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Antral follicles confer developmental competence on oocytes

Published online by Cambridge University Press:  26 September 2008

R.M. Moor ,
C Lee ,
Y.F. Dai  and
J Fulka Jr
R.M. Moor*
Affiliation:
The Babraham Institute, Cambridge, UK, and Institute of Animal Production, Prague, Czech Republic.
C Lee
Affiliation:
The Babraham Institute, Cambridge, UK, and Institute of Animal Production, Prague, Czech Republic.
Y.F. Dai
Affiliation:
The Babraham Institute, Cambridge, UK, and Institute of Animal Production, Prague, Czech Republic.
J Fulka Jr
Affiliation:
The Babraham Institute, Cambridge, UK, and Institute of Animal Production, Prague, Czech Republic.
*
R.M. Moor, Department of Development and Genetics, The Babraham Institute, Cambridge CB2 4AT, UK.
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Extract

This paper addresses the proposition, first advanced by Wilson (1925), that successful embryogenesis depends on an ordered series of events in oogenesis. It is at the completion of this varied set of intracellular changes that the oocyte finally acquires its full capacity to support fertilisation and development. Amongst the earliest nuclear events are those associated with chromosome pairing and meiotic recombination. During the growth phase cell volume increases 300-fold and the cytoplasm becomes the storage site for RNA and protein which will be mobilised during early development. Finally, a short phase of intracellular reprogramming, or maturation, completes the series of events during oogenesis that confer developmental competence upon the oocyte. Follicle cell support is an indispensable requirement for ordered oocyte development and provides the early germline cell with many of the essential nutrients and growth regulators required to ensure progression through the protracted growth phase (see contributions by Cecconi & Rosella and De Felici et al. this issue). Although different, the interactions between the full-grown oocyte and the antral follicle are no less crucial to the acquisition of competence than those involved in the earlier stages of oogenesis.

Type
Article
Information
Zygote , Volume 4 , Issue 4 , November 1996 , pp. 289 - 293
Copyright
Copyright © Cambridge University Press 1996

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References

Downs, S.M. & Daniel, S.A.J. (1988). Induction of maturation in cumulus cell-enclosed mouse oocytes by follicle-stimulating hormone and epidermal growth factor: evidence for a positive stimulus of somatic cell origin. J. Exp. Zool. 245, 8696.CrossRefGoogle ScholarPubMed
Mattioli, M., Galeati, G., Bacci, M.L. & Seren, E.. (1988). Follicular factors influence oocyte fertilizability by modulating the intercellular co-operation between cumulus cells and oocytes. Gamete Res. 21, 223–32.CrossRefGoogle Scholar
Moor, R.M. & Osborn, J.C.. (1983). Somatic control of protein synthesis in mammalian oocytes during maturation. In Molecular Biology of Egg Maturation, pp. 178–96. CIBA Foundation Symposium 98. London: Pitman Books.Google Scholar
Moor, R.M. & Warnes, G.M.. (1978). Regulation of oocyte maturation in mammals. In Control of Ovulation, ed. Crighton, D.B., Foxcroft, G.R., Haynes, N.B. & Lamming, G.E., pp. 159–76. London: Butterworth.CrossRefGoogle Scholar
Moor, R.M., Crosby, I.M.. & Osborn, J.C.. (1983). Growth and maturation of mammalian oocytes. In In vitro Fertilization and Embryo Transfer, pp. 3963. London: Academic Press.Google Scholar
Moor, R.M., Nagai, T. & Gandolfi, F.. (1990). Somatic cell interactions in early mammalian development. In From Ovulation to Implantation. Proceedings of the Seventh Reinier de Graaf Symposium, ed. Evers, J.L.H. & Heineman, M.J., pp. 177–93. Amsterdam: Elsevier.Google Scholar
Rao, C.. (1952). Advanced Statistical Methods in Biometric Research. New York: Wiley.Google Scholar
Turner, K., Martin, K.L., Woodward, B.J., Lenton, E.A. & Leese, H.J.. (1994). Comparison of pyruvate uptake by embryos derived from conception and non-conception natural cycles. Hym. Reprod. 9, 2362–6.CrossRefGoogle ScholarPubMed
Wilson, E.B.. (1925). The Cell in Development and Heredity. London: Macmillan.Google Scholar
Wurth, Y.. (1994). Bovine Embryo Production In Vitro: Influencing Factors. Den Haag, Netherlands: CIP-GEGEVENS Koninklijke Bibliotheek.Google Scholar
Yoshida, M., Ishigaki, K., Nagai, T., Chikyu, M. & Pursel, V.G.. (1993). Glutathione concentration during maturation and after fertilization in pig oocytes: relevance to the ability of oocytes to form male pronucleus. Biol. Reprod. 49, 8994.CrossRefGoogle Scholar