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鹿科动物资源丰富,其采食特点和消化特性存在种间差异。作为反刍动物,鹿科动物的生长发育、生理过程和生产性能与瘤胃微生物密切相关。研究表明,遗传因素与环境条件影响鹿科动物瘤胃微生物的组成,瘤胃微生物与鹿科动物对纤维物质利用和甲烷排放等相关。对鹿科动物分类和分布,采食习性以及瘤胃微生物的影响因素和生物学功能进行综述,以期为鹿科动物瘤胃微生态研究提供参考。
Abstract:The resources of Cervicidae are abundant, and their feeding and digestion characteristics are different among species. As ruminants, the growth, development, physiological process and production performance of deer are closely related to rumen microorganisms. Studies have shown that genetic factors and environmental conditions affect the composition of rumen microorganisms in deer, and rumen microorganisms are related to substance utilization and methane emission in deer.In this paper, the classification, distribution, feeding habits, factors affecting rumen microorganisms and their biological functions were reviewed, in order to provide reference for rumen microecology research of deer.
[1]刘汇涛,董依萌,王磊,等.中国鹿类动物分类及系统进化研究进展[J].野生动物学报,2017, 38(3):514-523.
[2]张鹏卜.中国鹿科动物与人类社会关系演变研究综述[J].古今农业,2022(3):127-136.
[3]盛和林.中国鹿类动物[M].上海:华东师范大学出版社,1992, 1-251.
[4] Gilbert C, Ropiquet A, Hassanin A. Mitochondrial and nuclear phylogenies of Cervidae(Mammalia, Ruminantia):Systematics,morphology, and biogeography[J]. Molecular Phylogenetics and Evolution, 2006, 40(1):101-117.
[5]巴恒星,胡鹏飞,李春义.鹿科动物基因组学研究进展[J].遗传,2021, 43(4):308-322.
[6] Simpson G G. The principles of classification and a classification of mammal[J]. American Museum of Natural History,1945, 85(3):1-307.
[7] Musser G G, Koopman K F, Corbet G B,et al. The mammals of the Indomalayan region:A systematic review[J]. Journal of Mammalogy, 1994, 75(3):799.
[8]李明,盛和林,玉手英利,等.麝、獐、麂和鹿间线粒体DNA的差异及其系统进化研究[J].兽类学报,1998, 18(3):184-191.
[9]何森,曹新芳,郑雪莉,等.宏基因组测序分析野生林麝瘤胃、小肠和大肠微生物组成和抗生素抗性基因[J].动物营养学报,2021, 33(1):484-493.
[10]吴家炎,王伟.中国白唇鹿[M].北京:中国林业出版社,1999:31-68.
[11] Dhakal T, Kim T S, Kim S H, et al. Distribution of sika deer(Cervus nippon)and the bioclimatic impact on their habitats in South Korea[J]. Scientific Reports, 2023, 13(1):19040.
[12] Ludt C J, Schroeder W, Rottmann O, et al. Mitochondrial DNA phylogeography of red deer(Cervus elaphus)[J]. Molecular Phylogenetics and Evolution, 2004, 31(3):1064-1083.
[13] Carrier A, Prunier J, Poisson W, et al. Design and validation of a 63K genome-wide SNP-genotyping platform for caribou/reindeer(Rangifer tarandus)[J]. BMC Genomics, 2022,23(1):687.
[14] Ohtaishi N, Gao Y T. A review of the distribution of all species of deer(Tragulidae, Moschidae and Cervidae)in China[J].Mammal Review, 1990, 20(2/3):125-144.
[15] Zhai J C, Liu W S, Yin Y J, et al. Analysis on genetic diversity of reindeer(Rangifer tarandus)in the greater khingan mountains using microsatellite markers[J]. Zoological Studies, 2017, 56:e11.
[16] Wang S N, Zhai J C, Liu W S, et al. Origins of Chinese reindeer(Rangifer tarandus)based on mitochondrial DNA analyses[J]. PLoS One, 2019, 14(11):e0225037.
[17] Hofmann R R. Evolutionary steps of ecophysiological adaptation and diversification of ruminants:A comparative view of their digestive system[J]. Oecologia, 1989, 78(4):443-457.
[18]支晓亮.东北地区驼鹿(Alces alces)种群现状及栖息地时空动态变化研究[D].哈尔滨:东北林业大学,2023.
[19] Li Z Z, Khattak R H, Han X Z, et al. Distribution update of water deer(Hydropotes inermis)and prediction of their potential distribution in Northeast China[J]. Scientific Reports,2023, 13(1):5610.
[20] Li Y, Peng Y X, Li H L, et al. Prediction of range expansion and estimation of dispersal routes of water deer(Hydropotes inermis)in the transboundary region between China, the Russian Far East and the Korean Peninsula[J]. PLoS One, 2022,17(4):e0264660.
[21]钱文熙,高秀华.茸鹿营养需要量及其消化生理特性研究进展[J].动物营养学报,2020, 32(10):4770-4778.
[22] Pope P B, MacKenzie A K, Gregor I, et al. Metagenomics of the Svalbard reindeer rumen microbiome reveals abundance of polysaccharide utilization loci[J]. PLoS One, 2012, 7(6):e38571.
[23] Li Z P, Liu H L, Li G Y, et al. Molecular diversity of rumen bacterial communities from tannin-rich and fiber-rich forage fed domestic sika deer(Cervus nippon)in China[J]. BMC Microbiology, 2013, 13(1):151.
[24] Miltko R, Kowalik B, Majewska M P, et al. The effect of Protozoa on the bacterial composition and hydrolytic activity of the roe deer rumen[J]. Animals, 2020, 10(3):467.
[25] Eto M, Yahara T, Kuroiwa A, et al. Dynamics of rumen microbiome in sika deer(Cervus nippon yakushimae)from unique subtropical ecosystem in Yakushima Island, Japan[J]. Scientific Reports, 2022, 12(1):21623.
[26]李志鹏.梅花鹿瘤胃微生物多样性与优势菌群分析[D].北京:中国农业科学院,2013.
[27] Li Z P, Wang X X, Zhang T, et al. Heterogeneous development of methanogens and the correlation with bacteria in the rumen and cecum of sika deer(Cervus nippon)during early life suggest different ecology relevance[J]. BMC Microbiology, 2019, 19(1):129.
[28]鲍坤.共轭亚油酸对育成梅花鹿生长、能量代谢及鹿茸品质影响的研究[D].北京:中国农业科学院,2021.
[29] Kittelmann S, Janssen P H. Characterization of rumen ciliate community composition in domestic sheep, deer, and cattle,feeding on varying diets, by means of PCR-DGGE and clone libraries[J]. FEMS Microbiology Ecology, 2011, 75(3):468-481.
[30] Svartstr?m O, Alneberg J, Terrapon N, et al. Ninety-nine de novo assembled genomes from the moose(Alces alces)rumen microbiome provide new insights into microbial plant biomass degradation[J]. The ISME Journal, 2017, 11(11):2538-2551.
[31] Yamano H, Ichimura Y, Sawabe Y, et al. Seasonal differences in rumen bacterial flora of wild Hokkaido sika deer and partial characterization of an unknown bacterial group possibly involved in fiber digestion in winter[J]. Animal Science Journal, 2019, 90(6):790-798.
[32] Dailey R N, Montgomery D L, Ingram J T, et al. Toxicity of the lichen secondary metabolite(+)-usnic acid in domestic sheep[J]. Veterinary Pathology, 2008, 45(1):19-25.
[33] Cook W E, Raisbeck M F, Cornish T E, et al. Paresis and death in elk(Cervus elaphus)due to lichen intoxication in Wyoming[J]. Journal of Wildlife Diseases, 2007, 43(3):498-503.
[34] Nikula A, Matala J, Hallikainen V, et al. Modelling the effect of moose Alces alces population density and regional forest structure on the amount of damage in forest seedling stands[J].Pest Management Science, 2021, 77(2):620-627.
[35] Cederlund G, Nystr?m A. Seasonal differences between moose and roe deer in ability to digest browse[J]. Ecography, 1981, 4(1):59-65.
[36] Lee S K, Woo C, Lee E J, et al. Using high-throughput sequencing to investigate the dietary composition of the Korean water deer(Hydropotes inermis argyropus):A spatiotemporal comparison[J]. Scientific Reports, 2022, 12:22271.
[37]丁玉华.中国麋鹿研究[M].长春:吉林科学技术出版社,2004.
[38] Gebert C, Verheyden-Tixier H. Variations of diet composition of red deer(Cervus elaphus L.)in Europe[J]. Mammal Review, 2001, 31(3/4):189-201.
[39]盛和林,刘志霄.中国麝科动物[M].上海:上海科学技术出版社,2007.
[40] Cornelis J, Casaer J, Hermy M. Impact of season, habitat and research techniques on diet composition of roe deer(Capreolus capreolus):A review[J]. Journal of Zoology, 1999,248(2):195-207.
[41]王晟楠.鹿科动物胃内微生物菌群结构及其功能分析[D].哈尔滨:东北林业大学,2020.
[42]?stbye K, Wilson R, Rudi K. Rumen microbiota for wild boreal cervids living in the same habitat[J]. FEMS Microbiology Letters, 2016, 363(20):233.
[43] Kim J H, Hong S W, Park B Y, et al. Characterisation of the bacterial community in the gastrointestinal tracts of elk(Cervus canadensis)[J]. Antonie Van Leeuwenhoek, 2019,112(2):225-235.
[44] Li Z P, Wang X X, Zhang T, et al. The development of microbiota and metabolome in small intestine of Sika Deer(Cervus nippon)from birth to weaning[J]. Frontiers in Microbiology, 2018, 9:4.
[45] Zhao G J, Ma T Y, Tang W J, et al. Gut microbiome of Chinese forest musk Deer examined across gender and age[J].BioMed Research International, 2019, 2019:9291216.
[46] Guo J H, Jin Y C, Tian X M, et al. Diet-induced microbial adaptation process of red deer(Cervus elaphus)under different introduced periods[J]. Frontiers in Microbiology, 2022,13:1033050.
[47] Ishaq S L, Wright A D. High-throughput DNA sequencing of the ruminal bacteria from moose(Alces alces)in Vermont,Alaska, and Norway[J]. Microbial Ecology, 2014, 68(2):185-195.
[48] Ilina L A, Filippova V A, Brazhnik E A, et al. The comparative analysis of the ruminal bacterial population in reindeer(Rangifer tarandus L.)from the Russian Arctic zone:Regional and seasonal effects[J]. Animals, 2021, 11(3):911.
[49] Xing X M, Ai C, Wang T J, et al. The first high-quality reference genome of sika deer provides insights into high-tannin adaptation[J]. Genomics, Proteomics&Bioinformatics,2023, 21(1):203-215.
[50] Wu Y, Guo X L, Zhao D H, et al. Effect of methionine supplementation on serum metabolism and the rumen bacterial community of sika deer(Cervus nippon)[J]. Animals, 2022,12(15):1950.
[51] Zhen J N, Ren Y J, Zhang H D, et al. Effect of different dietary regimes on the gut microbiota and fecal metabolites of Père david's deer[J]. Animals, 2022, 12(5):584.
[52] Li Z P, Wright A D G, Liu H L, et al. Bacterial community composition and fermentation patterns in the rumen of sika deer(Cervus nippon)fed three different diets[J]. Microbial Ecology, 2015, 69(2):307-318.
[53]穆瑞娜,韩雨,李松泽,等.鹿类动物消化道微生物组研究进展[J].经济动物学报,2022, 26(2):146-153.
[54] Wong M T, Wang W J, Couturier M, et al. Comparative metagenomics of cellulose-and poplar hydrolysate-degrading microcosms from gut microflora of the Canadian beaver(Castor canadensis)and North American moose(Alces americanus)after long-term enrichment[J]. Frontiers in Microbiology, 2017, 8:2504.
[55] Si H Z, Liu H L, Nan W X, et al. Effects of arginine supplementation on serum metabolites and the rumen bacterial community of sika deer(Cervus nippon)[J]. Frontiers in Veterinary Science, 2021, 8:630686.
[56] Seshadri R, Leahy S C, Attwood G T, et al. Cultivation and sequencing of rumen microbiome members from the Hungate1 000 Collection[J]. Nature Biotechnology, 2018, 36(4):359-367.
[57] Qian W X, Li Z P, Ao W P, et al. Bacterial community composition and fermentation in the rumen of Xinjiang brown cattle(Bos taurus), Tarim red deer(Cervus elaphus yarkandensis), and Karakul sheep(Ovis aries)[J]. Canadian Journal of Microbiology, 2017, 63(5):375-383.
[58] Purushe J, Fouts D E, Morrison M, et al. Comparative genome analysis of Prevotella ruminicola and Prevotella bryantii:Insights into their environmental niche[J]. Microbial Ecology,2010, 60(4):721-729.
[59]关鹏,任建刚,黄建智,等.不同中性洗涤纤维水平饲粮对塔里木马鹿瘤胃微生物种群结构的影响[J].动物营养学报,2023, 35(2):1206-1218.
[60] Sun W L, Shi H P, Gong C Y, et al. Effects of different yeast selenium levels on rumen fermentation parameters, digestive enzyme activity and gastrointestinal microflora of sika deer during antler growth[J]. Microorganisms, 2023, 11(6):1444.
[61] Solomon K V, Haitjema C H, Henske J K, et al. Earlybranching gut fungi possess a large, comprehensive array of biomass-degrading enzymes[J]. Science, 2016, 351(6278):1192-1195.
[62] Xie X, Yang C L, Guan L L, et al. Persistence of cellulolytic bacteria Fibrobacter and Treponema after short-term corn stover-based dietary intervention reveals the potential to improve rumen fibrolytic function[J]. Frontiers in Microbiology,2018, 9:1363.
[63] Ishaq S L, Kim C J, Reis D, et al. Fibrolytic bacteria isolated from the rumen of North American moose(Alces alces)and their use as a probiotic in neonatal lambs[J]. PLoS One,2015, 10(12):e0144804.
[64]吴家劲,朱森林,周密,等.奶牛瘤胃微生物研究进展和趋势[J].生物技术通报,2020, 36(2):27-38.
[65]宋阳,沈维军,万发春,等.日粮因素对瘤胃微生物多样性影响及调控的研究进展[J].经济动物学报,2023,27(4):290-296.
[66] Hill J, McSweeney C, Wright A D G, et al. Measuring methane production from ruminants[J]. Trends in Biotechnology,2016, 34(1):26-35.
[67] Na Y, Li D H, Choi Y, et al. Effects of feeding level on nutrient digestibility and enteric methane production in growing goats(Capra hircus hircus)and sika deer(Cervus nippon hortulorum)[J]. Asian-Australasian Journal of Animal Sciences, 2018, 31(8):1238-1243.
[68] Sun Y W, Sun Y J, Shi Z H, et al. Gut microbiota of wild and captive alpine musk deer(Moschus chrysogaster)[J].Frontiers in Microbiology, 2020, 10:3156.
[69] Pérez-Barbería F J, Mayes R W, Giráldez J, et al. Ericaceous species reduce methane emissions in sheep and red deer:Respiration chamber measurements and predictions at the scale of European heathlands[J]. The Science of the Total Environment, 2020, 714:136738.
[70] Li X H, Liu C, Chen Y X, et al. Effects of mineral salt supplement on enteric methane emissions, ruminal fermentation and methanogen community of lactating cows[J]. Animal Science Journal, 2017, 88(8):1049-1057.
[71] Wang M M, Ren C H, Wang P H, et al. Microbiome-metabolome reveals the contribution of the gut-testis axis to sperm motility in sheep(Ovis aries)[J]. Animals, 2023, 13(6):996.
[72] Reinoso-Peláez E L, Saura M, González-Recioó,et al. Impact of oestrus synchronization devices on ewes vaginal microbiota and artificial insemination outcome[J]. Frontiers in Microbiology, 2023, 14:1063807.
[73] Walker M B, Holton M P, Callaway T R, et al. Differences in microbial community composition between uterine horns ipsilateral and contralateral to the corpus luteum in beef cows on day15 of the estrous cycle[J]. Microorganisms, 2023, 11(8):2117.
[74]卫功庆,薛嘉璐,刘舒欣,等.中国梅花鹿种质资源的保护与利用[J].吉林农业大学学报,2022, 44(4):379-385.
[75] Qin T, Zhang G K, Zheng Y, et al. A population of stem cells with strong regenerative potential discovered in deer antlers[J]. Science, 2023, 379(6634):840-847.
[76]李峰.鹿角盘提取物对激素受体阳性乳腺癌模型作用及机制研究[D].长春:吉林大学,2022.
[77] Ny V, Needham T, Ceacero F. Potential benefits of amino acid supplementation for cervid performance and nutritional ecology, with special focus on lysine and methionine:A review[J]. Animal Nutrition, 2022, 11:391-401.
[78]郝林琳,刘松财,张明军,等.鲜马鹿茸不同部位多肽的提取及含量比较[J].吉林农业大学学报,2007, 29(4):378-380, 383.
[79]郝林琳,刘松财,夏青娟,等.鹿茸多肽的生物学活性研究[J].吉林农业大学学报,2006, 28(3):285-288.
[80]司华哲.饲粮添加精氨酸对梅花鹿产茸性能及其机理研究[D].长春:吉林农业大学,2021.
[81]吴炎.蛋氨酸水平对生茸期梅花鹿生产性能、血清生化和胃肠道菌群的影响[D].北京:中国农业科学院,2023.
[82]史鸿鹏.酵母硒水平对生茸期梅花鹿营养消化吸收及鹿茸硒蛋白表达的影响[D].北京:中国农业科学院,2021.
[83]史鸿鹏,陈丽红,司华哲,等.不同硒添加量对生茸期梅花鹿生产性能、营养物质表观消化率及血清生化指标的影响[J].动物营养学报,2021, 33(4):2235-2244.
基本信息:
DOI:10.13326/j.jea.2024.1929
中图分类号:S825
引用信息:
[1]周雅琳,刘晗璐.鹿科动物瘤胃微生物研究进展[J].经济动物学报,2024,28(02):79-85+76.DOI:10.13326/j.jea.2024.1929.
基金信息:
内蒙古自治区科技计划项目(2022YFDZ0072)