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MIsakova Zh.T., Chekirov K.B., Kipen V.N., Irsaliev M.I., Mukeeva S.B., Kurmanbekova S.B., Aitbaev K.A., Imanberdieva N.A. Genetic diversity of Bos grunniens bred in the Tien Shan of the Kyrgyz Republic. Sel'skokhozyaistvennaya Biologiya [Agricultural Biology], 2025, Vol. 60, № 4, p. 641-650.
(how to cite this article)

doi: 10.15389/agrobiology.2025.4.641eng

UDC: 636.293.3:575.174.015.3

Acknowledgements:
Carried out within the framework of the state assignment of the Ministry of Education and Science of the Kyrgyz Republic (Agreement No. 30-21 dated 02/15/2021 No. 129/1)

 

GENETIC DIVERSITY OF Bos grunniens BRED IN THE TIEN SHAN OF THE KYRGYZ REPUBLIC

Zh.T. Isakova1, K.B. Chekirov2, V.N. Kipen3, M.I. Irsaliev1,
S.B. Mukeeva1, G.T. Kurmanbekova2, K.A. Aitbaev1,
N.A. Imanberdieva2

1Research Institute of Molecular Biology and Medicine, 3, ul. Togolok Moldo, Bishkek, 720040 Kyrgyz Republic, e-mail jainagul@mail.ru (✉ corresponding author), moldobek@irsaliev.com, sezim.mukeeva.97@mail.ru, kaitbaev@yahoo.com
2Kyrgyz-Turkish Manas University, 56, prosp. Ch. Aitmatova, Bishkek, 720038 Kyrgyz Republic, e-mail kadyr.chekirov@manas.edu.kg, kurmanbekova@manas.edu.kg, nazgul.imanberdieva@manas.edu.kg;
3Institute of Genetics and Cytology of the National Academy of Sciences of Belarus, 27, ul. Akademicheskaya, Minsk, 220072 Republic of Belarus, e-mail v.kipen@igc.by

ORCID:
Isakova Zh.T. orcid.org/0000-0002-3681-6939
Mukeeva S.B. orcid.org/0000-0001-9584-4860
Chekirov K.B. orcid.org/0000-0001-6146-6750
Kurmanbekova G.T. orcid.org/0000-0002-0460-1351
Kipen V.N. orcid.org/0000-0002-7822-0746
Aitbaev K.A. orcid.org/0009-0004-8432-8843
Irsaliev M.I. orcid.org/0000-0002-8364-8982
Imanberdieva N.A. orcid.org/0000-0002-0280-6775

Final revision received November 23, 2022
Accepted May 19, 2023

The mountain range pastures, which occupy 90 % of the territory of the Kyrgyz Republic, are highly favorable for the development of yak breeding. Yaks (Bos grunniens) are exclusively pasture-based animals that are well-adapted to living in harsh high-mountain climatic conditions. Only a few countries in the world engage in yak breeding, and the Kyrgyz Republic has been breeding yaks since ancient times. The migration of yaks in the Tien Shan Mountains proceeded from south to north. During the evolutionary process in the Tien Shan and Pamir-Alai Mountains, a specific type of high-mountain yak was formed, exhibiting eight distinct coat colors, ranging from black and brown to variegated and light brown. It became necessary to clarify the genetic structure of the existing yak population in order to compile a preliminary genetic reference group of unique animals. In this study, the molecular genetic status of yaks bred in the high-mountain region of the Tien Shan of the Kyrgyz Republic was determined for the first time using microsatellite DNA markers. Specific characteristics that distinguish the Kyrgyz yak population from other geographic groups of these animals were identified, significantly contributing to the understanding of its genetic features. The obtained data also enable an assessment of genetic diversity and inbreeding risks in Tien Shan yak populations, which is crucial for developing conservation strategies and rational utilization of these animals. The aim of our research is to assess the genetic diversity of the domestic yak population bred in the highland region of the Tien Shan in the Kyrgyz Republic using DNA microsatellite markers. The study was conducted in 2021-2023 at the Research Institute of Molecular Biology and Medicine (Bishkek, Kyrgyz Republic) and the Institute of Genetics and Cytology (Minsk, Republic of Belarus). The research material was blood samples collected from an adult herd of 55 domestic yaks bred in the highland region of Kalmak-Ashuu (Kochkor district, Naryn region, Kyrgyz Republic). The samples were genotyped for 15 microsatellite loci: ETH3, INRA023, TGLA227, TGLA126, TGLA122, SPS115, ETH225, TGLA53, BM2113, BM1824, ETH10, BM1818, CSSM66, ILSTS006, and CSRM60. PCR was performed using Multiplex PCR Master (Jena Bioscience, Germany) in a multilocus format according to the manufacturer’s recommendations. The amplification products were then combined and subjected to fragment analysis. The PCR results were analyzed by capillary electrophoresis using an automatic genetic analyzer with laser-induced fluorescence detection, Applied Biosystems 3500 (Thermo Fisher, USA). Samples validated using the COrDIS Cattle kit (GORDIZ LLC, Russian Federation) served as controls. The analysis of population genetic parameters and the degree of differentiation based on the genetic distance matrix was performed using GenAlEx 6.503 software, with subsequent visualization of dendrograms using the Neighbor-joining algorithm in the Past v.4.03 program. The genetic structure of the studied yak sample was assessed by clustering in the STRUCTURE 2.3.4 program. The optimal number of clusters (ΔK) was determined using the POPHELPER v1.0.10 web application. In the 15 autosomal STR loci of the studied sample, 89 alleles were identified, 32 of which were rare (with an occurrence frequency of less than 5.0 %). Based on the assessment of genetic and population parameters (Na = 5.933±0.316, Ne = 3.015±0.235, Ho = 0.617±0.049, PIC = 0.581±0.130), a conclusion was made about the high values of genetic diversity in the studied yak sample. An electronic database of individual genotypes was created to form a reference group of yaks characterizing their genetic diversity in the region. The breeding schemes for domestic yaks in the high-mountain region of the Tien Shan are balanced and contribute to the preservation of genetic diversity. A comparative analysis of the results of this molecular genetic study with those of other similar works allows us to conclude that domestic yaks (Bos grunniens) bred in the Tien Shan of the Kyrgyz Republic exhibit significant genetic diversity.

Keywords: Bos grunniens, DNA, microsatellite markers, genotyping.

 

REFERENCES

  1. Abdikerimov A. Teoriya i praktika razvedeniya yakov v Kirgizstane [Theory and practice of yak breeding in Kyrgyzstan]. Bishkek, 2001 (in Russ.).
  2. Chertkiev Sh.Ch., Chortonbaev T.Dzh. Nauchnie osnovi formirovaniya myasnoy produktivnosti yakov v ontogeneze [Scientific basis for the formation of meat productivity of yaks in ontogenesis]. Bishkek, 2007 (in Russ.).
  3. Jacques G., Guedes J., Zhang S. Yak domestication: a review of linguistic, archaeological, and genetic evidence. Ethnobiology Letters, 2021, 12(1): 103-114 CrossRef
  4. Joshi S., Shrestha L., Bisht N., Wu N., Ismail M., Dorji T., Dangol G., Long R. Ethnic and cultural diversity amongst yak herding communities in the Asian highlands. Sustainability, 2020, 12(3): 957 CrossRef
  5. Jing X., Ding L., Zhou J., Huang X., Degen A., Long R. The adaptive strategies of yaks to live in the Asian highlands. Animal Nutrition, 2022, 4(9): 249-258 CrossRef
  6. Bazhenova B.A., Zabalueva Yu.Yu., Danilov M.B., Vtorushina I.A., Badmaev T.M. Tekhnika i tekhnologiya pishchevikh proizvodstv, 2018, 48(3): 16-33 CrossRef (in Russ.).
  7. Abdikerimov A.A., Samikbaev A.K., Bekzhanova E.A. Vestnik Kirgizskogo natsional’nogo agrarnogo universiteta im. K.I. Skryabina,2016, 1(37): 66-70 (in Russ.).
  8. Informatsionniy byulleten’ Kirgizskoy respubliki po prodovol’stvennoy bezopasnosti i bednosti [Information Bulletin of the Kyrgyz Republic on food security and poverty]. Bishkek, 2021 (in Russ.).
  9. Sambrook J., Russell D.W. Molecular Cloning. A Laboratory Manual. Third edition. Cold Spring Harbor Laboratory Press, New York, 2001.
  10. Barendse W., Armitage S.M., Kossarek L.M., Shalom A., Kirkpatrick B.W., Ryan A.M., Clayton D., Li L., Neibergs H.L., Zhang N., Grosse W.M., Weiss J., Creighton P., McCarthy F., Ron M., Teale A.J., Fries R., McGraw R.A., Moore S.S., Georges M., Soller M., Womack J.E., Hetzel D.J.S. A genetic linkage map of the bovine genome. Nat Genet., 1994, 6(3): 227-235 CrossRef
  11. ISAG Conference 2014, Xi’an, China. Cattle molecular markers and parentage testing workshop. Available: https://www.isag.us/Docs/Workshop%20report%20CMMPT%202014.pdf. No date.
  12. Bishop M.D., Kappes S.M., Keele J.W., Stone R.T., Sunden S.L., Hawkins G.A., Toldo S.S., Fries R, Grosz M.D., Yoo J.A genetic linkage map for cattle. Genetics, 1994, 136(2): 619-639 CrossRef
  13. Brezinsky L., Kemp S.J., Teale A.J. ILSTS006: a polymorphic bovine microsatellite. Animal Genetics, 1993, 24(1): 73 CrossRef
  14. Georges M., Massey J. Polymorphic DNA markers in Bovidae. World Intellectual Property Organization. Geneva. Patent application WO PUBL NO 92/13102.
  15. Toldo S.S., Fries R., Steffen P., Neibergs H.L., Barendse W., Womack J.E., Hetzel D.J., Stranzinger G. Physically mapped, cosmid-derived microsatellite markers as anchor loci on bovine chromosomes. Mammalian Genome, 1993, 4(12): 720-727 CrossRef
  16. Steffen P., Eggen A., Fries R., Dietz A.B. Womack E. Isolation and mapping of polymorphic microsatellites in cattle. Animal Genetics, 1993, 24(2): 121-124 CrossRef
  17. Vaiman D., Mercier D., Moazami-Goudarzi K., Eggen A., Ciampolini R., Lépingle A., Velmala R., Kaukinen J., Varvio S.L., Martin P., Levéziel H., Guérin G. A set of 99 cattle microsatellites: characterization, synteny mapping, and polymorphism. Mammalian Genome,1994, 5(5): 288-297 CrossRef
  18. Peakall R, Smouse PE. GenAlEx 6.5: genetic analysis in Excel. Population genetic software for teaching and research--an update. Bioinformatics, 2012, 28(19): 2537-2539 CrossRef
  19. Hammer Q., Harper A.T., Ryan P.D. Past: Paleontological statistics software package for education and data analysis. Palaeontologia Electronica, 2001, 4(1): 1-9.
  20. Nagy S., Poczai P., Cernák I., Gorji A.M., Hegedűs G., Taller J. PICcalc: an online program to calculate polymorphic information content for molecular genetic studies: Biochem. Genet., 2012, 50(9-10): 670-672 CrossRef
  21. Evanno G.S., Regnaunt S.J., Goudet J. Detecting the number of clusters of individuals using the software structure: a simulation study. Molecular Ecology, 2005, 14(8): 2611-2620 CrossRef
  22. Francis R.M. POPHELPER: an R package and web app to analyse and visualise population structure. Molecular Ecology Resources, 2016, 17(1): 27-32 CrossRef
  23. Botstein D., White R.L., Skalnick M.H., Davies R.W. Construction of a genetic linkage map in man using restriction fragment length polymorphism. Am. J. Hum. Genet., 1980, 32: 314-331.
  24. Xuebin Q., Jianlin H., Lkhagva B., Chekarova I,. Badamdorj D., Rege J.E., Hanotte O. Genetic diversity and differentiation of Mongolian and Russian yak populations. Journal of Animal Breeding and Genetics, 2005, 122(2): 117-126 CrossRef
  25. Zhang G., Chen W., Xue M., Wang Z., Chang H., Han X., Liao X., Wang D. Analysis of genetic diversity and population structure of Chinese yak breeds (Bos grunniens) using microsatellite markers. Journal of Genetics and Genomics, 2008, 35(4): 233-238 CrossRef
  26. Oyun N.Yu. Geneticheskoe raznoobrazie yaka (Bos grunniens) Sayano-Altayskogo regiona. Avtoreferat kandidatskoy dissertatsii [Genetic diversity of the yak (Bos grunniens) of the Sayan-Altai region. PhD Thesis]. Moscow,2022 (in Russ.).
  27. Hussain T., Wajid A., Soail M., Ali A., Abbas K., Marikar F.M.M.T., Muneeb M.M., Babar E. Molecular phylogeny and genetic diversity of domestic yaks (Bos grunniens) in Pakistan based on mitochondrial and microsatellite markers. Veterinarska Stanica, 2021, 52(6): e1-e14 CrossRef
  28. Nguyen T.T.Genini S., Menetrey F., Malek M., Vogeli P., Goe M. R., Stranzinger G. Application of bovine microsatellite markers for genetic diversity analysis of Swiss yak (Poephagus grunniens). Animal Genetics, 2005, 36(6): 484-489 CrossRef

 

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