GC-MS分析慢性氨气应激对肉鸡血清代谢物的影响

doi:10.3864/j.issn.0578-1752.2020.08.017

摘要/Abstract

摘要：

【目的】随着养殖业集约化和规模化的发展,舍内环境对畜禽生长的影响日益突出。在密闭舍饲条件下,不断产生有毒有害气体,其中氨气的危害最大,降低畜禽生产性能,威胁动物健康。为此开展慢性氨气应激对肉鸡血清代谢物影响的研究,从小分子物质和代谢途径方面探究氨气导致机体代谢发生的变化,为舍内氨气的合理调控提供数据支持。【方法】试验采用单因素完全随机设计,将96只21日龄健康AA肉鸡随机分成对照组和试验组,每组设4个重复,每个重复12只鸡。对照组氨气浓度为0 mg·kg ^-1,试验组氨气浓度为45 mg·kg ^-1。试验在人工模拟呼吸舱内进行,呼吸舱采用全自动化控制温湿度等养殖条件,采用网上平养,自由采食和饮水,24h 光照,试验期为21d。在肉鸡42日龄时,从每个重复中随机抽取2只,翅静脉采血,分离血清。将血清样品预处理后,采用气相色谱/质谱联用技术（gas chromatograph tandem mass spectrometer technology, GC-MS）检测代谢产物,利用质谱数据库对其进行鉴定。通过主成分分析、偏最小二乘法判别分析、正交偏最小二乘法判别分析、t-检验等,寻找差异代谢物,并利用生物信息学方法对差异代谢物进行通路富集分析。【结果】（1）利用 GC-MS 方法,结合质谱数据库对检测到的代谢物进行快速鉴定,在肉鸡血清中共检测到204种代谢物。将代谢组数据导入SIMCA-P软件进行多元统计分析,结合t-检验筛选出 23种差异代谢物,其中上调19个,下调4个。（2）差异代谢物主要涉及能量代谢（乳酸、α-酮戊二酸）、氨基酸代谢（L-别苏氨酸、L-高丝氨酸、烟酰甘氨酸）、脂肪酸代谢（硬脂酸、亚麻酸、亚油酸、胆固醇）以及核苷酸代谢（次黄嘌呤、尿嘧啶、胸腺嘧啶）等。（3）代谢通路富集分析表明,氨气应激主要影响了肉鸡血清的脂肪代谢通路,如亚油酸代谢、花生四烯酸代谢以及α-亚麻酸代谢。【结论】GC-MS较为全面地检测到血清的代谢物,能够准确地筛选出差异代谢物,同时慢性氨气应激显著影响肉鸡的血清代谢物含量,主要影响脂肪代谢通路,为阐明氨气应激影响营养代谢的机制提供参考。

关键词: 肉鸡, 代谢组学, 血清, 代谢物, 气相色谱/质谱联用技术

Abstract:

【Objective】With the development of intensive and large-scale broiler breeding, the impact of environmental conditions on the growth of livestock and poultry has become increasingly prominent. Under high-density feeding conditions, a large amount of toxic and harmful gases is generated constantly, among which ammonia is the most harmful gas which reduces the performance of livestock and poultry and threatens animal health. The purpose of this experiment was to study the effects of chronic ammonia stress on serum metabolites in broiler chickens, and to explore the changes of metabolism caused by ammonia stress in terms of small molecules and metabolic pathways, so as to provide data support for reasonable regulation of ammonia in the poultry house. 【Method】Ninety-six 21-day-old healthy AA broilers were randomly divided into control group and experimental group by a single factor completely random design, with 4 replicates in each group and 12 chickens per replicate. The control group ammonia concentration was 0 mg·kg ^-1, the test group ammonia concentration was 45 mg·kg ^-1. The experiment was carried out in an artificial simulated respiratory chamber, which was fully automated to control the temperature and humidity and the other environmental conditions. Broilers were raised in the nets and the feed and water were provided ad libitum during the entire experimental period. The trial lasted 21 days with 24 h lighting program. They were routinely managed according to the AA broiler feeding manual and immunized according to the routine procedures. Two broiler chickens pre replicate from each treatment were chosen randomly and blood samples were collected from the wing vein at 42 day-old. After pretreatment of serum samples, the metabolites were detected by GC-MS technology, and identified by mass spectral database. Principal component analysis (PCA), partial least-squares discriminant analysis (PLSDA), orthogonal partial least squares discriminant analysis (OPLSDA) and t-test were used to find the different metabolites, and then the bioinformatics methods was used to analyze the differential metabolic pathways. 【Result】Results showed that: (1) A total of 204 metabolites were detected in serum of broiler chickens by GC-MS combining with rapid identification of the detected metabolites performed with a mass spectrometry database. Metabolomics data were imported into SIMCA-P software for multivariate statistical analysis, and then t-test. Twenty-three different metabolites were identified, of which 19 were up-regulated and 4 were down-regulated. (2) Differential metabolites mainly involved energy metabolism (lactic acid, α-ketoglutaric acid), amino acid metabolism (L-Allothreonine acid, L-Homoserine, Nicotinylglycine), fatty acid metabolism (stearic acid, linolenic acid, linoleic acid, cholesterol) and nucleotide metabolism (hypoxanthine, uracil, thymine) and so on. (3) Metabolic pathway enrichment analysis showed that ammonia stress mainly affected the fat metabolism pathway in serum of broiler chickens, including linoleic acid metabolism, arachidonic acid metabolism and α-linolenic acid metabolism. 【Conclusion】 It can be seen that GC-MS can detect serum metabolites comprehensively, and screen differential metabolites accurately. Chronic ammonia stress significantly affected serum metabolites content of broilers, mainly affected fat metabolism pathway.

Key words: broiler, metabonomics, serum, metabolites, GC-MS

孙永波,王亚,萨仁娜,张宏福. GC-MS分析慢性氨气应激对肉鸡血清代谢物的影响[J]. 中国农业科学, 2020, 53(8): 1688-1698.

SUN YongBo,WANG Ya,SA RENNA,ZHANG HongFu. Effects of Chronic Ammonia Stress on Serum Metabolites of Broilers Based on GC-MS[J]. Scientia Agricultura Sinica, 2020, 53(8): 1688-1698.

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代谢物 Metabolites	变化趋势 Change trend	VIP 值 VIP value	P值 P value
乳酸 Lactic acid	↓	1.5807	0.0352
α-酮戊二酸 Alpha-ketoglutaric acid	↑	1.7845	0.0082
苏糖醇 Threitol	↑	1.4728	0.0354
肌醇 Myo-inositol	↑	1.4704	0.0412
硬脂酸 Stearic acid	↑	1.4236	0.0384
亚麻酸 Linolenic acid	↑	1.6603	0.0178
亚油酸 Linoleic acid	↑	1.6483	0.0134
反式-9-十八碳烯酸 Elaidic acid	↑	1.9429	0.0031
棕榈酸 Palmitic acid	↑	1.6947	0.0154
十八烯酸 Oleic acid	↑	1.7048	0.0128
花生四烯酸 Arachidonic acid	↑	1.8747	0.0048
亚油酸甲酯 Linoleic acid methyl ester	↑	1.4729	0.0356
D-甘油酸 D-Glyceric acid	↑	1.4868	0.0239
胆固醇 Cholesterol	↑	1.4233	0.0357
2-羟基丁酸 2-hydroxybutanoic acid	↑	1.8462	0.0072
3-羟基丁酸 3-hydroxybutyric acid	↑	2.2048	0.0003
次黄嘌呤 Hypoxanthine	↓	1.6020	0.0239
尿嘧啶 Uracil	↓	1.5908	0.0186
胸腺嘧啶 Thymine	↓	1.5775	0.0197
羟基脲 Hydroxyurea	↑	1.5766	0.0207
L-别苏氨酸 L-Allothreonine	↑	1.5866	0.0300
L-高丝氨酸 L-homoserine	↑	2.1316	0.0010
烟酰甘氨酸 Nicotinoylglycine	↑	1.5466	0.0211