Tissue Expression, SNPs Scanning of CNTF Gene and Its Association with Growth Traits in Hu Sheep (Ovis aries)
CHENG Jiang-Bo1, ZHANG De-Yin1, ZHANG Yu-Kun1, SONG Qi-Zhi1, LI Xiao-Long1, ZHAO Yuan1, XU Dan1, ZHANG Xiao-Xue1, LI Chong1, YUAN Lyu-Feng1, LI Fa-Di2,3, WANG Wei-Min1,*
1 College of Animal Science and Technology, Gansu Agricultural University, Lanzhou 730070, China; 2 College of Grassland Agricultural Science and Technology, Lanzhou University, Lanzhou 730000, China; 3 Gansu Mutton Sheep Breeding Biotechnology Engineering Laboratory, Minqin 733300, China
Abstract:Ciliary neurotrophic factor (CNTF) is a cytokine with multiple biological functions in vivo. It is an important candidate gene affecting muscle development. The aim of this study was to investigate the tissue expression pattern of CNTF gene in sheep (Ovis aries), scan its SNPs and analyze its association with growth traits in a large population. In this study, 1 399 Hu sheep with clear family tree and accurate phenotype records were raised in a specialized performance measurement house. Before morning feeding at 80, 100, 120, 140, 160 and 180 d, respectively, the weight of the sheep was weighed, and body length, body height, chest circumference and cannon circumference were measured at the same time. At the end of the assay period, whole blood samples of each sheep were collected by jugular vein for genomic DNA extraction. They were slaughtered immediately and tissue samples were taken. According to design the CNTF mRNA sequence specific primers, RNA from the collected tissue samples was extracted and reverse transcribed to cDNA, using qPCR technology to detect the CNTF gene expression in 10 tissues of Hu sheep. Genomic DNA was extracted from whole blood samples of the experimental population using genomic DNA extraction kit according to the instructions. Mixed DNA was used as the template to amplify the designed PCR primers. SNPs of the gene was scanned by mixed pool sequencing method, and the SPSS 23.0 software was used for correlation analysis with sheep growth traits. This results found a high positive association between growth traits, with a higher correlation between weight and body size indicators such as body length, body height, chest circumferences and cannon circumferences (P<0.01). The ovine CNTF gene was ubiquitously expressed, with expression observed in 10 tissues including heart, liver, spleen, lung, and kidney, with higher expression in liver and rumen. The sheep CNTF gene fragment was amplified and sequenced, a g.2576 C>G polymorphism locus was detected in intron 1 of the sheep CNTF gene. The SNP sites were genotyped by KASPar technique, and 3 genotypes were obtained, namely CC, CG and GG. In the experimental population, the genotype frequencies of CC, CG and GG genotypes were 0.13, 0.12 and 0.75, respectively, and the frequencies of alleles C and G were 0.19 and 0.81, respectively. The polymorphism information content of this locus was 0.26, which showed moderate polymorphism, and its heterzygosity (He), homozygosity (Ho) and effective number of alleles (Ne) were 0.31, 0.69 and 1.45, respectively. The results of trait association analysis showed that the polymorphism locus was significantly correlated with the growth traits such as body weight, body height, body length, chest circumference and cannon circumference of Hu sheep from 80 to 180 d (P<0.05). The body weight at 80, 100, 120, 140 and 160 d, body height at 80, 100 and 120 d and chest circumference at 160 d of individuals with GG genotype were significantly higher than those with CG genotype (P<0.05). The body height at 140, 160, 180 d, chest circumference at 80, 100, 140 and 180 d and cannon circumference at each stage were significantly higher in individuals with GG genotype than those with CG genotype and CC genotype (P<0.05). These results indicated that the CNTF gene g.2576 C>G locus could be used as a candidate molecular marker for breeding of growth traits in Hu sheep.
程江博, 张德印, 张煜坤, 宋其志, 李晓龙, 赵源, 徐丹, 张小雪, 李冲, 袁律峰, 李发弟, 王维民. 湖羊CNTF基因组织表达、SNPs扫描及其与生长性状关联分析[J]. 农业生物技术学报, 2022, 30(3): 506-516.
CHENG Jiang-Bo, ZHANG De-Yin, ZHANG Yu-Kun, SONG Qi-Zhi, LI Xiao-Long, ZHAO Yuan, XU Dan, ZHANG Xiao-Xue, LI Chong, YUAN Lyu-Feng, LI Fa-Di, WANG Wei-Min. Tissue Expression, SNPs Scanning of CNTF Gene and Its Association with Growth Traits in Hu Sheep (Ovis aries). 农业生物技术学报, 2022, 30(3): 506-516.
[1] 白飞英, 李建明, 王媛, 等. 2021. 湖羊及其利用[J]. 北方牧业, (4): 2. (Bai F Y, Li J M, Wang Y, et al. 2021. Hu sheep and its utilization[J]. Northern Livestock, (4): 2.) [2] 毕华, 袁力勇, 史新昌, 等. 2007. 睫状神经营养因子突变体的克隆, 表达, 纯化及生物学活性[J]. 中国生物制品学杂志, 20(5): 313-317. (Bi H, Yuan L Y, Shi X C, et al.2007. Cloning, expression, purification and biological activity of ciliary neurotrophic factor mutants[J]. Chinese Journal of Biologics, 20(5): 313-317.) [3] 郭强. 2019. 杜湖杂种绵羊肉用性能测定及生长性状遗传参数估计[D]. 硕士学位论文, 山西农业大学, 导师: 刘文忠, pp. 31-51. (Guo Q.2019. Determination of performance and estimation of genetic parameters of growth traits in Douhu hybrid mutton[D]. Thesis for M.S., Shanxi Agricultural University, Supervisor: Liu W Z, pp. 31-51. ) [4] 李丽, 周桐希. 2021. CNTF基因A/G多态性作为部分冰雪体能主导类项群运动员早期选材的相关性研究[J]. 哈尔滨体育学院学报, 39(2): 6. (Li L, Zhou T X.2021. The correlation of A/G polymorphism of CNTF gene as early selection of athletes in some snow and ice physical fitness dominant category[J]. Journal of Harbin Institute of Physical Education, 39(2): 6.) [5] 冉亮东, 吴建平, 郎侠, 等. 2021. 引入肉羊品种与湖羊杂交的屠宰性能, 肉品质及血液生化指标比较研究[J]. 畜牧与兽医, 53(4): 4. (Ran L D, Wu J P, Lang X, et al.2021. Comparative study on slaughter performance, meat quality and blood biochemical indices of introduced mutton and Hu sheep crosses[J]. Animal husbandry and Veterinary Medicine, 53(4): 4.) [6] 孙国权, 高树新, 吴慧光, 等. 2014. 解偶联蛋白1, 2和3基因在中国西门塔尔牛组织器官中的表达水平及其与胴体品质关系分析[J]. 华北农学报, 29(4): 5. (Sun G Q, Gao S X, Wu H G, et al.2014. Expression of uncoupling protein 1,2 and 3 genes in bovine tissues and their relationship with carcass quality in Chinese simmental cattle[J]. Chinese Journal of Agricultural Sciences, 29(4): 5.) [7] 王珮, 马力宏. 2003. CNTF及其基因多态性的研究进展[J]. 中国运动医学杂志, 22(002): 210-213. (Wang P, Ma L H.2003. Research progress of CNTF and its gene polymorphism[J]. Chinese Journal of Sports Medicine, 22(002): 210-213.) [8] 王宇博, 丁新玲, 张春光. 2014. 胶原神经再生室复合CNTF修复周围神经损伤的作用[J]. 赤峰学院学报(自然版), 000(005):38-39. (Wang Y B, Ding X L, Zhang C G.2014. The effect of collagen nerve regeneration cell composite CNTF on peripheral nerve injury[J]. Journal of Chifeng University (Natural Science), 000(005): 38-39.) [9] 薛丽娜, 罗惠娣, 周胜花, 等. 2020. 绵羊MC1R和AGOUTI基因多态性与毛色性状的关联分析[J]. 山西农业大学学报(自然科学版), 40(06): 107-113. (Xue L N, Luo H D, Zhou S H, et al.2020. Polymorphism of MC1R and AGOUTI genes and their association with coat color traits in sheep[J]. Journal of Shanxi Agricultural University (Natural Science Edition), 40(06): 107-113.) [10] 杨晓琳, 胡扬, 李燕春. 2014. 睫状神经营养因子基因G1357A多态位点作为举重运动员选材用分子标记可行性研究[J]. 中国运动医学杂志, 33(004): 308-311. (Yang X L, Hu Y, LI Y C.2014. Molecular markers of ciliary neurotrophic factor gene G1357A in weightlifters[J]. Chinese Journal of Sports Medicine, 33(004): 308-311.) [11] 袁淑青, 胡海峰, 刘英. 2015. 睫状神经营养因子的临床研究进展[J]. 世界临床药物, 36(10): 706-709. (Yuan S Q, Hu H F, Liu Y.2015. Clinical progress of ciliary neurotrophic factor[J]. World Clinical Drugs, 36(10): 706-709.) [12] 张圆, 吴利锋, 魏波,等. 2020. 湖羊饲养及繁育管理要点[J]. 中国畜禽种业, 16(11): 99-100. (Zhang Y, Wu L F, Wei B, et al.2020. Key points of breeding and breeding management of hu sheep[J]. China Livestock and poultry Breeding Industry, 16(11): 99-100.) [13] 张子蓓. 2018. CNTF对角膜神经修复的作用及机制研究[D]. 硕士学位论文, 青岛大学, 导师: 翟华蕾, pp. 26-29. (Zhang Z B.2018. Study on the effect and mechanism of CNTF on corneal nerve repair[D]. Thesis for M.S., Qingdao University, Supervisor: Zhai H L, pp. 26-29.) [14] Bellido T, Stahl N, Farruggella T J, et al.1996. Detection of receptors for interleukin-6, interleukin-11, leukemia inhibitory factor, oncostatin M, and ciliary neurotrophic factor in bone marrow stromal/osteoblastic cells[J]. Journal of Clinical Investigation, 97(2): 431-437. [15] Chao C H, Li B J, Gu X H, et al.2018. Marker-assisted selection of YY supermales from a genetically improved farmed tilapia-derived strain[J]. Zoological Research, 40(2): 108-112. [16] Georges M.1999. Towards marker assisted selection in livestock[J]. Reproduction Nutrition Development, 39(5-6):555. [17] Heidema A G, Wang P, van R C T, et al.2010. Sex-specific effects of CNTF, IL6 and UCP2 polymorphisms on weight gain[J]. Physiology & Behavior, 99(1): 1-7. [18] Homma H, Kobatake N, Sekimoto Y, et al.2020. Ciliary neurotrophic factor receptor rs41274853 polymorphism is associated with weightlifting performance in Japanese weightlifters[J]. The Journal of Strength & Conditioning Research, 34(11): 3037-3041. [19] Ip N Y, Mcclain J, Barrezueta N X, et al.1993. The alpha component of the CNTF receptor is required for signaling and defines potential CNTF targets in the adult and during development[J]. Neuron, 10(1): 89-102. [20] Juszczuk-Kubiak E, Bujko K, Grześ M, et al.2016. Study of bovine gene: The temporal-spatial expression patterns, polymorphism and association analysis with meat production traits[J]. Journal of Animal Science, 94(11): 4536-4548. [21] Li Q, Li J, Yu C P, et al.2021. Synonymous mutations that regulate translation speed might play a non-negligible role in liver cancer development[J]. British Medical Council Cancer, 21(1): 388. [22] Manthorpe M, Skaper S D, Barbin G, et al.2010. Cholinergic neuronotrophic factors. Concurrent activities on certain nerve growth factor-responsive neurons[J]. Journal of Neurochemistry, 38(2): 415-421. [23] Niersch J, Vega-Rubin-De-Celis S, Bazarna A, et al.2021. A BAP1 synonymous mutation results in exon skipping, loss of function and worse patient prognosis[J]. iScience, 24(3): 102173. [24] O'Dell S D, Syddall H E, Sayer A A, et al.2002. Null mutation in human ciliary neurotrophic factor gene confers higher body mass index in males[J]. European Journal of Human Genetics, 10(11): 749-52. [25] Roth S M, Schrager M A, Ferrell R E, et al.2001. CNTF genotype is associated with muscular strength and quality in humans across the adult age span[J]. Journal of Applied Physiology, 90(4): 1205. [26] Roth S M, Metter E J, Lee M R, et al.2003. C174T polymorphism in the CNTF receptor gene is associated with fat-free mass in men and women.[J]. Journal of applied physiology, 95(4): 1425-1430. [27] Serrote C M L, Reiniger L R S, Silva K B, et al.2019. Determining the polymorphism information content of a molecular marker[J]. Gene, 726: 144175. [28] Sharma Y, Miladi M, Dukare S, et al.2019. A pan-cancer analysis of synonymous mutations[J]. Nature Communications, 10(1): 2569. [29] Sherman E L, Nkrumah J D, Murdoch B M, et al.2008. Polymorphisms and haplotypes in the bovine neuropeptide Y, growth hormone receptor, ghrelin, insulin-like growth factor 2, and uncoupling proteins 2 and 3 genes and their associations with measures of growth, performance, feed efficiency, and carcass merit[J]. Journal of Animal Science, 86(1): 1-16. [30] Vigneswara V, Akpan N, Berry M, et al.2014. Combined suppression of CASP2 and CASP6 protects retinal ganglion cells from apoptosis and promotes axon regeneration through CNTF-mediated JAK/STAT signalling[J]. Brain: A Journal of Neurology, 137(Pt 6): 1656-75. [31] Walsh I M, Bowman M A, Santarriaga I F, et al.2020. Synonymous codon substitutions perturb cotranslational protein folding in vivo and impair cell fitness[J]. Proceedings of the National Academy of Sciences of the USA, 117(7): 3528-3534. [32] Wang M C, Forsberg N E.2000. Effects of ciliary neurotrophic factor (CNTF) on protein turnover in cultured muscle cells[J]. Cytokine, 12(1): 41-48. [33] Zhang D, Zhang X, Li F, et al.2020. The association of polymorphisms in the ovine PPARGC1B and ZEB2 genes with body weight in Hu sheep[J]. Animal Biotechnology, (8): 1-8. [34] Zhang R, Li X.2010. Association between IGF-IR, m-calpain and UCP-3 gene polymorphisms and growth traits in Nanyang cattle[J]. Molecular Biology Reports, 38(3):2179-2184. [35] Zhu W, Eto M, Mitsuhashi S, et al.2018. GNE myopathy caused by a synonymous mutation leading to aberrant mRNA splicing[J]. Neuromuscular Disorders, 28(2):154-157.
