生物炭对土壤微生物影响研究进展

近年来,生物炭作为土壤改良剂在国际上引起广泛关注。生物炭施入土壤后可以通过改变土壤的理化性质,直接或间接的影响土壤微生物的生存环境,为微生物提供良好的生长、繁殖空间,从而影响了微生物的丰度、活性以及群落组成,最终提高了作物产量。文章主要针对生物炭对土壤微生物影响的结果,以及不同种类的生物炭对土壤微生物影响的差异进行阐述,并着眼于当前该领域研究上存在的不足及对未来研究的方向进行了展望。     

Soil Characteristics Overwhelm Cultivar Effects on the Structure and Assembly of Root-Associated Microbiomes of Modern Maize

Modern breeding primarily targets crop yield traits and is likely to influence root-associated microbiomes, which play significant roles in plant growth and health. The relative importance of soil and cultivar factors in shaping root-associated microbiomes of modern maize (Zea mays L.) remains uncertain. We conducted a pot experiment in a controlled environment using three soils (Mollisol, Inceptisol, and Ultisol) and four contrasting cultivars, Denghai 605, Nonghua 816, Qiaoyu 8, and Zhengdan 958, which are widely planted in China. We used 16S rRNA gene amplicon sequencing to characterize the bacterial communities in the bulk soil, rhizosphere, and endosphere. Our results showed that the four cultivars had different shoot biomass and root exudate total organic carbon and organic acid contents. The microbiomes in the bulk soil, rhizosphere, and endosphere were different. We observed apparent community divergence between soils rather than cultivars, within which edaphic factors substantially contributed to microbiome variation. Moreover, permutational multivariate analysis of variance corroborated significant contributions of soil type but not cultivar on the root-associated microbiome structure. Differential abundance analysis confirmed that each soil presented a distinct root microbiome, while network analysis indicated different co-occurrence patterns of the root microbiome among the three soils. The core root microbiome members are implicated in plant growth promotion and nutrient acquisition in the roots. In conclusion, root-associated microbiomes of modern maize are much more controlled by soil characteristics than by cultivar root exudation. Our study is anticipated to help improve breeding strategies through integrative interactions of soils, cultivars, and their associated microbiomes.     

Impact of fertilization on cover crops and microbial community on a bauxite‐mined soil undergoing reclamation

The reclamation of bauxite‐mined areas can be favored by the application of organic and/or chemical fertilization to restore the vegetation. Otherwise, the impact of fertilizations on soil microbiota or plant–microbe interactions as land reclamation progresses is less understood. To address this issue, we evaluated the impact of organic and chemical fertilization on plants and soil microbial community within the first 36 months of land reclamation in a bauxite‐mined site. The experiment was set up according to a split‐plot design in which the main plots received fertilizations [non‐fertilized control (NF), chemical fertilization (CF; NPK and rock phosphate), organic fertilization (OF; poultry litter), and CF+OF combined], and the subplots received cover crops [no cover crops (NC), grass (B; Brachiaria), legume (S, Stylosanthes), and B+S combined]. Cover crops biomass yield was assessed annually with five field campaigns per year. We used phospholipid fatty acids (PLFAs) to infer the impacts of mining and restoration practices on actinobacteria, Gram‐negative and Gram‐positive bacteria, arbuscular mycorrhizal fungi, and fungi. Accordingly, PLFAs were determined before bauxite mining (pre‐mining), six months after topsoil reconfiguration (post‐mining), and after 14 and 36 months following the application of the fertilizations and cover crops. PLFAs results indicated that in post‐mining, the living microbiota was significantly lower than in pre‐mining. Cover crops biomass yield was highest for B and B+S fertilized with CF+OF at 14 and 36 months. Both parametric and non‐parametric statistics showed a temporal variation in the response of living microbes to the treatments applied. After 14 months, living microbes showed greatest response to OF, while at 36 months their response was strongest in the treatments with highest plant biomass production (B and B+S). These results suggest that in the early stages of land reclamation, living microbial biomass benefit the most from organic fertilizers. As this initial boost decline, living microbes are more likely to thrive in areas undergoing reclamation where they can develop synergistic interactions with plants.     

不同基肥对黄瓜根际土壤微生物群落多样性的影响

分别以RAPD分子生物学方法和BIOLOG生理学方法,研究了不同基肥对黄瓜根际土壤微生物群落DNA序列多样性和群落功能多样性的影响。结果表明,在本试验条件下,基肥为75000 kg/hm2有机肥处理和75000 kg/hm2有机肥加300 kg/hm2复合肥处理最好;基肥为600 kg/hm2复合肥处理而使土壤微生物群落DNA序列丰富度指数和多样性指数显著下降,与对照的DNA序列相似系数最低;有机肥处理有利于土壤微生物群落DNA序列多样性、均匀度和黄瓜产量的提高。此外,不同基肥处理改变了土壤微生物对单一碳源的利用能力。     

牛至油和肉桂醛添加组合对奶牛瘤胃微生物蛋白产量与养分消化率的影响

本试验旨在研究牛至油(Oo)与肉桂醛(CA)的不同添加组合对奶牛瘤胃微生物蛋白产量与养分消化率的影响。选取年龄、体重、胎次、产奶量、乳成分相近及泌乳期为(90±15)d的荷斯坦奶牛40头,随机分为10个组,每组4头。对照组(C)饲喂基础日粮,试验组饲喂不同添加水平的Oo和CA,Oo 3个梯度分别为11.5(L)、13(M)、14.5(H)g/(d·头);CA 3个梯度分别为15(L)、18(M)、21(H)g/(d·头),共组成9个不同的添加量组合,分别为LL、ML、HL、LM、MM、HM、LH、MH、HH(第1个字母为Oo添加水平,第2个字母为CA添加水平)。预试期15 d,正试期60 d。结果表明:试验组奶牛的瘤胃微生物蛋白(MCP)产量均有提高趋势,其中LH组效果最好,瘤胃MCP产量比C组提高了12.82%(P<0.05);试验组奶牛在养分表观消化率方面有提高趋势,其中以LH组最优,干物质与粗蛋白质的消化率高于C组(P<0.05),中性洗涤纤维与酸性洗涤纤维的消化率高于C组(P<0.01)。本试验条件下,综合考虑瘤胃MCP产量以及各主要养分的表观消化率,以添加Oo 11.5 g/(d·头)、CA 21 g/(d·头)为最佳。     

不同季节高寒草甸牧草瘤胃发酵特性和体外消化率分析

本文旨在探讨不同生育时期高寒草甸牧草的牦牛瘤胃体外发酵参数及CH₄产量。通过测定返青期、青草期和枯草期3个生育时期牧草的营养品质、瘤胃发酵参数和CH₄产量。结果表明：青草期牧草总能（Gross energy，GE）、粗蛋白（Crude protein，CP）和粗脂肪（Ether extract，EE）等均显著高于返青期和枯草期（P<0.05）；青草期牧草在各发酵时间点的体外干物质消化率（Dry matter digestibility，DMD）、粗蛋白消化率（Crude protein digestibility，CPD）和有机物质消化率（Organic matter digestibility，OMD）均显著高于返青期和枯草期（P<0.05）；青草期牧草12，24和48 h瘤胃NH₃-N、乙酸、丙酸、异丁酸、丁酸和异戊酸含量显著高于返青期和枯黄期（P<0.05）；不同发酵时间牧草总产气量和CH₄产量变化规律为：返青期>青草期>枯草期。综上所述，青草期草地生物量最高，牧草营养品质和体外消化率最高，CH₄排放最低，瘤胃发酵模式最优。建议选择青草期牧草放牧。     

亮氨酸对早期断奶湖羊瘤胃发育及细菌菌群的影响

本试验旨在研究日粮中添加亮氨酸对早期断奶湖羊瘤胃发育及瘤胃细菌菌群组成的影响。选用36只5日龄的湖羊羔羊,依据体重相近原则随机分成对照组(C,0 g/d)、亮氨酸低剂量添加组(L,0.66 g/d)和高剂量添加组(H,1.33 g/d),每组4个重复,每个重复3只羔羊。于30日龄断奶当天每组每个重复取1只羔羊屠宰以获得瘤胃组织及内容物样品(n=4)。结果表明:H组瘤胃乳头的长度较C组显著增加(线性,P<0.01);添加亮氨酸可使瘤胃挥发性脂肪酸水平显著提高(二次,P=0.05),但并未改变乙酸、丙酸和丁酸的摩尔比例(P>0.05);与C组相比,L与H组的瘤胃氨态氮浓度均显著降低(线性,P<0.05;二次,P>0.05);L组羔羊瘤胃内容物中微生物蛋白含量显著高于C组(二次,P=0.05);亮氨酸的添加并未改变瘤胃细菌物种丰富度和多样性指数,但对菌群组成有一定影响;L组瘤胃内最多的是厚壁菌门(49.5%);H组拟杆菌门(51.4%)显著高L和C组(二次,P=0.05);H组的普雷沃氏菌属最多(线性,P>0.05;二次,P>0.05),而L组的巨型球菌属最多(二次,P <0.01);与C组相比,L组的双歧杆菌属(二次,P<0.05)和光岗菌属显著增加(二次,P<0.05)。由此可见,添加亮氨酸可促进羔羊瘤胃发育,改变瘤胃细菌菌群组成。     

反刍动物兽药瘤胃缓控释制剂研究进展

瘤胃缓控释制剂多用于反刍动物抗胃肠道寄生虫或营养补充剂,国内外均有研究。本文主要介绍瘤胃缓控释制剂的机理及应用,以及存在的问题和发展前景。     

肠黏膜自然杀伤细胞的免疫功能及其调控

自然杀伤(NK)细胞是肠黏膜免疫屏障的重要组分。本文从NK细胞的发育学特征、分子表型切入,分析了其在维护肠道屏障完整性中发挥的功能,以及肠道微生物对其免疫功能的调节作用,旨在为疾病预防和肠道健康的营养调控提供理论依据。