Hostname: page-component-77c89778f8-m8s7h Total loading time: 0 Render date: 2024-07-17T12:34:01.908Z Has data issue: false hasContentIssue false
  • English
  • Français

Factors affecting folliculogenesis in ruminants

Published online by Cambridge University Press:  18 August 2016

R. Webb ,
R. G. Gosden ,
E. E. Telfer  and
R. M. Moor
R. Webb
Affiliation:
School of Biological Sciences, Division of Agriculture and Horticulture, University of Nottingham, Sutton Bonnington Campus, Loughborough LE12 5RD
R. G. Gosden
Affiliation:
Centrefor Reproduction, Growth and Development, University of Leeds, Leeds LS2 9NS
E. E. Telfer
Affiliation:
Institute of Ecology and Resources Management, School of Agriculture, University of Edinburgh, West Mains Road, Edinburgh EH9 3JG
R. M. Moor
Affiliation:
Laboratory of Protein Function, Babraham Institute, Cambridge CB2 4AT
Get access

Abstract

This review addresses the reasons for the lack of progress in the control of superovulation and highlights the importance of understanding the mechanisms underlying follicular development. The present inability to provide large numbers of viable embryos from selected females still restricts genetic improvement, whilst variability in ovarian response to hormones limit the present capacity for increasing reproductive efficiency.

Females are born with a large store of eggs which rapidly declines as puberty approaches. If these oocytes are normal then there is scope for increasing the reproductive potential of selected females. Oocytes must reach a certain size before they can complete all stages of development and the final changes that occur late in follicular development. It is likely that oocytes that do not produce specific factors at precise stages of development will not be viable. Hence, it is important to characterize oocyte secreted factors since there are potential indicators of oocyte quality.

The mechanisms that determine ovulation rate have still not been fully elucidated. Indeed follicular atresia, the process whereby follicles regress, is still not known. A better understanding of these processes should prove pivotal for the synchronization of follicular growth, for more precise oestrous synchronization and improved superovulatory response.

Nutrition can influence a whole range of reproductive parameters however, the pathways through which nutrition acts have not been fully elucidated. Metabolic hormones, particularly insulin and IGFs, appear to interact with gonadotrophins at the level of the gonads. Certainly gonadotropins provide the primary drive for the growth of follicles in the later stages of development and both insulin and IGF-1, possibly IGF-2, synergize with gonadotrophins to stimulate cell proliferation and hormone production. More research is required to determine the effects of other growth factors and their interaction with gonadotropins.

There is evidence, particularly from studies with rodents, that steroids can also modulate follicular growth and development, although information is very limited for ruminants. There may be a rôle for oestrogens in synchronizing follicular waves, to aid in oestrous synchronization regimes and for removing the dominant follicle to achieve improved superovulatory responses. However more information is required to determine whether these are feasible approaches.

Heritability for litter size is higher in sheep than in cattle. Exogenous gonadotropins are a commercially ineffective means of inducing twinning in sheep and cattle. Although there are differences in circulating gonadotropin concentrations, the mechanism(s) responsible for the high ovulation appear to reside essentially within the ovaries. The locus of the Booroola gene, a major gene for ovulation rate, has been established but not specifically identified. However sheep possessing major genes do provide extremely valuable models for investigating the mechanisms controlling ovulation rate, including a direct contrast to mono-ovulatory species such as cattle.

In conclusion, the relationship between oocyte quality, in both healthy follicles and those follicles destined for atresia, must be resolved before the future potential for increasing embryo yield can be predicted. In addition, a greater understanding of the factors affecting folliculogenesis in ruminants should ensure that the full benefits ensuing from the precise control of ovarian function are achieved. The improved use of artificial insemination and embryo transfer that would ensue from a greater understanding of the processes of folliculo genesis, coupled with the new technologies of genome and linkage mapping, should ensure a more rapid rate of genetic gain.

Keywords

folliclesnutritionovulation ratesuperovulation
Type
Research Article
Information
Animal Science , Volume 68 , Issue 2 , March 1999 , pp. 257 - 284
Copyright
Copyright © British Society of Animal Science 1999

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Adams, C. P., Evans, A.C. O. and Rawlings, N. C. 1994. Follicular waves and circulating gonadotropins in 8-month-old prepubertal heifers. Journal of Reproduction and Fertility 100: 2733.CrossRefGoogle ScholarPubMed
Adams, G. P., Matteri, R. L., Kastelic, J. P., , J. C. H. and Ginther, O. J. 1992. Association between surges of follicle-stimulating hormone and the emergence of follicular waves in heifers. Journal of Reproduction and Fertility 94: 177188.CrossRefGoogle ScholarPubMed
Adashi, E. Y. and Rohan, R. M. 1992. Intraovarian regulation. Peptidergic signalling systems. Trends in Endocrinology and Metabolism 3: 243248.Google Scholar
Alpizar, E. and Spicer, L. J. 1993. Effects of interleukin-6 on proliferation and follicle-stimulating hormone-induced estradiol production by bovine granulosa cells in-vitro: dependence on size of follicle. Biology of Reproduction 49: 3843.Google Scholar
Armstrong, D. G., Baxter, G., Gutierrez, C. G., Hogg, C. O., Glazyrin, A. L., Campbell, B. K., Bramley, T. A. and Webb, R. 1998. Insulin-like growth factor binding protein -2 and -4 messenger ribonucleic acid expression in bovine ovarian follicles: effect of gonadotropins and developmental status. Endocrinology 139: 21462154.Google Scholar
Armstrong, D. G., Baxter, G., Gutierrez, C. G., Woad, K. J., Sinclair, K. D., Robinson, J. J., McEvoy, T. G. and Webb, R. 1997. Ovarian IGF-II mRNA expression in cattle fed different energy and protein diets. Journal of Reproduction and Fertility, Abstract Series 14: 13 (abstr.).Google Scholar
Armstrong, D. G., Hogg, C. O., Campbell, B.K. and Webb, R. 1996. Insulin-like growth factor (IGF) binding protein production by primary cultures of ovine granulosa and theca cells. The effect of IGF-I, gonadotropin and follicle size. Biology of Reproduction 55: 11631171.CrossRefGoogle ScholarPubMed
Armstrong, D. G. and Webb, R. 1997. Ovarian follicular dominance: novel mechanisms and protein factors. Reviews of Reproduction 2: 139146.CrossRefGoogle Scholar
Ash worth, C. J. 1994. Nutritional factors related to embryonic mortality in the domestic species. In Embryonic mortality in domestic species (ed. Zavy, M. T. and Geisert, R. D.), pp. 179194. CRC Press.Google Scholar
Baird, D. T., Campbell, B.K., Mann, G. E. and McNeilly, A. S. 1991. Inhibin and oestradiol in the control of FSH secretion in the sheep. Journal of Reproduction and Fertility, Supplement 43: 125138.Google Scholar
Baker, J., Hardy, M. P., Zhou, J., Bondy, C., Lupu, F., Bellve, A. R. and Efstratiadis, A. 1996. Effects of an IGF1 gene null mutation on mouse reproduction. Molecular Endocrinology 10: 903918.Google Scholar
Bao, B. and Garverick, H. A. 1998. Expression of steroidogenic enzyme and gonadotropin receptor genes in bovine follicles during ovarian follicular waves: a review. Journal of Animal Science 76: 19031921.CrossRefGoogle ScholarPubMed
Bao, B., Garverick, H. A., Smith, G. W., Smith, M. F., Salfen, B. E. and Youngquist, R. S. 1997. Expression of messenger ribonucleic acid (mRNA) encoding 3ß-hydroxysteroid dehydrogenase Δ4 Δ5 isomerase (3ß-HSD) during recruitment and selection of bovine ovarian follicles: identification of dominant follicles by expression of 3ß-HSD mRNA within the granulosa cell layer. Biology of Reproduction 56: 14661473.Google Scholar
Baxter, G., O’Shea, T., Campbell, B. K. and Webb, R. 1995. Effects of bovine follicular fluid (bFF) fractions, which delay oestrus in sheep and cattle, on proliferation and steroid production by cultured granulosa cells. Journal of Reproduction and Fertility, Abstract Series 15: 189 (abstr.).Google Scholar
Berndtson, A. K., Vincent, S. E. and Fortune, J. E. 1995. Low and high concentrations of gonadotropins differentially regulate hormone production by theca interna and granulosa cells from bovine preovulatory follicles. Biology of Reproduction 52: 13341342.Google Scholar
Bigelow, K. L. and Fortune, J. E. 1998. Characteristics of prolonged dominant versus control follicles: follicle cell numbers, steroidogenic capabilities and messenger ribonucleic acid for steroidogenic enzymes. Biology of Reproduction 58: 12411249.CrossRefGoogle ScholarPubMed
Bindon, B. M., Chang, T. S. and Turner, H. N. 1972. Ovarian responses for gonadotrophin by Merino ewes selected for fecundity. Australian Journal of Biolological Science 37: 163189.Google Scholar
Bo, G. A., Adams, G. P., Pierson, R. A. and Mapletoft, R. J. 1995. Exogenous control of follicular wave emergence in cattle. Theriogenology 43: 3140.CrossRefGoogle Scholar
Boland, M. P., Murphy, M. G. and Roche, J. F. 1990. The use of ultrasound to monitor ovarian function in farm animals. Agriculture, Biotechnology News and Information 2: 841844.Google Scholar
Bols, P. E. J., Ysebaert, M. T., Lein, A., Coryn, M., Soom, A. van and Kruif, A. de. 1998. Effects of long-term treatment with bovine somatrotropin on follicular dynamics and subsequent oocyte and blastocyst yield in an OPU-IVF program. Theriogenology 49: 983995.Google Scholar
Buccione, R., Vanderhyden, B. C., Caron, P. J. and Eppig, J. J. 1990. FSH-induced expansion of the mouse cumulus oophorus in vitro is dependent upon a specific factor secreted by the oocyte. Developmental Biology 138: 1625.CrossRefGoogle ScholarPubMed
Butterwick, R. F., Rowlinson, P., Weekes, T. E. C., Parker, D. S. and Armstrong, D. G. 1988. The effect of long-term daily administration of bovine somatotropin on the performance of dairy heifers during their first lactation. Animal Production 46: 483 (abstr.).Google Scholar
Byskov, A. G. 1986. Differentiation of the mammalian embryonic gonad. Physiological Reviews 66: 71117.Google Scholar
Cahill, L. P. and Mauleon, P. 1980. The population of primordial and small follicles in the sheep. Journal of Reproduction and Fertility 61: 201206.Google Scholar
Cahill, L. P. and Mauleon, P. 1981. Influence of season and cycle and breed on follicular growth rates in sheep. Journal of Reproduction and Fertility 68: 321328.Google Scholar
Campbell, B. K., Baird, D. T. and Webb, R. 1998. Effects of dose of LH on androgen production and luteinization of ovine theca cells cultured in a serum-free system. Journal of Reproduction and Fertility 112: 6977.CrossRefGoogle Scholar
Campbell, B. K., Gordon, B. M., Dobson, H. and Scaramuzzi, R. J. 1993. Insulin-like growth factors can stimulate oestradiol production both in vivo and in vitro . Journal of Reproduction and Fertility, Abstract Series 12: 21 (abstr.).Google Scholar
Campbell, B. K., Gordon, B. M. and Scaramuzzi, R. J. 1994. The effect of ovarian arterial infusion of transforming growth factor oc on ovarian follicle populations and ovarian hormone secretion in ewes with an autotransplanted ovary. Journal of Endocrinology 143: 1324.Google Scholar
Campbell, B. K., Picton, H. M., Mann, G. E., McNeilly, A. S. and Baird, D. T. 1991. Effect of steroid- and inhibin-free ovine follicular fluid on ovarian follicles and ovarian hormone secretion. Journal of Reproduction and Fertility 93: 8196.CrossRefGoogle ScholarPubMed
Campbell, B. K., Scaramuzzi, R. J. and Webb, R. 1995. Control of antral follicle development and selection in sheep and cattle. Journal of Reproduction and Fertility, Supplement 49: 335350.Google Scholar
Campbell, B. K., Scaramuzzi, R. J. and Webb, R. 1996a. Induction and maintenance of oestradiol and immuno-reactive inhibin production with FSH by ovine granulosa cells cultured in serum free media. Journal of Reproduction and Fertility 106: 716.Google Scholar
Campbell, B. K., Souza, C. J. H., Baird, D. T. and Webb, R. 1996b. The FecB gene acts at the ovarian level to enhance ovulation rate. Thirteenth international congress on animal reproduction, vol. 2, p. 72 (abstr.).Google Scholar
Campbell, B. K. and Webb, R. 1995. Evidence that inhibin has autocrine and paracrine actions in controlling ovarian function in sheep. Journal of Reproduction and Fertility, Abstract Series 15: 140 (abstr.).Google Scholar
Carson, R. S., Findlay, J. K., Clarke, I. J. and Burger, H. G. 1981. Estradiol, testosterone and androstenedione in ovine follicular fluid during growth and atresia of ovarian follicles. Biology of Reproduction 24: 105113.Google Scholar
Charlton, H. M., Parry, D., Halpin, D. M. G. and Webb, R. 1982. Distribution of 125I-labelled follicle-stimulating hormone and human chorionic gonadotrophin in the gonads of hypogonadal (hpg) mice. Journal of Endocrinology 93: 247252.Google Scholar
Chase Jr, C. C., Kirby, C. J., Hammond, A. C., Olson, T. A. and Lucy, M. C. 1998. Patterns of ovarian growth and development in cattle with a growth hormone receptor deficiency. Journal of Animal Science 76: 212219.Google Scholar
Cole, W. J., Madsen, K. S., Hintz, R. L. and Collier, R. J. 1991. Effect of recombinantly-derived bovine somatotropin on reproductive performance of dairy cattle. Theriogenology 36: 573595.Google Scholar
Crowe, A. A., Padmanabhan, V., Mihm, M., Beitins, I. Z. and Roche, J. F. 1998. Resumption of follicular waves in beef cows is not associated with periparturient changes in follicle-stimulating hormone heterogeneity despite major changes in steroid and luteinizing hormone concentrations. Biology of Reproduction 58: 14451450.Google Scholar
de la Sota, R. L., Simmen, F. A., Diaz, T. and Thatcher, W. W. 1996. Insulin-like growth factor system in bovine first-wave dominant and subordinate follicles. Biology of Reproduction 55: 803812.Google Scholar
de la Sota, R. L., Lucy, M. C., Staples, C.R. and Thatcher, W. W. 1993. Effects of recombinant bovine somatotropin (Sometribove) on ovarian function in lactating and nonlactating dairy cows. Journal of Dairy Science 76: 10021013.CrossRefGoogle ScholarPubMed
Demeter-Arlotto, M., Rainey, W. E. and Simpson, E. R. 1993. Maintenance and regulation of 17 a-hydroxylase expression by bovine thecal cells in primary culture. Endocrinology 132:13531358.Google Scholar
Diaz, T., Schmitt, E. J.-P., de la Sota, R. L., Thatcher, M.-J. and Thatcher, W. W. 1998. Human chorionic gonadotrophin-induced alterations in ovarian follicular dynamics during the estrous cycle of heifers. Journal of Animal Science 76: 19291936.Google Scholar
Donaldson, L. E. and Perry, B. 1983. Embryo production by repeated superovulation of commercial donor cows. Theriogenology 20: 163168.CrossRefGoogle Scholar
Dong, J., Albertini, D. F., Nishimori, K., Kumar, T. R., Naifung, L. and Matsuk, M. M. 1996. Growth differentiation factor-9 is required during early ovarian folliculogenesis. Nature 383: 531535.Google Scholar
Dott, H. M., Hay, M. F., Cran, D. G. and Moor, R. M. 1979. Effect of exogenous gonadotrophin (PMSG) on the antral follicle population in the sheep. Journal of Reproduction and Fertility 56: 683689.Google Scholar
Downing, J. A. and Scaramuzzi, R. J. 1991. Nutrient effects on ovulation rate, ovarian function and the gonadotrophic and metabolic hormones in sheep. Journal of Reproduction and Fertility, Supplement 43: 209227.Google Scholar
Downing, J. A., Scaramuzzi, R. J. and Joss, J. 1993. The direct effect of insulin on ovarian steroid secretion in ewes with an autotransplanted ovary. Proceedings of the Australian Society of Reproductive Biology 25: 54.Google Scholar
Driancourt, M. A., Fry, R. C., Clarke, I. J. and Cahill, L. P. 1987. Follicular growth and regression during the 8 days after hypophysectomy in sheep. Journal of Reproduction and Fertility 79: 635641.Google Scholar
Driancourt, M. A., Philipon, P., Locatelli, A., Jacques, E. and Webb, R. 1988. Are differences in FSH concentrations involved in the control of ovulation rate in Romanov and Ile-de-France ewes? Journal of Reproduction and Fertility 83: 509516.Google Scholar
Driancourt, M. A., Thatcher, W. W., Terqui, M. and Andrieu, D. 1991a. Dynamics of ovarian follicular development in cattle during the estrous cycle, earlv pregnancy and in response to PMSG. Domestic Animal Endocrinology 8: 209221.Google Scholar
Driancourt, M. A., Webb, R. and Fry, R. C. 1991b. Does follicular dominance occur in ewes? Journal of Reproduction and Fertility 93: 6370.Google Scholar
Dufour, J., Cahill, L. P. and Mauleon, P. 1979. Short- and long-term effects of hypophysectomy and unilateral ovariectomy on ovarian follicular populations in sheep. Journal of Reproduction and Fertility 57: 301309.Google Scholar
Dufour, J., Whitmore, O. J., Ginther, O. J. and Casida, L. E. 1972. Identification of the ovulating follicle by its size on different days of the estrous cycle in heifers. Journal of Animal Science 34: 8587.Google Scholar
Dunn, T. G. and Moss, G. E. 1992. Effects of nutrient deficiencies and excesses on reproductive efficiency of livestock. Journal of Animal Science 70: 15801593.CrossRefGoogle ScholarPubMed
Echternkamp, S. E., Spicer, L. J., Gregory, K. E., Canning, S. F. and Hammond, J. M. 1990. Concentrations of insulinlike growth factor-I in blood and ovarian follicular fluid of cattle selected for twins. Biology of Reproduction 43: 814.Google Scholar
Eckery, D. C., Moeller, C. L., Nett, T. M. and Sawyer, H. R. 1997. Localization and quantification of binding sites for follicle-stimulating hormone, luteinizing hormone, growth hormone, and insulin-like growth factor 1 in sheep ovarian follicles. Biology of Reproduction 57: 507513.Google Scholar
El-Roeiy, A., Chen, X., Roberts, V. J., LeRoith, D., Roberts Jr, C. T. and Yen, S. S. C. 1993. Expression of insulin-like growth factor-I (IGF-I) and IGF-II and the IGF-I, IGF-II and insulin receptor genes and localization of the gene products in the human ovary. Journal of Clinical Endocrinology and Metabolism 77: 14111418.Google ScholarPubMed
England, B. G., Dahmer, M. K. and Webb, R. 1981. Relationships between follicular size and antral fluid steroid concentrations at three stages of the estrous cycle in the ewe. Biology of Reproduction 24: 10681075.CrossRefGoogle ScholarPubMed
Eppig, J. J. and Schroeder, A. C. 1986. Culture systems for mammalian oocyte development: progress and prospects. Theriogenology 25: 97106.Google Scholar
Findlay, J. K. 1993. An update on the roles of inhibin, activin, and follistatin as local regulators of folliculogenesis. Biology of Reproduction 48: 1523.Google Scholar
Findlay, J. K. 1994. Peripheral and local regulators of folliculogenesis. Reproduction, Fertility and Development 6: 127139.Google Scholar
Fischer, B. 1993. Growth factors as regulators of mammalian preimplantation development. In Preimplantation embryo development (ed. Bavister, B. D.), pp. 8396. Springer-Verlag, New York.Google Scholar
Fleming, J. S., Greenwood, P. J., Heath, D. A., Hudson, N. L., Lun, S., Shaw, L. and McNatty, K. P. 1995. Expression of gonadotrophin subunit genes in sheep that were homozygous carriers and non-carriers of the Booroola fecundity gene FecB. Journal of Reproduction and Fertility 103: 315321.Google Scholar
Folley, S. J. and Malpress, F. H. 1945. The response of the bovine ovary to pregnant mare’s serum and horse pituitary extract. Proceedings of the Royal Society of London, Series B 132: 164188.Google Scholar
Fortune, J.E. 1994. Ovarian follicular growth and development in mammals. Biology of Reproduction 50: 225232.Google Scholar
Fortune, J. E., Sirois, J., Turzillo, A. M. and Lavoir, M. 1991. Follicle selection in domestic species. Journal of Reproduction and Fertility, Supplement 43: 187198.Google Scholar
Fry, R. C., Clarke, I. J., Cummins, J. T., Bindon, B. M., Piper, L. R. and Canili, L. P. 1988. Induction of ovulation in chronically hypophysectomized Booroola ewes. Journal of Reproduction and Fertility 82: 711715.Google Scholar
Garrett, W. M. and Guthrie, H. D. 1996. Expression of androgen receptors and steroidogenic enzymes in relation to follicular growth and atresia following ovulation in pigs. Biology of Reproduction 55: 949955.Google Scholar
Ginther, O. J., Knopf, L. and Kaestilic, J. P. 1989. Temporal associations among ovarian events in cattle during the oestrous cycles with two and three follicular waves. Journal of Reproduction and Fertility 87: 223230.CrossRefGoogle ScholarPubMed
Ginther, O. J., Kot, K., Kulick, L. J., Martin, S. and Wiltbank, M. C. 1996a. Relationship between FSH and ovarian follicular waves during the last six months of pregnancy in cattle Journal of Reproduction and Fertility 108: 271279.Google Scholar
Ginther, O. J., Wiltbank, M. C., Fricke, P. M., Gibbons, J. R. and Kot, K. 1996b. Selection of the dominant follicle in cattle. Biology of Reproduction 55: 11871194.Google Scholar
Giudice, L. C. 1992. Insulin-like growth factors and ovarian follicular development. Endocrine Reviews 13: 641669.Google Scholar
Gong, J. G. 1992. The role of growth hormone, insulin-like growth factor-I and insulin in the control of ovarian follicular growth and development in the heifer. Ph.D. thesis, The University of Edinburgh. Google Scholar
Gong, J. G., Baxter, G., Bramley, T. A. and Webb, R. 1997. Enhancement of ovarian follicle development in heifers by treatment with recombinant bovine somatotrophin: a dose-response study. Journal of Reproduction and Fertility 110: 9197.CrossRefGoogle ScholarPubMed
Gong, J. G., Bramley, T. A., Gutierrez, C. G., Peters, A. R. and Webb, R. 1994a. Effects of chronic treatment with a gonadotrophin-releasing hormone agonist on peripheral concentrations of FSH and LH, and ovulation function in heifers. Journal of Reproduction and Fertility 105: 263270.Google Scholar
Gong, J. G., Bramley, T. and Webb, R. 1991. The effect of recombinant bovine somatropin on ovarian function in heifers: follicular populations and peripheral hormones. Biology of Reproduction 45: 941949.CrossRefGoogle Scholar
Gong, J. G., Bramley, T. A. and Webb, R. 1993a. The effect of recombinant bovine somatotrophin on ovarian follicular growth and development in heifers. Journal of Reproduction and Fertility 97: 247254.Google Scholar
Gong, J. G., Bramley, T. A., Wilmut, I. and Webb, R. 1993b. The effect of recombinant bovine somatotropin on the superovulatory response to pregnant mare serum gonadotropin in heifers. Biology of Reproduction 48: 11411149.Google Scholar
Gong, J. G., Campbell, B. K., Bramley, T. A., Gutierrez, C. G., Peters, A. R. and Webb, R. 1996a. Suppression in the secretion of follicle-stimulating hormone and luteinizing hormone and ovarian follicle development in heifers continuously infused with a gonadotropin-releasing hormone agonist. Biology of Reproduction 55: 6874.Google Scholar
Gong, J. G., Campbell, B. K., Bramley, T. A. and Webb, R. 1996b. Treatment with recombinant bovine somatotrophin enhances ovarian follicle development and increases the secretion of insulin-like growth factor-I by ovarian follicles in ewes. Animal Reproduction Science 41: 1326.Google Scholar
Gong, J. G., McBride, D., Bramley, T. A. and Webb, R. 1994b. Effects of recombinant bovine somatotrophin, insulin-like growth factor-I and insulin on bovine granulosa cell steroidogenesis in vitro . Journal of Endocrinology 143: 157164.CrossRefGoogle ScholarPubMed
Gong, J. G. and Webb, R. 1996. Control of ovarian follicle development in domestic ruminants: its manipulation to increase ovulation rate and improve reproductive performance. Animal Breeding Abstracts 64: 195204.Google Scholar
Gong, J. G., Wilmut, I., Bramley, T. A. and Webb, R. 1995. Pretreatment with recombinant bovine somatotropin enhances the superovulatory response to FSH in heifers. Theriogenology 45: 611622.Google Scholar
Goodman, A. L. and Hodgen, G. D. 1983. The ovarian triad of the primate menstrual cycle. Recent Progress in Hormone Research 39: 173.Google ScholarPubMed
Gosden, R. G. 1993. Follicular growth and endocrinology during the transition from fertile life to postmenopausal era. In Ovarian endocrinopathies (ed. Schats, R. and Schoemaker, J.), pp. 313. Parthenon, New York and London.Google Scholar
Gosden, R. G. 1995. Oocyte development throughout life. Cambridge reviews in human reproduction, gametes — the oocyte (ed. Grudzinskas, J. G. and Yovich, J. L.), pp. 19149. Cambridge University Press, Cambridge.Google Scholar
Gosden, R. G., Baird, D. T., Wade, J. C. and Webb, R. 1994. Restoration of fertility to oophorectomized sheep by ovarian autografts stored at -196°C. Human Reproduction 9: 597603.Google Scholar
Gosden, R. G., Hunter, R. H. F., Telfer, E., Torrance, C. and Brown, N. 1988. Physiological factors underlying the formation of follicular fluid. Journal of Reproduction and Fertility 82: 813825.CrossRefGoogle ScholarPubMed
Gosden, R. G., Krapez, J. and Briggs, D. 1997. The life history of the mammalian oocyte. BioEssays 19: 875882.Google Scholar
Gosden, R. G. and Spears, N. 1997. Programmed cell death in the reproductive system. British Medical Bulletin 52: 644661.Google Scholar
Gosden, R. G. and Telfer, E. E. 1987. Numbers of follicles and oocytes in mammalian ovaries and their allometric relationships. Journal of Zoology 211: 169175.Google Scholar
Gospodarowicz, D. and Ferrara, N. 1989. Fibroblast growth factor and the control of pituitary and gonad development and function. Journal of Steroid Biochemistry 32:183191.Google Scholar
Greve, T., Caliesen, H., Hyttel, P., Høier, R. and Assey, R. 1995. The effects of exogenous gonadotropins on oocyte and embryo quality in cattle. Theriogenology 43: 4150.Google Scholar
Grimes, R. W., Barber, J. A., Shimasaki, S., Ling, N. and Hammond, J. M. 1994. Porcine ovarian granulosa cells secrete insulin-like growth factor-binding proteins-4 and -5 and express their messenger ribonucleic acids: regulation by follicle-stimulating hormone and insulin-like growth factor-I. Biology of Reproduction 50: 695701.Google Scholar
Grimes, R. W., Matton, P. and Ireland, J. J. 1987. A comparison of histological and non-histological indices of atresia and follicular function. Biology of Reproduction 37: 8288.CrossRefGoogle ScholarPubMed
Guilbault, L. A., Grasso, F., Lussier, J. G., Rouillier, P. and Matton, P. 1991. Decreased superovulatory responses in heifers superovulated in the presence of a dominant follicle. Journal of Reproduction and Fertility 91: 8189.Google Scholar
Guthrie, H. D., Garrett, W. M. and Cooper, B. S. 1998. Follicle-stimulating hormone and insulin-like growth factor-1 attenuate apoptosis in cultured porcine granulosa cells. Biology of Reproduction 58: 390396.Google Scholar
Gutierrez, C. G., Campbell, B. K., Armstrong, D. T. and Webb, R. 1997a. Insulin-like growth factor-I (IGF-I) production by bovine granulosa cells in vitro and peripheral IGF-I measurement in cattle serum: an evaluation of IGFBP extraction protocols. Journal of Endocrinology 153: 231240.Google Scholar
Gutierrez, C. G., Campbell, B.K. and Webb, R. 1997b. Development of a long-term bovine granulosa cell culture system: induction and maintainance of estradiol production, response to FSH and morphological characteristics. Biology of Reproduction 56: 608616.CrossRefGoogle ScholarPubMed
Gutierrez, C. G., Oldham, J., Bramley, T. A., Gong, J. G., Campbell, B. K. and Webb, R. 1997c. The recruitment of ovarian follicles is enhanced by increased dietary intake in heifers. Journal of Animal Science 75: 18761884.Google Scholar
Hackett, A. J. and Hafs, H. D. 1969. Pituitary and hypothalamic endocrine changes during the bovine estrous cycle. Journal of Animal Science 28: 531536.Google Scholar
Halpin, D. M. G., Charlton, H. M. and Faddy, M. J. 1986. Effects of gonadotrophin deficiency on follicular development in hypogonadal (hpg) mice. Journal of Reproduction and Fertility 78: 119125.Google Scholar
Hammond, J. 1927. The physiology of reproduction in the cow. Cambridge University Press, Cambridge.Google Scholar
Hay, M. F., Moor, R. M., Cran, D. G. and Dott, H. K. 1979. Regeneration of atretic sheep ovarian follicles in vitro . Journal of Reproduction and Fertility 55: 195207.CrossRefGoogle ScholarPubMed
Hernandez, E. R., Hurwitz, A., Vera, A., Pellicer, A., Adashi, E. Y., LeRoith, D. and Roberts Jr, C. 1992. Expression of genes encoding the insulin-like growth factors and their receptors in the human ovary. Journal of Clinical Endocrinology and Metabolism 74: 419425.Google Scholar
Herrler, A., Einspanier, R., Schams, D. and Niemann, H. 1994. Effect of recombinant bovine somatotropin (rBST) on follicular IGF-I contents and the ovarian response following superovulatory treatment in dairy cows: a preliminary study. Theriogenology 41: 601611.Google Scholar
Hillier, S. G. 1991. Regulatory functions for inhibin and activin in human ovaries. Journal of Endocrinology 131: 171175.Google Scholar
Hillier, S. G., Whitelaw, P. F. and Smyth, C. D. 1994. Follicular oestrogen synthesis: the ‘two-cell, two-gonadotrophin’ model revisited. Molecular and Cellular Endocrinology 100: 5154.Google Scholar
Howard, H. J. and Ford, J. J. 1994. Differential steroidogenic response of subpopulations of porcine granulosa cells to insulin-like growth factor-I (IGF-I) or IGF-I analogs. Biology of Reproduction 51: 108115.Google Scholar
Hsueh, A. J. W., Bicsak, T. A., Jia, X.-C, Dahl, K. D., Fauser, B. C. J. M., Galway, A.B., Czekała, N., Pavlou, S. N., Papkoff, H., Keene, J. and Boime, I. 1989. Granulosa cells as hormone targets: the role of biologically active follicle-stimulating hormone in reproduction. Recent Progress in Hormone Research 45: 209277.Google Scholar
Hsueh, A. J. W., Billig, H. and Tsafrir, A. 1994. Ovarian follicle atresia: a hormonally controlled apoptotic process. Endocrine Reviews 15: 707724.Google Scholar
Huhtinen, M., Rainio, V., Aalto, J., Bredbacka, P. and Maki-Tanila, A. 1992. Increased ovarian responses in the absence of a dominant follicle in superovulated cows. Theriogenology 37: 457463.Google Scholar
Ireland, J. J., Coulson, P. B. and Murphree, R. L. 1979. Follicular development during four stages of the estrous cycle of beef cattle. Journal of Animal Science 49: 12611269.Google Scholar
Johnson, S. K. and Smith, M. F. 1985. Effects of charcoal-extracted, bovine follicular fluid on gonadotropin concentrations, the onset of estrus and luteal function in heifers. Journal of Animal Science 61: 203209.Google Scholar
Jolly, P. D., Tisdall, D. J., Heath, D. A., Lun, S. and McNatty, K. P. 1994. Apoptosis in bovine granulosa cells in relation to steroid synthesis, cyclic adonosine 3’,5’-monophosphate response to follicle-stimulating hormone and luteinizing hormone, and follicular atresia. Biology of Reproduction 51: 934944.Google Scholar
Jones, E. C. and Krohn, P. L. 1961. The relationship between age, numbers of oocytes and fertility in virgin and multiparous mice. Journal of Endocrinology 21: 469495.Google Scholar
Jones, J. I. and Clemmons, D. R. 1995. Insulin-like growth factors and their binding proteins: biological actions. Endocrine Reviews 16: 334.Google Scholar
Kahn, C. R., Baird, K. L., Flier, J. S., Grunfeld, C., Harmon, J. T., Harrison, L. C., Karlsson, F. A., Kasuga, M., King, G. L., Lang, U. C., Podskalny, J. M. and Obberghen, E. V. 1981. Insulin receptors, receptor antibodies, and the mechanisms of insulin action. Recent Progress in Hormone Research 37: 477538.Google Scholar
Kirby, C. J., Smith, M. F., Keisler, D. H. and Lucy, M. C. 1997. Follicular function in lactating dairy cows treated with sustained release bovine somatotropin. Journal of Dairy Science 80: 273285.Google Scholar
Knight, P. G. 1996. Roles of inhibins, activins, and follistatin in the female reproductive system. Frontiers in Neuroendocrinology 17: 476509.Google Scholar
Ko, J. C. H., Kastelic, J. P., Del Campo, M. R. and Ginther, O. J. 1991. Effects of a dominant follicle on ovarian follicular dynamics during the oestrous cycle in heifers. Journal of Reproduction and Fertility 91: 511519.Google Scholar
Kohram, H., Bousquet, D., Durocher, J. and Guilbault, L. A. 1998. Alterations of follicular dynamics and superovulatory responses by gonadotropin releasing hormone and follicular puncture in cattle: a field trial. Theriogenology 49: 11651174.Google Scholar
Kuiper, G.G.J. M., Enmark, E., Pelto-Huikko, M. and Niìsson, S. 1996. Cloning of a novel estrogen receptor expressed in the rat prostate and ovary. Proceedings of the National Academy of Sciences of the United States of America 93: 59255930.Google Scholar
Langhout, D. J., Spicer, L. J. and Geisert, R. D. 1991. Development of a culture system for bovine granulosa cells: effects of growth hormone, estradiol and gonadotropins on cell proliferation, steroidogenesis and protein synthesis. Journal of Animal Science 69: 33213334.CrossRefGoogle ScholarPubMed
Lanneluc, L., Drinkwater, R. D., Elsen, J. M., Hetzel, D. J. S., Nguyen, T. C., Piper, L. R., Thimonier, J., Harrison, B. and Gellin, J. 1994. Genetic markers for the Booroola fecundity (Fec) gene in sheep. Mammalian Genome 5: 2633.Google Scholar
Law, A. S., Baxter, G., Logue, D. N., O’Shea, T. and Webb, R. 1992. Evidence for the action of a bovine follicular fluid factor(s) other than inhibin in suppressing follicular development and delaying oestrus in heifers. Journal of Reproduction and Fertility 96: 603616.Google Scholar
Law, A. S., Burt, D. W. and Armstrong, D. G. 1995. Expression of transforming growth factor-ß mRNA in chicken ovarian follicular tissue. General Comparative Endocrinology 98: 227233.Google Scholar
Leeuwenberg, B. R., Hudson, N. L., Moore, L. G., Hurst, P. R. and McNatty, K. P. 1996. Peripheral and ovarian IGF-I concentrations during the ovine oestrous cycle. Journal of Endocrinology 148: 281289.Google Scholar
Leeuwenberg, B. R., Hurst, P. R. and McNatty, K. P. 1995. Expression of IGF-I mRNA in the ovine ovary. Journal of Molecular Endocrinology 15: 251258.Google Scholar
Liu, J. Y., Aronow, B. J., Witte, D. P., Pope, W. F. and La Barbera, A. R. 1998. Cyclic and maturation-dependent regulation of follicle-stimulating hormone receptor and luteinizing hormone receptor messenger ribonucleic acid expression in the porcine ovary. Biology of Reproduction 58: 648658.Google Scholar
Liu, Y. X., Peng, X. R. and Ny, T. 1991. Tissue specific and time coordinated hormone regulation of plasminogen-activator-inhibitor type I and tissue-type plasminogen activator in the rat ovary during gonadotropin-induced ovulation. European Journal of Biochemistry 195: 549555.Google Scholar
Lobb, D. K. and Dorrington, J. 1992. Intraovarian regulation of folliclular development. Animal Reproduction Science 28: 343354.Google Scholar
Logan, A. and Hill, D. J. 1992. Bioavailability: is this a key event in regulating the actions of peptide growth factors? Journal of Endocrinology 134: 157161.Google Scholar
Lubahn, D.B., Moyer, J. S., Golding, T. S., Course, J. F., Korack, K. S. and Smithies, O. 1993. Alteration of reproductive function but not prenatal sexual development after insertional disruption of the mouse estrogen-receptor gene. Proceedings of the National Academy of Sciences of the United States of America 90: 1116211166.Google Scholar
Luck, M. 1990. The gonada! extracellular matrix. Oxford Reviews of Reproductive Biology 16: 3485.Google Scholar
Luck, M. R., Rodgers, R. J. and Findlay, J. K. 1990. Secretion and gene expression of inhibin, oxytocin and steriod hormones during the in vitro differentiation of bovine granulosa ciels. Reproduction, Fertility and Development 2: 1125.Google Scholar
Lucy, M. C., Bilby, C. R., Kirby, C. J., Yuan, W. and Boyd, C. K. 1999. Role of growth hormone in development and maintenance of follicles and corpora lutea. Journal of Reproduction and Fertility, Suppűement In press.Google Scholar
Lucy, M. C., Collier, R. J., Kitchell, M. J., Dibner, J. J., Hauser, S. J. and Krivi, G. G. 1993. Immuno-histochemical and nucleic acid analysis of somatotropin receptor populations in the bovine ovary. Biology of Reproduction 48: 12191227.Google Scholar
Lussier, J. G., Matton, P. and Dufour, J. J. 1994. Growth rates of follicles in the ovary of the cow. Journal of Reproduction and Fertility 81: 301307.Google Scholar
McEvoy, T. G., Robinson, J. J., Aitken, R. P., Finlay, P. A. and Robertson, I. S. 1995. Relationship between pre-ovulatory feed intake, progesterone priming and the subsequent in vitro development of ova collected from superovulatory ewes. Theriogenology 43: 276.Google Scholar
McNatty, K. P., Heath, D. A., Hudson, N. and Clarke, I. J. 1990. Effect of long-term hypophysectomy on ovarian follicle populations and gonadotrophin-induced adenosine cyclic 3’5’Monophosphate output by follicles from Booroola ewes with or without the F gene. Journal of Reproduction and Fertility 90: 515522.Google Scholar
McNatty, K. P., Hudson, N. L., Lun, S., Heath, D. A., Shaw, L., Condell, L., Phillips, D. J. and Clarke, I. J. 1993. Gonadotrophin-releasing hormone and the control of ovulation rate by the FecB gene in Booroola ewes. Journal of Reproduction and Fertility 98: 97105.Google Scholar
McNeilly, A. S. and Fraser, H. M. 1987. Effect of gonadotrophin-releasing hormone agonist-induced suppression of LH and FSH on follicle growth and corpus luteum function in the ewe. Journal of Endocrinology 115: 273282.Google Scholar
McNeilly, A. S., Jonassen, J. A. and Fraser, H. M. 1986. Suppression of follicular development after chronic LHRH immunoneutralization in the ewe. Journal of Reproduction and Fertility 76: 481490.Google Scholar
Matton, P., Adelakoun, V., Couture, Y. and Dufour, J. J. 1981. Growth and replacement of the bovine ovarian follicles during the estrous cycle. Journal of Animal Science 52: 813820.Google Scholar
Matzuk, M. M., Kumar, T. R., Shou, W., Coerver, K. A., Lau, A., Behringer, R. R. and Finegold, M. J. 1996. Transgenic models to study the roles of inhibins and activins on reproduction, oncogenesis and development. Recent Progress in Hormone Research 51:123157.Google Scholar
Monget, P. and Monniaux, D. 1995. Growth factors and control of folliculogenesis. Journal of Reproduction and Fertility, Supplement 49: 321333.Google Scholar
Monget, P., Monniaux, D., Pisselet, C. and Durand, P. 1993. Changes in insulin-like growth factor-I (IGF-I), IGF-II, and their binding proteins during growth and atresia of ovine ovarian follicles. Endocrinology 132: 14381446.Google Scholar
Monniaux, D., Chupín, D. and Saumande, J. 1983. Superovulatory responses of cattle. Theriogenology 19: 5581.Google Scholar
Monniaux, D., Mariana, J. C. and Gibson, W. R. 1984. Action of PMSG on follicular populations in the heifer. Journal of Reproduction and Fertility 70: 243253.Google Scholar
Monniaux, D., Monget, P., Besnard, N., Huet, C. and Pisselet, C. 1997. Growth factors and antral follicular development in domestic ruminants. Theriogenology 47: 312.Google Scholar
Montgomery, G. W., Crawford, A. M., Penty, J. M., Dodds, K. G., Ede, A. J., Henry, H. M., Pierson, C. A., Lord, E. A., Galloway, G. M., Schmack, A. E., Sise, J. A., Swarbrick, P. A., Hanrahan, V., Buchanan, F. C. and Hill, D. F. 1993. The ovine Booroola fecundity gene (FecB) is linked to markers from a region of human chromosome 4q. Nature Genetics 4: 410414.Google Scholar
Moor, R. M., Cahill, L. P. and Stewart, F. 1980. Ovarian stimulation or egg production as a limiting factor of egg transfer. IXth international congress on animal reproduction and artificial insemination, Madrid, pp. 4354.Google Scholar
Moor, R. M., Kruip, T. A. M. and Green, D. 1984. Intraovarian control of folliculogenesis: limits to superovulation? Theriogenology 21:103116.Google Scholar
Moor, R. M., Lee, C., Dai, Y. F. and Fulka Jr, J. 1996. Antral follicles confer developmental competence on oocytes. Zygote 4: 289293.Google Scholar
Morbeck, D. E., Esbenshade, K. L., Flowers, W. L. and Britt, J. H. 1992. Kinetics of follicle growth in the prepubertal gilt. Biology of Reproduction 47: 485491.Google Scholar
Mulheron, G. W., Danielpour, D. and Schomberg, D. W. 1991. Rat thecal interstitial cells express transforming growth factor-ß type 1 and 2, but only type 2 is regulated by gonadotropins in vitro . Endocrinology 129: 368374.Google Scholar
Murphy, M. G., Boland, M. P. and Roche, J. F. 1998. The effects of dose and duration of administration of pFSH during the first follicular wave on the ovulation rate of beef heifers. Theriogenology 49: 557569.Google Scholar
Murphy, M. G., Enright, W. J., Crowe, M. A., McConnell, K., Spicer, L. J., Boland, M. P. and Roche, J. F. 1991. Effect of dietary intake on pattern of growth of dominant follicles during the oestrous cycle in beef heifers. Journal of Reproduction and Fertility 92: 333338.Google Scholar
Neufield, G., Ferrara, N., Schweigerer, L., Mitchell, R. and Gospodarowicz, D. 1987. Bovine granulosa cells produce basic fibroblast growth factor. Endocrinology 121: 597603.Google Scholar
Oktay, K., Nugent, D., Newton, H., Salha, O., Chatterjee, P. and Gosden, R. G. 1997. Isolation and characterisation of primordial follicles from fresh and cryopreserved human ovarian tissue. Fertility and Sterility 67: 481486.Google Scholar
O’Shea, T., Hilliard, M. A., Anderson, T., Bindon, B. M., Findlay, J. K., Tsonis, C. G. and Wilkins, J F. 1994. Inhibin immunization for increasing ovulation rate and superovulation. Theriogenology 41: 317.Google Scholar
Pedersen, T. 1970. Follicle kinetics in the ovary of the cyclic mouse. Acta Endocrinología 64: 304323.Google Scholar
Peluso, J., Luciano, A. M., Pappalardo, A. and White, B. A. 1995. Cellular and molecular mechanisms that mediate insulin-dependent rat granulosa cell mitosis. Biology of Reproduction 52: 124130.Google Scholar
Penny, L. A., Armstrong, D. G., Baxter, G., Hogg, C., Kindahl, H., Bramley, T., Watson, E. D. and Webb, R. 1998. Expression of momocyte chemoattractant protein-1 in the bovine corpus luteum around the time of natural luteolysis; association with T-lymphocytes. Biology of Reproduction In press.Google Scholar
Perks, C. M., Denning-Kendall, P.A, Gilmour, R. S. and Wathes, D. C. 1995. Localization of messenger ribonucleic acids for insulin-like growth factor I (IGF-I), IGF-II and the type I IGF receptor in the ovine ovary throughout the estrous cycle. Endocrinology 136: 52665273.Google Scholar
Peters, H. 1979. Some aspects of early follicular development. In Ovarian follicular development and function (ed. Midgley, A. R. and Sadler, W. A.), pp. 113. Raven Press, New York.Google Scholar
Picton, H. M., Tsonis, C. G. and McNeilly, A. S. 1990. FSH causes a time-dependent stimulation of preovulatory follicle growth in the absence of pulsatile LH secretion in ewes chronically treated with gonadotrophin-releasing hormone agonist, journal of Endocrinology 126: 297307.Google Scholar
Pierson, R. A. and Ginther, O. J. 1984. Ultrasonography of the bovine ovary. Theriogenology 21: 495504.Google Scholar
Poretsky, L. and Kalin, M. F. 1987. The gonadotropic function of insulin. Endocrine Reviews 8: 132141.CrossRefGoogle ScholarPubMed
Prendiville, D. J., Enright, W. J., Crowe, M. A., Finnerty, M., Hynes, N. and Roche, J. F. 1995. Immunization of heifers against gonadotropin-releasing hormone: antibody titers, ovarian function, body growth, and carcass characteristics. Journal of Animal Science 73: 23822389.Google Scholar
Price, C. A. and Webb, R. 1988. Steroid control of gonadotropin secretion and ovarian function in heifers. Endocrinology 122: 22222231.Google Scholar
Price, C. A. and Webb, R. 1989. Ovarian response to hCG treatment during the oestrous cycle in heifers. Journal of Reproduction and Fertility 86: 303308.Google Scholar
Quirk, S. M., Hickey, G. J. and Fortune, J. E. 1986. Growth and regression of ovarian follicles during the follicular phase of the oestrous cycle in heifers undergoing spontaneous and PGF-2oc induced luteolysis. Journal of Reproduction and Fertility 77: 211219.CrossRefGoogle ScholarPubMed
Rajakoski, E. 1960. The ovarian follicular system in sexually mature heifers with special reference to seasonal, cyclical and left-right variations. Acta Endocrinologica, Supplement 52: 168.Google Scholar
Rajamahendran, R. and Taylor, C. 1990. Characterization of ovarian activity in postpartum dairy cows using ultrasound imaging and progesterone profiles. Animal Reproduction Science 22: 171180.Google Scholar
Ralph, J. H. 1996. Factors affecting follicle and oocyte development in cattle. Ph.D. thesis, University of Edinburgh. Google Scholar
Ralph, J. H., Wilmut, I. and Telfer, E. E. 1995. In vitro growth of bovine preantral follicles and the influence of FSH on follicular and oocyte diameters. Journal of Reproduction and Fertility, Abstract Series 15: 6 (abstr.).Google Scholar
Ratts, V. S., Flaws, J. A., Kolp, R., Sorensen, C. M. and Tilly, J. L. 1995. Ablation of bcl-2 gene expression decreases the numbers of oocytes and primordial follicles established in the post-natal female mouse gonad. Endocrinology 136: 36653668.Google Scholar
Ravindra, J. P., Rawlings, N. C., Evans, A.C. O. and Adams, G. P. 1994. Ultrasonographic study of ovarian follicular dynamics in ewes during the oestrous cycle. Journal of Reproduction and Fertility 101: 501509.Google Scholar
Redmer, D. A. and Reynolds, L. P. 1996. Angiogenisis in the ovary. Reviews of Reproduction 1: 182192.Google Scholar
Richards, J. S. 1994. Hormonal control of gene expression in the ovary. Endocrine Reviews 15: 725751.Google Scholar
Richards, J. S., Fitzpatrick, S. L., Clemens, J. W., Morris, J.K., Alliston, T. and Sirois, J. 1995. Ovarian cell differentiation: a cascade of multiple hormones, cellular signals and regulated genes. Recent Progress in Hormone Research 50: 223254.Google Scholar
Roberts, A. J. and Skinner, M. K. 1991. Transforming growth factor-a and -ß differentially regulate growth and steroidogenesis of bovine thecal cells during antral follicle development. Endocrinology 129: 20412048.Google Scholar
Roberts, A. R. and Echternkamp, S. E. 1994. In vitro production of estradiol by bovine granulosa cells: evaluation of culture condition, stage of follicular development, and location of cells within follicles. Biology of Reproduction 51: 273282.Google Scholar
Robinson, J. J. 1990. Nutrition in the reproduction of farm animals. Nutrition Research Reviews 3: 253276.Google Scholar
Robinson, J.J. 1996. Nutrition and reproduction. Animal Reproduction Science 42: 2534.Google Scholar
Robker, R. L. and Richards, J. S. 1998. Hormone-induced proliferation and differentiation of granulosa cells: a coordinated balance of the cell cycle regulators cyclin D2 and p27Kipi . Molecular Endocrinology 12: 924940.Google Scholar
Roche, J. F. 1996. Control and regulation of folliculogenesis — a symposium in perspective. Reviews of Reproduction 1: 1927.Google Scholar
Rouillier, P., Guilbault, L. A., Lussier, J. G. and Matton, P. 1996. Changes in morphological appearance and functional capacity of recruited follicles in cows treated with FSH in the presence or absence of a dominant follicle. Theriogenology 46: 10531061.Google Scholar
Rouillier, P., Matton, P., Sirard, M.-A. and Guilbault, L.A. 1998. Effect of bovine follicular fluid from healthy and atretic follicles on follicle-stimulating hormone-induced production of estradiol by bovine granulosa cells cultured in vitro . Journal of Animal Science 76: 11721177.Google Scholar
Roy, S. K. and Greenwald, G. S. 1989. Hormonal requirements for the growth and differentiation of hamster preantral follicles in long-term culture. Journal of Reproduction and Fertility 87: 103114.CrossRefGoogle ScholarPubMed
Rutledge, J. J. 1975. Twinning in cattle. Journal of Animal Science 40: 803815.Google Scholar
Salamonsen, L. A. 1996. Matrix metalloproteinases and their tissue inhibitors in endocrinology. Trends in Endocrinology 7: 2834.Google Scholar
Saumande, J. 1991. Culture of bovine granulosa cells in a chemically defined serum-free medium: the effect of insulin and fibronectin on the response to FSH. Journal of Steroid Biochemistry and Molecular Biology 38: 189196.Google Scholar
Savio, J. D., Boland, M. P. and Roche, J. F. 1990. Development of dominant follicles during the oestrous cycle of heifers. Journal of Reproduction and Fertility 88: 581591.Google Scholar
Savio, J. D., Keenan, L., Boland, M. P. and Roche, J. F. 1988. Pattern of growth of dominant follicles during the oestrous cycle of heifers. Journal of Reproduction and Fertility 83: 663671.Google Scholar
Savio, J. D., Thatcher, W. W., Badinga, L., de la Sota, R. L. and Wolfenson, D. 1993. Regulation of dominant follicle turnover during the oestrous cycle of cows. Journal of Reproduction and Fertility 97: 197203.Google Scholar
Schrick, F. N., Surface, R. A., Pritchard, J. Y., Dailey, R. A., Townsend, E. C. and Inskeep, E. K. 1993. Ovarian structures during the estrous cycle and early pregnancy in ewes. Biology of Reproduction 49: 11331140.Google Scholar
Sirois, J. and Fortune, J. E. 1988. Ovarian follicular dynamics during the estrous cycle in heifers monitored by real-time ultrasonography. Biology of Reproduction 39: 308317.Google Scholar
Sirois, J. and Fortune, J. E. 1990. Lengthening of the bovine estrous cycle with low levels of exogenous progesterone: a model for studying ovarian follicular dynamics. Endocrinology 127: 916925.Google Scholar
Skinner, M. K. and Coffey Jr, R. U. J. 1988. Regulation of ovarian cell growth through the local production of transforming growth factor-ß by theca cells. Endocrinology 123: 26322638.Google Scholar
Skinner, M. K., Keski-Oja, J., Osteen, K. G. and Moses, H. L. 1987. Ovarian thecal cells produce transforming growth factor-ß which can regulate granulosa cell growth. Endocrinology 121: 786792.Google Scholar
Smeaton, T. C. and Robertson, H.A. 1971. Studies on the growth and atresia of Graafian follicles in the ovary of sheep. Journal of Reproduction and Fertility 25: 243252.Google Scholar
Smith, C. L. 1998. Cross-talk between peptide growth factor and estrogen receptor signaling pathways. Biology of Reproduction 58: 627632.Google Scholar
Smith, G. W., McCrone, S., Petersen, S. L. and Smith, M. F. 1995. Expression of messenger ribonucleic acid encoding tissue inhibitor of metalloproteinases-2 within ovine follicles and corpora lutea. Endocrinology 136: 570576.Google Scholar
Smith, J. F. 1976. Follicle populations in sheep. Proceedings of the New Zealand Society of Animal Production 56: 247251.Google Scholar
Souza, C. J. H., Campbell, B. K. and Baird, D. T. 1996. Follicular dynamics and ovarian steroid secretion in sheep during anoestrus. Journal of Reproduction and Fertility 108: 101106.Google Scholar
Souza, C. J. H., Campbell, B. K. and Baird, D. T. 1997. Follicular dynamics and ovarian steroid secretion in sheep during the follicular and early luteal phases of the estrous cycle. Biology of Reproduction 56: 483488.Google Scholar
Souza, C. J. H., Campbell, B. K. and Baird, D. T. 1998. Follicular waves and concentrations of steroids and inhibin A in ovarian venous blood during the luteal phase of the oestrous cycle in ewes with an ovarian autotransplant. Journal of Endocrinology 156: 563572.Google Scholar
Spicer, L. J., Alpizar, E. and Echternkamp, S. E. 1993a. Effects of insulin, insulin-like growth factor I, and gonadotropins on bovine granulosa cell proliferation, progesterone production, estradiol production and (or) insulin-like growth factor I production in vitro . Journal of Animal Science 71: 12321241.Google Scholar
Spicer, L. J. and Echternkamp, S. E. 1995. The ovarian insulin and insulin-like growth factor system with an emphasis on domestic animals. Domestic Animal Endocrinology 12: 223245.Google Scholar
Spicer, L. J., Echternkamp, S. E., Canning, S. F. and Hammond, J. M. 1988. Relationship between concentration of immunoreactive insulin-like growth factor-I in follicular fluid and various biochemical markers of differentiation in bovine antral follicles. Biology of Reproduction 39: 573580.Google Scholar
Spicer, L. J., Echternkamp, S.E., Wong, E. A., Hamilton, D. T. and Vernon, R. K. 1995. Serum hormones, follicular fluid steroids, insulin-like growth factors and their binding proteins, and ovarian IGF mRNA in sheep with different ovulation rates. Journal of Animal Science 73: 11521163.Google Scholar
Spicer, L. J., Hanrahan, J. P., Zavy, M. T. and Enright, W. J. 1993b. Relationship between ovulation rate and concentrations of insulin-like growth factor-I in plasma during the oestrous cycle in various genotypes of sheep. Journal of Reproduction and Fertility 97: 403409.Google Scholar
Spicer, L. J. and Stewart, R. 1996. Interaction among basic fibroblast growth factor, epidermal growth factor, insulin and insulin-like growth factor-I (IGF-I) on cell numbers and steroidogenesis of bovine thecal cells: role of IGF-I receptors. Biology of Reproduction 54: 255263.Google Scholar
Staigmiller, R.B., Bellows, R. A., Anderson, G.B., Seidel Jr, G. E., Foote, W. D., Menino Jr, A. R. and Wright Jr, R. W. 1992. Superovulation of cattle with equine pituitary extract and porcine FSH. Theriogenology 37: 10911099.Google Scholar
Staigmiller, R. B. and England, B. G. 1982. Folliculogenesis in the bovine. Theriogenology 17: 4352.Google Scholar
Staigmiller, R.B., England, B. G., Webb, R., Short, R. E. and Bellows, R. A. 1982. Estrogen secretion and gonadotropin binding by individual bovine follicles during estrus. Journal of Animal Science 55: 14731482.Google Scholar
Stock, A. E. and Fortune, J. E. 1993. Ovarian follicular dominance in cattle: relationship between prolonged growth of the ovulatory follicle and endocrine parameters. Endocrinology 132: 11081114.Google Scholar
Sunderland, S. J., Crowe, M. A., Boland, M. P., Roche, J. F. and Ireland, J. J. 1994. Selection, dominance and atresia of follicles during oestrous cycle of heifers. Journal of Reproduction and Fertility 101: 547555.Google Scholar
Sunderland, S. J., Knight, P. G., Boland, M. P., Roche, J. F. and Ireland, J. J. 1996. Alterations in intrafollicular levels of different molecular mass forms of inhibin during development of follicular- and luteal-phase dominant follicles in heifers. Biology of Reproduction 54: 453462.Google Scholar
Telfer, E. E. and Robertson, M. A. 1993. Programmed cell death in murine primordial and preantral follicles: from birth to puberty. Biology of Reproduction 48: (suppl. 1) 141 (abstr.).Google Scholar
Terqui, M., Wrathall, J. H. M., Driancourt, M. A. and Knight, P. G. 1995. Modulation of ovarian function by steroid and inhibin immunization. Livestock Production Science 42: 181192.Google Scholar
Thatcher, W. W., de la Sota, R. L., Schmitt, E. J.-P., Diaz, T. C., Badinga, L., Simmen, F. A., Staples, C. R. and Drost, M. 1996. Control and management of ovarian follicles in cattle to optimize fertility. Reproduction, Fertility and Development 8: 203217.Google Scholar
Tilly, J. L. 1996. Apoptosis and ovarian function. Reviews of Reproduction 1: 162172.Google Scholar
Tsai, S.-J. and Wiltbank, M. C. 1998. Prostaglandin F2a regulates distinct physiological changes in early and mid-cycle bovine corpora lutea. Biology of Reproduction 58: 346352.Google Scholar
Turzillo, A. and Fortune, J. 1990. Suppression of the secondary FSH surge with bovine follicular fluid is associated with delayed ovarian follicular development in heifers. Journal of Reproduction and Fertility 89: 643653.Google Scholar
Vanderhyden, B. C. 1993. Species differences in the regulation of cumulus expansion by an oocyte-secreted factor(s). Journal of Reproduction and Fertility 98: 219227.Google Scholar
Vanderhyden, B. C., Caron, P. J., Buccione, R. and Eppig, J. J. 1990. Developmental pattern of the secretion of cumulus expansion — enabling factor by mouse oocytes and the role of oocytes in promoting granulosa cell differentiation. Developmental Biology 140: 307317.Google Scholar
Vanderhyden, B. C., Telfer, E. E. and Eppig, J. J. 1992. Mouse oocytes promote proliferation of granulosa cells from preantral and antral follicles in vitro . Biology of Reproduction 46: 11961204.Google Scholar
Vernon, R. K. and Spicer, L. J. 1994. Effects of basic fibroblast growth factor and heparin on follicle-stimulating hormone-induced steroidogenesis by bovine granulosa cells. Journal of Animal Science 72: 26962702.Google Scholar
Wade, G. N. and Schneider, J. E. 1992. Metabolic fuels and reproduction in female mammals. Neuroscience Biobehavioural Reviews 16: 235272.Google Scholar
Wandji, S. A., Eppig, J. J. and Fortune, J. E. 1996. FSH and growth factors affect the growth and endocrine function in vitro of granulosa cells of bovine preantral follicles. Theriogenology 45: 817832.Google Scholar
Wandji, S.-A., Pelletier, G. and Sirard, M.-A. 1992. Ontogeny and cellular localisation of 125I-labelled insulinlike growth factor-I, 125I-labelled follicle-stimulating hormone and 125I-labelled human chorionic gonadotropin binding sites in ovaries from bovine fetuses and neonatal calves. Biology of Reproduction 47: 814822.Google Scholar
Webb, R. and Armstrong, D. G. 1998. Control of ovarian function; effect of local interactions and environmental influences on follicular turnover in cattle: a review. Livestock Production Science 53: 95112.Google Scholar
Webb, R., Baxter, G., McBride, D., Ritchie, M. and Springbett, A. J. 1992a. Mechanism controlling ovulation rate in ewes in relation to seasonal anoestrus. Journal of Reproduction and Fertility 94: 143151.Google Scholar
Webb, R., Campbell, B. K. and Driancourt, M. A. 1995. Follicular cells from sheep carrying the FecB gene are more sensitive to gonadotropins in vitro . Journal of Reproduction and Fertility, Abstract Series 15: 29 (abstr.).Google Scholar
Webb, R., Campbell, B. K., Garverick, H. A., Gong, J. G., Gutierrez, C. G. and Armstrong, D. G. 1999. Molecular mechanisms regulating follicular recruitment and selection. Journal of Reroduction and Fertility, Supplement In press.Google Scholar
Webb, R., Driancourt, M. A. and Hanrahan, J. P. 1998. Ovulation rate in the ewe: mechanisms underlying genetic variation. Proceedings of the 6th world congress on genetics applied to livestock production, Annidale, vol. 27, pp. 310.Google Scholar
Webb, R. and Gauld, I. K. 1985a. Folliculogenesis in sheep: control of ovulation rate. In Genetics of reproduction in sheep (ed. Land, R. B. and Robinson, D. W.), pp. 261274. Butterworths, London.Google Scholar
Webb, R. and Gauld, I. K. 1985b. Genetics and physiology of follicle recruitment and maturation during seasonal anoestrus. In Endocrinal causes of seasonal and lactational anoestrus in farm animals (ed. Ellendorf, F. and Elsaesser, F.), pp. 1928. Martinus Nijhoff, Dordecht.Google Scholar
Webb, R., Gauld, I. K. and Driancourt, M. A. 1989. Morphological and functional characterization of large antral follicles in three breeds of sheep with different ovulation rates. Journal of Reproduction and Fertility 87: 243255.Google Scholar
Webb, R., Gong, J. G., Law, A. S. and Rusbridge, S. M. 1992b. Control of ovarian function in cattle. Journal of Reproduction and Fertility, Supplement 45: 141156.Google Scholar
Webb, R., Land, R.B., Pathiraja, N. and Morris, B. A. 1984. Passive immunization against steroid hormones in the female. In Immunological aspects of reproduction in mammals (ed. Crighton, D. B. J.), pp. 475499. Butterworths, London.Google Scholar
Webb, R. and Morris, B. A. 1988. The effects of steroid and inhibin immunity on FSH and ovulation. Proceedings of the 11th international congress on animimal reproduction 3: 183191.Google Scholar
Wood, S. C., Glencross, R. G., Bleach, E. C., Lovell, R., Beard, A. J. and Knight, P. G. 1993. The ability of steroid-free bovine follicular fluid to suppress FSH secretion and delay ovulation persists in heifers actively immunized against inhibin. Journal of Endocrinology 136: 137148.Google Scholar
Wrathall, J. H. M. and Knight, P. G. 1995. Effects of inhibin-related peptides and oestradiol on androstenedione and progesterone secretion by bovine theca cells. Journal of Endocrinology 145: 491500.Google Scholar
Xu, Z. Z., Garverick, H. A., Smith, G. W., Smith, M. F., Hamilton, S. A. and Youngquist, R. S. 1995a. Expression of follicle-stimulating hormone and luteinizing hormone receptor messenger ribonucleic acids in bovine follicles during the first follicular wave. Biology of Reproduction 53: 951957.Google Scholar
Xu, Z. Z., Garverick, H. A., Smith, G. W., Smith, M. F., Hamilton, S. A. and Youngquist, R. S. 1995b. Expression of messenger ribonucleic acid encoding cytochrome P450 side-chain cleavage, cytochrome P450 17oc-hydroxylase and cytochrome P450 aromatase in bovine follicles during the first follicular wave. Endocrinology 136: 981989.Google Scholar
Yoshinaga-Hirabayashi, T. and Osawa, Y. 1994. Steroidogenic activity of atretic follicles in the cyclic hamster ovary and relation to ultrastructural observations. Histochemistry 102: 5967.Google Scholar
Yuan, W.B., Bao, H. A., Garverick, R. S., Youngquist, R. S. and Lucy, M. C. 1998. Follicular selection and dominance in cattle is associated with divergent patterns of ovarian gene expression for insulin-like growth factor (IGF)-I, IGF-II and IGF binding protein-2 in dominant and subordinate follicles. Domestic Animal Endocrinology 15: 5563.Google Scholar
Zavy, M. T. 1994. Embryonic mortality in cattle. In Embryonic mortality in domestic species (ed. Zavy, M. T. and Geisert, R. D.), pp. 199240. CRC Press.Google Scholar