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Aspects of Ovarian Function in a Line of Sheep with a Novel X-Linked Maternally-Imprinted Gene that is Associated with an Increased Ovulation Rate

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posted on 2021-11-07, 23:34 authored by Feary, Elisabeth Sheinach

Fecundity is a term that refers to the number of offspring produced per female. It combines fertility (i.e. ability to produce offspring) and prolificacy (i.e. number of offspring). Ovulation rate i.e. the number of mature eggs released from the ovaries during one reproductive cycle in sheep, as with other mammals, is controlled by an exchange of hormonal signals between the pituitary gland and the ovary. Genetic mutations affecting ovulation are commonly referred to as the fecundity genes (Fec). The most obvious outcome is the number of offspring produced. There is already evidence of a number of major genes affecting the ovulation rate in sheep, specifically the Booroola, Inverdale, Hanna and more recently the Woodlands gene. The sheep carrying the Woodlands gene arose because the mutation was first recognised on a farm in Woodlands, Southland, New Zealand. Woodlands have a novel, X-linked maternally-imprinted, fecundity trait referred to as FecX2w, where Fec = fecundity, X = X chromosome, 2= 2nd mutation identified on X and W= Woodlands. The studies in this thesis investigated ovarian follicular development in both 4-week old Woodland carrier (W+) and non-carrier (++) lambs and adult ewes and evaluated some aspects of the endocrine interactions between the ovary and pituitary gland. The purpose was to identify potential physiological effects of the FecX2w gene on ovarian function. A confounding issue during these studies was the discovery that a large ovary phenotype (LOP) which was present in many of the W+ but not ++ lambs at 4 weeks of age was in fact a coincidence and not linked to the FecX2w mutation. The key findings from the studies of lambs and/or ewes that were carriers (W+) or non-carriers (++) of the FecX2w gene were: 1. No genotype differences were present either in the numbers of primordial (i.e. Type 1/1a follicles) or developing preantral (i.e. Types 2-4 follicles); 2. Significant genotype differences were present in the numbers of small antral (Type 5) follicles (W+>++; p<0.05); 3. An earlier onset of antral follicular development in W+ vs. ++ ewes with irregularities in morphology between the basement membrane and stroma in the former; 4. No genotype differences in the onset of gene expression during follicular development or in the cell-types expressing GDF9, BMP15, alpha inhibin, beta A inhibin and beta B inhibin, FSHR, ER alpha, or ER beta; 5. No genotype differences in the levels of GDF9 or BMP15 gene expression in oocytes throughout follicular growth; 6. No genotype difference in the diameters that follicles reached in W+ vs. ++ ewes; 7. Some lambs at 4-weeks of age had unusually large ovaries with an exceptional level of antral follicular development that is reminiscent of a polycystic ovarian condition. The underlying cause of this condition is unknown. In conclusion, the physiological characteristics of ovarian follicular development in ewes with the FecX2w gene is different from that in ewes with the Booroola, Inverdale, Hanna or other recently identified mutations.

History

Copyright Date

2006-01-01

Date of Award

2006-01-01

Publisher

Te Herenga Waka—Victoria University of Wellington

Rights License

Author Retains Copyright

Degree Discipline

Cell and Molecular Bioscience

Degree Grantor

Te Herenga Waka—Victoria University of Wellington

Degree Level

Doctoral

Degree Name

Doctor of Philosophy

Victoria University of Wellington Item Type

Awarded Doctoral Thesis

Language

en_NZ

Victoria University of Wellington School

School of Biological Sciences

Advisors

McNatty, Ken; Jordan, Bill