Emus (Dromaius novaehollandiae) are expected to become a novel poultry species for producing eggs, meat, and oil. In our previous studies, Japanese emu populations were predicted to have reduced genetic diversity through inbreeding. For a sustainable emu industry in Japan, it is necessary to understand the current genetic structure and relationships in dispersed farms. In this study, we investigated the genetic structure and relationships of six Japanese emu farms based on mitochondrial DNA and microsatellite polymorphisms. We analyzed the DNA sequences of the mitochondrial D-loop region in 157 individuals and detected four haplotypes with four nucleotide substitution sites (Hap-a, Hap-b, Hap-c, and Hap-d). Analysis of molecular variance revealed that 43.6% of total variance was "among population," and the FST value was 0.436 with significant genetic differentiation (P < 0.001). In microsatellite analysis, the expected (HE ) and observed (HO ) heterozygosities were 0.53-0.64 and 0.44-0.59, respectively. Phylogenetic trees and STRUCTURE analysis revealed that the six Japanese farmed emu populations could be divided into four genetically differentiated groups. Therefore, we identified genetic resources that may be useful in extending the genetic diversity of Japanese farms and are predicted to contribute to the conservation and reconstruction of populations.
Keywords: Dromaius novaehollandiae; emu; genetic diversity; microsatellite markers; mitochondrial DNA.
© 2022 Japanese Society of Animal Science.