennycuik, Pamela R. Raphael, Kathryn A. Chapman, R. E. and Hardy, Margaret H. 1986. The site of action of the asebia locus (ab) in the skin of the mouse. Genetical Research, Vol. 48, Issue. 3, p. 179.

Hébert, Jean M. Rosenquist, Thomas Götz, Jürgen and Martin, Gail R. 1994. FGF5 as a regulator of the hair growth cycle: Evidence from targeted and spontaneous mutations. Cell, Vol. 78, Issue. 6, p. 1017.

Rosenquist, Thomas A. and Martin, Gail R. 1996. Fibroblast growth factor signalling in the hair growth cycle: Expression of the fibroblast growth factor receptor and ligand genes in the murine hair follicle. Developmental Dynamics, Vol. 205, Issue. 4, p. 379.

Sundberg, John P. and King, Lloyd E. 1996. MOUSE MODELS FOR THE STUDY OF HUMAN HAIR LOSS. Dermatologic Clinics, Vol. 14, Issue. 4, p. 619.

Sundberg, John P. and King, Lloyd E. 1996. Mouse Mutations as Animal Models and Biomedical Tools for Dermatological Research. Journal of Investigative Dermatology, Vol. 106, Issue. 2, p. 368.

Sundberg, J. P. Rourk, M. H. Boggess, D. Hogan, M. E. Sundberg, B. A. and Bertolino, A. P. 1997. Angora Mouse Mutation: Altered Hair Cycle, Follicular Dystrophy, Phenotypic Maintenance of Skin Grafts, and Changes in Keratin Expression. Veterinary Pathology, Vol. 34, Issue. 3, p. 171.

Ornitz, David M. and Waksman, Gabriel 1997. Growth Factors and Wound Healing. p. 151.

Millar, Sarah E. Willert, Karl Salinas, Patricia C. Roelink, Henk Nusse, Roel Sussman, Daniel J. and Barsh, Gregory S. 1999. WNT Signaling in the Control of Hair Growth and Structure. Developmental Biology, Vol. 207, Issue. 1, p. 133.

Nakamura, M. Sundberg, J. P. and Paus, R. 2001. Mutant laboratory mice with abnormalities in hair follicle morphogenesis, cycling, and/or structure: annotated tables. Experimental Dermatology, Vol. 10, Issue. 6, p. 369.

Mikkola, Marja L. and Thesleff, Irma 2003. Ectodysplasin signaling in development. Cytokine & Growth Factor Reviews, Vol. 14, Issue. 3-4, p. 211.

Cho, Yong Mee Woodard, Grant L. Dunbar, Maureen Gocken, Todd Jimènez, Juan A. and Foley, John 2003. Hair-Cycle-Dependent Expression of Parathyroid Hormone-Related Protein and its Type I Receptor: Evidence for Regulation at the Anagen to Catagen Transition. Journal of Investigative Dermatology, Vol. 120, Issue. 5, p. 715.

Ma, Liang Liu, Jian Wu, Tobey Plikus, Maksim Jiang, Ting-Xin Bi, Qun Liu, Yi-Hsin Müller-Röver, Sven Peters, Heiko Sundberg, John P. Maxson, Rob Maas, Richard L. and Chuong, Cheng-Ming 2003. `Cyclic alopecia' inMsx2mutants: defects in hair cycling and hair shaft differentiation. Development, Vol. 130, Issue. 2, p. 379.

Yu, Mei Finner, Andreas Shapiro, Jerry Lo, Blanche Barekatain, Armin and McElwee, Kevin J 2006. Hair follicles and their role in skin health. Expert Review of Dermatology, Vol. 1, Issue. 6, p. 855.

Kehler, James S. David, Victor A. Schäffer, Alejandro A. Bajema, Kristina Eizirik, Eduardo Ryugo, David K. Hannah, Steven S. O'Brien, Stephen J. and Menotti-Raymond, Marilyn 2007. Four Independent Mutations in the Feline Fibroblast Growth Factor 5 Gene Determine the Long-Haired Phenotype in Domestic Cats. Journal of Heredity, Vol. 98, Issue. 6, p. 555.

Malinina, N. A. Konyukhov, B. V. and Nesterov, A. P. 2007. Gene angora enhances the effects of gene waved alopecia in mouse. Russian Journal of Genetics, Vol. 43, Issue. 11, p. 1319.

Konyukhov, B. V. Martynova, M. Yu. and Nesterova, A. P. 2007. Gene angora as a modifier of the hairless gene in mouse. Russian Journal of Genetics, Vol. 43, Issue. 2, p. 190.

LIU, Wu-Xian JIA, Bin SHI, Guo-Qing REN, Jian-Gong LIU, Ka and MA, Run-Lin 2011. Cloning, expression analysis and RNA interference of <I>FGF5</I> gene in sheep. Hereditas (Beijing), Vol. 33, Issue. 9, p. 982.

Breitkopf, Trisia Leung, Gigi Yu, Mei Wang, Eddy and McElwee, Kevin J. 2013. The Basic Science of Hair Biology. Dermatologic Clinics, Vol. 31, Issue. 1, p. 1.

Higgins, Claire A. Petukhova, Lynn Harel, Sivan Ho, Yuan Y. Drill, Esther Shapiro, Lawrence Wajid, Muhammad and Christiano, Angela M. 2014. FGF5 is a crucial regulator of hair length in humans. Proceedings of the National Academy of Sciences, Vol. 111, Issue. 29, p. 10648.

Takahashi, Ryo Takahashi, Gou Kameyama, Yuichi Sato, Masahiro Ohtsuka, Masato and Wada, Kenta 2022. Gender-Difference in Hair Length as Revealed by Crispr-Based Production of Long-Haired Mice with Dysfunctional FGF5 Mutations. International Journal of Molecular Sciences, Vol. 23, Issue. 19, p. 11855.

Download full list

Article contents

The angora locus (go) in the mouse: hair morphology, duration of growth cycle and site of action

Summary

References

REFERENCES

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests