The 84-bp Indel Polymorphism of The Sterol Regulatory Element-Binding Protein 1 (SREBP1) Gene in Several Cattle Breeds in Indonesia

Saiful Anwar, Widya Pintaka Bayu Putra, Isyana Khaerunnisa, Ari Sulistyo Wulandari, Koko Wisnu Prihatin, Sutikno Sutikno

Abstract

Sterol regulatory element-binding protein 1 (SREBP1) gene is a gene that encodes SREBP1, a family of transcription factors that have a key role in lipid homeostasis as well as fatty acid metabolisms. The present study aimed to detect the 84-bp indel polymorphism in the intron 5 of the SREBP1 gene (84-bp indel) in several cattle breeds in Indonesia.  A total of 740 cattle of six breeds (Limousin, Simmental, Holstein-Friesian, Bali, Sumbawa, and Pasundan) from two National Artificial Insemination Centers (NAICs) and smallholder farmers were used in this study. The detection of 84-bp indel polymorphism was performed using the polymerase chain reaction (PCR) method and visualized through a gel agarose electrophoresis system. The study showed that the L allele (insertion-type) was common and is fixed in Holstein-Friesian, Bali, and Sumbawa cattle (1.00). Meanwhile, the S allele (deletion-type) was found in Limousin, Simmental, and Pasundan cattle with a frequency of 0.24, 0.16, and 0.01, respectively. The presence of the S allele in Pasundan cattle was only found in the form of the heterozygous LS genotype (0.03). In conclusion, the 84-bp indel of the SREBP1 gene was found to be polymorphic in Limousin, Simmental, and Pasundan cattle, but monomorphic in Holstein-Friesian, Bali, and Sumbawa cattle.

Keywords

Fatty Acid; Indel; Indonesian Local Cattle; SREBP1 Gene

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References

Allendorf FW, Luikart G. 2007. Conservation and the genetics of populations. Oxford (UK): Blackwell Publishing.

Anwar S, Volkandari SD, Wulandari AS, Putra WPB, Sophian E, Said S. 2020. Detection of F94L mutation of the MSTN gene in four Indonesian local cattle breeds. J Indones Trop Anim Agric. 45:7–14.

Bhuiyan MSA, Yu SL, Jeon JT, Yoon D, Cho YM, Park EW, Kim NK, Kim KS, Lee JH. 2009. DNA polymorphisms in SREBF1 and FASN genes affect fatty acid composition in Korean cattle (Hanwoo). Asian-Australasian J Anim Sci. 22:765–773.

Bionaz M, Vargas-Bello-Pérez E, Busato S. 2020. Advances in fatty acids nutrition in dairy cows: from gut to cells and effects on performance. J Anim Sci Biotechnol. 11:1–36.

Carcangiu V, Luridiana S, Pulinas L, Di Stefano M V., Cosso G, Mura MC. 2021. Improving dairy performance through molecular characterization of SREBP-1 gene in Sarda sheep breed. Heliyon. 7:e06489. DOI:10.1016 /j.heliyon.2021.e06489.

Catalanotto C, Cogoni C, Zardo G. 2016. MicroRNA in control of gene expression: An overview of nuclear functions. Int J Mol Sci. 17.

Cui Y, Chen R, Lv X, Pan C. 2019. Detection of coding sequence, mRNA expression, and three insertions/deletions (indels) of KDM6A gene in male pig. Theriogenology. 133:10–21.

Deng Q, Li Xinwei, Fu S, Yin L, Zhang Y, Wang T, Wang J, Liu L, Yuan X, Sun G, et al. 2014. SREBP-1c gene silencing can decrease lipid deposits in bovine hepatocytes cultured in vitro. Cell Physiol Biochem. 33:1568–1578.

Deng T, Pang C, Ma X, Duan A, Liang S, Lu X, Liang X. 2017. Buffalo SREBP1: molecular cloning, expression and association analysis with milk production traits. Anim Genet. 48:720–721.

Eberlé D, Hegarty B, Bossard P, Ferré P, Foufelle F. 2004. SREBP transcription factors: Master regulators of lipid homeostasis. Biochimie. 86:839–848.

Gamarra D, Aldai N, Arakawa A, Barron LJR, López-Oceja A, de Pancorbo MM, Taniguchi M. 2018. Distinct correlations between lipogenic gene expression and fatty acid composition of subcutaneous fat among cattle breeds. BMC Vet Res. 14:1–12.

Gamarra D, Aldai N, Arakawa A, de Pancorbo MM, Taniguchi M. 2021. Effect of a genetic polymorphism in SREBP1 on fatty acid composition and related gene expression in subcutaneous fat tissue of beef cattle breeds. Anim Sci J. 92:1–11.

Gao J, Song X, Wu H, Tang Q, Wei Z, Wang X, Lan X, Zhang B. 2020. Detection of rs665862918 (15-bp indel) of the HIAT1 gene and its strong genetic effects on growth traits in goats. Animals. 10:1–9.

Gao YY, Cheng G, Cheng ZX, Bao C, Yamada T, Cao GF, Bao SQ, Schreurs NM, Zan LS, Tong B. 2022. Association of variants in FABP4, FASN, SCD, SREBP1, and TCAP genes with intramuscular fat, carcass traits, and body size in Chinese Qinchuan cattle. Meat Sci. 192:108882.

Hall TA. 1999. BioEdit: A User-Friendly Biological Sequence Alignment Editor and Analysis Program for Windows 95/98/NT. Nucleic Acids Symp Ser. 41:95–98.

Han C, Vinsky M, Aldai N, Dugan MER, McAllister TA, Li C. 2013. Association analyses of DNA polymorphisms in bovine SREBP-1, LXRα, FADS1 genes with fatty acid composition in Canadian commercial crossbred beef steers. Meat Sci. 93:429–436.

Han LQ, Gao TY, Yang GY, Loor JJ. 2018. Overexpression of SREBF chaperone (SCAP) enhances nuclear SREBP1 translocation to upregulate fatty acid synthase (FASN) gene expression in bovine mammary epithelial cells. J Dairy Sci. 101:6523–6531. DOI:10.3168 /jds.2018-14382.

Hartl DL. 1988. A Primer of Population Genetics. 2nd Ed. Massachusetts (USA): Sinauer Associates, Incorporated.

Harvatine KJ, Bauman DE. 2006. SREBP1 and thyroid hormone responsive spot 14 (S14) are involved in the regulation of bovine mammary lipid synthesis during diet-induced milk fat depression and treatment with CLA. J Nutr. 136:2468–2474.

Hoashi S, Ashida N, Ohsaki H, Utsugi T, Sasazaki S, Taniguchi M, Oyama K, Mukai F, Mannen H. 2007. Genotype of bovine sterol regulatory element binding protein-1 (SREBP-1) is associated with fatty acid composition in Japanese Black cattle. Mamm Genome. 18:880–886.

Huang YZ, He H, Sun JJ, Wang J, Li ZJ, Lan XY, Lei CZ, Zhang CL, Zhang EP, Wang JQ, et al. 2011. Haplotype combination of SREBP-1c gene sequence variants is associated with growth traits in cattle. Genome. 54:507–516.

Jiang J, Gao Y, Hou Y, Li W, Zhang S, Zhang Q, Sun D. 2016. Whole-genome resequencing of Holstein bulls for indel discovery and identification of genes associated with milk composition traits in dairy cattle. PLoS One. 11:1–16.

Jiang J, Liu L, Gao Y, Shi L, Li Y, Liang W, Sun D. 2019. Determination of genetic associations between indels in 11 candidate genes and milk composition traits in the Chinese Holstein population. BMC Genet. 20:1–12.

Kaneda M, Lin BZ, Sasazaki S, Oyama K, Mannen H. 2011. Allele frequencies of gene polymorphisms related to economic traits in Bos taurus and Bos indicus cattle breeds. Anim Sci J. 82:717–721.

Kawaguchi F, Kakiuchi F, Oyama K, Mannen H, Sasazaki S. 2021. Effect of five polymorphisms on percentage of oleic acid in beef and investigation of linkage disequilibrium to confirm the locations of quantitative trait loci on BTA19 in Japanese black cattle. Life. 11.

Lee Y, Oh D, Lee J, La B, Yeo J. 2013. Novel single nucleotide polymorphisms of bovine SREBP1 gene is association with fatty acid composition and marbling score in commercial Korean cattle (Hanwoo). Mol Biol Rep. 40:247–254.

Li C, Sun D, Zhang S, Yang S, Alim MA, Zhang Q, Li Y, Liu L. 2016. Genetic effects of FASN, PPARGC1A, ABCG2 and IGF1 revealing the association with milk fatty acids in a Chinese Holstein cattle population based on a post genome-wide association study. BMC Genet [Internet]. 17. DOI:10.1186/s12863-016-0418-x.

Li N, Zhao F, Wei C, Liang M, Zhang N, Wang C, Li QZ, Gao XJ. 2014. Function of SREBP1 in the milk fat synthesis of dairy cow mammary epithelial cells. Int J Mol Sci. 15:16998–17013.

Li XZ, Yan CG, Gao QS, Yan Y, Choi SH, Smith SB. 2018. Adipogenic/lipogenic gene expression and fatty acid composition in chuck, loin, and round muscles in response to grain feeding of Yanbian Yellow cattle. J Anim Sci. 96:2698–2709.

Liang C, Qiao L, Han Y, Liu J, Zhang J, Liu W. 2020. Regulatory roles of SREBF1 and SREBF2 in lipid metabolism and deposition in two Chinese representative fat-tailed sheep breeds. Animals. 10:1–14.

Liu X, Guo XY, Xu XZ, Wu M, Zhang X, Li Q, Ma PP, Zhang Y, Wang CY, Geng FJ, et al. 2012. Novel single nucleotide polymorphisms of the bovine methyltransferase 3b gene and their association with meat quality traits in beef cattle. Genet Mol Res. 11:2569–2577.

Ma L, Corl BA. 2012. Transcriptional regulation of lipid synthesis in bovine mammary epithelial cells by sterol regulatory element binding protein-1. J Dairy Sci. 95:3743–3755.

Matsuhashi T, Maruyama S, Uemoto Y, Kobayashi N, Mannen H, Abe T, Sakaguchi S, Kobayashi E. 2011. Effects of bovine fatty acid synthase, stearoyl-coenzyme A desaturase, sterol regulatory element-binding protein 1, and growth hormone gene polymorphisms on fatty acid composition and carcass traits in Japanese Black cattle. J Anim Sci. 89:12–22.

Nafikov RA, Schoonmaker JP, Korn KT, Noack K, Garrick DJ, Koehler KJ, Minick-Bormann J, Reecy JM, Spurlock DE, Beitz DC. 2013. Sterol regulatory element binding transcription factor 1 (SREBF1) polymorphism and milk fatty acid composition. J Dairy Sci. 96:2605–2616. DOI:10.3168/jds.2012-6075.

O’Brien J, Hayder H, Zayed Y, Peng C. 2018. Overview of microRNA biogenesis, mechanisms of actions, and circulation. Front Endocrinol (Lausanne). 9:1–12.

Ohsaki H, Tanaka A, Hoashi S, Sasazaki S, Oyama K, Taniguchi M, Mukai F, Mannen H. 2009. Effect of SCD and SREBP genotypes on fatty acid composition in adipose tissue of Japanese black cattle herds. Anim Sci J. 80:225–232.

Otto JR, Mwangi FW, Pewan SB, Adegboye OA, Malau-Aduli AEO. 2022. Lipogenic gene single nucleotide polymorphic DNA markers associated with intramuscular fat, fat melting point, and health-beneficial omega-3 long-chain polyunsaturated fatty acids in Australian pasture-based bowen genetics Forest Pastoral Angus, Hereford. Genes (Basel). 13.

Peakall R, Smouse PE. 2012. GenALEx 6.5: Genetic analysis in Excel. Population genetic software for teaching and research-an update. Bioinformatics. 28:2537–2539.

Peng K, Zhang GL, Yu T, Cao Y, Yu YS, Chen H, Lei CZ, Lan XY, Zhao YM. 2020. Detection of InDel variations within seven candidate genes and their associations with phenotypic traits in three cattle breeds. Anim Biotechnol. 31:463–471. DOI:10.1080/10495398.2019. 1620258.

Proskura WS. 2013. Insertion/deletion polymorphism of the sterol regulatory element-binding protein I gene in different cattle breeds. Turkish J Vet Anim Sci. 38:104–106.

Proskura WS, Dybus A, Zaborski D, Sobek Z, Yu YH, Cheng YH. 2017. Polymorphism in the SREBP-1 gene is associated with milk production traits of Jersey cattle. Indian J Anim Sci. 87:924–926.

Rincon G, Islas-Trejo A, Castillo AR, Bauman DE, German BJ, Medrano JF. 2012. Polymorphisms in genes in the SREBP1 signaling pathway and SCD are associated with milk fatty acid composition in Holstein cattle. J Dairy Res. 79:66–75.

Sasazaki S. 2021. Development of DNA markers for improvement of meat quality in a Japanese Black cattle population in Hyogo Prefecture. Anim Sci J. 92:1–7.

Shimano H, Sato R. 2017. SREBP-regulated lipid metabolism: Convergent physiology-divergent pathophysiology. Nat Rev Endocrinol. 13:710–730. DOI:10.1038/nrendo.2017.91.

Srikanth K, Kwan A, Lee E, Kim S, Lim Y, Chung H. 2015. Associations of Single nucleotide polymorphisms in the bovine FADS6 gene with fatty acid composition in Hanwoo (Korean Cattle). Open J Genet. 05:137–144.

Tsiplakou E, Flemetakis E, Kouri ED, Sotirakoglou K, Zervas G. 2015. The effect of long-term under-and over-feeding on the expression of genes related to lipid metabolism in mammary tissue of sheep. J Dairy Res. 82:107–112.

Wang J, Zhang X, He X, Yang B, Wang H, Shan X, Li C, Sun D, Wu R. 2018. LPS-induced reduction of triglyceride synthesis and secretion in dairy cow mammary epithelial cells via decreased SREBP1 expression and activity. J Dairy Res. 85:439–444.

Wang Z, Zhang X, Jiang E, Yan H, Zhu H, Chen H, Liu J, Qu L, Pan C, Lan X. 2020. InDels within caprine IGF2BP1 intron 2 and the 3′-untranslated regions are associated with goat growth traits. Anim Genet. 51:117–121.

Wen G, Pachner LI, Gessner DK, Eder K, Ringseis R. 2016. Sterol-regulatory element-binding proteins are regulators of the sodium/iodide symporter in mammary epithelial cells. J Dairy Sci. 99:9211–9226. DOI:10.3168/jds.2016-11174.

Xu HF, Luo J, Zhao WS, Yang YC, Tian HB, Shi HB, Bionaz M. 2016. Overexpression of SREBP1 (sterol regulatory

element binding protein 1) promotes de novo fatty acid synthesis and triacylglycerol accumulation in goat mammary epithelial cells. J Dairy Sci. 99:783–795.

Xu L, Zhang LP, Yuan ZR, Guo LP, Zhu M, Gao X, Gao HJ, Li JY, Xu SZ. 2013. Polymorphism of SREBP1 is associated with beef fatty acid composition in Simmental bulls. Genet Mol Res. 12:5802–5809.

Xu W, Chen Q, Jia Y, Deng J, Jiang S, Qin G, Qiu Q, Wang X, Yang X, Jiang H. 2019. Isolation, characterization, and SREBP1 functional analysis of mammary epithelial cell in buffalo. J Food Biochem. 43:1–11.

Zhang S, Han RL, Gao ZY, Zhu SK, Tian YD, Sun GR, Kang XT. 2014. A novel 31-bp indel in the paired box 7 (PAX7) gene is associated with chicken performance traits. Br Poult Sci. 55:31–36.

Zhao H, Wu M, Wang S, Yu X, Li Z, Dang R, Sun X. 2018. Identification of a novel 24 bp insertion-deletion (indel) of the androgen receptor gene and its association with growth traits in four indigenous cattle breeds. Arch Anim Breed. 61:71–78.

Zhou M, Zhu Z, Sun HZ, Zhao K, Dugan MER, Bruce H, Fitzsimmons C, Li C, Guan LL. 2022. Breed dependent regulatory mechanisms of beneficial and non-beneficial fatty acid profiles in subcutaneous adipose tissue in cattle with divergent feed efficiency. Sci Rep. 12:1–16. DOI:10.1038/s41598-022-08572-8.

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