Development of a PCR-based assay to differentiate Cervus elaphus sibiricus from Cervus antlers
详细信息 查看全文
- 作者:Young Hwa Kim (1)
Jae Woong Lee (1)
Sungwook Chae (1)
Sang Ho Moon (2)
Eui Jeong Do (3)
Seung Eun Oh (3)
Gui Jun Zhang (4)
Mi Young Lee (1)
1. KM-Based Herbal Drug Development Group ; Korea Institute of Oriental Medicine ; 1672 Yuseongdae-ro ; Yuseong-gu ; Daejeon ; 305-811 ; Republic of Korea
2. Division of Food Bioscience ; Konkuk University ; 268 Chungwondae-ro ; Chungju-si ; Chungbuk ; 380-701 ; Republic of Korea
3. Department of Biological Sciences ; Konkuk University ; 120 Neungdong-ro ; Gwangiin-gu ; Seoul ; 143-701 ; Republic of Korea
4. School of Chinese Materia Medica ; Beijing University of Chinese Medicine ; No.6 Wang Jing Zhong Huan ; Nan Lu ; Chaoyang District ; Beijing ; 100102 ; China - 关键词:Agarose gel electrophoresis ; Cervus antlers ; Cervus elaphus sibiricus ; Differentiation ; D ; loop region ; Mitochondrial DNA
- 刊名:Journal of the Korean Society for Applied Biological Chemistry
- 出版年:2015
- 出版时间:February 2015
- 年:2015
- 卷:58
- 期:1
- 页码:61-66
- 全文大小:665 KB
- 参考文献:1. Baranova, AI, Kholodova, MV, Davydov, AV, Rozhkov, I (2012) Polymorphism of the mtDNA control region in wild reindeer Rangifer tarandus (Mammalia: Artiodactyla) from the European part of Russia. Genetika 48: pp. 1098-1104
2. Bottero, MT, Dalmasso, IA, Nucera, D, Turi, RM, Rosati, S, Squadrone, S, Goria, M, Civera, T (2003) Development of a PCR assay for the detection of animal tissues in ruminant feeds. J Food Prot 66: pp. 2307-2312
Pharmacopoeia of the People鈥檚 Republic of China. China Medical Science and Technology Press, China
3. Dai, TY, Wang, CH, Chen, KN, Huang, IN, Hong, WS, Wang, SY, Chen, YP, Kuo, SY, Chen, MJ (2011) The antiinfective effects of velvet antler of Formosan sambar deer (Cervus unicolor swinhoei) on Staphylococcus aureus-infected mice. Evid Based Complement Altern Med.
4. Dalmasso, A, Fontanella, E, Piatti, P, Civera, T, Rosati, S, Bottero, MT (2004) A multiplex PCR assay for the identification of animal species in feedstuffs. Mol Cell Probes 18: pp. 81-87 CrossRef
5. Han, DS, Kim, YC, Kim, JW, Hur, H (1994) In Cervi Parvum Cornu-paper collection for production, constituents, pharmacology and clinical application. Hallymwon, Korea
6. Hong, ND, Won, DH, Kim, NJ, Chang, SY, Youn, WG, Kim, HS (1991) Studies on the analysis of constituents of deer horn (I). Assay of trace elements and TLC pattern analysis of gangliosides. Korean J Pharmacogn 22: pp. 171-182
7. Hong, ND, Won, DH, Kim, NJ, Chang, SY, Youn, WG, Kim, HS (1993) Studies on the analysis of constituents of deer horn (II). Analysis of gangliosides and free amino acids. Korean J Pharmacogn 24: pp. 38-46
8. Kim, KS, Choi, YH, Kim, KH, Lee, YC, Kim, CH, Moon, SH, Kang, SG, Park, YG (2004) Protective and anti-arthritic effects of deer antler aqua-acupuncture (DAA), inhibiting dihydroorotate dehydrogenase, on phosphate ions-mediated chondrocyte apoptosis and rat collagen-induced arthritis. Int Immunopharmacol 4: pp. 963-973 4.04.010" target="_blank" title="It opens in new window">CrossRef
9. Kim, ES, Kim, YH, Ko, BS, Oh, SE, Do, EJ, Lee, MY (2012) Multiplex polymerase chain reaction (PCR) and fluorescence-based capillary electrophoresis for identification of deer species from antlers. Afr J Biotechnol 11: pp. 3079-3086
10. Kim, JH, Yang, YI, Ahn, JH, Lee, JG, Lee, KT, Choi, JH (2012) Deer (Cervus elaphus) antler extract suppresses adhesion and migration of endometriotic cells and regulates MMP-2 and MMP-9 expression. J Ethnopharmacol 140: pp. 391-397 CrossRef
11. Kim, YH, Kim, ES, Ko, BS, Oh, SE, Ryuk, JA, Chae, SW, Lee, HW, Choi, GY, Seo, DW, Lee, MY (2012) A PCR-based assay for discriminating Cervus and Rangifer (Cervidae) antlers with mitochondrial DNA polymorphisms. J Anim Sci 90: pp. 2075-2083 4421" target="_blank" title="It opens in new window">CrossRef
The Korean Herbal Pharmacopoeia. Korea Food & Drug Administration, Korea
12. Kuo, CY, Wang, T, Dai, TY, Wang, CH, Chen, KN, Chen, YP, Chen, MJ (2012) Effect of the velvet antler of Formosan sambar deer (Cervus unicolor swinhoei) on the prevention of an allergic airway response in mice. Evid Based Complement Altern Med.
13. Lee, MR, Yun, BS, Zhang, DL, Liu, L, Wang, Z, Wang, CL, Gu, LJ, Wang, CY, Mo, EK, Ly, SY, Sung, C (2010) Effect of aqueous antler extract on scopolamine-induced memory impairment in mice and antioxidant activities. Food Sci Biotechnol 19: pp. 655-661 CrossRef
14. Oh, SJ, Kim, TH, Yoon, DH, Park, EW, Lee, HY, Cheong, IC, Thak, YT, Kim, KN, Han, JY (2000) A study on genotype frequencies of the bovine melanocortin receptor 1 (MCa1R) in cattle breeds. J Anim Sci Technol (Korean) 42: pp. 735-744
15. Polziehn, RO, Strobeck, C (1998) Phylogeny of wapiti, red deer, sika deer, and other North American cervids as determined from mitochondrial DNA. Mol Phylogenet Evol 10: pp. 249-258 CrossRef
16. Polziehn, RO, Strobeck, C (2002) A phylogenetic comparison of red deer and wapiti using mitochondrial DNA. Mol Phylogenet Evol 22: pp. 342-356 CrossRef
17. Polziehn, RO, Hamr, J, Mallory, FF, Strobeck, C (1998) Phylogenetic status of North American wapiti (Cervus elaphus) subspecies. Can J Zool 76: pp. 998-1010 CrossRef
18. Shah, SR, DesJardins, JD, Blob, RW (2008) Antler stiffness in caribou (Rangifer tarandus): testing variation in bone material properties between males and females. Zoology 111: pp. 476-482 CrossRef
19. Shim, YH, Seong, RS, Kim, DS, Kang, SJ, Chang, SY, Kim, HJ (2011) Utilization of real-time PCR to detect Rangifer Cornu contamination in Cervi Parvum Cornu. Arch Pharm Res 34: pp. 237-244 CrossRef
20. Sunwoo, HH, Sim, JS Morphological, chemical, and molecular characteristics of active components in velvet antlers for biomedicine and nutraceuticals. In: Sim, JS, Sunwoo, HH, Hudson, RJ, Jeon, BT eds. (2001) Antler science and product technology. ASPT Center, University of Alberta, Canada, pp. 111-134
21. Yoo, HS, Lee, GN, Lee, JS (2010) Molecular identification of deer antlers using nucleotide sequences of mitochondrial displacement loop region. J Life Sci 20: pp. 1859-1866 CrossRef
22. Zha, DM, Xing, XM, Yang, FH (2011) Rapid identification of deer products by multiplex PCR assay. Food Chem 129: pp. 1904-1908 41" target="_blank" title="It opens in new window">CrossRef
23. Zvycha默naia, E, Danilkin, AA, Kholodova, MV, Sipko, TP, Berber, AP (2011) Analysis of the variability of the control region and cytochrome b gene of mtDNA of Capreolus pygargus Pall. Izv Akad Nauk Ser Biol 5: pp. 511-517 - 刊物主题:Applied Microbiology; Bioorganic Chemistry; Biological Techniques;
- 出版者:Springer Netherlands
- ISSN:2234-344X
文摘
Deer antlers (Cervi Parvum Cornu) are reported to possess various pharmacological properties, including anti-infective, anti-arthritic, anti-allergic, and anti-endometriotic properties, and are credited with reversing memory impairment. To determine the global distribution of Cervus subspecies by analyzing antlers, 166 samples of Cervus subspecies antlers were collected from Russia, Canada, China, New Zealand, and Korea. The respective deer subspecies were identified by amplifying the D-loop region of mitochondrial DNA isolated from the antler samples. On the basis of the mitochondrial DNA sequence, a C. elaphus sibiricus-specific primer was developed that differentiates C. e. sibiricus from four C. e. subspecies (C. e. manitobensis, C. e. nelsoni, C. e. canadensis, and C. e. bactrianus), C. elaphus, and C. nippon. This was confirmed using agarose gel electrophoresis. This primer set produced a specific 396-bp fragment that amplified only C. e. sibiricus in antler samples. A 468-bp fragment derived from the cytochrome b gene was used as the internal control to verify the success of amplification in all samples. This method may assist in rapid and effective differentiation between products from Cervus species and other deer products.