微生物醌指纹法在环境微生物群体组成研究中的应用*

微生物醌是能量代谢过程的电子传递体,不同的微生物含有不同种类和分子结构的醌。因此,环境样品中微生物醌的组成,即醌指纹可在一定程度上反映微生物的群体结构。本文简要介绍了微生物醌的分析方法,并利用醌指纹对活性污泥中的微生物群体组成进行了解析。     

DNA指纹图技术分析微生物肥料菌种组成稳定性

目的 分析2种市售微生物肥料在不同生产批次中微生物菌种组成的稳定性。方法 利用ERIC-PCR基因组DNA指纹图技术和16S rDNA V3扩增一温度梯度凝胶电泳（PCR-TGGE）指纹图技术。结果 这2种微生物肥料在同一个生产批次不同包装之间的2种DNA指纹图谱相似性较高,分别在78%～95%和96%～100%,表明同一个批次内的菌种组成比较一致,但其在不同的生产批次之间菌种组成差异存在显著性,反映在2种DNA指纹图谱上,不同生产批次样品间ERIC-PCR指纹图相似性最低只有10%,PCR-TGGE指纹图相似性最低为46%。结论 通过ERIC-PCR和PCR-TGGE DNA指纹图技术可以对微生物肥料中菌种组成的稳定性进行快速、准确的分析,如何保持菌种组成在批次之间的稳定一致,是复合菌种微生物肥料质量控制中面临的难题。     

土壤微生物群落多样性解析法:从培养到非培养

土壤微生物群落多样性是土壤微生物生态学和环境科学的重点研究内容之一.传统的土壤微生物群落多样性解析技术是指纯培养分离法(平板分离和形态分析法以及群落水平生理学指纹法).后来,研究者们建立了多样性评价较为客观的生物标记法(磷脂脂肪酸法和呼吸醌指纹法).随着土壤基因组提取技术和基因片段扩增(PCR)技术的发展,大量的现代分子生物学技术不断地涌现并极大地推动了土壤微生物群落多样性的研究进程.这些技术主要包括:G+C％含量、DNA复性动力学、核酸杂交法(FISH和DNA芯片技术)、土壤宏基因组学以及DNA指纹图谱技术等.综述了这些技术的基本原理、比较了各种技术的优缺点并且介绍了他们在土壤微生物群落多样性研究中的应用,展望了这些技术的发展方向.     

PCR指纹图谱技术分析人体口腔内微生物菌群结构

目的 应用PCR-DGGE指纹图谱技术对人体口腔微生物菌群结构进行系统性研究.方法 对1例健康人唾液周期性采集的样品和8例健康人个体的唾液与牙菌斑采集的样品,进行微生物群落总DNA的抽提.以此为模板扩增16S rRNA V3可变区,产物经DGGE指纹图谱分析其组成结构,并运用UVIBAND/MAP等软件比较所得群落指纹图谱的相似性指数.结果 同一健康人个体不同采样时间的唾液菌群结构相似性系数＞74%,通过对不同健康个体口腔样本的研究,发现同一个体的唾液与牙菌斑菌群结构存在差异（84%～95%）.结论 同一健康个体其唾液微生物菌群在一定时间内基本稳定,仅有微小的变化;唾液与同个体牙菌斑的微生物组成虽然存在差异,但这种差异要明显小于个体间的差异.     

基于PLFA指纹图谱表征浓香型酒糟醅微生物群落结构

以9株白酒酿造过程中常见的菌株为对象,研究了不同种属菌株的细胞膜特征组分磷酸脂肪酸(PLFA)的特征,以及检出量与菌株生物量之间的关系.结果表明:供试细菌、放线菌、霉菌和酵母菌的PLFA指纹图谱存在显著差异,各菌株的PLFA指纹图谱可作为区别种属的依据.不同供试菌株生物量在一定范围内与检出的总PLFA量或16:0含量呈线性关系.将不同生物量的革兰氏阳性菌G+、革兰氏阴性菌G-和真菌分别加入糟醅后,检出的PLFA相对含量与对照差异显著.基于PLFA的指纹图谱能够定量或半定量地表征糟醅微生物群落结构特征及动态变化.经对多家酿酒企业糟醅PLFA组成的检测及微生物群落结构的剖析,该方法具有普适性.     

微生物生物膜研究的新进展

微生物在生长过程中为适应生存环境而形成了生物膜,Dr.Costerton JW在生物膜方面的研究为我们开拓了微生物学的新领域。微生物生物膜是由微生物群体及其包被的细胞外多聚物和基质网组成,它们彼此黏附或者黏附到组织或物体的表面。微生物生物膜与微生物的耐药性形成、基因的转移以及引起机体的持续性感染等都密切相关。目前对生物膜的研究重点已经深入到微生物相互间的信号传递、致病基因的转移以及如何干预微生物生物膜的形成等方面。此外,在治理污水和环境保护工程、生物材料工程和食品工业等方面,微生物生物膜技术已经得到了应用。     

不同产地丹参药材HPLC指纹图谱分析及4种菲醌类成分含量的比较

对7个产地丹参(Salvia miltiorrhiza Bge.)药材进行了HPLC分析并确定了其指纹图谱的共有模式谱,在此基础上比较了7个产地丹参药材中4种菲醌类成分(二氢丹参酮Ⅰ、丹参酮Ⅰ、隐丹参酮和丹参酮ⅡA)的相对含量。结果表明:来源于不同产地的丹参药材的HPLC图谱均有21个峰,其中有8个共有峰;各共有峰的相对保留时间基本相同,RSD值均小于0.086%;但相对峰面积差异明显。以4号峰(二氢丹参酮Ⅰ)为参照峰,初步构建了丹参药材的HPLC指纹图谱的共有模式谱,7个产地丹参药材的HPLC指纹图谱与共有模式谱的相似性良好,相似度值为0.916～0.973。不同产地丹参药材中4种菲醌类成分的相对含量有明显差异,其中,河南产药材中4种菲醌类成分含量均最高,而河北产药材中均最低;此外,不同产地丹参药材中4种成分的组成比例也有明显差异。根据实验结果,建议将丹参药材的HPLC指纹图谱的共有模式谱作为丹参药材质量控制和真伪辨别的标准之一。     

微生物生态学理论框架

微生物是生态系统的重要组成部分,直接或间接地参与所有的生态过程。微生物生态学是基于微生物群体的科学,利用微生物群体DNA/RNA等标志物,重点研究微生物群落构建、组成演变、多样性及其与环境的关系,在生态学理论的指导和反复模型拟合下由统计分析得出具有普遍意义的结论。其研究范围从基因尺度到全球尺度。分子生物学技术的发展,使人们可以直接从基因水平上考查其多样性,从而使得对微生物空间分布格局及其成因的深入研究成为可能。进而可以从方法学探讨微生物生物多样性、分布格局、影响机制及其对全球变化的响应等。在微生物生态学研究中,群落构建与演化、分布特征(含植物-微生物相互关系)、执行群体功能的机理(生物地球化学循环等)、对环境变化的响应与反馈机理是今后需要关注的重点领域。概述了微生物生态学的概念,并初步提出其理论框架,在对比宏观生态学基础理论和模型的基础上,分析微生物多样性的研究内容、研究方法和群落构建的理论机制,展望了今后研究的重点领域。     

未培养微生物的研究与微生物分子生态学的发展*

近年来现代分子技术和基因组学逐渐渗透到有关生命科学的整个领域,也为微生物生态学提供了新的研究方法和机遇。16S rRNA基因序列分析、DNA-DNA杂交、核酸指纹图谱以及宏基因组学等分子技术检查自然环境中的微生物,可以克服传统纯培养技术的不足,是一条探知未培养微生物、寻找新基因及其产物的新途径,开启了我们认识微生物多样性和获得新资源的大门。     

BOX-PCR技术在微生物多样性研究中的应用

近年来在微生物多样性研究中,利用微生物基因组中广泛分布的短重复序列设计引物,选择性地扩增重复序列之间的不同基因区域,以得到大小不等的DNA扩增片段的方法日渐增多.以BOX插入因子(细菌基因组重复序列)为基础的PCR技术,具有操作简单快捷,可重复性强,容易获得较为丰富的扩增条带等特点,最初主要应用于细菌的多样性研究.目前研究发现用BoxA1R引物对微生物中的真菌、放线菌进行选择性的扩增,也能够达到很好的遗传及多样性分析的目的.本文综述了BOX-PCR指纹图谱分析技术的特点和一般步骤;结合作者对植物内生细菌的BOX-PCR指纹图谱分析体系的优化,对BOX-PCR技术的改进进行了总结:并对该技术在微生物菌株多样性研究领域的应用现状和前景进行了阐述.     

Analytical precision and repeatability of respiratory quinones for quantitative study of microbial community structure in environmental samples

Microbial community structure is one of the important factors controlling the pollutant-degrading capacity of ecosystems. The analysis of microbial quinones has gained increased recognition as a simple and useful approach for studying microbial structure in environmental samples. The analytical precision of quinone characterization using high performance liquid chromatograph (HPLC) with a UV-detector was studied in this study. Activated sludge was used as a typical mixed culture. The coefficient of variation of quinone content was lower than 6%, and that of microbial diversity calculated from the composition of quinones was as low as 3%. Statistical analyses on the analytical precision of quinones demonstrated that the critical value of dissimilarity between two quinone profiles of activated sludge, which is used to make a judgement whether the two quinone profiles are different or not, is 0.1 for the analytical method used in this study. The values of minimum biomass required for quinone analysis to have a reliable analytical result of microbial quinones were 2 mg-dry-cell for activated sludge.     

Microbial community dynamics during start-up operation of flowerpot-using fed-batch reactors for composting of household biowaste

Microbial community changes during start-up operation of flowerpot-using fed-batch reactors for composting of household biowaste were studied by quinone profiling, rRNA-targeted fluorescence in situ hybridization (FISH) and cultivation methods. Total and plate counts of bacteria and quinone contents in the reactors increased sharply with time during the start-up period. These increase patterns had two phases; the first increase occurred during 3-4 weeks from the start of waste loading and the second increase was found during the subsequent 4 weeks. The microbial biomass was temporally reduced between the two succession phases. Ubiquinones predominated at the beginning of operation but decreased sharply with time, whereas partially saturated menaquinones became predominant at the fully acclimated stage. These data indicated that the major constituents of microbial populations changed from ubiquinone-containing Proteobacteria to Actinobacteria during the period of operation. Neighbour-joining dendrograms constructed based on the quinone profile data suggested that at least one month is required to establish a stable community structure with the Actinobacteria predominating. The characteristic population shift in the start-up process was also demonstrated by FISH probing and 16S rDNA sequence comparisons of bacterial strains isolated.     

Analysis of the differences in microbial community structures between suspended and sessile microorganisms in rivers based on quinone profile

In this study, a quinone profiling method was applied to clarify the differences in community structure between suspended and sessile microorganisms in rivers. The compositions of microbial quinone of 6 sites for 4 rivers were analyzed. Ubiquinone (UQ)-8, UQ-10, menaquinone (MK)-7, and plastoquinone (PQ)-9 were observed in all samples of suspended and sessile microorganisms for the sites investigated. The dominant quinone species in suspended microorganisms was ubiquinone, and that in sessile microorganism was photosynthetic quinones (namely PQ-9 and vitamin K1). This indicated that aerobic bacteria were abundant in the suspended microorganisms, and photosynthetic microorganisms such as micro-algae and cyanobacteria dominated in the sessile microorganisms. The quinone concentration in the river waters tested, which reflects the concentration of suspended microorganisms, ranged from 0.045 to 1.813 nmol/L. The microbial diversities of suspended and sessile microorganisms calculated based on the composition of all quinones were in the range from 3.4 to 7.5, which was lower than those for activated sludge and soils. Moreover, the diversity of heterotrophic bacteria for sessile microorganisms in the rivers was higher than that for the suspended microorganisms.     

Microbial community succession and lignocellulose degradation during agricultural waste composting

The changes of microbial community during agricultural waste composting were successfully studied by quinone profiles. Mesophilic bacteria indicated by MK-7 and mesophilic fungi containing Q-9 as major quinone were predominant and seemed to be important during the initial stage of composting. Actinobacteria indicated by a series of partially saturated and long-chain menaquinones were preponderant during the thermophilic period. While Actinobacteria, fungi and some bacteria, especially those microbes containing MK-7(H4) found in Gram-positive bacteria with a low G+C content or Actinobacteria were found cooperate during the latter maturating period. Since lignocellulsoe is abundant in the agricultural wastes and its degradation is essential for the operation of composting, it’s important to establish the correlation between the quinone profiles changes and lignocellulose degradation. The microbes containing Q-9 or Q-10(H2) as major quinone were found to be the most important hemicellulose and cellulose degrading microorganisms during composting. While the microorganisms containing Q-9(H2) as major quinone and many thermophilic Actinobacteria were believed to be responsible for lignin degradation during agricultural waste composting.     

Phospholipid-Derived Fatty Acids and Quinones as Markers for Bacterial Biomass and Community Structure in Marine Sediments

Phospholipid-derived fatty acids (PLFA) and respiratory quinones (RQ) are microbial compounds that have been utilized as biomarkers to quantify bacterial biomass and to characterize microbial community structure in sediments, waters, and soils. While PLFAs have been widely used as quantitative bacterial biomarkers in marine sediments, applications of quinone analysis in marine sediments are very limited. In this study, we investigated the relation between both groups of bacterial biomarkers in a broad range of marine sediments from the intertidal zone to the deep sea. We found a good log-log correlation between concentrations of bacterial PLFA and RQ over several orders of magnitude. This relationship is probably due to metabolic variation in quinone concentrations in bacterial cells in different environments, whereas PLFA concentrations are relatively stable under different conditions. We also found a good agreement in the community structure classifications based on the bacterial PLFAs and RQs. These results strengthen the application of both compounds as quantitative bacterial biomarkers. Moreover, the bacterial PLFA- and RQ profiles revealed a comparable dissimilarity pattern of the sampled sediments, but with a higher level of dissimilarity for the RQs. This means that the quinone method has a higher resolution for resolving differences in bacterial community composition. Combining PLFA and quinone analysis as a complementary method is a good strategy to yield higher resolving power in bacterial community structure.     

Toward the bioremediation of dioxin-polluted soil: structural and functional analyses of in situ microbial populations by quinone profiling and culture-dependent methods

In order to obtain basic information toward the bioremediation of dioxin-polluted soil, microbial communities in farmland soils polluted with high concentrations of polychlorinated dibenzo-p-dioxins (PCDDs) and polychlorinated dibenzofurans (PCDFs) were studied by quinone profiling as well as conventional microbiological methods. The concentration of PCDD/Fs in the polluted soils ranged from 36 to 4,980 pg toxicity equivalent quality (TEQ) g(-1) dry weight of soil. There was an inverse relationship between the levels of PCDD/Fs and microbial biomass as measured by direct cell counting and quinone profiling. The most abundant quinone type detected was either MK-6 or Q-10. In addition, MK-8, MK-8(H2), and MK-9(H8) were detected in significant amounts. Numerical analysis of quinone profiles showed that the heavily polluted soils (> or = 1,430 pg TEQ g(-1)) contained different community structures from lightly polluted soils (< or = 56 pg TEQ g(-1)). Cultivation of the microbial populations in the heavily polluted soils with dibenzofuran or 2-chlorodibenzofuran resulted in enrichment of Q-10-containing bacteria. When the heavily polluted soil was incubated in static bottles with autoclaved compost as an organic nutrient additive, the concentrations of PCDD/Fs in the soil were decreased by 22% after 3 months of incubation. These results indicate that dioxin pollution exerted a significant effect on microbial populations in soil in terms of quantity, quality, and activity. The in situ microbial populations in the dioxin-polluted soil were suggested to have a potential for the transformation of PCDD/Fs and oxidative degradation of the lower chlorinated ones thus produced.     

Seasonal microbial community dynamics in a flowerpot-using personal composting system for disposal of household biowaste

Microbial community dynamics in a flowerpot-using solid biowaste composting (FUSBIC) process were monitored seasonally by quinone profiling and conventional microbiological methods. The FUSBIC system, which consisted of three flowerpots (14 L or 20 L capacity) with 5-6 kg each of a soil-compost mixture (SCM) as the primary reactors, was loaded daily with household biowaste from November 1998 to October 1999. The monthly average waste reduction rate was 88.2% for the 14-L system and 92.5% for the 20-L system on a wet weight basis. The direct total microbial count detected in the 14-L primary reactors ranged from 4.5 to 9.6x10(11) cells.g(-1) of dry wt of SCM, and the viable count of aerobic heterotrophic bacteria recovered on agar plates at 28 degrees C varied from 1.9 to 5.7x10(11) CFU.g(-1) of dry wt. The quinone content of SCM samples from the 14-L and 20-L systems ranged from 160 to 353 nmol.g(-1) of dry SCM. Ubiquinones, unsaturated menaquinones, and partially saturated menaquinones constituted 15.0-36.4, 14.8-22.0, and 41.8-61.6 mol% of the total content, respectively. The major quinone types detected were usually MK-8(H(2)), MK-9(H(2)), and Q-10. Variations in quinone profiles were evaluated numerically by using two parameters, the dissimilarity index (D) and microbial divergence index (MD(q)). The upper limit of seasonal changes in the microbial community structure was about 30% as expressed by D values. The MD(q) values calculated ranged from 18 to 22. A significant positive correlation was found between seasonal temperature and bacterial populations containing partially saturated menaquinones. These results indicated that the FUSBIC system contained highly diverse microbial populations that fluctuated to some extent depending on seasonal temperature. Members of the Actinobacteria were suggested to be the major constituents of the total population present.     

Protistan grazing and viral lysis losses of bacterial carbon production in a large mesotrophic lake (Lake Biwa)

The grazing and lysis mortalities of planktonic bacteria were estimated using the modified dilution method and respiratory quinone (RQ) analysis in mesotrophic Lake Biwa, Japan. The planktonic bacterial assemblages in the lake consisted of various RQ subgroups with different growth and mortality rates. The sum of total bacterial mortalities due to protistan grazing and viral lysis accounted for 96.6 % (range 89.0–107.2 %) of daily total bacterial production. This is the first report that successfully demonstrates a balanced relationship between bacterial production and losses using the modified dilution method in a lake. The growth rates of ubiquinone (UQ)-containing bacteria were faster than those of menaquinone-containing bacteria. Especially the dominant and fastest growing bacterial groups in the present study were the bacterial groups containing UQ-8 or UQ-10. The sum of their production and loss accounted for 60 % of carbon fluxes within the microbial loop. Thus, a large portion of the carbon cycling through the bacterial community in Lake Biwa can be explained by the carbon fluxes through dominant bacterial groups.     

Characterization of depth-related population variation in microbial communities of a coastal marine sediment using 16S rDNA-based approaches and quinone profiling

Depth-related changes in whole-community structure were evaluated in a coastal marine sediment using a molecular fingerprinting method, terminal restriction fragment length polymorphism (T-RFLP) analysis, and a chemotaxonomic technique (quinone profiling). Dendrograms derived from both T-RFLP analysis and quinone profiling indicated a significant variation in microbial community structure between the 0-2 cm layer and deeper layers. This corresponded to the dramatic change in the redox potential, acid-volatile sulphide-sulphur and bacterial numbers observed at 0-2 cm and 2-4 cm depths. A significant change in the number of terminal restriction fragments (T-RFs) was also detected at this transition depth. However, the change in major T-RFs with depth was not seen in electropherograms. The population changes were primarily variations in minor ribotypes. Most quinone homologues were detected at all depths, although the quinone composition changed with depth. Therefore, quinone profiling also suggested that the depth-related variation was primarily attributable to minor bacterial groups rather than change in the major population structure. 16S rDNA clone library analysis revealed that clones belonging to the genera Vibrio and Serratia predominated as major bacterial groups at all depths. Our data suggested that the sediment community might result from sedimentation effects of sinking particles. Overall, our results demonstrated that the combined methods of T-RFLP analysis and quinone profiling were effective for assessing depth-related microbial populations.     

Changes in the microbial community structure during thermophilic composting of manure as detected by the quinone profile method

Quinone profiles and physico-chemical properties were measured to characterize the microbial community structure during a 14-day thermophilic composting of cattle manure mixed with rice straw as a bulking agent. The change in total quinone content (TQ) and the divergence of quinone (DQ) indicated that the microbial biomass reached a peak followed by a decrease, whereas the microbial community diversity increased continuously during the composting process. The high mole fraction of ubiquinones in the raw materials, and at the beginning of the composting period suggested that fungi and/or Proteobacteria were present. The predominance of MK-7 from days 3 to 7 suggested that Bacillus spp. were the main microbial species. An increase in partially saturated and long-chain menaquinones during the latter composting period indicated that the proliferation of various species of Actinobacteria was occurring. The microbial community structure, as expressed by TQ and DQ, corresponded well to physico-chemical properties such as the C/N ratio, pH, O₂ consumption and compost mass reduction.