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Identification of gene locus polymorphism involved in heat stress ‎‎(HSP90β) in Marandi indigenous and commercial chickens‎

Document Type : Article

Authors

1 Department of Animal Science, ‎Maragheh Branch, Islamic Azad ‎University, Maragheh, Iran

2 ‎Department of Pathobiology, Faculty ‎of Veterinary, Urmia Branch, Islamic ‎Azad University, Urmia, Iran

3 ‎Department of Basic Sciences, ‎Bonab Branch, Islamic Azad ‎University, Bonab, Iran

4 ‎Department of Basic Sciences, ‎Maragheh Branch, Islamic Azad ‎University, Maragheh, Iran

10.30473/eab.2023.65118.1884

Abstract

Heat stress causes significant economic losses in poultry production and leads to the reduction of several physiological and metabolic factors. This research was conducted in order to investigate the allelic and genotypic polymorphisms of the gene involved in heat stress (HSP90β) in Marandi indigenous, broiler and laying chickens using PCR-RFLP technique. Randomly, blood was taken from 300 chicken and genomic DNA was extracted by salting out method. Amplification of the desired gene locus with a length of 494 bp was performed using specific primers and MspI enzyme was used to identify the mutation in the desired gene locus. After enzymatic digestion, two genotypes M1M1 and M1M2 and two alleles M1 (with a band of 494 bp) and M2 (with two bands of 248 bp and 246 bp) were identified for the HSP90β marker locus. Marandi indigenous and broiler chicken masses were in the Hardy-Weinberg equilibrium. For Marandi indigenous and broiler chicken populations, the Shannon information index at the HSP90β marker locus was 0.25 and 0.40, the fixation index is -0.07 and -0.16, and the observed heterozygosity index was 0.14 and 0.28, respectively. Due to the presence of polymorphism and mutation in the studied gene locus, it can be used in the Marandi indigenous and broiler chickens by genetic selection with the help of this marker to eliminate heat-sensitive chickens and keep heat-resistant chickens.

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References
Asadollahpour Nanae, H., Kharrati‑Koopaee, H., & Esmailizadeh, A. (2022). Genetic diversity and signatures of selection for heat tolerance and immune response in Iranian native chickens. BMC Genomics, 23, 224.
Chen, Z. Y., Gan, J. K., Xiao, X., Jiang, L. Y., Zhang, X. Q., & Luo, Q. B. (2013). The association of SNPs in Hsp90β gene 5′ flanking region with thermo tolerance traits and tissue mRNA expression in two chicken breeds. Molecular biology reports, 40, (9), 5295-5306.
Duangjinda, M., Tunim, S., Duangdaen, C., & Boonkum, W. (2017). Hsp70 genotypes and heat tolerance of commercial and native chickens reared in hot and humid conditions. Brazilian Journal of Poultry Science, 19, 7-18.
Galal, A., Radwan, L. M., Rezik, H. H., & Ayoub, H. (2019). Expression levels of HSP70 and CPT-1 in three local breeds of chickens reared under normal or heat stress conditions after the introduction of the naked neck gene. Journal of Thermal Biology, 80, 113-118.
Gheisari, A. (2005). Collection of research projects and research results of native chicken in Isfahan province. Ministry of Agriculture Jihad of Isfahan. (In Persian).
Hao, Y., & Gu, X. H. (2014). Effects of heat shock protein 90 expression on pectoralis major oxidation in broilers exposed to acute heat stress. Poultry Science, 93 (11), 2709-2717.
Hemati, B., Banabazi, M. H., Shahkarami, S., Mohandesan, E., & Burger, P. (2017). Genetic diversity within Bactrian camel population of Ardebil province. Research on Animal Production, 8 (16), 192-197. (In Persian).
Guerreiro, E. N., Giachetto, P. F., Givisiez, P. E. N. J., Ferro, A., Ferro, M. I. T., & Gabriel, J. E. (2004). Brain and hepatic Hsp70 protein levels in heat-acclimated broiler chickens during heat stress. Brazilian Journal of Poultry Science, 6 (4), 201-206.
Kapakin, K. A. T., Gümüş, R., Imik, H., Kapakin, S., & Sağlam, Y. S. (2012). Effects of ascorbic and α-lipoic acid on secretion of HSP-70 and apoptosis in liver and kidneys of broilers exposed to heat stress. Ankara Üniversitesi Veteriner Fakültesi Dergisi, 59, (4), 279-287.
Lin, H., Decuypere, E., & Buyse, J. (2006). Acute heat stress induces oxidative stress in broiler chickens. Comparative Biochemistry and Physiology Part A, Molecular & Integrative Physiology, 144, (1), 11-17.
Lin, T. W., Lo, C. W., Lai, S. Y., Fan, R. J., Lo, C. J., Chou, Y. M., Thiruvengadam, R., Wang, A. H. J., & Wang, M. Y. (2007). Chicken heat shock protein 90 is a component of the putative cellular receptor complex of infectious bursal disease virus. Journal of Virology, 81 (16), 8730-8741.
Liu, C. P., Fu, J., Xu, F. P., Wang, X. S., & Li, S. (2014).  The role of heat shock proteins in oxidative stress damage induced by Se deficiency in chicken livers. Biometals, 28, 163-173.
Mashaly, M. M., Hendricks, G. L., Kalama, M. A., Gehad, A. E., Abbas, A. O., & Patterson, P. H. (2004).  Effect  of  heat  stress  on  production parameters  and  immune  responses  of commercial laying hens. Poultry Science, 83(6), 889-894.
Maiti, S., & Picard, D. (2022). Cytosolic Hsp90 isoform-specific functions and clinical significance. Biomolecules, 12, 1166.
Mayahi, M., Talazadeh, F., & Abdoshah, M. (2018). Comparison of the performance between three strains of broiler chicks in Iran. Iranian Veterinary Journal, 13(4), 100-108. (In Persian).
Miller, S. A., Dykes, D. D., & Polesky, H. F. (1988). A simple salting out procedure for extracting DNA from human nucleated cells. Nucleic Acids Research, 16(3), 12-15.
Mohammadabadi, M. R., Nikbakhti, M., Mirzaee, H. R., Shandi, A., Saghi, D. A., Romanov, M. N., & Moiseyeva, I. G. (2010). Genetic variability in three native Iranian chicken populations of the Khorasan province based on microsatellite markers. Russian Journal of Genetics, 46 (4), 505-509.
Morimoto, R. I., Hunt, C., Huang, S. Y., Berg, K. L., & Banerji, S. S. (1986).  Organization, nucleotide sequence and transcription of the chicken HSP70 gene.  Journal of Biological Chemistry, 26 1(27), 12692-12699.
Nazari, M., Salabi, F., & Radpoor, S. (2020). Investigation of Heat shock protein 70 gene polymorphism in Khuzestan native chicken. Agricultural Biotechnology Journal, 12 (1), 81-100. (In Persian).
Nikoubin Borujeni, M., Pirany, N., & Rafiei Boroujeni, F. (2016). Analysis of genetic diversity in Fars native chicken based on partial mitochondrial DNA D-loop region sequences. Research on Animal Production, 7, (14), 180-185. (In Persian).
Radwan, L. M., & Mahrous, M. Y. (2019). Genetic selection for growth performance and thermal tolerance under high ambient temperature after two generations using heat shock protein 90 expression as an index. Animal Production Science, 59 (4), 628-633.
Radwan, L. M. (2020). Genetic improvement of egg laying traits in Fayoumi chickens bred under conditions of heat stress through selection and gene expression studies. Journal of Thermal Biology, 89, 102545.
Shojaei, M., Mohammadabadi, M. R., Asadi Fozi, M., Dayani, O., Khezri, A., & Akhondi, M. (2010). Association of growth trait and leptin gene polymorphism in Kermani sheep. Journal of Cell and Molecular Research, 2, 67-73.
Sheraiba, N. I., Hemeda, S. A., Mahboub, H. D. H., & Heikal, H. S. (2019). HSP70 and HSP90β genes polymorphism and its association with thermotolerance in Fayoumi and Leghorn chicken breeds. Journal of Current Veterinary Research, 2, 55- 62.
Sigei, C., Kariuki, D., Ndiema, E., Wainaina, E., Maina, S., Makanda, M., & Ommeh, S. (2015). In silico detection of signatures for adaptive evolution at select innate immune and heat stress genes in indigenous poultry. JKUAT Scientific Conference, 161-173.
Surai, P. F. (2015). Antioxidant systems in poultry biology, heat shock proteins. Journal of Science, 5 (12), 1188-1222.
Tamzil, M. H., Noor, R. R., & Hardjosworo, P. S. (2013). Polymorphism of the Heat shock protein gene in kampong, Arabic and commercial chickens. Jurnal Veteriner, 14 (3), 317-326.
Tohidi, R., Nassiri, M., & Javadmanesh, A. (2021). A study on the expression of HASPA2 and HSPB1 genes and gene ontology in the liver of Khorasan native chickens under acute heat stress. Animal science journal, 34 (130), 53-62. (In Persian).
Wan, Y., Ma, C., Wei, P., Fang, Q., Guo, X., Zhou, B., & Jiang, R. (2017). Dynamic expression of HSP90B1 mRNA in the hypothalamus of two Chinese chicken breeds under heat stress and association analysis with a SNP in Huainan chickens. Czech Journal of Animal Science, 62 (2), 82-87.
Yeh, F., Rongcal, Y., & Boyle, T. (2000). POPGENE 1.32, A free program for the analysis of genetic variation among and within populations using co-dominant and dominant markers. Department of Renewable Resources, University of Alberta, Alberta, Canada.
Zamani, P., Akhondi, M., Mohammadabadi, M. R., Saki, A. A., Ershadi, A., Banabazi, M. H., & Abdolmohammadi, A. R. (2013). Genetic variation of Mehraban sheep using two intersimple sequence repeat (ISSR) markers. African Journal of Biotechnology, 10(10), 1812-1817.
Zhen, F. S., Du, H. L., Xu, H. P., & Luo, Q. B. (2006). Tissue and allelic-specific expression of Hsp70 gene in chickens, basal and heat-stress-induced mRNA level quantified with real-time reverse transcriptase polymerase chain reaction. British Poultry Science, 47, 449-455.
Experimental animal Biology
Volume 12, Issue 1 - Serial Number 45
No.1
September 2023
Pages 1-8
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