No CrossRef data available.
Article contents
Detection of the β-lactoglobulin genotype in zebu cattle (Gangatiri) milk using high-resolution accurate mass spectroscopy
Published online by Cambridge University Press: 25 August 2023
Abstract
We studied the genetic polymorphism of beta-lactoglobulin (β-Lg) whey protein in Gangatiri zebu cows for this Research Communication. The polymorphic nature of milk protein fractions and their association with milk production traits, composition and quality has attracted several efforts in evaluating the allelic distribution of protein locus as a potential dairy trait marker. Genetic variants of β-Lg have highly significant effects on casein number (B > A) and protein recovery (B > A) and also determine the yield of cheese dry matter (B > A). Molecular techniques of polyacrylamide gel electrophoresis and high-resolution accurate mass-spectroscopy were applied to characterize the β-Lg protein obtained from the Gangatiri breed milk. Sequence analysis of β-Lg showed the presence of variant B having UniProt database accession number P02754, coded on the PAEP gene. Our study can provide reference and guidance for the selection of superior milk (having β-LgB) from this indigenous breed that could potentially give a good yield of β-Lg for industrial applications.
- Type
- Research Article
- Information
- Copyright
- Copyright © The Author(s), 2023. Published by Cambridge University Press on behalf of Hannah Dairy Research Foundation
References
Andrews, TA 1983 Proteinases in normal bovine milk and their actions on casein. Journal of Dairy Research 50, 45–55.CrossRefGoogle Scholar
Botaro, BG, Lima, YVR, Aquino, AA, Fernandes, RHR, Garcia, JF and Santos, MV 2008 Effect of beta-lactoglobulin polymorphism and seasonality on bovine milk composition. Journal of Dairy Research 75, 176–181.CrossRefGoogle ScholarPubMed
Chopra, A, Ali, SA, Bathla, S, Rawat, P, Vohra, V, Kumar, S and Mohanty, AK (2020) High-resolution mass spectrometer-based ultra-deep profile of milk whey proteome in Indian Zebu (Sahiwal) cattle. Frontiers in Nutrition 7, 150.CrossRefGoogle ScholarPubMed
Di Gregorio, P, Di Grigoli, A, Di Trana, A, Alabiso, M, Maniaci, G, Rando, A, Valluzzi, C, Finizio, D and Bonanno, A (2017) Effects of different genotypes at the CSN3 and LGB loci on milk and cheese-making characteristics of the bovine Cinisara breed. International Dairy Journal 71, 1–5.CrossRefGoogle Scholar
Dinc, H, Ozkan, E, Koban, E and Togan, I (2013) Beta-casein A1/A2, kappa-casein and beta-lactoglobulin polymorphisms in Turkish cattle breeds. Archives Animal Breeding 56, 650–657.CrossRefGoogle Scholar
Farrell, HM Jr, Jimenez-Flores, R, Bleck, GT, Brown, EM, Butler, JE, Creamer, LK, Hicks, CL, Hollar, CM, Ng-Kwai-Hang, KF and Swaisgood, HE (2004) Nomenclature of the proteins of cows’ milk – sixth revision. Journal of Dairy Science 87, 1641–1674.CrossRefGoogle ScholarPubMed
Gharedaghi, L, Shahrbabak, HM and Sadeghi, M (2016) Identification of novel SNP in caprine β-lactoglobulin gene. Journal of Genetics 95, 485–490.CrossRefGoogle ScholarPubMed
Keppler, JK, Heyse, A, Scheidler, E, Uttinger, MJ, Fitzner, L, Jandt, U, Heyn, TR, Lautenbach, V, Loch, JI, Lohr, J, Kieserling, H, Günther, G, Kempf, E, Grosch, JH, Lewiński, K, Jahn, D, Lübbert, C, Peukert, W, Kulozik, U, Drusch, S, Krull, R, Schwarz, K and Biedendieck, R (2021) Towards recombinantly produced milk proteins: physicochemical and emulsifying properties of engineered whey protein beta-lactoglobulin variants. Food Hydrocolloids 110, 106132.CrossRefGoogle Scholar
Khaldi, Z, Nafti, M, Jilani, MT and Souid, S (2023) Effect of kappa casein and beta lactoglobulin genetic variants on milk composition traits in Tunisian oasis autochthonous goats. Journal of Advanced Veterinary Research 13, 123–131.Google Scholar
Lukač, D, Vidović, V, Nemeš, Ž, Stupar, M and Popović-Vranješ, A (2013) Genotypic frequencies of the ß-lactoglobulin, κ-casein and transferrin in Serbian Holstein-Friesian dairy cattle. Mljekarstvo/Dairy 63, 203–210.Google Scholar
Maletic, M, Aleksić, N, Vejnović, B, Nikšić, D, Kulić, M, Đukić, B and Ćirković, D (2016) Polymorphism of κ-casein and β-lactoglobulin genes in Busha and Holstein Friesian dairy cows in Serbia. Mljekarstvo: časopis za unaprjeđenje proizvodnje i prerade mlijeka 66, 198–205.CrossRefGoogle Scholar
Meza-Nieto, MA, González-Córdova, AF, Piloni-Martini, J and Vallejo-Cordoba, B (2013) Effect of β-lactoglobulin A and B whey protein variants on cheese yield potential of a model milk system. Journal of Dairy Science 96, 6777–6781.CrossRefGoogle Scholar
Mir, SN, Ullah, O and Sheikh, R (2014) Genetic polymorphism of milk protein variants and their association studies with milk yield in Sahiwal cattle. African Journal of Biotechnology 13, 555–565.Google Scholar
Nguyen, DD, Solah, VA, Busetti, F, Smolenski, G and Cooney, T (2020) Application of ultra-high performance liquid chromatography coupled to high-resolution mass spectrometry (Orbitrap™) for the determination of beta-casein phenotypes in cow milk. Food Chemistry 307, 125532.CrossRefGoogle ScholarPubMed
Singh, MK, Kumar, A, Nimmanapalli, R and Hooda, A (2023) Probing of alpha, beta and kappa-caseins polymorphic variants in Gangatiri cow milk with the use of polyacrylamide gel electrophoresis and HRAMS. Journal of Dairy Research 90, 1–4.CrossRefGoogle Scholar
Vincent, D, Ezernieks, V, Elkins, A, Nguyen, N, Moate, PJ, Cocks, BG and Rochfort, S (2016) Milk bottom-up proteomics: method optimization. Frontiers in Genetics 6, 360.CrossRefGoogle ScholarPubMed
Zaglool, AW, Awad, A, El, I, Araby, E and El-Bayomi, KM (2016) Association of β-lactoglobulin gene polymorphism with milk yield, fat and protein in Holstein-Friesian cattle. World Veterinary Journal 6, 117–122.CrossRefGoogle Scholar
Zepeda-Batista, JL, Alarcón-Zúñiga, B, Ruíz-Flores, A, Núñez-Domínguez, R and Ramírez-Valverde, R (2015) Polymorphism of three milk protein genes in Mexican Jersey cattle. Electronic Journal of Biotechnology 18, 1–4.CrossRefGoogle Scholar
Singh et al. supplementary material
Table S1
PDF
261.9 KB