Genome-wide Scans Identify Known and Novel Regions Associated with Prolificacy and Reproduction Traits in a Sub-Saharan African Indigenous Sheep (Ovis Aries)

Overview

Journal Mamm Genome

Specialty Genetics

Date 2019 Nov 24

PMID 31758253

Citations 13

Authors

Asrat Tera Dolebo

Negar Khayatzadeh

Aberra Melesse

David Wragg

Mourad Rekik

Aynalem Haile

Barbara Rischkowsky

Max F Rothschild

Joram M Mwacharo

Affiliations

Soon will be listed here.

Abstract

Maximizing the number of offspring born per female is a key functionality trait in commercial- and/or subsistence-oriented livestock enterprises. Although the number of offspring born is closely associated with female fertility and reproductive success, the genetic control of these traits remains poorly understood in sub-Saharan Africa livestock. Using selection signature analysis performed on Ovine HD BeadChip data from the prolific Bonga sheep in Ethiopia, 41 candidate regions under selection were identified. The analysis revealed one strong selection signature on a candidate region on chromosome X spanning BMP15, suggesting this to be the primary candidate prolificacy gene in the breed. The analysis also identified several candidate regions spanning genes not reported before in prolific sheep but underlying fertility and reproduction in other species. The genes associated with female reproduction traits included SPOCK1 (age at first oestrus), GPR173 (mediator of ovarian cyclicity), HB-EGF (signalling early pregnancy success) and SMARCAL1 and HMGN3a (regulate gene expression during embryogenesis). The genes involved in male reproduction were FOXJ1 (sperm function and successful fertilization) and NME5 (spermatogenesis). We also observed genes such as PKD2L2, MAGED1 and KDM3B, which have been associated with diverse fertility traits in both sexes of other species. The results confirm the complexity of the genetic mechanisms underlying reproduction while suggesting that prolificacy in the Bonga sheep, and possibly African indigenous sheep is partly under the control of BMP15 while other genes that enhance male and female fertility are essential for reproductive fitness.

Citing Articles

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