梅花鹿茸、马鹿茸和赤鹿茸的差异蛋白质组学分析及候选特征肽段的筛选

doi:10.11843/j.issn.0366-6964.2025.09.022

Abstract

Abstract:

The purpose of this study was to explore the differences in components and peptide sequences among sika deer velvet antlers, red deer velvet antlers and New Zealand red deer velvet antlers from the perspective of comparative proteomics, and to provide accurate scientific basis for the identification and quality evaluation of deer velvet antler. In this study, the tissues of sika deer velvet antlers, red deer velvet antlers and New Zealand red deer velvet antlers collected from adult healthy male deer were used as experimental materials and were divided into three groups, including 10 two-branched sika deer velvet antlers, 10 three-branched red deer velvet antlers and 7 three-branched New Zealand red deer velvet antlers. After sample processing, 4D-DIA proteomics technology was used in combination with bioinformatics methods to analyze differentially expressed proteins and differential peptides. A total of 7 377 proteins and 56 739 peptides were identified in this study. There were 6 486 proteins and 41 878 peptides common to sika deer velvet antler, red deer velvet antler and New Zealand red deer velvet antler. In total, 640 differentially expressed proteins were identified. The 461 differentially expressed proteins were identified in sika deer velvet antler vs. red deer velvet antler comparison group, which 270 were up-regulated and 191 were down-regulated. The 391 differentially expressed proteins were identified in sika deer velvet antler vs. New Zealand red deer velvet antler comparison group, which 246 were up-regulated and 145 were down-regulated. The 96 differentially expressed proteins were identified in red deer velvet antler vs. New Zealand red deer velvet antler comparison group, which 50 were up-regulated and 46 were down-regulated. The differentially expressed proteins were mainly involved in biological processes such as the negative regulation of peptidase activity, the regulation of acute inflammatory responses, and the regulation of protein activation cascades. The differentially expressed proteins were mainly involved in pathways such as the intestinal immune network for IgA production and the complement and coagulation cascades. The 5, 1 and 3 candidate characteristic peptides were screened for sika deer velvet antlers, red deer velvet antlers and New Zealand red deer velvet antlers, respectively. There are certain differences in protein expression levels and peptide sequences among sika deer velvet antlers, red deer velvet antlers and New Zealand red deer velvet antlers. This study can provide a basis for the identification of sika deer velvet antlers, red deer velvet antlers and New Zealand red deer velvet antlers, and also offer certain theoretical support for clarifying the differences in biological among sika deer velvet antlers, red deer velvet antlers and New Zealand red deer velvet antlers.

Key words: sika deer velvet antler, red deer velvet antler, New Zealand red deer velvet antler, proteomics

CLC Number:

S825.2

HE Huihui, ZHANG Handa, ZHANG Ranran, WANG Tianjiao, LI Gongteng, GE Yunhua, XING Xiumei. Comparative Proteomics Analysis and Screening of Candidate Characteristic Peptides of Sika Deer Velvet Antler, Red Deer Velvet Antler and New Zealand Red Deer Velvet Antler[J]. Acta Veterinaria et Zootechnica Sinica, 2025, 56(9): 4393-4409.

Figures/Tables 14

Table 1

Fig. 1

Fig. 2

Fig. 3

Fig. 4

Fig. 5

Fig. 6

Fig. 7

Fig. 8

Fig. 9

Fig. 10

Fig. 11

Table 2

Table 3

References 57

1	潘黛安, 刘那, 王思明, 等. 鹿茸水溶性蛋白的结构表征与抗疲劳活性研究[J]. 中国医院药学杂志, 2024, 44 (21): 2470- 2476.
	PAN D A , LIU N , WANG S M , et al. Structural characterization and anti-fatigue activity of water-soluble protein of velvet antler[J]. Chinese Journal of Hospital Pharmacy, 2024, 44 (21): 2470- 2476.
2	中华人民共和国药典2020年版. 一部[S]. 2020: 336.
	Pharmacopoeia of the People 's Republic of China 2020 Edition. Part Ⅰ[S]. 2020: 336. (in Chinese)
3	MENG D S , LI Y R , CHEN Z , et al. Exosomes derived from antler mesenchymal stem cells promote wound healing by miR-21-5p/STAT3 Axis[J]. Int J Nanomed, 2024, 19, 11257- 11273. doi: 10.2147/IJN.S481044
4	WANG Y S , CHU W H , ZHAI J J , et al. High quality repair of osteochondral defects in rats using the extracellular matrix of antler stem cells[J]. World J Stem Cells, 2024, 16 (2): 176- 190. doi: 10.4252/wjsc.v16.i2.176
5	LIU Z P , LI W , GENG L L , et al. Cross-species metabolomic analysis identifies uridine as a potent regeneration promoting factor[J]. Cell Discov, 2022, 8 (1): 6. doi: 10.1038/s41421-021-00361-3
6	LIU L Y , JIAO Y , YANG M , et al. Network pharmacology, molecular docking and molecular dynamics to explore the potential immunomodulatory mechanisms of deer antler[J]. Int J Mol Sci, 2023, 24 (12): 10370. doi: 10.3390/ijms241210370
7	邢秀梅, 张然然, 孔繁涛. 新冠疫情对中国茸鹿产业的影响分析[J]. 农业展望, 2021, 17 (4): 52- 55.
	XING X M , ZHANG R R , KONG F T . Influence of COVID-19 pandemic on China 's velvet deer industry[J]. Agricultural Outlook, 2021, 17 (4): 52- 55.
8	张然然, 孙印石, 王桂武, 等. 吉林省梅花鹿产业发展的思考[J]. 特产研究, 2022, 44 (5): 151- 154.
	ZHANG R R , SUN Y S , WANG G W , et al. Thoughts on accelerating the development of sika deer industry in Jilin Province[J]. Special Wild Economic Animal and Plant Research, 2022, 44 (5): 151- 154.
9	李寅博, 刘贺, 刘迪, 等. 抚顺地区清原马鹿繁育及种质资源利用现状及对策建议[J]. 畜禽业, 2024, 35 (8): 25- 28.
	LI Y B , LIU H , LIU D , et al. Current situation of breeding and germplasm resources utilization of qingyuan wapiti in fushun area and suggestions on countermeasures[J]. Livestock and Poultry Industry, 2024, 35 (8): 25- 28.
10	靳梦亚, 董玲, 罗元明, 等. 利用iTRAQ技术联合2D LC-MS研究不同加工工艺鹿茸的差异蛋白质组学[J]. 药学学报, 2015, 50 (12): 1637- 1644.
	JIN M Y , DONG L , LUO Y M , et al. Comparative proteomics study of different processing technology for pilose antler using iTRAQ technology coupled with 2D LC-MS[J]. Acta Pharmaceutica Sinica, 2015, 50 (12): 1637- 1644.
11	刘文媛. 基于蛋白质组学和代谢组学的鹿茸区段划分与生物活性物质的分析与鉴别[D]. 北京: 中国农业科学院, 2020: 6-19.
	LIU W Y. Analysis and identification of bioactive compounds from four portions of velvet antlers in sika deer (Cervus nippon) based on proteomics and metabolomics[D]. Beijing: Chinese Academy of Agricultural Sciences, 2020: 6-19. (in Chinese)
12	SU H , TANG X L , ZHANG X C , et al. Comparative proteomics analysis reveals the difference during antler regeneration stage between red deer and sika deer[J]. PeerJ, 2019, 7, e7299. doi: 10.7717/peerj.7299
13	周秋丽, 刘永强, 王颖, 等. 梅花鹿茸和马鹿茸多肽化学性质及生物活性比较[J]. 中国中药杂志, 2001 (10): 51- 54.
	ZHOU Q L , LIU Y Q , WANG Y , et al. A compaison of chemical composition and bioactivity of polvpeptides from velvet antlers of Cervus nippon Temminck and Cervus elaphus Linnaeus[J]. China Journal of Chinese Materia Medica, 2001 (10): 51- 54.
14	阳洪波, 王韦达, 李意, 等. 基于特征肽段的液相色谱-质谱技术鉴定胶原蛋白的物种来源[J]. 分析测试学报, 2018, 37 (11): 1279- 1286.
	YANG H B , WANG W D , LI Y , et al. Identification of species origin of collagen based on liquid chromatography-mass spectrometry with peptide markers[J]. Journal of Instrumental Analysis, 2018, 37 (11): 1279- 1286.
15	JOHNSON P E , BAUMGARTNER S , ALDICK T , et al. Current perspectives and recommendations for the development of mass spectrometry methods for the determination of allergens in foods[J]. J AOAC Int, 2011, 94 (4): 1026- 1033. doi: 10.1093/jaoac/94.4.1026
16	张淑霞, 祝伟霞, 刘胜男, 等. 基于HPLC-Q-Exactive的PRM技术检测核桃露中核桃、杏仁、花生、大豆源性成分[J]. 食品科技, 2020, 45 (9): 273- 280.
	ZHANG S X , ZHU W X , LIU S N , et al. Detection of walnut, almond, peanut and soybean derived ingredients in walnut drink based on HPLC-Q-Exactive with parallel reaction monitoring mode[J]. Food Science and Technology, 2020, 45 (9): 273- 280.
17	张九凯, 马聪聪, 邢冉冉, 等. 基于鸟枪蛋白组学与质谱多反应监测技术的三文鱼物种鉴别研究[J]. 食品安全质量检测学报, 2022, 13 (16): 5271- 5278.
	ZHANG J K , MA C C , XING R R , et al. Authentication of salmon species based on shotgun proteomics and mass spectrometry multiple reaction monitoring techniques[J]. Journal of Food Safety & Quality, 2022, 13 (16): 5271- 5278.
18	王磊, 张然然, 刘华淼, 等. 马鹿鹿茸不同部位差异蛋白质组学分析[J]. 畜牧兽医学报, 2017, 48 (8): 1401- 1415. doi: 10.11843/j.issn.0366-6964.2017.08.004
	WANG L , ZHANG R R , LIU H M , et al. Comparative proteomics analysis on different parts of Cervus elaphus songaricus velvet antler[J]. Acta Veterinaria et Zootechnica Sinica, 2017, 48 (8): 1401- 1415. doi: 10.11843/j.issn.0366-6964.2017.08.004
19	张然然, 刘华淼, 邵元臣, 等. 不同生长时期梅花鹿鹿茸差异蛋白质组学分析[J]. 畜牧兽医学报, 2016, 47 (3): 493- 501. doi: 10.11843/j.issn.0366-6964.2016.03.010
	ZHANG R R , LIU H M , SHAO Y C . Comparative proteomic analysis in different growth stages of sika deer velvet antler[J]. Acta Veterinaria et Zootechnica Sinica, 2016, 47 (3): 493- 501. doi: 10.11843/j.issn.0366-6964.2016.03.010
20	LOU R , SHUI W . Acquisition and analysis of DIA-based proteomic data: a comprehensive survey in 2023[J]. Mol Cell Proteomics, 2024, 23 (2): 100712. doi: 10.1016/j.mcpro.2024.100712
21	VITKO D , CHOU W F , NOURI GOLMAEI S , et al. timsTOF HT improves protein identification and quantitative reproducibility for deep unbiased plasma protein biomarker discovery[J]. J Proteome Res, 2024, 23 (3): 929- 938. doi: 10.1021/acs.jproteome.3c00646
22	ALSUBAIT A , ALDOSSARY W , RASHID M , et al. CYP1B1 gene: implications in glaucoma and cancer[J]. J Cancer, 2020, 11 (16): 4652- 4661. doi: 10.7150/jca.42669
23	KWON Y J , BAEK H S , YE D J , et al. CYP1B1 enhances cell proliferation and metastasis through induction of EMT and activation of Wnt/β-catenin signaling via Sp1 upregulation[J]. PLoS One, 2016, 11 (3): e0151598. doi: 10.1371/journal.pone.0151598
24	LI F , ZHU W F , GONZALEZ F J . Potential role of CYP1B1 in the development and treatment of metabolic diseases[J]. Pharm Ther, 2017, 178, 18- 30. doi: 10.1016/j.pharmthera.2017.03.007
25	ALLEN S P , MADEN M , PRICE J S . A role for retinoic acid in regulating the regeneration of deer antlers[J]. Dev Biol, 2002, 251 (2): 409- 423. doi: 10.1006/dbio.2002.0816
26	LAZZERI G , LENZI P , SIGNORINI G , et al. Retinoic acid promotes neuronal differentiation while increasing proteins and organelles related to autophagy[J]. Int J Mol Sci, 2025, 26 (4): 1691. doi: 10.3390/ijms26041691
27	RUBINSTEIN A D , EISENSTEIN M , BER Y , et al. The autophagy protein Atg12 associates with antiapoptotic Bcl-2 family members to promote mitochondrial apoptosis[J]. Mol Cell, 2011, 44 (5): 698- 709. doi: 10.1016/j.molcel.2011.10.014
28	ALOKE C , ONISURU O O , ACHILONU I . Glutathione S-transferase: a versatile and dynamic enzyme[J]. Biochem Biophys Res Commun, 2024, 734, 150774. doi: 10.1016/j.bbrc.2024.150774
29	AWASTHI Y C , RAMANA K V , CHAUDHARY P , et al. Regulatory roles of glutathione-S-transferases and 4-hydroxynonenal in stress-mediated signaling and toxicity[J]. Free Radic Biol Med, 2017, 111, 235- 243. doi: 10.1016/j.freeradbiomed.2016.10.493
30	张然然, 荣敏, 董依萌, 等. 不同生长时期梅花鹿鹿茸代谢组分析[J]. 畜牧兽医学报, 2022, 53 (12): 4518- 4526. doi: 10.11843/j.issn.0366-6964.2022.12.037
	ZHANG R R , RONG M , DONG Y M , et al. Metabolomic analysis of sika deer antler in different growth stages[J]. Acta Veterinaria et Zootechnica Sinica, 2022, 53 (12): 4518- 4526. doi: 10.11843/j.issn.0366-6964.2022.12.037
31	邬慧慧. 高低产鹿茸软骨层RNA-seq分析及花生四烯酸对鹿茸软骨细胞增殖影响的研究[D]. 武汉: 华中农业大学, 2023: 38-40.
	WU H H. RNA-seq analysis of high and low yielding deer antlercartilage layer and effects of arachidonic acid on theproliferation of deer antler chondrocytes[D]. Wuhan: Huazhong Agricultural University, 2023: 38-40. (in Chinese)
32	SCIAN M , PAÇO L , MURPHREE T A , et al. Reversibility and low commitment to forward catalysis in the conjugation of lipid alkenals by glutathione transferase A4-4[J]. Biomolecules, 2023, 13 (2): 329. doi: 10.3390/biom13020329
33	PETIT F M , SERRES C , BOURGEON F , et al. Identification of sperm head proteins involved in zona pellucida binding[J]. Hum Reprod, 2013, 28 (4): 852- 865. doi: 10.1093/humrep/des452
34	AYDEMIR B , ONARAN I , KIZILER A R , et al. Increased oxidative damage of sperm and seminal plasma in men with idiopathic infertility is higher in patients with glutathione S-transferase Mu-1 null genotype[J]. Asian J Androl, 2007, 9 (1): 108- 115. doi: 10.1111/j.1745-7262.2007.00237.x
35	RUBES J , SELEVAN S G , SRAM R J , et al. GSTM1 genotype influences the susceptibility of men to sperm DNA damage associated with exposure to air pollution[J]. Mutat Res, 2007, 625 (1-2): 20- 28. doi: 10.1016/j.mrfmmm.2007.05.012
36	LLAVANERA M , MATEO-OTERO Y , BONET S , et al. The triple role of glutathione S-transferases in mammalian male fertility[J]. Cell Mol Life Sci, 2020, 77 (12): 2331- 2342. doi: 10.1007/s00018-019-03405-w
37	房磊, 吴瑕, 杨晨, 等. 鹿茸对昆明小鼠精子质量的影响[J]. 畜禽业, 2011 (6): 42- 43.
	FANG L , WU X , YANG C , et al. The effects of pilose on sperm quality of Kunming mice[J]. Livestock and Poultry Industry, 2011 (6): 42- 43.
38	BENEŠ H , VUONG M K , BOERMA M , et al. Protection from oxidative and electrophilic stress in the Gsta4-null mouse heart[J]. Cardiovasc Toxicol, 2013, 13 (4): 347- 356. doi: 10.1007/s12012-013-9215-1
39	ZHENG Z, GRANADO H S, LI C. Fibromodulin, a multifunctional matricellular modulator[J]. J Dent Res, 2023 Feb; 102(2): 125-134.
40	ZHAO F , BAI Y , XIANG X R , et al. The role of fibromodulin in inflammatory responses and diseases associated with inflammation[J]. Front Immunol, 2023, 14, 1191787. doi: 10.3389/fimmu.2023.1191787
41	ALCAIDE-RUGGIERO L , CUGAT R , DOMÍNGUEZ J M . Proteoglycans in articular cartilage and their contribution to chondral injury and repair mechanisms[J]. Int J Mol Sci, 2023, 24 (13): 10824. doi: 10.3390/ijms241310824
42	BOSKEY A L , ROBEY P G , LEIKIN S . The regulatory role of matrix proteins in mineralization of bone[M]. Massachusetts: Avademic Press, 2013: 235- 255.
43	ZHENG Z , JAMES A W , LI C S , et al. Fibromodulin reduces scar formation in adult cutaneous wounds by eliciting a fetal-like phenotype[J]. Signal Transduct Target Ther, 2017, 2 (1): 17050. doi: 10.1038/sigtrans.2017.50
44	XU X , HA P , YEN E , et al. Small leucine-rich proteoglycans in tendon wound healing[J]. Adv Wound Care, 2022, 11 (4): 202- 214. doi: 10.1089/wound.2021.0069
45	HILL L J , MOAKES R J A , VAREECHON C , et al. Sustained release of decorin to the surface of the eye enables scarless corneal regeneration[J]. NPJ Regen Med, 2018, 3 (1): 23. doi: 10.1038/s41536-018-0061-4
46	GUPTA S , BUYANK F , SINHA N R , et al. Decorin regulates collagen fibrillogenesis during corneal wound healing in mouse in vivo[J]. Exp Eye Res, 2022, 216, 108933. doi: 10.1016/j.exer.2022.108933
47	HUANG X K , ZHU Z Y , DU M R , et al. FMOD alleviates depression-like behaviors by targeting the PI3K/AKT/mTOR signaling after traumatic brain injury[J]. Neuromol Med, 2024, 26 (1): 24. doi: 10.1007/s12017-024-08793-2
48	OSHIMA K , SIDDIQUI N , ORFILA J E , et al. A role for decorin in improving motor deficits after traumatic brain injury[J]. Matrix Biol, 2024, 125, 88- 99. doi: 10.1016/j.matbio.2023.12.005
49	MOHINDRA P , ZHONG J X , FANG Q , et al. Local decorin delivery via hyaluronic acid microrods improves cardiac performance, ventricular remodeling after myocardial infarction[J]. NPJ Regen Med, 2023, 8 (1): 60. doi: 10.1038/s41536-023-00336-w
50	ANDENÆS K , LUNDE I G , MOHAMMADZADEH N , et al. The extracellular matrix proteoglycan fibromodulin is upregulated in clinical and experimental heart failure and affects cardiac remodeling[J]. PLoS One, 2018, 13 (7): e0201422. doi: 10.1371/journal.pone.0201422
51	TU T , SHI Y , ZHOU B Y , et al. Type I collagen and fibromodulin enhance the tenogenic phenotype of hASCs and their potential for tendon regeneration[J]. NPJ Regen Med, 2023, 8 (1): 67. doi: 10.1038/s41536-023-00341-z
52	DELALANDE A , GOSSELIN M P , SUWALSKI A , et al. Enhanced Achilles tendon healing by fibromodulin gene transfer[J]. Nanomedicine, 2015, 11 (7): 1735- 1744. doi: 10.1016/j.nano.2015.05.004
53	PECHANEC M Y , BOYD T N , BAAR K , et al. Adding exogenous biglycan or decorin improves tendon formation for equine peritenon and tendon proper cells in vitro[J]. BMC Musculoskelet Disord, 2020, 21 (1): 627. doi: 10.1186/s12891-020-03650-2
54	DUNKMAN A A , BUCKLEY M R , MIENALTOWSKI M J , et al. The tendon injury response is influenced by decorin and biglycan[J]. Ann Biomed Eng, 2014, 42 (3): 619- 630. doi: 10.1007/s10439-013-0915-2
55	WANG M Y , LIU W J , WU L Y , et al. The research progress in transforming growth factor-β2[J]. Cells, 2023, 12 (23): 2739. doi: 10.3390/cells12232739
56	KOCH D W , SCHNABEL L V , ELLIS I M , et al. TGF-β2 enhances expression of equine bone marrow-derived mesenchymal stem cell paracrine factors with known associations to tendon healing[J]. Stem Cell Res Ther, 2022, 13 (1): 477. doi: 10.1186/s13287-022-03172-9
57	HAGA M , ⅡDA K , OKADA M . Positive and negative feedback regulation of the TGF-β1 explains two equilibrium states in skin aging[J]. iScience, 2024, 27 (5): 109708. doi: 10.1016/j.isci.2024.109708

样品序号 Sample number	蛋白质浓度/(μg·μL^-1) Protein concentration	终体积/μL Volume	蛋白总量/μg Total protein
H1	7.37	100	737
H2	7.19	100	719
H3	7.23	100	723
H4	7.03	100	703
H5	5.26	100	526
H6	5.56	100	556
H7	7.81	100	781
H8	7.42	100	742
H9	7.66	100	766
H10	7.13	100	713
M1	5.69	100	569
M2	6.41	100	641
M3	7.67	100	767
M4	7.18	100	718
M5	7.33	100	733
M6	7.46	100	746
M7	7.00	100	700
M8	6.46	100	646
M9	6.55	100	655
M10	6.35	100	635
X1	5.09	100	509
X2	6.04	100	604
X3	6.56	100	656
X4	6.25	100	625
X5	6.34	100	634
X6	7.52	100	752
X7	7.74	100	774

编号 No.	序列 Sequence	缩写 Abbreviation	蛋白名称 Protein name	物种 Species	H vs. M变化倍数 Fold change	H vs. X变化倍数 Fold change	M vs. X变化倍数 Fold change
1	PGGDTIFGR	HINT1	组氨酸三联体核苷酸结合蛋白1	梅花鹿茸	0.80	—	—
2	ASSSSAAAAAASSSASCSR	CKAP4	细胞骨架相关蛋白4	梅花鹿茸	—	—	—
3	SLAEVAEQLLDR	B3AT	阴离子转运蛋白(带3)	梅花鹿茸	0.52	0.56	—
4	DNLLPVLLLK	B3AT	阴离子转运蛋白(带3)	梅花鹿茸	0.52	0.56	—
5	ACTILLR	CCT3	T复合物蛋白1亚基γ	梅花鹿茸	0.80	—	—
6	TSTGSTSASTTVAATGSK	CLIP2	含CAP-Gly结构域的接头蛋白2	梅花鹿茸	0.85	—	—
7	AFEPYFEILEAYSTK	SGPL1	鞘氨醇-1-磷酸裂解酶1	梅花鹿茸	—	—	—
8	GLGAGAGAGEESPAACLPR	PGRMC2	膜相关孕激素受体2	马鹿茸	—	1.47	—
9	NNVDSVSQTSSSTFQYITLLK	FGB	纤维蛋白原β链	赤鹿茸	0.69	—	—
10	GVLIDTSR	HEXB	氨基己糖苷酶B	赤鹿茸	1.20	1.15	—
11	ALDELLQASHDAGR	PTX3	五聚蛋白3	赤鹿茸	—	—	—
12	QVTPQHTFR	CFH	补体因子H	赤鹿茸	0.72	0.67	—
13	GIPDDVDAALALPAHNYNSR	VTN	玻连蛋白	赤鹿茸	—	—	—
14	MELLAYLLGEK	GSTK1	谷胱甘肽S转移酶K1	赤鹿茸	—	1.33	—
15	VQASTAMGSPK	TN	腱生蛋白	赤鹿茸	1.14	—	—
16	CTCEMETLISMLQIPR	LRRC17	富亮氨酸重复序列蛋白17	赤鹿茸	0.61	0.57	—
17	SAGAASAADHGAPGVAPAQHSLGPGR	LAGE3	EKC/KEOPS复合体亚基	赤鹿茸	—	—	—
18	AEQVEGVINLGNTLVDR	SPTA1	血影蛋白α链	赤鹿茸	0.41	0.46	—

蛋白质名称 Protein name	H vs. M变化倍数 H vs. M fold change	H vs. X变化倍数 H vs. X fold change	M vs. X变化倍数 M vs. X fold change
CYP1B1	0.49	0.55	—
ATG12	2.22	2.01	—
GSTA1	1.54	2.47	1.60
GSTA2	1.50	2.90	1.92
GSTA4	3.65	3.50	—
GSTM1	0.43	0.63	—
GSTM3	0.34	0.36	—
FMOD	3.00	2.12	—
DCN	2.15	1.53	—
TGF-β2	2.91	2.53	—
THBS1	—	—	—

[1]	LIU Yuxin, CHEN Si, GAO Yang, GU Deyuan, PENG Haitao, ZHANG Dong, ZHANG Ru, XU Huihui, LIU Yaqiao, YANG Yanling. Proteomic Analysis and Immunogenicity Evaluation of Outer Membrane Vesicles of Brucella melitensis [J]. Acta Veterinaria et Zootechnica Sinica, 2025, 56(7): 3378-3389.
[2]	HOU Zhongyi, WANG Baowei, ZHANG Ming'ai, KONG Min, ZHANG Jing, WANG Binghan, YUE Bin, LU Xiu, FAN Wenlei. The Regulation Mechanism of Lipid Metabolism in Foie Gras Formation Based on Proteomics Analysis [J]. Acta Veterinaria et Zootechnica Sinica, 2025, 56(5): 2182-2193.
[3]	ZHANG Xinrui, FU Yu, YANG Zhuo, SHEN Wenjuan, TAO Jinzhong. Study of Early Pregnancy Diagnostic Proteins in Dairy Cows [J]. Acta Veterinaria et Zootechnica Sinica, 2024, 55(2): 451-460.
[4]	Zhou YU, Baigao YANG, Chongyang LI, Peipei ZHANG, Jianhua CAO, Yifan NIU, Guangsheng QIN, Xueming ZHAO. DIA Quantitative Proteomics Analysis of Buffalo Saliva at Different Estrus Stages [J]. Acta Veterinaria et Zootechnica Sinica, 2024, 55(11): 5072-5084.
[5]	YAO Ying, ZHOU Yingcong, DU Peiyan, LI Yijuan, QIAN Wenjie, LI Liuyang, YU Zhipeng, CUI Yan, YU Sijiu, FAN Jiangfeng. Proteomic Analysis of Yak Serum During Pregnancy Based on TMT Technology [J]. Acta Veterinaria et Zootechnica Sinica, 2024, 55(1): 192-206.
[6]	HE Wenfeng, LI Chen, CHANG Hongtao, LI Longxi, CHEN Jing, YANG Guoqing, LIU Huimin. Screening and Identifying of Host Proteins that Inhibit Pseudorabies Virus Replication [J]. Acta Veterinaria et Zootechnica Sinica, 2023, 54(3): 1177-1186.
[7]	YAN Shuo, ZHAO Shanshan, ZHU Zhendong, PAN Qingjie, DONG Huansheng. Study on Nuclear-plasma Transporter KPNA4 of Sheep Sperm Cell [J]. Acta Veterinaria et Zootechnica Sinica, 2022, 53(7): 2194-2201.
[8]	QI Mengfan, XIE Su, GAO Ruonan, SUN Yishan, SUN Xiaomei, HE Junfei, LU Huiwen, LU Shihao, CHEN Xin, LI Qingchun, HUANG Tao. Identification of Differentially Expressed Proteins in Blood of Sows at Early Pregnancy [J]. Acta Veterinaria et Zootechnica Sinica, 2022, 53(4): 1109-1121.
[9]	FU Ming, HE Junjun, ZHU Xingquan, CONG Wei. Proteomic Analysis of Changes in the Mouse Brain Tissue Infected with Toxoplasma gondii Oocysts during the Acute and Chronic Stage [J]. Acta Veterinaria et Zootechnica Sinica, 2022, 53(2): 556-566.
[10]	ZHANG Anrong, WU Zhengke, CHEN Zhimin, CHANG Wenhuan, CAI Huiyi, LIU Guohua, ZHENG Aijuan. Unraveling Molecular Mechanism of Acute Immunological Stress Affecting Meat Quality of Broiler Chickens by Proteomics Analysis [J]. Acta Veterinaria et Zootechnica Sinica, 2021, 52(8): 2138-2150.
[11]	WANG Xinyue, ZHAO Zhida, SHI Tianpei, SHANG Mingyu, ZHANG Li. The Data Analysis of Embryonic Skeletal Muscle Proteomic in Sheep Based on Parallel Reaction Monitoring Technology [J]. Acta Veterinaria et Zootechnica Sinica, 2020, 51(7): 1587-1596.
[12]	PENG Mengling, HU Wenye, LI Naixin, WANG Juhua, DING Jianping, ZHOU Jie. The Changes of Hepatic Proteins during Chicken Embryonic Development Based on Proteomics Analysis [J]. Acta Veterinaria et Zootechnica Sinica, 2020, 51(2): 252-259.
[13]	ZHAO Chang, ZHANG Jiang, BAI Yunlong, SUN Shuhan, SONG Yuxi, XIA Cheng. Analysis of Serum Differential Proteins in Cows with Inactive Ovaries Based on iTRAQ Technology [J]. ACTA VETERINARIA ET ZOOTECHNICA SINICA, 2019, 50(5): 972-982.
[14]	ZHOU Yucheng, GUO Mengnan, CHENG Shipeng, ZHANG Haiwei, ZHOU Manli, QIAO Lianjiang, YANG Yanling. Differential Analysis of Ubiquitination Modification of Host Immune-related Proteins after Brucella 16M Infection [J]. ACTA VETERINARIA ET ZOOTECHNICA SINICA, 2019, 50(11): 2290-2301.
[15]	XU Meng-fei, LU Ping-ping, MA Xun, ZHANG Yan-yan, WANG Wei-ye, MENG Ji-meng, WANG Zheng-rong, BO Xin-wen. Advances in Echinococcus granulosus Proteomics [J]. ACTA VETERINARIA ET ZOOTECHNICA SINICA, 2018, 49(3): 466-476.

Comparative Proteomics Analysis and Screening of Candidate Characteristic Peptides of Sika Deer Velvet Antler, Red Deer Velvet Antler and New Zealand Red Deer Velvet Antler

RichHTML

PDF (PC)

Knowledge

Abstract

Cite this article

share this article

Figures/Tables 14

References 57

Related Articles 15

Recommended Articles

Metrics

Comments