Date Received: Aug 29, 2025
Date Accepted: Apr 15, 2026
Date Published: Jun 30, 2026
Views
Download
How to Cite:
Genomic Approaches for the Conservation and Improvement of Korean Native Chickens – A Review
,
Eunjin Cho
2
,
Jaewon Kim
1
,
Roshani Fernando
1
,
Jinhyeong Kim
1
,
Jun Heon Lee (*)
1, 2
Keywords
Korean native chickens, genetic diversity, selection signatures, genomic selection, association study, diseas-resistance genes
Abstract
Understanding the genomic basis of indigenous livestock is essential for both conservation and sustainable improvement. Korean native chickens (KNCs), although representing a small fraction of the poultry industry in Korea, are distinguished by their unique meat quality, robustness, and adaptability. Recent genomic studies have investigated their genetic diversity, evolutionary history, and economically important traits. High-density SNP arrays and population structure analyses have clarified the distinct identity of KNC lines, while runs of homozygosity have provided insights into inbreeding, conservation progress, and functional loci. Selection signature analyses have identified candidate genes related to growth, metabolism, reproduction, and immune function, reflecting line-specific adaptation. Genome-wide association studies have further identified variants associated with taste-active compounds, fatty acid composition, and growth traits, offering a foundation for genomic selection. Moreover, research on disease-related genes, such as the major histocompatibility complex B genes, has documented substantial genetic variability in KNCs, establishing important genomic resources for subsequent studies on avian immunity and pathogen response. Together, these findings highlight KNCs as valuable reservoirs of genetic variation with implications for both conservation and breeding. More broadly, the genomic insights obtained from KNCs provide a cautious yet informative model for indigenous livestock worldwide, demonstrating how genomic tools can support sustainable breeding programs that balance biodiversity preservation with productivity.
References
Abasht B., Dekkers J. C. & Lamont S. J. (2006). Review of quantitative trait loci identified in the chicken. Poultry science. 85(12): 2079-2096. DOI:10.1093/ps/85.12.2079.
Chazara O., Pinard-Van Der Laan M. H., Tixier-Boichard M. & Bed' Hom B. (2008). Molecular genotype investigation of the Gallus gallus major histocompatibility complex. Developments in biologicals. 132: 271-278. DOI: 10.1159/000317171.
Cho E., Kim M., Kim J. H., Roh H. J., Kim S. C., Jin D. H., Kim D. C. & Lee J. H. (2023). Application of genomic big data to analyze the genetic diversity and population structure of Korean domestic chickens. Journal of Animal Science and Technology. 65(5): 912. DOI: 10.5187/jast.2023.e8.
Cho S., Manjula P., Kim M., Cho E., Lee D., Lee, S. H., Lee JH. & Seo D. (2021). Comparison of Selection Signatures between Korean Native and Commercial Chickens Using 600K SNP Array Data. Genes. 12(6):824. DOI: 10.3390/genes12060824.
Choi J., Lee J. H., Jang H. J., Lee K. T., Kim T. H., Lee H. J., Heo K. N., Kim C. D., Han J. Y. & Park M. N. (2014). Genetic variants of chicken TYR gene and associations with feather color of Korean native chicken (KNC). Korean Journal of Poultry Science. 40(2): 139-145. DOI: 10.5536/KJPS.2013.40.2.139.
Dinh T. T., To K. V. & Schilling M. W. (2021). Fatty acid composition of meat animals as flavor precursors. Meat and Muscle Biology. 5(1): 1-16. DOI: 10.22175/mmb.12251.
Domingues P. & Hale B. G. (2017). Functional insights into ANP32A-dependent influenza A virus polymerase host restriction. Cell reports. 20(11): 2538-2546. DOI: 10.1016/j.celrep.2017.08.061.
Ediriweera T. K., Manjula P., Cho E., Kim M. & Lee J. H. (2022). Application of next-generation sequencing for the high-resolution typing of MHC-B in Korean native chicken. Frontiers in genetics. 13. DOI: 10.3389/fgene.2022.886376.
FAO (2025). Food and Agriculture Organization of the United Nations. Retrieved from https://www.fao.org/dad-is/browse-by-country-and-species/en/ on August 19, 2025.
Fulton J. E., Juul-Madsen H. R., Ashwell C. M., McCarron A. M., Arthur J. A., O'Sullivan N. P. & Taylor R. L. Jr. (2006). Molecular genotype identification of the Gallus gallus major histocompatibility complex. Immunogenetics. 58(5-6): 407-421. DOI: 10.1007/s00251-006-0119.
Fulton J. E., McCarron A. M., Lund A. R., Pinegar K. N., Wolc A., Chazara O., Bed'Hom B., Berres M. & Miller M. M. (2016). A high-density SNP panel reveals extensive diversity, frequent recombination and multiple recombination hotspots within the chicken major histocompatibility complex B region between BG2 and CD1A1. Genetics, Selection, Evolution. 48: 1. DOI: 10.1186/s12711-015-0181-x.
Jang S., Lim Y., Moon T., Choi Y. & Choi J. (2024). Comparison of the meat quality characteristics among commercial broiler, Korean Hanhyup 3 and organic chicken. Korean Journal of Poultry Science. 51(3): 145-151. DOI: 10.5536/KJPS.2024.51.3.145.
Jin S., Jayasena D. D., Jo C. & Lee J. H. (2017). The breeding history and commercial development of the Korean native chicken. Worlds Poultry Science Journal. 73(1): 163-174. DOI: 10.1017/S004393391600088X.
Kaufman J., Völk H. & Wallny H. J. (1995). A minimal essential MHC and an unrecognized MHC: two extremes in selection for polymorphism. Immunological reviews. 143: 63-88. DOI: 10.1111/j.1600-065x.1995.tb00670.x.
Kim M., Munyaneza J. P., Cho E., Jang A., Jo C., Nam K., Choo H. J. & Lee J. H. (2023). Genome-wide association study of nucleotide-related compounds in Korean native chicken breast meat. Animals. 13: 2966. DOI: 10.3390/ani13182966.
Kim M., Munyaneza J. P., Cho E., Jang A., Jo C., Nam K., Choo H. J. & Lee J. H. (2024). Genome-wide association studies of anserine and carnosine contents in the breast meat of Korean native chickens. Poultry Science. 103: 103590. DOI: 10.1016/j.psj.2024.103590.
Kim J., Macharia J. K., Kim M., Heo J. M., Yu M., Choo H. J. & Lee J. H. (2024). Runs of homozygosity analysis for selection signatures in the Yellow Korean native chicken. Animal Bioscience. 37(10): 1683-1691. DOI: 10.5713/ab.24.0092.
Kim J., Agulto T. N., Cho E., Kim M., Munyaneza J. P., Kim J. & Lee J. H. (2025). Screening of genetic variation for the ANP32A gene in Korean native chickens. Journal of Animal Breeding and Genomics. 9(2): 49-55. DOI: 10.12972/jabng.2025.9.2.1.
Macharia J. K., Kim J., Kim M., Cho E., Munyaneza J. P. & Lee J. H. (2024a). Characterisation of runs of homozygosity and inbreeding coefficients in the red-brown Korean native chickens. Animal Bioscience. 37(8): 1355-1366. DOI: 10.5713/ab.23.0514.
Macharia J. K., Kim J., Kim M., Cho E., Munyaneza J. P., Choo H. J. & Lee J. H. (2024b). Identification of genetic loci associated with live body weight and carcass weight in red brown Korean native chickens. Journal of Animal Breeding and Genomics. 8(3): 69-79. DOI: 10.12972/jabng.20240303.
Malomane D. K., Simianer H., Weigend A., Reimer C., Schmitt A. O. & Weigend S. (2019). The SYNBREED chicken diversity panel: a global resource to assess chicken diversity at high genomic resolution. BMC Genomics. 20: 345. DOI: 10.1186/s12864-019-5727-9.
Manjula P., Bed'Hom B., Hoque M. R., Cho S., Seo D., Chazara O., Lee S. H. & Lee J. H. (2020a). Genetic diversity of MHC-B in 12 chicken populations in Korea revealed by single-nucleotide polymorphisms. Immunogenetics. 72(6-7): 367-379. DOI: 10.1007/s00251-020-01176-4.
Manjula P., Fulton J. E., Seo D. & Lee J. H. (2020b). Major histocompatibility complex B variability in Korean native chicken breeds. Poultry science. 99(10): 4704-4713. DOI: 10.1016/j.psj.2020.05.049.
Manjula P., Kim M., Cho S., Seo D. & Lee J. H. (2021). High levels of genetic variation in MHC-linked microsatellite markers from native chicken breeds. Genes. 12(2): 240. DOI: 10.3390/genes12020240.
Munyaneza J. P., Kim M., Cho E., Jang A., Choo H. J. & Lee J. H. (2023). Association of single-nucleotide polymorphisms in dual specificity phosphatase 8 and insulin-like growth factor 2 genes with inosine-5′-monophosphate, inosine, and hypoxanthine contents in chickens. Animal Bioscience. 36(9): 1357-1366. DOI: 10.5713/ab.23.0080.
Munyaneza J. P., Kim M., Cho E., Jang A., Choo H. J. & Lee J. H. (2024). Association of histamine-N-methyl transferase gene polymorphisms with carnosine content in red-brown Korean native chickens. Animal Bioscience. 37(9): 1517-1525. DOI: 10.5713/ab.23.0552.
Munyaneza J. P., Kim M., Cho E., Jang A., Choo H. J. & Lee J. H. (2025). Genome-wide association studies of the fatty acid composition of Korean native chicken breast meat. Journal of Animal Science and Technology. 67(2): 314-324. DOI: 10.5187/jast.2024.e24.
Mwacharo J. M., Jianlin H. & Amano T. (2006). Native African chicken: valuable genetic resources for future breeding improvement. Journal of Animal Genetics. 34 (2): 63-69. DOI: 10.5924/abgri2000.34.2_63.
Park S., Kim N., Choi S. & Moon J. (2020). The consumption patterns of Korean native chicken. Korean Journal of Poultry Science. 47(4): 247-254. DOI: 10.5536/KJPS.2020.47.4.247.
Purfield D. C., Berry D. P., McParland S. & Bradley D. G. (2012). Runs of homozygosity and population history in cattle. BMC Genetics. 13: 70. DOI: 10.1186/1471-2156-13-70.
Saravanan K., Panigrahi M., Kumar H., Bhushan B., Dutt T. & Mishra B. (2020). Selection signatures in livestock genome: A review of concepts, approaches and applications. Livestock Science. 241: 104257. DOI: 10.1016/j.livsci.2020.104257.
You Z., Bai Y., Bo D., Feng Y., Shen J., Wang Y., Li J. & Bai Y. (2024). A review of taste-active compounds in meat: Identification, influencing factors, and taste transduction mechanism. Journal of Food Science. 89(12): 8128-8155. DOI: 10.1111/1750-3841.17480.