Authors: Abtehal Y. Anaas, Mohd. Nazmi Bin Abd. Manap

Abstract:

Meat Tenderness is one of the most important factors affecting consumers' assessment of meat quality. Variation in meat tenderness is genetically controlled and varies among breeds, and it is also influenced by environmental factors that can affect its creation during rigor mortis and postmortem. The final postmortem meat tenderization relies on the extent of proteolysis of myofibrillar proteins caused by the endogenous activity of the proteolytic calpain system. This calpain system includes different calcium-dependent cysteine proteases, and an inhibitor, calpastatin. It is widely accepted that in farm animals including chickens, the μ-calpain gene (CAPN1) is a physiological candidate gene for meat tenderness. This study aimed to identify the association of single nucleotide polymorphism (SNP) markers in the CAPN1 gene with the tenderness of chicken breast meat from two Malaysian native and commercial broiler breed crosses. Ten, five months old native chickens and ten, 42 days commercial broilers were collected from the local market and breast muscles were removed two hours after slaughter, packed separately in plastic bags and kept at -20ºC for 24 h. The tenderness phenotype for all chickens’ breast meats was determined by Warner-Bratzler Shear Force (WBSF). Thawing and cooking losses were also measured in the same breast samples before using in WBSF determination. Polymerase chain reaction (PCR) was used to identify the previously reported C7198A and G9950A SNPs in the CAPN1 gene and assess their associations with meat tenderness in the two breeds. The broiler breast meat showed lower shear force values and lower thawing loss rates than the native chickens (p<0.05), whereas there were similar in the rates of cooking loss. The study confirms some previous results that the markers CAPN1 C7198A and G9950A were not significantly associated with the variation in meat tenderness in chickens. Therefore, further study is needed to confirm the functional molecular mechanism of these SNPs and evaluate their associations in different chicken populations.

Keywords: CAPNl, chicken, meat tenderness, meat quality, SNPs.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1112333

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References:

[1] S.D. Shackelford, T.L. Wheeler, M.K. Meade, and J.O. Reagan. “Consumer impressions of Tender Select beef”. J. Anim. Sci. Vol. 79, pp. 2605-2614, 2001.
[2] J.T. Shun, M. Zhang, Y.J. Shan, W.J. Xu, K.W. Chen and H.F. Li. “Analysis of the genetic effects of CAPN1 gene polymorphisms on chicken meat tenderness”. Genet. Mol. Res. Vol. 14, no. 1, pp. 1393-1403, Feb. 2015.
[3] D.E. Goll, V.F. Thompson, H. Li, and W. Wei. “The calpain system”. Physiol. Rev. Vol. 83, pp. 731-801, 2003.
[4] F. Okumura, T. Shimogiri, Y. Shinbo, and K. Yoshizawa. “Linkage mapping of four chicken calpain genes”. Anim. Sci. J. Vol. 76, pp. 121-127, 2005.
[5] M. Koohmaraie. “Biochemical factors regulating the toughening and tenderization processes of meat”. Meat. Sci. Vol. 43S1, pp. 193-201, 1996.
[6] G.H. Geesink, and M. Koohmaraie. “Effect of calpastatin on degradation of myofibrillar proteins by mu-calpain under postmortem conditions”. J. Anim. Sci. Vol. 77, pp. 2685-2692, 1999.
[7] B.T. Page, E. Casas, M.P. Heaton, and N.G. Cullen. “Evaluation of single-nucleotide polymorphisms in CAPN1 for association with meat tenderness in cattle”. J. Anim. Sci. Vol. 80, pp. 3077-3085, 2002.
[8] F. Okumura, T. Shimogiri, K. Kawabe, and S. Okamoto. “Gene constitution of South-East Asian native chickens, commercial chickens and jungle fowl using polymorphisms of four calpain genes”. Anim. Sci. J. Vol. 77, pp. 188-195, 2006.
[9] Z.R. Zhang, Q. Zhu, X.S. Jiang, and H.R. “Study on correlation between single nucleotide polymorphism of CAPN1 gene and muscle tenderness and carcass traits in chicken”. Yi Chuan Vol. 29, pp. 982-988, 2007a.
[10] Z.R. Zhang, Q. Zhu, and Y.P. Liu. “Correlation analysis on single nucleotide polymorphism of CAPN1 gene and meat quality and carcass traits in chickens”. Agric. Sci. China Vol. 6, pp. 749-754, 2007b.
[11] Z.R. Zhang, Y.P. Liu, X. Jiang, and H.R. Du. “Study on association of single nucleotide polymorphism of CAPN1 gene with muscle fibre and carcass traits in quality chicken populations”. J. Anim. Breed. Genet. Vol. 125, pp. 258-264, 2008.
[12] C. Ribeca. Bonfatti, A. Cecchinato, and A. Albera. “Association of polymorphisms in calpain 1, (mu/I) large subunit, calpastatin, and cathepsin D genes with meat quality traits in double-muscled Piemontese cattle”. Anim. Genet. Vol. 44, pp. 193-196, 2013.
[13] S. Dadgar, E. S. Lee, T. L. V. Leer, N. Burlinguette, H. L. Classen, T. G. Crowe and P. J. Shand. “Effect of microclimate temperature during transportation of broiler chickens on quality of the Pectoralis major muscle”. Poult. Sci. Vol. 89, pp. 1033-1041, 2010.
[14] X. Fernandez, V. Sante, E. Baeza, E. Lebihan-Duval, C. Berri, H. Remignon, R. Babile, G. Le Pottier, N. Millet, P. Berge, and T. Astruc. “Post-mortem muscle metabolism and meat quality in three genetic types of turkey”. Brit. Poult. Sci. Vol. 42, pp. 462-469, 2001.
[15] Beutler, A. 2007. Introduction to Poultry Production in Saskatchewan, University of Saskatchewan, Saskatoon, Saskatchewan, S7N 5A8. http://www.agriculture.gov.sk.ca/Introduction_Poultry_Production_Saskatchwan Accessed: October, 2015.
[16] S. Jaturasitha, A. Kayan and M. Wicke. “Carcass and meat characteristics of male chickens between Thai indigenous compared with improved layer breeds and their crossbred”. Arch. Ani. Breed. Vol. 51, no. 3, pp. 283-294, 2008.
[17] C. Larzul, P. Le Roy, J. Gogué, A. Talmant, B. Jacquet, L. Lefaucheur, P. Ecolan, P. Sellier and G. Monin. “Selection for reduced muscle glycolytic potential in Large White pigs: Correlated responses in meat quality and muscle compositional traits”. Genet. Sel. Evol. Vol. 31, pp. 61-76, 1999.
[18] E. Le Bihan-Duval, M. Debut, C.M. Berri, N. Sellier, V. Santé-Lhoutellier, Y. Jégo and C. Beaumont. “Chicken meat quality: genetic variability and relationship with growth and muscle characteristics”. BMC Genet. Vol. 9, no. 53, pp. 6, 2008.
[19] A.C. Fanatico, L.C. Cavitt, P.B. Pillai, J.L. Emmert and C.M. Owens. “Evaluation of Slower-Growing Broiler Genotypes Grown with and without outdoor Access: Meat Quality”. Poult. Sci. Vol. 84. pp. 1785–1790, 2005.
[20] M. Debut, C. Berri, E. Baéza, N. Sellier, C. Arnould, D. Guémené, N. Jehl, B. Boutten, Y. Jego, C. Beaumont and E. Le Bihan-Duval. “Variation of chicken technological meat quality in relation to genotype and pre-slaughter stress conditions”. Poult. Sci. Vol. 82, p. 1829–1838, 2003.
[21] H.J. Jeon, J.H. Choe, Y. Jung, Z.A. Kruk, D.G. Lim, and C. Jo. “Comparison of the chemical composition, textural characteristics, and sensory properties of North and South Korean native chickens and commercial broilers”. Korean J Food Sci An. Vol. 30, pp. 171–178, 2010.
[22] C. Wattanachant, A. Songsang, S. Wattanasit, P. Adulyatham and S. Wattanachant. “Carcass quality, chemical composition, physical properties and textural characteristics of meat from naked-neck chicken and common Thai indigenous chicken”. Research report, Prince of Songkla University. Songkhla, Thailand. pp. 158, 2004.
[23] U. Intarachot, T. Aob-aon and S. Siangjaew. “Age and size of Thai native crossbred chickens raising for self-consumption”. The report of animal research for 1996. Department of Livestock Development, Bangkok, Thailand. 298-319, 1997.
[24] F.C. Yap, Y.J. Yan, K.T. Loon, J.L.N. Zhen, N.W. Kamau & J.V. Kumaran. 2010. “Phylogenetic analysis of different breeds of domestic chickens in selected area of Peninsular Malaysia inferred from partial cytochrome b gene information and RAPD markers”. Anim. biotech. Vol. 21, pp. 226-240, 2010.
[25] I. H. Lokman, Y. M. Goh, A.Q. Sazili, M.M. Noordin & A.B.Z. Zuki “Meat Characteristics of Red Jungle Fowl (Gallus gallus Spadiceus), Malaysian Domestic Chickens (Gallus gallus Domesticus) and Commercial Broiler” Pertanika J. of Tropical Agric. Sci. 38.4, 2015.