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The induction of tail malformations in trisomy 16 mouse fetuses heterozygous for the curly tail recessive gene

Published online by Cambridge University Press:  14 April 2009

John Anthony Crolla ,
Sarah Katrine Lakeman  and
Mary J. Seller
John Anthony Crolla*
Affiliation:
Paediatric Research Unit, Prince Philip Research Laboratories, United Medical & Dental Schools of Guy's & St Thomas' Hospitals, Floor 8, Guy's Tower, Guy's Hospital, London SE1 9RT, UK
Sarah Katrine Lakeman
Affiliation:
Paediatric Research Unit, Prince Philip Research Laboratories, United Medical & Dental Schools of Guy's & St Thomas' Hospitals, Floor 8, Guy's Tower, Guy's Hospital, London SE1 9RT, UK
Mary J. Seller
Affiliation:
Paediatric Research Unit, Prince Philip Research Laboratories, United Medical & Dental Schools of Guy's & St Thomas' Hospitals, Floor 8, Guy's Tower, Guy's Hospital, London SE1 9RT, UK
*
*Wessex Regional Cytogenetics Unit, General Hospital, Salisbury, Wiltshire, SP2 7SX, U.K., Corresponding author.
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The mouse mutant curly tail is thought to be inherited as an autosomal recessive (ct/ct) with incomplete penetrance so that approximately 60% of ct/ct individuals exhibit the curly tail (CT) phenotype. By outcrossing ct/ct with mouse stock carrying specific heterozygous combinations of Robertsonian (Rb) chromosomes, trisomy 16 (Ts16) and Ts19 mouse fetuses (and their chromosomally balanced littermates) were derived which were heterozygous for the ct gene. All of the Ts16 (ct/Rb;Rb) fetuses, studied between days 14–19 gestation had tail malformations, 86% of which were tail flexion defects (TFD) apparently very similar to the curly tail phenotype. Neither Ts19 nor any of the chromosomally balanced (ct/Rb) littermates from both experimental crosses showed any type of tail or other spinal malformation. At the 27–29 somite stage of development, Ts16 (ct/Rb;Rb) fetuses did not show any significant delay in the closure of the posterior neuropore (PNP) compared with their littermate controls, suggesting that the tail malformation observed in Ts16 (ct/Rb;Rb) occur as a result of mechanisms which differ significantly from those thought to be responsible to causing the curly tail malformation.

Type
Research Article
Information
Genetics Research , Volume 55 , Issue 1 , February 1990 , pp. 27 - 32
Copyright
Copyright © Cambridge University Press 1990

References

Bacchus, C., Sterz, H., Buselmaier, W., Sahai, S. & Winking, H. (1987). Genesis and systemization of cardiovascular anomalies and analysis of skeletal malformations in murine trisomy 16 and 19. Two animal models for human trisomies. Human Genetics 11, 1222.Google Scholar
Baranov, V. S. (1983). Chromosomal control of early embryonic development in mice. I. Experiments on embryos with autosomal monosomy. Genetica 61, 165177.CrossRefGoogle Scholar
Bond, D. J. & Chandley, A. C. (1983). Aneuploidy. Oxford, New York, Toronto: Oxford University Press.Google Scholar
Copp, A. J. (1985). Relationship between timing of posterior neuropore closure and development of spinal neural tube defects in mutant (curly tail) and normal mouse embryos in culture. Journal of Embryology and experimental Morphology 88, 3954.Google ScholarPubMed
Copp, A. J., Crolla, J. A. & Brook, F. A. (1988). Prevention of spinal neural tube defects in the mouse embryo by growth retardation during neurulation. Development 104, 297303.CrossRefGoogle ScholarPubMed
Copp, A. J., Seller, M. J. & Polani, P. E. (1982). Neural tube development in mutant (curly tail) and normal mouse embryos: the timing of posterior neuropore closure in vivo and in vitro. Journal of Embryology and experimental Morphology 69, 151167.Google ScholarPubMed
Cowell, J. K. (1984). A photographic representation of the variability in the G-banded structure of the chromosomes in the mouse karyotype. A guide to the identification of the individual chromosomes. Chromosoma 89, 294320.CrossRefGoogle Scholar
Dyban, A. P. & Baranov, V. S. (1987). Cytogenetics of Mammalian Embryonic Development. Oxford: Clarendon Press.Google Scholar
Embury, S., Seller, M. J., Adinolfi, M. & Polani, P. E. (1979). Neural tube defects in curly tail mice. I. Incidence, expression and similarity to the human condition. Proceedings of the Royal Society, London B 206, 8594.Google Scholar
Epstein, C. J. (1985). The mouse trisomies: experimental systems for the study of aneuploidy. In Issues and Reviews in Teratology, vol. 3 (ed. Kalter, H.), pp. 171217. New York: Plenum Press.CrossRefGoogle Scholar
Gearhart, J. D., Davisson, M. T. & Oster-Granite, M. L. (1986). Autosomal aneuploidy in mice: generation and developmental consequences. Brain Research Bulletin 16, 789801.CrossRefGoogle ScholarPubMed
Gropp, A. (1982). Value of an animal model for trisomy. Virchow's Archives (Perth, Australia) 395, 117131.CrossRefGoogle ScholarPubMed
Gropp, A. & Kolbus, U. (1974). Exencephaly in the syndrome of trisomy no. 12 of the foetal mouse. Nature 249, 145147.CrossRefGoogle ScholarPubMed
Gropp, A. & Kolbus, U. & Giers, D. (1975). Systematic approach to the study of trisomy in the mouse. II. Cytogenetics and Cell Genetics 14, 4262.CrossRefGoogle Scholar
Gropp, A. & Winking, H. (1981). Robertsonian trans-locations: cytology, meiosis, segregation patterns and biological consequences of heterozygosity. In Biology of the House Mouse (ed. Berry, R. J.), pp. 141181. London, New York: Academic Press.Google Scholar
Grüneberg, H. (1954). Genetical studies on the skeleton of the mouse. VIII. Curly tail. Journal of Genetics 52, 5267.CrossRefGoogle Scholar
Hassold, T. J., & Jacobs, P. A. (1984). Trisomy in man. Annual Reviews of Genetics 18, 6997.CrossRefGoogle ScholarPubMed
Meredith, R. (1969). A simple method for preparing meiotic chromosomes from mammalian testis. Chromosoma 26, 254258.CrossRefGoogle ScholarPubMed
Miyabara, S., Gropp, A. & Winking, H. (1982). Trisomy 16 in the mouse fetus associated with generalised edema and cardiovascular and urinary tract anomalies. Teratology 25, 369380.CrossRefGoogle ScholarPubMed
Polani, P. E. & Adinolfi, M. (1980). Chromosome 21 of Man, 22 of great apes and 16 of the mouse. Developmental Medicine and Child Neurology 22, 223225.CrossRefGoogle ScholarPubMed
Shapiro, B. (1983). Down syndrome – a disruption of homeostasis. American Journal of Medical Genetics 14, 241269.CrossRefGoogle ScholarPubMed
Tettenborn, U. & Gropp, A. (1970). Meiotic non-disjunction in mice and mouse hybrids. Cytogenetics 9, 272283.CrossRefGoogle Scholar
Warkany, J. (1971). Congenital Malformations: Notes and Comments. Chicago: Year Book Medical Publishers Inc.Google Scholar
White, B. J., Tjio, J.-H., Van de Water, L. C. & Crandall, C. (1972). Trisomy for the smallest autosome of the mouse and identification of the TlWh translocation chromosome. Cytogenetics 11, 363378.CrossRefGoogle Scholar