不同填装密度下添加乳酸菌和糖对小麦秸秆黄贮饲料发酵品质及微生物群落的影响

doi:10.12160/j.issn.1672-5190.2024.02.002

畜牧与饲料科学 ›› 2024, Vol. 45 ›› Issue (2): 9-19.doi: 10.12160/j.issn.1672-5190.2024.02.002

不同填装密度下添加乳酸菌和糖对小麦秸秆黄贮饲料发酵品质及微生物群落的影响

李东洋^1,2, 乌尼尔², 娜娜², 孙林^2,3, 杨宝珠⁴, 李鹅^1,2, 薛艳林²

1.宁夏大学林业与草业学院,宁夏银川 750021;
2.青贮饲料微生物资源开发与利用内蒙古自治区工程研究中心/内蒙古自治区农牧业科学院,内蒙古呼和浩特 010031;
3.西华师范大学生命科学学院,四川南充 637002;
4.内蒙古大学,内蒙古呼和浩特 010021

收稿日期:2024-01-31 出版日期:2024-03-30 发布日期:2024-05-06
通讯作者: 薛艳林（1979—）,男,研究员,博士,主要研究方向为饲草料加工贮藏与利用。
作者简介:李东洋（1999—）,男,硕士研究生,主要研究方向为饲草加工贮藏与利用。
基金资助:
内蒙古农牧业青年创新基金项目（2023QNJJM01）; 中央引导地方科技发展资金项目（2022ZY0152）

Effects of Adding Lactic Acid Bacteria and Sugar on Fermentation Quality and Microbial Community of Wheat Straw Yellow Storage at Different Compaction Densities

LI Dongyang^1,2, Wuni′er², Nana², SUN Lin^2,3, YANG Baozhu⁴, LI E^1,2, XUE Yanlin²

1. College of Forestry and Prataculture,Ningxia University,Yinchuan 750021,China;
2. Inner Mongolia Engineering Research Center of Development and Utilization of Microbial Resources in Silage/Inner Mongolia Academy of Agricultural and Animal Husbandry Sciences,Hohhot 010031,China;
3. College of Life Science,China West Normal University,Nanchong 637002,China;
4. Inner Mongolia University,Hohhot 010021,China

Received:2024-01-31 Online:2024-03-30 Published:2024-05-06

摘要/Abstract

摘要： [目的]探究在不同填装密度下添加乳酸菌和糖对小麦秸秆黄贮饲料发酵损失率、发酵品质和微生物群落结构的影响。[方法]将小麦秸秆粉碎,调节水分含量至60%,混合均匀后随机分成2等份。取一份加入由活菌数为1×10⁵ CFU/g的植物乳杆菌（添加量为5 g/t）和白砂糖（添加量为10 kg/t）组成的混合添加剂并均匀喷洒3%的无菌水,按450、500、550 kg/m³的密度进行填装调制黄贮饲料（添加剂处理组）;另一份均匀喷洒3%的无菌水,按450、500、550 kg/m³的密度进行填装调制黄贮饲料（对照组）。分别于发酵1、3、6、15、35、200 d测定2组不同填装密度黄贮饲料的发酵损失率;在发酵200 d开盖取样,测定发酵品质、微生物数量和微生物多样性。[结果]从黄贮3 d开始至200 d,2组黄贮饲料的发酵损失率均显著（P<0.05）增加;发酵35 d和200 d,添加剂处理组的发酵损失率显著（P<0.05）低于对照组。添加剂处理组的pH值显著（P<0.05）低于对照组,乳酸含量显著（P<0.05）高于对照组,氨态氮含量显著（P<0.05）低于对照组,酸碱缓冲能力值显著（P<0.05）高于对照组。添加剂处理组的乳酸菌数量和酵母菌数量显著（P<0.05）低于对照组。2组黄贮饲料中的主要菌属均为乳植杆菌属（Lactiplantibacillus）和迟缓乳杆菌属（Lentilactobacillus）,相对丰度分别为22.12%~49.18%和1.45%~49.91%,这两个属在黄贮饲料中的总相对丰度大于34.25%。在450 kg/m³填装密度下,添加剂处理组的明串珠菌属（Leuconostoc）和肠杆菌属（Enterobacter）相对丰度显著（P<0.05）低于对照组;在500 kg/m³填装密度下,添加剂处理组的迟缓乳杆菌属、明串珠菌属相对丰度显著（P<0.05）低于对照组,而肠杆菌属、泛菌属（Pantoea）、罗尔斯通氏菌属（Ralstonia）和魏斯氏菌属（Weissella）相对丰度显著（P<0.05）高于对照组;在550 kg/m³填装密度下,添加剂处理组的迟缓乳杆菌属、肠杆菌属和明串珠菌属相对丰度显著（P<0.05）低于对照组,而芽孢杆菌属（Bacillus）和类芽孢杆菌属（Paenibacillus）相对丰度显著（P<0.05）高于对照组。迟缓乳杆菌属的相对丰度与乳酸含量、乳酸/乙酸和酸碱缓冲能力值呈负相关（P>0.05）,与乙酸含量呈正相关（P>0.05）,与pH值呈显著（P<0.05）正相关,与氨态氮含量呈显著（P<0.01）正相关;肠球菌属（Enterococcus）、乳球菌属（Lactococcus）的相对丰度与乳酸含量呈显著（P<0.05）负相关,与乳酸/乙酸和酸碱缓冲能力值呈显著（P<0.01）负相关,与pH值呈显著（P<0.01）正相关。乳酸菌和酵母菌数量与pH值、氨态氮含量呈显著（P<0.01）正相关,与乳酸/乙酸呈显著（P<0.01）负相关。[结论]提高填装密度、使用添加剂可降低小麦秸秆黄贮饲料的发酵损失率,改善发酵品质。

关键词: 乳酸菌添加剂, 填装密度, 小麦秸秆黄贮, 微生物群落结构, 发酵品质

Abstract: [Objective] This study was conducted to assess the effects of adding lactic acid bacteria and sugars on fermentation weight loss, fermentation quality and microbial community structure of wheat straw yellow storage at different compaction densities. [Method] Wheat straw was crushed into proper length and the initial moisture content was adjusted to 60%. After well mixing, it was randomly divide into two equal parts. One part was supplemented with the additives composed of a commercially available microbial agent containing 1×10⁵ CFU/g of Lactobacillus plantarum （5 g/t） and white sugar （10 kg/t）, evenly sprayed with 3% sterile water, and then compacted to prepare yellow storage at the densities of 450, 500 and 550 kg/m³ （additive treatment group）, respectively. The other part was evenly sprayed with 3% sterile water, and then compacted to prepare yellow storage at the densities of 450, 500 and 550 kg/m³ （control group）, respectively. Fermentation weight loss of the yellow storage of the two groups with different compaction densities were measured after fermentation for 1, 3, 6, 15, 35 and 200 d, respectively. At 200 d of fermentation, the yellow storage samples were taken to assess the fermentation quality, microbial quantity and microbial diversity. [Result] From 3 d to 200 d of fermentation, the fermentation weight loss of both groups increased significantly （P<0.05）. At 35 d and 200 d of fermentation, the fermentation weight loss of the additive treatment group was significantly （P<0.05） lower than that of the control group. Compared with the control group, the additive treatment group had significantly （P<0.05） lower pH value, significantly （P<0.05） higher lactic acid content, significantly （P<0.05） reduced ammoniacal nitrogen content, and significantly （P<0.05） elevated acid-base buffering capacity. The number of lactic acid bacteria and yeasts of the additive treatment group was significantly （P<0.05） lower than that of the control group. Lactiplantibacillus and Lentilactobacillus were found as the dominant bacterial genera in both groups, with relative abundance of 22.12%-49.18% and 1.45%-49.91%, respectively, and their total relative abundance exceeded 34.25%. At the compaction density of 450 kg/m³, the relative abundance of Leuconostoc and Enterobacter of the additive treatment group was significantly （P<0.05） lower than that of the control group. At the compaction density of 500 kg/m³, significantly （P<0.05） lower relative abundance of Lentilactobacillus and Leuconostoc as well as significantly （P<0.05） higher relative abundance of Enterobacter, Pantoea, Ralstonia and Weissella were observed in the additive treatment group compared with the control group. At the compaction density of 550 kg/m³, the additive treatment group had significantly （P<0.05） decreased relative abundance of Lentilactobacillus, Enterobacter and Leuconostoc as well as significantly （P<0.05） increased relative abundance of Bacillus and Paenibacillus than the control group. The relative abundance of Lentilactobacillus was negatively correlated with lactic acid content, the ratio of lactic acid to acetic acid, and acid-base buffering capacity （P>0.05）, positively correlated with acetic acid content （P>0.05）, significantly （P<0.05） positively correlated with pH value, and significantly （P<0.01） positively correlated with ammoniacal nitrogen content. The relative abundance of Enterococcus and Lactococcus was significantly （P<0.05） negatively correlated with lactic acid content, significantly （P<0.01） negatively correlated with the ratio of lactic acid to acetic acid as well as acid-base buffering capacity, and significantly （P<0.01） positively correlated with pH value. The number of lactic acid bacteria and yeasts was significantly （P<0.01） positively correlated with pH value and ammoniacal nitrogen content, and significantly （P<0.01） negatively correlated with the ratio of lactic acid to acetic acid. [Conclusion] Increasing compaction density and utilizing microbial additive can reduce the fermentation weight loss and ameliorate the fermentation quality of wheat straw yellow storage.

Key words: lactic acid bacteria additive, compaction density, wheat straw yellow storage, microbial community structure, fermentation quality

中图分类号:

S816.5

李东洋, 乌尼尔, 娜娜, 孙林, 杨宝珠, 李鹅, 薛艳林. 不同填装密度下添加乳酸菌和糖对小麦秸秆黄贮饲料发酵品质及微生物群落的影响[J]. 畜牧与饲料科学, 2024, 45(2): 9-19.

LI Dongyang, Wuni′er, Nana, SUN Lin, YANG Baozhu, LI E, XUE Yanlin. Effects of Adding Lactic Acid Bacteria and Sugar on Fermentation Quality and Microbial Community of Wheat Straw Yellow Storage at Different Compaction Densities[J]. Animal Husbandry and Feed Science, 2024, 45(2): 9-19.

参考文献

[1] 张文举,王加启,龚月生,等.秸秆饲料资源开发利用的研究进展[J].国外畜牧科技,2001,28(3):15-18.
[2] 杨洪岩,崔宗均,王小芬,等.秸秆发酵饲料添加剂及其研究进展[J].畜牧与兽医,2005,37(6):50-54.
[3] 张丹丹,张元庆,程景,等.不同粗饲料组合对晋南牛瘤胃体外发酵特性的研究[J].草业学报,2021,30(7):93-100.
[4] 程景,张元庆,张丹丹,等.全株玉米青贮、小麦秸秆、苜蓿干草组合的体外消化特性及组合效应研究[J].动物营养学报,2021,33(5):2982-2992.
[5] 宗成,吴金鑫,朱九刚,等.添加剂对农副产物和小麦秸秆混合青贮发酵品质的影响[J].中国农业科学,2022,55(5):1037-1046.
[6] XU H W, SUN L, NA N, et al.Dynamics of bacterial community and fermentation quality in Leymus chinensis silage treated with lactic acid bacteria and/or water[J].Frontiers in Microbiology,2021,12:717120.
[7] WANG C, SUN L, XU H W, et al.Microbial communities, metabolites, fermentation quality and aerobic stability of whole-plant corn silage collected from family farms in desert steppe of North China[J].Processes,2021,9(5):784.
[8] PLAYNE M J, MCDONALD P.The buffering constituents of herbage and of silage[J].Journal of the Science of Food and Agriculture,1966,17(6):264-268.
[9] WILLIAM H,GEORGE W L.Official methods of analysis of AOAC International[M].18^th ed. Gaithersburg:Association of Official Analytical Chemists,2005.
[10] SAVOIE P, JOFRIET J C.Silage storage[M]//BUXTON D R, MUCK R E, HARRISON J H. Agronomy monographs. Madison, WI, USA:American Society of Agronomy, Crop Science Society of America, Soil Science Society of America,2015:405-467.
[11] RANDBY A T, BAKKEN A K.Effect of acid based additive treatment of low dry matter grass crops on losses and silage quality in bunker silos[J].Animal Feed Science and Technology,2021,275:114869.
[12] BORREANI G, TABACCO E, SCHMIDT R J, et al.Silage review:Factors affecting dry matter and quality losses in silages[J].Journal of Dairy Science,2018,101(5):3952-3979.
[13] SAMARASINGHE M B, LARSEN M, JOHANSEN M, et al.Effects of shredding on silage density and fermentation quality[J].Grass and Forage Science,2019,74(2):244-253.
[14] MUCK R E,KUNG L.Effect of silage additives on ensiling[C]//Proceedigns of the Silage Field to Feedbunk North American Conference,Hershey,Pennsylvania. Ithaca, New York:Northeast Regional Agricultural Engineering Service,1997:187-210.
[15] XIA T Q, WANG T W, SUN J H, et al.Modulation of fermentation quality and metabolome in co-ensiling of Sesbania cannabina and sweet sorghum by lactic acid bacterial inoculants[J].Frontiers in Microbiology,2022,13:851271.
[16] THOMAS P C, CHAMBERLAIN D G, KELLY N C, et al.The nutritive value of silages. Digestion of nitrogenous constituents in sheep receiving diets of grass silage and grass silage and barley[J].The British Journal of Nutrition,1980,43(3):469-479.
[17] SUCU E, KALKAN H, CANBOLAT O, et al.Effects of ensiling density on nutritive value of maize and sorghum silages[J].Revista Brasileira De Zootecnia,2016,45(10):596-603.
[18] 何家俊,赵国强,李莉,等.纤维素酶对玉米秸秆与酒糟混合青贮营养成分、发酵品质、瘤胃体外降解率及微生物多样性的影响[J].动物营养学报,2023,35(5):3190-3200.
[19] 李岩东,戴丽梅.饲料青贮过程中的生物化学变化[J].养殖技术顾问,2012(3):70.
[20] SUN L, NA N, LI X M, et al.Impact of packing density on the bacterial community, fermentation, and in vitro digestibility of whole-crop barley silage[J].Agriculture,2021,11(7):672.
[21] BAI C S, PAN G, LENG R X, et al.Effect of ensiling density and storage temperature on fermentation quality, bacterial community, and nitrate concentration of sorghum-sudangrass silage[J].Frontiers in Microbiology,2022,13:828320.
[22] XU H W, WU N E, NA N, et al.Fermentation weight loss, fermentation quality, and bacterial community of ensiling of sweet sorghum with lactic acid bacteria at different silo densities[J].Frontiers in Microbiology,2022,13:1013913.
[23] HERRMANN C, HEIERMANN M, IDLER C.Effects of ensiling, silage additives and storage period on methane formation of biogas crops[J].Bioresource Technology,2011,102(8):5153-5161.

不同填装密度下添加乳酸菌和糖对小麦秸秆黄贮饲料发酵品质及微生物群落的影响

Effects of Adding Lactic Acid Bacteria and Sugar on Fermentation Quality and Microbial Community of Wheat Straw Yellow Storage at Different Compaction Densities

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