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Daughterless X Sxr/Y Sxr mice

Published online by Cambridge University Press:  14 April 2009

Anne McLaren  and
Paul S. Burgoyne
Anne McLaren
Affiliation:
MRC Mammalian Development Unit, Wolfson House (University College London), 4 Stephenson Way, London NW1 2HE
Paul S. Burgoyne
Affiliation:
MRC Mammalian Development Unit, Wolfson House (University College London), 4 Stephenson Way, London NW1 2HE
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McLaren & Monk (1982) and Cattanach et al. (1982) reported that T(X; 16)16H/X Sxr mice, in which the X chromosome bearing Sxr is the inactivated X chromosome, can develop as fertile females. By mating such females to X/Y Sxr males it has been possible to produce mice homozygous for Sxr. Two X Sxr / Y Sxr males were identified which together fathered 141 sons and 1 daughter. The single daughter proved to be XO, indicating a non-disjunctional event with neither paternal sex chromosome being transmitted. It is concluded that X Sxr / Y Sxr mice are viable and fertile, and that all their progeny, provided they receive a paternal sex chromosome, develop as males.

Type
Research Article
Information
Genetics Research , Volume 42 , Issue 3 , December 1983 , pp. 345 - 349
Copyright
Copyright © Cambridge University Press 1983

References

REFERENCES

Blackler, A. W. (1965). Germ-cell transfer and sex ratio in Xenopus laevis. Journal of Embryology and Experimental Morphology 13, 5161.Google ScholarPubMed
Bucher, T., Bender, W., Fundele, R., Hofner, H. & Linke, I. (1980). Quantitative evaluation of electrophoretic allo- and isozyme patterns. FEBS Letters 115, 319324.CrossRefGoogle ScholarPubMed
Burgoyne, P. S. (1978). The role of the sex chromosomes in mammalian germ cell differentiation. Annales de Biologie Animate Biochime et Biophysique 18 (2B), 317325.CrossRefGoogle Scholar
Burgoyne, P. S. (1982). Genetic homology and crossing over in the X and Y chromosomes of mammals. Human Genetics 61, 8590.CrossRefGoogle ScholarPubMed
Cattanach, B. M. (1974). Position effect variegation in the mouse. Genetical Research 23, 291306.CrossRefGoogle ScholarPubMed
Cattanach, B. M., Evans, E. P., Burtenshaw, M. & Barlow, J. (1982). Male and female development in mice of identical chromosome constitution. Nature 300, 445446.CrossRefGoogle ScholarPubMed
Cattanach, B. M., Pollard, C. E. & Hawkes, S. G. (1971). Sex-reversed mice: XX and XO males. Cytogenetics 10, 318337.CrossRefGoogle ScholarPubMed
Eicher, E. M. (1982). Primary sex determining genes in mice: a brief review. In Prospects for Sexing Mammalian Sperm (ed. Amann, R. P. and Seidel, G. E.), pp. 121135. Colorado: Colorado Associated University.Google Scholar
Eldridge, F. (1980). X-autosome translocation in cattle. 4th European Colloquium on Cytogenetics of Domestic Animals, pp. 2330.Google Scholar
Evans, E. P., Burtenshaw, M. & Cattanach, B. M. (1982). Cytological evidence for meiotic crossing-over between the X and Y chromosome of male mice carrying the sex reversing (Sxr) factor. Nature 300, 443445.CrossRefGoogle Scholar
Gustavsson, I., Fraccaro, M., Tiepolo, L. & Lindstein, J. (1968). Presumptive X-autosome translocation in a cow: preferential inactivation of the normal X chromosome. Nature 218, 183184.CrossRefGoogle Scholar
Gustavsson, I. (1971). Early DNA replication patterns of the normal sex chromosomes and a presumptive X-autosome translocation in cattle (Bos taurus L.). Nature 229, 339341.CrossRefGoogle Scholar
Lyon, M. F., Searle, A. G., Ford, C. E. & Ohno, S. (1964). A mouse translocation suppressing sex linked variegation. Cytogenetics 3, 306323.CrossRefGoogle ScholarPubMed
McLaren, A. (1983). Sex reversal in the mouse. Differentiation 23 (Suppl.), S93–S98.Google ScholarPubMed
McLaren, A. & Monk, M. (1982). Fertile females produced by inactivation of an X chromosome of ‘sex-reversed’ mice. Nature 300, 446448.CrossRefGoogle Scholar
Singh, L. & Jones, K. W. (1982). Sex reversal in the mouse (Mus musculus) is caused by a recurrent non-reciprocal crossover involving the X and an aberrant Y chromosome. Cell 28, 205216.CrossRefGoogle Scholar
Strunnikov, V. A. (1981). Fertility and sex control and its fundamental and practical implications. In Problems of Developmental Biology (ed. Krushchov, N.), pp. 105142. Moscow: Mir.Google Scholar