乙醇对瘤胃液接种稻秸的体外发酵产物及细菌群落结构的影响

旨在研究乙醇对山羊瘤胃液与水稻秸秆厌氧共培养的影响。利用频繁传代的体外发酵技术和高通量测序方法,分析了短链脂肪酸(SCFA)产量和细菌群落的变化。结果表明,经体外培养传代8次的稻秸发酵液的总短链脂肪酸产量显著高于瘤胃液(P<0.01);与未添加乙醇的稻秸发酵液相比,添加乙醇显著提高了乙酸、戊酸和己酸的比例,降低了丙酸和丁酸的比例(P<0.01),总SCFA产量及异丁酸和异戊酸比例无显著差异。与瘤胃液相比,稻秸发酵液的拟杆菌门(Bacteroidetes)相对丰度下降,厚壁菌门(Firmicutes)相对丰度升高(P<0.05),且添加乙醇显著提高了厚壁菌门和放线菌门(Actinobacteria)的相对丰度(P<0.05);添加乙醇使双歧杆菌属(Bifidobacterium)、未定性的毛螺菌属(unidentified Lachnospiraceae)、产琥珀酸菌属(Succiniclasticum)、脱硫弧菌属(Desulfovibrio)和未定性的梭菌属(unidentified Clostridiales)的相对丰度显著升高(P<0.05)。乙醇使稻秸发酵液的显著性差异物种(Biomarker)增加;稻秸发酵液与瘤胃液亲缘关系较近,而添加乙醇显著改变了细菌区系;短链脂肪酸比例在稻秸发酵液细菌群落多样性中具有重要作用。研究表明,体外频繁传代和添加乙醇可以提高稻秸发酵液的乙酸、戊酸和己酸产量,乙醇改变了稻秸发酵液的细菌群落结构。     

生物发酵稻秸对湖羊消化道上皮形态及微生物区系的影响

【目的】本研究旨在通过显微观察和16SrRNA基因高通量测序技术来探究饲喂生物发酵稻秸对湖羊肠道上皮形态及微生物区系的影响。【方法】试验选择70日龄、体重相近(25.15±0.47)kg的湖羊公羔21只,根据饲粮中粗饲料的组成随机分为3组：稻秸组、生物发酵稻秸组和苜蓿干草组,饲粮精粗比为6:4,试验持续7周,其中适应期3周,正试期4周,结束后屠宰取样,采集瘤胃、空肠和结肠上皮组织进行观察测量,收集对应肠段内容物用于微生物区系和代谢产物测定。【结果】与稻秸组相比,饲喂生物发酵稻秸显著提高湖羊瘤胃中纤维杆菌(Fibrobacteres)的相对丰度和挥发性脂肪酸(volatile fatty acids, VFA)的含量,促进瘤胃上皮的发育;显著提高湖羊空肠中厚壁菌门(Firmicutes)和疣微菌门(Verrucomicrobia)的相对丰度,改变空肠微生物菌群结构,促进空肠上皮组织的发育;改变湖羊结肠微生物菌群结构。【结论】饲喂生物发酵稻秸有利于湖羊肠道上皮的发育,并增加消化道内的微生物多样性。     

载锌凹凸棒石黏土对瘤胃体外发酵细菌多样性的影响

【目的】研究载锌凹凸棒石黏土对瘤胃体外发酵细菌多样性的影响。【方法】本试验采用离子交换法制备载锌凹凸棒石黏土,利用16S rDNA测序技术分析了载锌凹凸棒石黏土对奶牛瘤胃体外发酵细菌菌群和多样性的影响。【结果】研究共获得1490959个有效序列和87662个OTUs。测序结果表明,与对照组相比,试验Ⅳ组中的细菌多样性在体外发酵24 h时提高,试验Ⅳ组中的细菌丰度在体外发酵48 h时提高。细菌菌群组成分析表明,60个样本中的优势菌门主要是厚壁菌门、拟杆菌门、变形菌门和黏胶球形菌门。与对照组相比,各试验组的厚壁菌门在体外发酵24 h和48 h时均显著增加(P0.05),试验Ⅳ组中拟杆菌门在发酵48 h时显著降低(P0.05);60个样本中共获得124个细菌菌属,其中对照组与试验组中普氏菌属含量均没有显著变化(P0.05)。在体外发酵48 h时,试验Ⅳ组中密螺旋体属含量与对照组相比显著增加(P0.05),而食物谷菌属和假丁酸弧菌属含量与对照组相比均显著降低(P0.05)。【结论】载锌凹凸棒石黏土对奶牛瘤胃体外发酵中细菌多样性产生一定影响,其影响随发酵时间和添加剂量而不同。     

洋河酒窖泥细菌群落结构与菌株产酸能力分析

【背景】窖泥微生物的种类及其代谢产物类型是影响浓香型白酒发酵过程中丁酸和己酸等白酒中主要有机酸合成的影响因素之一。【目的】揭示浓香型白酒不同窖龄窖泥细菌群落结构,研究厌氧细菌产酸性能,阐明窖泥细菌与白酒中有机酸合成的相关性。【方法】通过Illumina HiSeq高通量测序,基于16S rRNA基因序列分析不同窖龄窖泥细菌的组成。分离获得厌氧细菌,通过比较菌株产丁酸和己酸能力来分析窖泥的微生物代谢特性。【结果】洋河酒窖泥细菌主要分布于梭菌纲(Clostridia)、拟杆菌纲(Bacteroidia)、互营养菌纲(Synergistia)和芽孢杆菌纲(Bacilli)。20年窖龄的窖泥中氢孢菌属(Hydrogenispora)和瘤胃梭菌属(Ruminiclostridium)丰度显著增加。窖泥细菌间相关性分析表明,瘤胃梭菌属(Ruminiclostridium)为窖泥中影响最大的核心微生物,很多微生物与梭菌属(Clostridium)菌株之间多为相互促进关系。通过传统可培养方法共分离得到梭菌目(Clostridiales)的20株厌氧菌。其中梭菌属(Clostridium)菌株产酸能力高于其他菌属,酪丁酸梭菌(Clostridium tyrobutyricum)和丁酸梭菌(Clostridium butyricum)产丁酸和己酸的能力最强。产丁酸能力最高的菌主要分离自5年和20年窖龄窖泥,产己酸能力最高的菌分离自20年窖龄窖泥。【结论】解析了浓香型白酒不同窖龄窖泥的细菌组成,并对菌株产丁酸和己酸的能力进行了比较,为揭示窖泥微生物功能及其对白酒风味物质合成的影响奠定了相关的研究基础。     

郫县豆瓣细菌多样性及群落结构动态变化北大核心

【目的】通过检测郫县豆瓣在不同发酵阶段细菌的种类、丰度及数量,探究郫县豆瓣的不同发酵产品发酵过程中细菌的动态变化情况。【方法】采用16S rRNA基因测序对郫县豆瓣4个发酵阶段中细菌种类及丰度进行分析,利用荧光定量PCR(quantitative real-time PCR,qPCR)方法检测不同发酵阶段的细菌总数。【结果】郫县豆瓣在初期的发酵过程中细菌群落处于动态稳定,在不同发酵阶段细菌群落组成相对丰富,从郫县豆瓣整个初期的发酵过程来看,细菌群落多样性呈现升高的趋势,Shannon指数从1.25升高到3.50;在郫县豆瓣初期发酵过程中细菌群落的数量以及多样性与发酵环境息息相关,不同发酵阶段细菌群落的多样性也有所不同,其中在干辣椒发酵阶段中泛菌属(Pantoea)为最优势菌属,占比为20%;在蚕豆瓣发酵阶段中葡萄球菌属(Staphylococcus)的相对丰度最高,占比为38%;混合发酵后,在红油豆瓣发酵阶段的最优势菌属是乳酸杆菌属(Lactobacillus),占比达到27%,郫县豆瓣发酵阶段的最优势菌属是乳酸杆菌属(Lactobacillus),占比为62%。【结论】推断在郫县豆瓣不同发酵阶段初期相对丰度较大的菌属对郫县豆瓣的质量以及产量可能会产生重大影响。     

不同能量代谢率的山羊瘤胃微生物结构与组成的差异性

【背景】能量代谢率是衡量饲粮利用效率的一个重要组成部分,提高反刍动物对不同营养物质所含能量的消化代谢率,有助于提高反刍动物对能量的利用效率。【目的】通过高通量测序技术比较不同能量代谢率的山羊瘤胃微生物结构与组成的差异。【方法】以19只山羊作为试验动物,通过代谢试验和呼吸测热试验筛选出高能量代谢率表型组(HEU)和低能量代谢率表型组(LEU)山羊各5只。分别采集HEU、LEU组每只山羊瘤胃内容物,提取微生物总DNA,用细菌通用引物对细菌16S rRNA基因的高可变区进行PCR扩增,利用Illumina Mi Seq平台对扩增子进行高通量测序,并用QIIME等软件对测序序列进行生物信息学分析。【结果】拟杆菌门(44.20%±9.39%)、厚壁菌门(16.40%±5.44%)和变形菌门(11.30%±7.42%)在两组山羊瘤胃微生物中均为优势菌门,其中厚壁菌门是两组中共享的优势菌门。LEU组(6.71%±2.47%)中芽孢杆菌纲相对丰度显著高于HEU组(P0.05)。两组相对丰度最高的目均为乳酸杆菌目,LEU组(4.98%±1.88%)乳酸杆菌目相对丰度显著高于HEU组(P0.05)。在科水平,有7个科的相对丰度在组间差异性显著(P0.05)。拟杆菌科在两组中均为相对丰度最高的科,LEU组(3.64%±1.32%)拟杆菌科的相对丰度显著高于HEU组(P0.05)。在属水平,有9个属的相对丰度在组间差异性显著(P0.05)。HEU组(0.61%±0.36%)仅有普雷沃氏菌属的相对丰度显著高于LEU组(0.16%±0.07%),其他8个属的相对丰度均显著低于LEU组(P0.05)。其中瘤胃球菌属在HEU组(2.53%±0.62%)和LEU组(4.19%±1.43%)中均为相对丰度最高的属。【结论】不同能量代谢率的山羊瘤胃微生物结构与组成存在显著性差异。     

溶菌酶对瘤胃体外发酵、甲烷生成及微生物菌群结构的影响

【目的】通过体外静态模拟瘤胃发酵法研究溶菌酶对瘤胃发酵、甲烷生成及微生物菌群结构的影响。【方法】采用单因素多水平试验设计,溶菌酶添加水平分别为0(L-0,对照组)、0.1 mg/100 m L(L-0.1)、1 mg/100 m L(L-1)、10 mg/100 m L(L-10)和100 mg/100 m L(L-100),定时测定产气量和甲烷产量,培养24 h后,发酵液用于发酵参数和微生物菌群数量的q PCR测定,其中L-0、L-1和L-100三个组发酵液同时进行16S r RNA基因Illumina高通量测序。【结果】与对照组相比,低剂量溶菌酶添加(L-0.1组)不影响甲烷产量、氨氮浓度、干物质消失率、有机物消失率和总挥发性脂肪酸等瘤胃发酵参数(P0.05);随着剂量提高,L-1处理组甲烷产量、氨氮浓度显著降低(P0.05),丙酸浓度显著增加(P0.05),并且干物质消失率、有机物消失率和总挥发性脂肪酸不受影响(P0.05);而较高剂量组(L-10和L-100组)虽然甲烷产量显著降低,丙酸浓度显著增加(P0.05),但干物质消失率和有机物消失率也显著降低(P0.05)。q PCR结果显示高剂量组(L-100组)总菌、原虫、甲烷菌数量与对照组相比显著降低(P0.05),而L-0.1、L-1和L-10组总菌、真菌和原虫数量与对照组相比均无显著变化(P0.05)。高通量测序主成分分析(PCA)显示对照组与溶菌酶添加组间瘤胃细菌组成的明显区分,说明添加溶菌酶显著改变了瘤胃细菌菌群结构。溶菌酶通过增加月形单胞菌和琥珀酸弧菌等丙酸生成菌的相对丰度,使更多的氢被用于生成丙酸,导致甲烷产量降低;溶菌酶可抑制普雷沃氏菌和拟杆菌属等蛋白降解菌的生长,进而减少蛋白质过度降解,降低氨氮浓度。【结论】添加适宜浓度(1 mg/100 m L)的溶菌酶可通过调控瘤胃微生态改变瘤胃发酵模式,降低瘤胃甲烷和氨的生成,短期内并不影响饲料消化。     

模拟增温对青海湖鸟岛土壤微生物的影响

【背景】土壤微生物对其生存的微环境变化极为敏感,鸟岛作为湖滨湿地,对气候变化具有敏感性,但目前关于青海湖鸟岛的土壤微生物鲜有研究。【目的】探究气候变暖后青海湖鸟岛土壤微生物群落特征的变化。【方法】利用开顶箱模拟增温,通过高通量测序方法了解温度升高后土壤细菌及真菌的群落结构以及多样性的变化情况。【结果】温度的升高并未改变青海湖鸟岛土壤微生物的优势菌群,细菌优势菌群为变形菌门和酸杆菌门;真菌优势菌门为子囊菌门,优势菌纲为座囊菌纲。但增温改变了土壤微生物的群落结构,显著升高了拟杆菌门、蓝细菌门、Patescibacteria及球囊菌纲的相对丰度,显著降低了锤舌菌纲的相对丰度。土壤微生物群落的多样性指数也发生了变化,温度上升后微生物的ACE指数及Chao1指数均降低,细菌的Simpson指数及真菌的Shannon指数降低。【结论】青海湖鸟岛土壤微生物对温度升高的响应明显,增温改变了土壤细菌拟杆菌门、蓝细菌门、Patescibacteria的相对丰度及真菌的球囊菌纲、锤舌菌纲的相对丰度,降低了土壤微生物的多样性。     

大叶藻(Zostera marina)海草床沉积物细菌和古菌丰度及组成的垂直剖面特征

【背景】海草床是重要的"蓝碳"生态系统,对全球碳汇有重要贡献。海草床沉积物剖面的垂直梯度特征显著,表层呈现氧化态,富含活性有机质,而深层呈还原态,以惰性有机质为主。【目的】探究这种垂直特征如何影响微生物的丰度和群落分布。【方法】利用荧光定量PCR和16SrRNA基因高通量测序等手段,测定了山东荣成天鹅湖大叶藻海草床不同深度(5、10、15、20、25和30 cm)沉积物中细菌和古菌丰度、多样性和群落结构的变化。【结果】细菌和古菌16S rRNA基因拷贝数随深度的增加而降低,在沉积物5cm深处,细菌的16SrRNA基因拷贝数显著高于20cm和30cm层(ANOVA,P0.05)。深度对细菌和古菌α多样性指数没有显著影响(P0.05)。细菌中相对丰度最高的是变形菌门,其次是绿弯菌门,拟杆菌门,浮霉菌门等,其中δ-变形菌和浮霉菌的相对丰度随深度显著增加(P0.05)。古菌群落中深古菌门比例最高,在25cm深处达到70%以上;其次是乌斯菌门、洛基古菌门、广古菌门和奇古菌门等。奇古菌门比例随深度增加而显著降低(P0.05),其他古菌类群在不同深度间差异不显著(P0.05)。【结论】海草床沉积物细菌和古菌的丰度、多样性和群落分布具有明显的垂直特征,这种特征可能受沉积物有机质组成和氧化还原状况影响。     

泸型酒酒醅细菌群落的发酵演替规律

【目的】考察泸型酒发酵过程中酒醅细菌群落的演替规律,探讨菌群演替与环境因素变化的相关性。【方法】采用高通量测序技术分析泸型酒酒醅细菌群落的演替规律,并运用Mantel test分析不同发酵阶段的细菌群落演替与环境因素变化的相关性。【结果】酒醅发酵过程中有397个属的微生物,其中Lactobacillus、Bacillus、Weissella、Dysgonomonas、Comamonas以及Ruminococcaceae为优势属(相对丰度1.0%)。通过聚类分析可将酒醅发酵过程划分为3个阶段:阶段I (0–5 d),阶段II (6–17 d)和阶段III(18–40d),且3个阶段的酒醅菌群结构差异显著(P0.05)。Metastats分析结果表明,与阶段I相比,阶段II酒醅细菌群落中Lactobacillus和unclassifiedLactobacillaceae相对丰度显著升高(P0.05),而unclassifiedBacillaceae、 Staphylococcus、 Bacillus、 unclassified Enterobacteriaceae、 Lactococcus、Pseudomonas、Thermoactinomyces、Leuconostoc、Staphylococcus相对丰度显著降低(P0.05)。与阶段II相比,阶段III酒醅细菌群落中Lactobacillus相对丰度显著增长(P0.05),Comamonas、Acetobacter、unclassified Bacilli、Clostridium、Bacillus、Ruminococcus、unclassified Porphyromonadaceae和unclassified Streptophyta相对丰度显著下降(P0.05)。结果表明,阶段I的细菌菌群演替与酒醅温度、水分和乙醇浓度变化线性相关(P0.05);阶段II和阶段III的细菌菌群演替与酒醅温度、水分、酸度、乙醇浓度均没有相关性(P0.05)。【结论】泸型酒酒醅中细菌群落在不同发酵阶段结构差异显著,且温度、水分以及乙醇浓度对酒醅发酵前期(0–5 d)细菌群落演替具有重要作用。     

Effect of dilute acid pretreatment on the saccharification and fermentation of rye straw

This research shows the effect of dilute acid pretreatment with various sulfuric acid concentrations (0.5–2.0% [wt/vol]) on enzymatic saccharification and fermentation yield of rye straw. After pretreatment, solids of rye straw were suspended in Na citrate buffer or post-pretreatment liquids (prehydrolysates) containing sugars liberated after hemicellulose hydrolysis. Saccharification was conducted using enzymes dosage of 15 or 25 FPU/g cellulose. Cellulose saccharification rate after rye straw pretreatment was enhanced by performing enzymatic hydrolysis in sodium citrate buffer in comparison with hemicellulose prehydrolysate. The maximum cellulose saccharification rate (69%) was reached in sodium citrate buffer (biomass pretreated with 2.0% [wt/vol] H₂SO₄). Lignocellulosic complex of rye straw after pretreatment was subjected to separate hydrolysis and fermentation (SHF) or separate hydrolysis and co-fermentation (SHCF). The SHF processes conducted in the sodium citrate buffer using monoculture of Saccharomyces cerevisiae (Ethanol Red) were more efficient compared to hemicellulose prehydrolysate in respect with ethanol yields. Maximum fermentation efficiency of SHF processes obtained after rye straw pretreatment at 1.5% [wt/vol] H₂SO₄ and saccharification using enzymes dosage of 25 FPU/g in sodium citrate buffer, achieving 40.6% of theoretical yield. However, SHCF process using cocultures of pentose-fermenting yeast, after pretreatment of raw material at 1.5% [wt/vol] H₂SO₄ and hydrolysis using enzymes dosage of 25 FPU/g, resulted in the highest ethanol yield among studied methods, achieving 9.4 g/L of ethanol, corresponding to 55% of theoretical yield.     

Isolation,characterization, and quantification of <Emphasis Type="Italic">Clostridium kluyveri</Emphasis> from the bovine rumen

A strain of Clostridium kluyveri was isolated from the bovine rumen in a medium containing ethanol as an electron donor and acetate and succinate (common products of rumen fermentation) as electron acceptors. The isolate displayed a narrow substrate range but wide temperature and pH ranges atypical of ruminal bacteria and a maximum specific growth rate near the typical liquid dilution rate of the rumen. Quantitative real-time PCR revealed that C. kluyveri was widespread among bovine ruminal samples but was present at only very low levels (0.00002% to 0.0002% of bacterial 16S rRNA gene copy number). However, the species was present in much higher levels (0.26% of bacterial 16S rRNA gene copy number) in lucerne silage (but not maize silage) that comprised much of the cows’ diet. While C. kluyveri may account for several observations regarding ethanol utilization and volatile fatty acid production in the rumen, its population size and growth characteristics suggest that it is not a significant contributor to ruminal metabolism in typical dairy cattle, although it may be a significant contributor to silage fermentation. The ability of unadapted cultures to produce substantial levels (12.8 g L⁻¹) of caproic (hexanoic) acid in vitro suggests that this strain may have potential for industrial production of caproic acid.     

芝麻香型白酒发酵过程中乳酸菌多样性及其演替规律

【背景】乳酸菌是白酒发酵过程中一类非常重要的微生物,其种类及动态变化对于白酒品质具有重要影响。然而,目前对于芝麻香型白酒发酵过程中乳酸菌群落结构及其演替规律的认识并不全面。【目的】揭示芝麻香型白酒发酵过程中乳酸菌的多样性及菌群的演替规律,为更好地探索白酒酿造机理和控制白酒品质提供生物学依据。【方法】利用高通量测序技术对芝麻香型白酒发酵过程中乳酸菌菌群演替进行跟踪分析,同时采用实时荧光定量PCR对发酵过程中乳酸菌的生物量进行定量分析。【结果】高通量测序结果显示,芝麻香型白酒发酵过程涉及5个属的乳酸菌:魏斯氏菌属(Weissella)、片球菌属(Pediococcus)、乳杆菌属(Lactobacillus)、明串珠菌属(Leuconostoc)和乳球菌属(Lactococcus),共计43种乳酸菌。其中,在发酵过程中平均相对丰度大于0.5%的乳酸菌有10种,分别是类肠膜魏斯氏菌(Weissella paramesenteroides)、食窦魏斯氏菌(Weissella cibaria)、融合魏斯氏菌(Weissella confusa)、戊糖片球菌(Pediococcus pentosaceus)、假肠膜明串珠菌(Leuconostoc pseudomesenteroides)、发酵乳杆菌(Lactobacillus fermentum)、植物乳杆菌(Lactobacillus plantarum)、副干酪乳杆菌(Lactobacillus paracasei)、耐酸乳杆菌(Lactobacillus acetotolerans)和Lactobacillus sp.。在堆积发酵过程中,Weissella属占细菌总量的50%以上,其次是Pediococcus属和Lactobacillus属,而Leuconostoc属和Lactococcus属相对较少。在窖池发酵过程中Lactobacillus属的乳酸菌逐渐成为优势细菌,尤其是Lactobacillus sp.在窖池发酵中后期相对丰度达到80%以上。实时荧光定量PCR结果显示,在堆积发酵和窖池发酵前期乳酸菌总量变化不大;从窖池发酵5 d开始,乳酸菌总量迅速上升,30 d时达到最大值。【结论】对白酒发酵过程中乳酸菌种类及动态变化的研究有助于探究白酒酿造过程中乳酸菌功能,进而解析白酒酿造机理,最终达到控制白酒品质的目的。     

芝麻香型白酒微生物多样性及其与胁迫因子相关性

【背景】近年来芝麻香型白酒的生产工艺日臻成熟,然而相应的科学研究却没有同步发展起来。高通量测序技术越来越多地应用于物种多样性的研究,但偏重于研究物种的相对丰度,没有关注物种的生物数量。【目的】深度解析芝麻香型白酒发酵过程微生物群落结构变化及其与胁迫因子相关性,并研究主要酵母菌与细菌的相关性,为揭示芝麻香型白酒发酵机理和控制发酵质量提供理论支撑。【方法】使用Thermofisher的Ion S5~(TM)XL测序平台进行16S rDNA和ITS rDNA扩增子高通量测序,结合微生物传统的定量方法,测定芝麻香型白酒发酵过程微生物群落结构的变化,同时监测发酵过程乳酸、乙酸、乙醇的含量变化,通过样品复杂度分析、多样品比较分析、环境因子关联性分析探究发酵过程微生物群落及其与胁迫因子的关系。通过Pearson相关性分析酵母菌与细菌的相关性。【结果】发酵前期纤维素菌、魏斯氏菌和芽孢杆菌占主要优势,发酵中后期乳杆菌占绝对优势,其次是纤维素菌、魏斯氏菌和芽孢杆菌。整个发酵过程伊萨酵母占绝对优势,其次是维克霉菌、酿酒酵母、假丝酵母。大部分微生物与胁迫因子呈负相关,只有乳杆菌与乙酸呈极显著性正相关。酵母菌与部分细菌呈正相关性。【结论】白酒发酵过程胁迫因子和微生物间的相互作用促进了群落演替过程,发酵后期乳杆菌和芽孢杆菌发酵产酸抑制了大部分不耐酸菌,有机酸是影响群落结构变化的主要胁迫因子。微生物数量结合相对丰度揭示了发酵过程群落结构演替及其与环境因子相关性的更多信息。     

清香型白酒中乳酸菌和酵母菌的相互作用

【目的】探究清香型白酒中不同乳酸菌和酵母菌的相互作用,了解不同菌株的发酵性能,为更深入地认识白酒发酵机理、实现发酵过程优化提供理论基础。【方法】利用程序控温和固态发酵模拟清香型白酒酿造环境,测定纯培养和共培养中菌株的理化指标、活菌数以及主要代谢产物的变化。【结果】Saccharomyces cerevisiae YJ1糖消耗快产乙醇和酯类物质多,Lactobacillus plantarum JMRS4糖消耗快产酸较多。共培养中乳酸菌对Saccharomyces cerevisiae YJ1的生长和产乙醇抑制较大,对Candida aaseri MJ7产乙醇几乎无影响。乳酸菌对Pichia kudriavzevii MJ14的生物量和乙醇代谢抑制作用较小,还对其产己酸乙酯、乙酸乙酯和异戊醇等代谢产物有促进作用;而反过来Pichia kudriavzevii MJ14对3株乳酸菌产乳酸均有抑制作用,对产乙酸则有促进作用。【结论】建立了一种固态培养方法,结合清香型白酒发酵温度变化规律,有效模拟了实际发酵环境。Pichia kudriavzevii MJ14在与乳酸菌共培养中受到的抑制较小并能有效抑制乳酸菌产乳酸,Saccharomyces cerevisiae YJ1能代谢产生多种风味物质,对清香型白酒酿造有重要意义。     

Improved bio-energy yields via sequential ethanol fermentation and biogas digestion of steam exploded oat straw

Using standard laboratory equipment, thermochemically pretreated oat straw was enzymatically saccharified and fermented to ethanol, and after removal of ethanol the remaining material was subjected to biogas digestion. A detailed mass balance calculation shows that, for steam explosion pretreatment, this combined ethanol fermentation and biogas digestion converts 85-87% of the higher heating value (HHV) of holocellulose (cellulose and hemicellulose) in the oat straw into biofuel energy. The energy (HHV) yield of the produced ethanol and methane was 9.5-9.8 MJ/(kg dry oat straw), which is 28-34% higher than direct biogas digestion that yielded 7.3-7.4 MJ/(kg dry oat straw). The rate of biogas formation from the fermentation residues was also higher than from the corresponding pretreated but unfermented oat straw, indicating that the biogas digestion could be terminated after only 24 days. This suggests that the ethanol process acts as an additional pretreatment for the biogas process.     

Evaluation of native potential probiotic bacteria using an in vitro ruminal fermentation system

Rumen microbiota provides an important source of protein to grazing animals and produces volatile fatty acids (VFA), the main energy source for ruminants generated by fibre fermentation. Probiotics can be used to modulate rumen fermentation, and native microbiota is a source of potentially useful microorganisms. In this work, ruminal bacterial strains were isolated and subsequently identified, and their potential to modify fermentation patterns with wheat straw, microcrystalline cellulose and oat xylan as substrates was assessed by in vitro gas production and VFA fermentation patterns. Four of the isolates were identified as Pseudobutyrivibrio ruminis and two corresponded to new members of the Lachnospiraceae family. The addition of one P. ruminis (strain 50C) and one Lachnospiraceae (strain 21C) to the fermentation system which used wheat straw as the substrate significantly increased total VFA concentration without altering the total gas produced in one case and showed a decrease in total gas production in the other. All bacterial strains induced higher butyric acid concentrations with the three substrates (up to 31 mM in the case of Lachnospiraceae 21C incubated with oat xylan and 25 mM in microcrystalline cellulose fermenters to which P. ruminis 50C had been added) compared to the control, which had concentrations of <1 mM. Analysis of the fermentation products suggested that the addition of probiotics to the fermentation system had the potential to induce metabolic shifts that would result in better energy yields. These results show that native bacteria have promising features as fermentation modulators, thereby justifying further research to assess their use as probiotics for ruminants.     

The bacteriocins of ruminal bacteria and their potential as an alternative to antibiotics

Beef cattle have been fed ionophores and other antibiotics for more than 20 years to decrease ruminal fermentation losses (e.g methane and ammonia) and increase feed efficiency, and these improvements have been explained by an inhibition of gram-positive ruminal bacteria. Ionophores are not used to treat human disease, but there has been an increased perception that antibiotics should not be used as feed additives. Some bacteria produce small peptides (bacteriocins) that inhibit gram-positive bacteria. In vitro experiments indicated that the bacteriocin, nisin, and the ionophore, monensin, had similar effects on ruminal fermentation. However, preliminary results indicated that mixed ruminal bacteria degraded nisin, and the ruminal bacterium, Streptococcus bovis, became highly nisin-resistant. A variety of ruminal bacteria produce bacteriocins, and bacteriocin production has, in some cases, been correlated with changes in ruminal ecology. Some ruminal bacteriocins are as potent as nisin in vitro, and resistance can be circumvented. Based on these results, ruminal bacteriocins may provide an alternative to antibiotics in cattle rations.