基于超高效液相色谱-静电场轨道阱高分辨质谱的深静脉血栓模型大鼠血浆代谢组学分析

doi:10.3724/SP.J.1123.2021.12024

摘要/Abstract

摘要：

深静脉血栓(DVT)是一种血栓栓塞性疾病,具有高发病率、高死亡率和高后遗症3大特点。采用左股静脉不完全结扎加高渗盐水刺激建立DVT大鼠模型,使用超高效液相色谱-静电场轨道阱高分辨质谱(UHPLC-Orbitrap HRMS)检测假手术组与DVT模型组的血浆代谢谱,用主成分分析(PCA)及正交偏最小二乘-判别分析(OPLS-DA)对代谢组数据进行多元统计分析,观察两组间的代谢表型差异,将多变量模型分析中的变量重要性值(VIP>1)以及代谢物在模型组中的变化倍数(FC≤0.5或FC≥2,且P<0.05)作为差异代谢物筛选条件。最终在DVT模型组与假手术组间筛选得到27种差异代谢物,这些代谢物反映了DVT大鼠的代谢紊乱情况。具体表现为与假手术组相比,DVT模型组中三甲基胺氮氧化物(TMAO)、维生素K、鹅去氧胆酸、牛磺酸、1-甲基烟酰胺、7-酮胆固醇、反式十六烷基-2-烯醇肉碱、乙烯基乙酰甘氨酸、丙酰脯氨酸、咪唑乙酸、咪唑乙酸核糖苷、1,3,7-三甲基尿酸、1-丁胺、2-羟基异丙酸、吡哆醛、5α-四氢皮质酮、苯乳酸的水平显著升高;而3-脱氢肉碱、磷脂酰胆碱22∶6/20∶2(PC 22∶6/20∶2)、甘油二酯18∶3/20∶4(DG 18∶3/20∶4)、溶血磷脂酰胆碱20∶2(LysoPC 20∶2)、波维酸、鹅肌肽、L-肌肽、辛酸、羟基丙酮酸、3-羟基癸酸的水平显著降低。基于京都基因与基因组百科全书数据库(KEGG)代谢通路的差异丰度(DA)分析显示DVT模型大鼠与假手术组的代谢通路差异主要集中在初级胆汁酸生物合成、胆汁分泌、组氨酸代谢、亚油酸代谢、甘油磷脂代谢和β-丙氨酸代谢。紊乱的代谢物和代谢途径可为进一步深入理解DVT的病理机制、寻找诊断标志物及药物作用靶点提供参考。

关键词: 超高效液相色谱-静电场轨道阱高分辨质谱, 代谢组学, 深静脉血栓

Abstract:

Deep vein thrombosis (DVT) is a venous thromboembolic disease characterized by high incidence, mortality, and sequelae. Therefore, the effective prevention of DVT has become a critical public health concern. However, due to its complexity, the pathophysiological mechanism of DVT remains unclear. Metabolomics can be employed to analyze disease characteristics and provide scientific evidence on the underlying mechanisms. In this study, an established left femoral vein ligation rat model of DVT (n=10) was used and compared with sham surgery controls (n=10). In the DVT group, rats were anesthetized using an intraperitoneal injection of 10% chloral hydrate (300 mg/kg), after which the hair was shaved and the groin disinfected. A 2-cm longitudinal incision was made along the midpoint of the left groin area, and then the left femoral vein was separated. The vein was partially ligated at its proximal end to shrink the blood vessel lumen to approximately half. Then, 0.4 mL of 10% hypertonic saline was slowly injected from the distal end of the left femoral vein. At the same time, the femoral vein turned dark red, which indicated the formation of thrombosis. Finally, the incision was sutured after verifying bleeding in the surrounding tissue. Keeping all other procedures the same as the DVT group, the vein in the control group was not ligated or stimulated using hyper-tonic saline. The abdominal aorta plasma from rats in each group was collected seven days later. Untargeted metabolomics analysis based on ultra-high performance liquid chromatography-electrostatic field orbitrap high resolution mass spectrometry (UHPLC-Orbitrap HRMS) was conducted to investigate the plasma metabolic profiles of the sham surgery control and DVT groups. Principal component analysis (PCA) and orthogonal to partial least squares discrimi-nant analysis (OPLS-DA) on metabolome data for multivariate statistical analysis were employed to assess differences in the metabolic profile between the two groups. The results revealed distinct profiles for the DVT and control groups. The selection criteria for the differential metabolites were the variable importance in the projection (VIP) values of OPLS-DA (VIP>1) and fold changes (FC) in the DVT group (FC≤0.5 or FC≥2, P<0.05). The resulting 27 differential metabolites reflecting a metabolic disorder in the DVT group were selected and analyzed. Of these, the levels of 17 metabolites significantly increased in the DVT group, including trimethylamine N-oxide (TMAO), 4-amino-2-methyl-1-naphthol, chenodeoxycholic acid, and 7-ketocholesterol, whereas the levels of 10 metabolites decreased, including 3-dehydroxycarnitine, phosphatidylcholine 22∶6/20∶2 (PC 22∶6/20∶2), diglyceride 18∶3/20∶4 (DG 18∶3/20∶4) and anserine. To identify the changes in the metabolic pathway reflected by these differential metabolites, a differential abundance (DA) analysis based on the Kyoto Encyclopedia of Genes and Genomes metabolic pathway was conducted. The results showed that the differences in the metabolic pathways between the DVT and control groups were mainly manifested in the primary bile acid biosynthesis, bile secretion, histidine metabolism, linoleic acid metabolism, glycerophospholipid metabolism, and β-alanine metabolism pathways. Among them, the primary bile acid biosynthesis and bile secretion pathways were upregulated in the DVT group, whereas the glycerophospholipid metabolism, linoleic acid metabolism, and β-alanine metabolism pathways were downregulated. The histidine metabolism pathway contained upregulated as well as downregulated metabolites, resulting in a DA score of 0. In conclusion, these results indicate that the plasma metabolic profiling of the DVT group was significantly altered, while the disordered metabolites and metabolic pathways could provide a reference to further understand the pathological mechanism of DVT and identify new drug targets.

Key words: ultra-high performance liquid chromatography-electrostatic field orbitrap high resolution mass spectrometry (UHPLC-Orbitrap HRMS), metabolomics, deep vein thrombosis (DVT)

中图分类号:

O658

谷艳, 臧鹏, 李进霞, 闫燕艳, 王佳. 基于超高效液相色谱-静电场轨道阱高分辨质谱的深静脉血栓模型大鼠血浆代谢组学分析[J]. 色谱, 2022, 40(8): 736-745.

GU Yan, ZANG Peng, LI Jinxia, YAN Yanyan, WANG Jia. Plasma metabolomics in a deep vein thrombosis rat model based on ultra-high performance liquid chromatography-electrostatic field orbitrap high resolution mass spectrometry[J]. Chinese Journal of Chromatography, 2022, 40(8): 736-745.

图/表 7

图1 (a)假手术组与(b)DVT模型组大鼠静脉血栓的苏木精-伊红染色

Fig. 1 Hematoxylin-eosin staining of venous thrombosis in (a) sham surgery control and (b) deep vein thrombosis (DVT) rat groups

图2 ESI模式下血浆样本的PCA得分图

Fig. 2 Principal component analysis (PCA) score plots of the plasma samples in ESI mode

图3 假手术组与DVT模型组大鼠血浆代谢物火山图

Fig. 3 Volcano maps of the rat plasma metabolites in the sham surgery control and DVT model groups FC: fold change of metabolite in DVT model group versus the control group; P-value: calculated in student t-test which was used to test the significance of metabolites between the two groups. Red dot: the level of metabolite was upregulated in DVT model group. Blue dot: the level of metabolite was downregulated in DVT model group. Gray dot: the level of metabolite was not changed in DVT model group.

图4 假手术组与DVT模型组大鼠血浆代谢物的(a)PCA和(b)OPLS-DA得分图

Fig. 4 (a) PCA and (b) orthogonal to partial least squares discriminant analysis (OPLS-DA) score plots of rat plasma metabolites in the sham surgery control and DVT model groups

图5 假手术组与DVT模型组大鼠血浆差异代谢物热图

Fig. 5 Heat map of the differential metabolites in the sham surgery control and DVT model groups

表1 假手术组与DVT模型组间的血浆差异代谢物

Table 1 Differential metabolites of the plasma sample in the sham surgery control and DVT model groups

Metabolite	FC	P-value	ESI^±	Category
Trimethylamine N-oxide	2.82	2.4×10^-4	+	aminoxides
4-Amino-2-methyl-1-naphthol	2.86	1.0×10^-3	+	naphthols
Chenodeoxycholic acid	3.20	1.6×10^-2	+	bile acids
Taurocholic acid	3.15	7.8×10^-4	-	bile acids
7-Ketocholesterol	2.40	2.0×10^-3	+	cholesterols
trans-Hexadec-2-enoyl carnitine	3.05	2.6×10^-2	+	fatty acids
Leucinic acid	6.02	1.0×10^-3	-	branched fatty acids
1-Methylnicotinamide	3.91	1.0×10^-3	+	pyridinecarboxylic acids
Vinylacetylglycine	2.85	2.7×10^-2	+	amino acids
Valylproline	3.40	1.1×10^-6	+	amino acids
1-Butylamine	3.02	5.7×10^-8	+	amines
Imidazoleacetic acid riboside	2.13	2.6×10^-2	+	nucleosides
1,3,7-Trimethyluric acid	3.94	1.0×10^-3	+	purines
5α-Tetrahydrocorticosterone	2.80	1.7×10^-2	-	steroids
Phenyllactic acid	2.50	2.0×10^-3	-	phenylpropanoids
Pyridoxal	2.55	4.1×10^-4	+	pyridines
Imidazoleacetic acid	2.08	4.0×10^-3	-	organic heterocycles
3-Dehydroxycarnitine	0.36	3.8×10^-2	+	keto acids
PC(22∶6(4Z,7Z,10Z,13Z,16Z,19Z)/20∶2(11Z,14Z))	0.48	2.9×10^-5	+	glycerophospholipids
DG(18∶3(6Z,9Z,12Z)/20∶4(5Z,8Z,11Z,14Z))	0.41	6.3×10^-5	+	glycerolipids
LysoPC(20∶2(11Z,14Z))	0.44	2.1×10^-4	+	glycerophospholipids
Anserine	0.36	1.9×10^-2	-	peptidomimetics
L-Carnosine	0.10	2.2×10^-2	-	peptidomimetics
Caprylic acid	0.43	6.8×10^-5	-	fatty acids
Bovinic acid	0.49	5.0×10^-3	-	fatty acids
3-Hydroxycapric acid	0.36	1.7×10^-5	-	fatty acids
Hydroxypyruvic acid	0.36	4.0×10^-3	-	organic acids

图6 基于京都基因与基因组百科全书数据库的通路差异丰度得分图

Fig. 6 Differential abundance score plot by Kyoto Encyclopedia of Genes and Genomes (KEGG) pathways Different color indicated the different metabolic classifications of the pathway. The positive value of the line segment indicated the pathway was upregulated in DVT model group. The negative value of the line segment indicated that the pathway was downregulated in DVT model group. The size of the segment endpoint indicated the number of differential metabolites involved in the pathway.

参考文献

[1]	Heit J A, Spencer F A, White R H. J Thromb Thrombolysis, 2016, 41(1): 3
[2]	Rosendaal F R. Lancet, 1999, 353(9159): 1167
[3]	Vorkas P A, Shalhoub J, Isaac G, et al. J Proteome Res, 2015, 14(3): 1389
[4]	Sung Y, Spagou K, Kafeza M, et al. Eur J Vasc Endovasc Surg, 2018, 55(5): 703
[5]	Cao J, Lü X G, Li Y, et al. Journal of Forensic Medicine, 2018, 34(3): 228
[5]	曹洁, 吕晓革, 李宇, 等. 法医学杂志, 2018, 34(3): 228
[6]	Zhang C S, Ke C J, Feng Q X, et al. New Medicine, 2014, 45(10): 647
[6]	张朝顺, 柯常江, 冯起校, 等. 新医学, 2014, 45(10): 647
[7]	Smith C A, Want E J, O’Maille G, et al. Anal Chem, 2006, 78(3): 779
[8]	Chen A L. and Health, Biped 2017, 26(17): 113
[8]	陈爱玲. 双足与保健, 2017, 26(17): 113
[9]	Trygg J, Wold S. J Chemom, 2002, 16(3): 119
[10]	Sun R, Yang N, Kong B, et al. Mol Pharmacol, 2017, 91(2): 110
[11]	Baker K S, Kopec A K, Pant A, et al. Arterioscler Thromb Vasc Biol, 2019, 39(10): 2038
[12]	Potthoff M J, Boney-Montoya J, Choi M, et al. Cell Metab, 2011, 13(6): 729
[13]	Makishima M, Okamoto A Y, Repa J J, et al. Science, 1999, 284(5418): 1362
[14]	Sun R B, Yang N, Kong B, et al. Mol Pharmacol, 2017, 91(2): 110
[15]	Katakura Y, Totsuka M, Imabayashi E, et al. Nutrients, 2017, 9(11): 1199
[16]	Hipkiss A R, Gaunitz F. Amino Acids, 2014, 46(2): 327
[17]	Romano K A, Martinez-del C A, Kasahara K, et al. Cell Host Microbe, 2017, 22(3): 279
[18]	Skye S M, Zhu W F, Romano K A, et al. Circ Res, 2018, 123(10): 1164
[19]	Rombouts C, Hemeryck L Y, Van Hecke T, et al. Sci Rep, 2017, 7: 42514
[20]	Koeth R A, Levison B S, Culley M K, et al. Cell Metab, 2014, 20(5): 799
[21]	Ma Y, Liu G, Tang M Y, et al. Front Immunol, 2021, 12: 640305
[22]	Koh S S, Ooi C Y, Lui M Y, et al. Neuromolecular Med, 2021, 23(1): 184
[23]	Li W, Ghosh M, Eftekhari S, et al. Biochem Biophys Res Commun, 2011, 409(4): 711
[24]	Chang M C, Chen Y J, Liou E J, et al. Oncotarget, 2016, 7(46): 74473