Biotechnology Bulletin ›› 2021, Vol. 37 ›› Issue (9): 86-94.doi: 10.13560/j.cnki.biotech.bull.1985.2021-0831
Previous Articles Next Articles
MAO Ting1(), NIU Yong-yan1, ZHENG Qun1, YANG Tao1, MU Yong-song2, ZHU Ying1, JI Bin1, WANG Zhi-ye1()
Received:
2021-06-30
Online:
2021-09-26
Published:
2021-10-25
Contact:
WANG Zhi-ye
E-mail:maotingjiayou@126.com;zhiye_wang@sina.com
MAO Ting, NIU Yong-yan, ZHENG Qun, YANG Tao, MU Yong-song, ZHU Ying, JI Bin, WANG Zhi-ye. Effects of Microbial Inoculants on the Fermentation Quality and Microbial Community Diversity of Alfalfa Silage[J]. Biotechnology Bulletin, 2021, 37(9): 86-94.
项目 Index | 数值 Numeric value |
---|---|
干物质 Dry matter/(g·kg-1 FM) | 382±0.42 |
pH | 6.43±0.25 |
酸性洗涤纤维Acid detergent fiber/(g·kg-1 DM) | 345±1.20 |
中性洗涤纤维Neutral detergent fiber/(g·kg-1 DM) | 452±0.35 |
粗蛋白Crude protein/(g·kg-1 DM) | 206±0.32 |
可溶性碳水化合物 Water soluble carbohydrate/(g·kg-1 DM) | 68.3±0.25 |
Table 1 Chemical composition of fresh alfalfa
项目 Index | 数值 Numeric value |
---|---|
干物质 Dry matter/(g·kg-1 FM) | 382±0.42 |
pH | 6.43±0.25 |
酸性洗涤纤维Acid detergent fiber/(g·kg-1 DM) | 345±1.20 |
中性洗涤纤维Neutral detergent fiber/(g·kg-1 DM) | 452±0.35 |
粗蛋白Crude protein/(g·kg-1 DM) | 206±0.32 |
可溶性碳水化合物 Water soluble carbohydrate/(g·kg-1 DM) | 68.3±0.25 |
时间 Time/d | 添加剂 Silage additive | 干物质 DM/(g·kg-1 FM) | 营养成分/(g·kg-1 DM) | ||||
---|---|---|---|---|---|---|---|
粗蛋白 CP | 可溶性碳水化和物 WSC | 中性洗涤纤维NDF | 酸性洗涤纤维ADF | 木质素 Lignin | |||
30 | YB | 324±0.40e | 253±0.31e | 61.5±0.03cd | 333±0.26c | 286±0.30b | 86±0.52ab |
aFGJ | 323±0.26e | 225±0.25c | 59.7±0.02ab | 359±0.79e | 304±0.15f | 82±0.10ab | |
GSSW | 305±0.58ab | 274±0.06h | 62.8±0.00d | 356±0.30e | 291±0.35cd | 87±0.06b | |
CK | 304±0.21ab | 216.±0.29b | 60.4±0.05bc | 404±0.44h | 300±0.21e | 86±0.13ab | |
50 | YB | 315±0.12d | 246±0.23f | 58.9±0.06ab | 325±0.17b | 263±0.41a | 83±0.05ab |
aFGJ | 311±0.21cd | 215±0.10ab | 58.6±0.03a | 330±0.06bc | 294±0.12d | 82±0.11a | |
GSSW | 304±0.25ab | 269±0.25j | 60.7±0.02bc | 343±0.15d | 287±0.16bc | 86±0.15ab | |
CK | 299±0.12a | 213±0.29ab | 60.1±0.03bcd | 397±0.25j | 292±0.25cd | 87±0.13ab | |
70 | YB | 317±0.20d | 237±0.25d | 62.5±0.01d | 323±0.32b | 260±0.27a | 83±0.14ab |
aFGJ | 315±0.35d | 210±0.12a | 60.6±0.03bc | 333±0.15c | 294±0.31d | 82±0.22a | |
GSSW | 303±0.29ab | 245±0.25f | 67.8±0.21f | 314±0.21a | 284±0.09b | 83±0.16ab | |
CK | 296±0.21a | 208±0.21a | 59.9±0.02bcd | 387±0.31f | 285±0.03b | 86±0.11ab |
Table 2 Effect of time and silage additive on the nutritional quality of alfalfa silage
时间 Time/d | 添加剂 Silage additive | 干物质 DM/(g·kg-1 FM) | 营养成分/(g·kg-1 DM) | ||||
---|---|---|---|---|---|---|---|
粗蛋白 CP | 可溶性碳水化和物 WSC | 中性洗涤纤维NDF | 酸性洗涤纤维ADF | 木质素 Lignin | |||
30 | YB | 324±0.40e | 253±0.31e | 61.5±0.03cd | 333±0.26c | 286±0.30b | 86±0.52ab |
aFGJ | 323±0.26e | 225±0.25c | 59.7±0.02ab | 359±0.79e | 304±0.15f | 82±0.10ab | |
GSSW | 305±0.58ab | 274±0.06h | 62.8±0.00d | 356±0.30e | 291±0.35cd | 87±0.06b | |
CK | 304±0.21ab | 216.±0.29b | 60.4±0.05bc | 404±0.44h | 300±0.21e | 86±0.13ab | |
50 | YB | 315±0.12d | 246±0.23f | 58.9±0.06ab | 325±0.17b | 263±0.41a | 83±0.05ab |
aFGJ | 311±0.21cd | 215±0.10ab | 58.6±0.03a | 330±0.06bc | 294±0.12d | 82±0.11a | |
GSSW | 304±0.25ab | 269±0.25j | 60.7±0.02bc | 343±0.15d | 287±0.16bc | 86±0.15ab | |
CK | 299±0.12a | 213±0.29ab | 60.1±0.03bcd | 397±0.25j | 292±0.25cd | 87±0.13ab | |
70 | YB | 317±0.20d | 237±0.25d | 62.5±0.01d | 323±0.32b | 260±0.27a | 83±0.14ab |
aFGJ | 315±0.35d | 210±0.12a | 60.6±0.03bc | 333±0.15c | 294±0.31d | 82±0.22a | |
GSSW | 303±0.29ab | 245±0.25f | 67.8±0.21f | 314±0.21a | 284±0.09b | 83±0.16ab | |
CK | 296±0.21a | 208±0.21a | 59.9±0.02bcd | 387±0.31f | 285±0.03b | 86±0.11ab |
时间Time /d | 添加剂 Silage additive | pH | 氨氮/总氮 Ammonia nitrogen/Total nitrogen | 挥发性脂肪酸 Volatile fatty acid/(g·kg-1DM) | ||
---|---|---|---|---|---|---|
乳酸 Lactic acid | 乙酸 Acetic acid | 丁酸 Butyric acid | ||||
30 | YB | 5.02±0.02ef | 60.5±0.03a | 42.3±0.01e | 12.4±0.04c | |
aFGJ | 5.13±0.01fg | 63.1±0.03c | 32.9±0.06a | 11.1±0.01b | 0.1±0.01a | |
GSSW | 5.08±0.07e | 59.7±0.05a | 43.2±0.04f | 11.2±0.02b | -- | |
CK | 5.57±0.07i | 69.5±0.07f | 33.4±0.05a | 10.5±0.04a | 0.9±0.12d | |
50 | YB | 4.56±0.02c | 60.3±0.11a | 44.6±0.02h | 18.9±0.04d | -- |
aFGJ | 4.82±0.01d | 63.3±0.01c | 40.2±0.02d | 12.5±0.02c | 0.6±0.05c | |
GSSW | 4.50±0.02b | 61.9±0.06b | 59.8±0.06g | 11.2±0.03b | -- | |
CK | 5.21±0.02h | 72.5±0.12g | 33.2±0.06a | 10.2±0.02a | 1.2±0.04f | |
70 | YB | 4.25±0.01a | 67.2±0.05e | 44.5±0.03h | 20.2±0.03e | -- |
aFGJ | 4.80±0.02d | 65.1±0.01d | 38.7±0.06c | 13.9±0.05f | 0.6±0.02c | |
GSSW | 4.20±0.01a | 64.5±0.03d | 52.3±0.03k | 13.2±0.03g | -- | |
CK | 5.17±0.05gh | 78.5±0.12h | 35.5±0.04b | 11.2±0.01b | 2.0±0.01ab |
Table 3 Effect of time and silage additive on the fermentation quality of alfalfa silage
时间Time /d | 添加剂 Silage additive | pH | 氨氮/总氮 Ammonia nitrogen/Total nitrogen | 挥发性脂肪酸 Volatile fatty acid/(g·kg-1DM) | ||
---|---|---|---|---|---|---|
乳酸 Lactic acid | 乙酸 Acetic acid | 丁酸 Butyric acid | ||||
30 | YB | 5.02±0.02ef | 60.5±0.03a | 42.3±0.01e | 12.4±0.04c | |
aFGJ | 5.13±0.01fg | 63.1±0.03c | 32.9±0.06a | 11.1±0.01b | 0.1±0.01a | |
GSSW | 5.08±0.07e | 59.7±0.05a | 43.2±0.04f | 11.2±0.02b | -- | |
CK | 5.57±0.07i | 69.5±0.07f | 33.4±0.05a | 10.5±0.04a | 0.9±0.12d | |
50 | YB | 4.56±0.02c | 60.3±0.11a | 44.6±0.02h | 18.9±0.04d | -- |
aFGJ | 4.82±0.01d | 63.3±0.01c | 40.2±0.02d | 12.5±0.02c | 0.6±0.05c | |
GSSW | 4.50±0.02b | 61.9±0.06b | 59.8±0.06g | 11.2±0.03b | -- | |
CK | 5.21±0.02h | 72.5±0.12g | 33.2±0.06a | 10.2±0.02a | 1.2±0.04f | |
70 | YB | 4.25±0.01a | 67.2±0.05e | 44.5±0.03h | 20.2±0.03e | -- |
aFGJ | 4.80±0.02d | 65.1±0.01d | 38.7±0.06c | 13.9±0.05f | 0.6±0.02c | |
GSSW | 4.20±0.01a | 64.5±0.03d | 52.3±0.03k | 13.2±0.03g | -- | |
CK | 5.17±0.05gh | 78.5±0.12h | 35.5±0.04b | 11.2±0.01b | 2.0±0.01ab |
[1] |
Wen AY, Yuan XJ, Wang J, et al. Effects of four short-chain fatty acids or salts on dynamics of fermentation and microbial characteristics of alfalfa silage[J]. Animal Feed Sci Technol, 2017, 223:141-148.
doi: 10.1016/j.anifeedsci.2016.11.017 URL |
[2] | Jones DJC. The biochemistry of silage[J]. The Journal of Agricultural Science, 1991, 117(3):386-386. |
[3] | Uher D, Konjačić M, Jareš D, et al. The effect of bacterial inoculant on chemical composition and fermentation of alfalfa silage[J]. J Central Eur Agric, 2019, 20(2):657-664. |
[4] | 王楠, 陈诚轩, 谢鹏, 等. 甜高粱作为反刍动物饲料的最佳收获期的研究[J]. 生物技术通报, 2018, 34(10):100-107. |
Wang N, Chen CX, Xie P, et al. The best harvest time of sweet Sorghum for forge based on biomass and nutritional quality[J]. Biotechnol Bull, 2018, 34(10):100-107. | |
[5] | 俸祥仁, 潘堂峰, 李芳芳, 等. 不同发酵剂对甘蔗叶梢青贮发酵品质的影响[J]. 福建农业科技, 2019(7):29-32. |
Feng XR, Pan TF, Li FF, et al. Effects of different starter cultures on silage fermentation quality of sugarcane tips[J]. Fujian Agric Sci Technol, 2019(7):29-32. | |
[6] |
Fijałkowska M, Przemieniecki SW, Purwin C, et al. The effect of an additive containing three Lactobacillus species on the fermentation pattern and microbiological status of silage[J]. J Sci Food Agric, 2020, 100(3):1174-1184.
doi: 10.1002/jsfa.v100.3 URL |
[7] |
Alhaag H, Yuan XJ, Mala A, et al. Fermentation characteristics of Lactobacillus plantarum and Pediococcus species isolated from sweet Sorghum silage and their application as silage inoculants[J]. Appl Sci, 2019, 9(6):1247.
doi: 10.3390/app9061247 URL |
[8] |
Kuppusamy P, Kim D, Soundharrajan I, et al. Low-carbohydrate tolerant LAB strains identified from rumen fluid:investigation of probiotic activity and legume silage fermentation[J]. Microorganisms, 2020, 8(7):1044.
doi: 10.3390/microorganisms8071044 URL |
[9] |
Guo XS, Undersander DJ, Combs DK. Effect of Lactobacillus inoculants and forage dry matter on the fermentation and aerobic stability of ensiled mixed-crop tall fescue and meadow fescue[J]. J Dairy Sci, 2013, 96(3):1735-1744.
doi: 10.3168/jds.2045-5786 pmid: 23332843 |
[10] |
Li DX, Wang YP, Zhang YC, et al. Evaluation of lactic acid bacteria isolated from alfalfa for silage fermentation[J]. Grassl Sci, 2018, 64(3):190-198.
doi: 10.1111/grs.2018.64.issue-3 URL |
[11] |
Chen L, Li JF, et al. Effects of lactic acid bacteria inoculants and fibrolytic enzymes on the fermentation quality, in vitro degradability, ruminal variables and microbial communities of high-moisture alfalfa silage[J]. Grassl Sci, 2019, 65(4):216-225.
doi: 10.1111/grs.12240 |
[12] |
Suryadi U, Nugraheni YR, Prasetyo AF, et al. Evaluation of effects of a novel probiotic feed supplement on the quality of broiler meat[J]. Vet World, 2019, 12(11):1775-1778.
doi: 10.14202/vetworld. URL |
[13] | 卢强, 撒多文, 都帅, 等. 盐碱地苜蓿青贮品质及微生物群落的研究[J]. 黑龙江畜牧兽医, 2020(2):96-100, 150. |
Lu Q, Sa DW, Du S, et al. Study on the quality and microbial community of alfalfa silage in saline-alkali soil[J]. Heilongjiang Animal Sci Vet Med, 2020(2):96-100, 150. | |
[14] | 包维臣. 苜蓿青贮发酵过程中微生物多样性动态变化及其功能基因组研究[D]. 呼和浩特:内蒙古农业大学, 2019. |
Bao WC. Dynamics variation of microbial diversity and functional geneomics during alfalfa silage fermentation process[D]. Hohhot:Inner Mongolia Agricultural University, 2019. | |
[15] | Xin PC, Huang JH, Yuan XJ, et al. Research on mixed ensiling of alfalfa and whole plant corn[J]. Animal Husbandry & Veterinary Medicine, 2019, 51(4):39-42. |
[16] |
Wang S, Dong Z, Li J, et al. Pediococcus acidilactici strains as silage inoculants for improving the fermentation quality, nutritive value andin vitroruminal digestibility in different forages[J]. J Appl Microbiol, 2019, 126(2):424-434.
doi: 10.1111/jam.14146 pmid: 30383317 |
[17] | Braman WL, Kurtz JE, Bryan KA. Effect of fermented corn silage density and bacterial inoculants on corn silage pH and fermentation end products[J]. J Animal Sci, 2016, 94(S1):27. |
[18] |
Wang Y, Sheng HF, He Y, et al. Comparison of the levels of bacterial diversity in freshwater, intertidal wetland, and marine sediments by using millions of illumina tags[J]. Appl Environ Microbiol, 2012, 78(23):8264-8271.
doi: 10.1128/AEM.01821-12 URL |
[19] |
Wang Y, Chen X, Wang C, et al. The bacterial community and fermentation quality of mulberry(Morus alba)leaf silage with or without Lactobacillus casei and sucrose[J]. Bioresour Technol, 2019, 293:122059.
doi: 10.1016/j.biortech.2019.122059 URL |
[20] | 刘婷, 王腾飞, 罗宽, 等. 苜蓿青贮添加剂研究进展[J]. 饲料研究, 2016(19):12-14, 22. |
Liu T, Wang TF, Luo K, et al. Research progress of alfalfa silage additives[J]. Feed Res, 2016(19):12-14, 22. | |
[21] | 李旺, 马召稳, 李元晓, 等. 苜蓿青贮优势菌种筛选及应用效果[J]. 动物营养学报, 2020, 32(4):1883-1890. |
Li W, Ma ZW, Li YX, et al. Screening and application effects of dominant strains of alfalfa silage[J]. Chin J Animal Nutr, 2020, 32(4):1883-1890. | |
[22] |
Bai J, Xu DM, Xie DM, et al. Effects of antibacterial peptide-producing Bacillus subtilis and Lactobacillus buchneri on fermentation, aerobic stability, and microbial community of alfalfa silage[J]. Bioresour Technol, 2020, 315:123881.
doi: 10.1016/j.biortech.2020.123881 URL |
[23] | Rychen G, Aquilina G, et al. Safety and efficacy of Bacillus amyloliquefaciens(NCIMB 30229)as a silage additive for all animal species[J]. EFSA J, 2017, 15(6):4860. |
[24] |
Li FH, Ding ZT, Adesogan AT, et al. Effects of class IIa bacteriocin-producing Lactobacillus species on fermentation quality and aerobic stability of alfalfa silage[J]. Animals, 2020, 10(9):1575.
doi: 10.3390/ani10091575 URL |
[25] |
Mariotti M, Fratini F, Cerri D, et al. Use of fresh scotta whey as an additive for alfalfa silage[J]. Agronomy, 2020, 10(3):365.
doi: 10.3390/agronomy10030365 URL |
[26] |
Liu QH, Dong ZH, Shao T. Effect of additives on fatty acid profile of high moisture alfalfa silage during ensiling and after exposure to air[J]. Animal Feed Sci Technol, 2018, 236:29-38.
doi: 10.1016/j.anifeedsci.2017.11.022 URL |
[27] |
Edgar RC. UPARSE:highly accurate OTU sequences from microbial amplicon reads[J]. Nat Methods, 2013, 10(10):996-998.
doi: 10.1038/nmeth.2604 URL |
[28] |
Tohno M, Kitahara M, Irisawa T, et al. Lactobacillus silagei sp. nov., isolated from orchardgrass silage[J]. Int J Syst Evol Microbiol, 2013, 63(Pt_12):4613-4618.
doi: 10.1099/ijs.0.053124-0 URL |
[29] |
Zhao SS, Wang YP, Yang FY, et al. Screening a Lactobacillus plantarum strain for good adaption in alfalfa ensiling and demonstrating its improvement of alfalfa silage quality[J]. J Appl Microbiol, 2020, 129(2):233-242.
doi: 10.1111/jam.14604 pmid: 32027450 |
[1] | ZHAO Zhi-xiang, WANG Dian-dong, ZHOU Ya-lin, WANG Pei, YAN Wan-rong, YAN Bei, LUO Lu-yun, ZHANG Zhuo. Control of Pepper Fusarium Wilt by Bacillus subtilis Ya-1 and Its Effect on Rhizosphere Fungal Microbial Community [J]. Biotechnology Bulletin, 2023, 39(9): 213-224. |
[2] | SUN Hai-hang, GUAN Hui-lin, WANG Xu, WANG Tong, LI Hong-lin, PENG Wen-jie, LIU Bo-zhen, FAN Fang-ling. Effects of Biochar on the Soil Properties and Fungal Community Structure under Continuous Cropping of Panax notoginseng [J]. Biotechnology Bulletin, 2023, 39(2): 221-231. |
[3] | CHEN Tian-ci, WU Shao-lan, YANG Guo-hui, JIANG Dan-xia, JIANG Yu-ji, CHEN Bing-zhi. Effects of Ganoderma resinaceum Alcohol Extract on Sleep and Intestinal Microbiota in Mice [J]. Biotechnology Bulletin, 2022, 38(8): 225-232. |
[4] | ZHAO Lin-yan, GUAN Hui-lin, WANG Ke-shu, LU Yan-lei, XIANG Ping, WEI Fu-gang, YANG Shao-zhou, XU Wu-mei. Effects of Soil Moisture on the Microbial Community Under Continuous Cropping of Panax notoginseng [J]. Biotechnology Bulletin, 2022, 38(7): 215-223. |
[5] | ZHONG Hui, LIU Ya-jun, WANG Bin-hua, HE Meng-jie, WU Lan. Effects of Analysis Methods on the Analyzed Results of 16S rRNA Gene Amplicon Sequencing in Bacterial Communities [J]. Biotechnology Bulletin, 2022, 38(6): 81-92. |
[6] | ZHAO Lin-yan, GUAN Hui-lin, XIANG Ping, LI Ze-cheng, BAI Yu-long, SONG Hong-chuan, SUN Shi-zhong, XU Wu-mei. Composition Features of Microbial Community in the Rhizospheric Soil of Bletilla striata with Root Rot [J]. Biotechnology Bulletin, 2022, 38(2): 67-74. |
[7] | GAO Hui-hui, JIA Chen-bo, HAN Qin, SU Jian-yu, XU Chun-yan. Microbiological Mechanism of Root Rot of Lycium barbarum Ningqi-7 [J]. Biotechnology Bulletin, 2022, 38(12): 244-251. |
[8] | CHEN Yu-jie, ZHENG Hua-bao, ZHOU Xin-yan. Modified High-throughput Sequencing Reveals the Effects of Different Algicides towards Algal Community [J]. Biotechnology Bulletin, 2022, 38(11): 70-79. |
[9] | YAN Hui-lin, LU Guang-xin, DENG Ye, GU Song-song, YAN Cheng-liang, MA Kun, ZHAO Yang-an, ZHANG Hai-juan, WANG Ying-cheng, ZHOU Xue-li, DOU Sheng-yun. Effects of Rhizobium Seed Dressing on the Soil Microbial Community of Grass-legume Mixtures in Alpine Regions [J]. Biotechnology Bulletin, 2022, 38(10): 204-215. |
[10] | CAO Xiu-kai, WANG Shan, GE Ling, ZHANG Wei-bo, SUN Wei. Advances in Extrachromosomal Circular DNA and Their Application in Domestic Animal Breeding [J]. Biotechnology Bulletin, 2022, 38(1): 247-257. |
[11] | CHEN Meng-yan, BAI Jie, KE Wen-can, XU Dong-mei, AI Lin, GUO Xu-sheng. Research Advances in Silage Microbial Communities and Functions [J]. Biotechnology Bulletin, 2021, 37(9): 11-23. |
[12] | CUI Xin-yu, LI Rong-rong, CAI Rui, WANG Yan, ZHENG Meng-hu, XU Chun-cheng. Isolation,Identification of Lactic Acid Degrading Bacteria in Alfalfa Silage and Their Degradation Characterization [J]. Biotechnology Bulletin, 2021, 37(9): 58-67. |
[13] | JIANG Fu-gui, CHENG Hai-jian, WEI Chen, ZHANG Zhao-kun, SU Wen-zheng, SHI Guang, SONG En-liang. Effects of Addition Amount of Molasses on the Fermentation Quality and Microbial Diversity of Hybrid Broussonetia papyrifera L. Vent Silage [J]. Biotechnology Bulletin, 2021, 37(9): 68-76. |
[14] | TANG Die, ZHOU Qian. Research Advances in Plant Genome Assembly [J]. Biotechnology Bulletin, 2021, 37(6): 1-12. |
[15] | ZHU Bin, GAN Chen-chen, WANG Hong-cheng. Characteristics of the Complete Chloroplast Genome of Dendrobium thyrsiflorum and Its Phylogenetic Relationship Analysis [J]. Biotechnology Bulletin, 2021, 37(5): 38-47. |
Viewed | ||||||
Full text |
|
|||||
Abstract |
|
|||||