Effect of simulated tillage on microbial autotrophic CO2 fixation in paddy and upland soils.

Tillage is a common agricultural practice affecting soil structure and biogeochemistry. To evaluate how tillage affects soil microbial CO2 fixation, we incubated and continuously labelled samples from two paddy soils and two upland soils subjected to simulated conventional tillage (CT) and no-tillage (NT) treatments. Results showed that CO2 fixation ((14)C-SOC) in CT soils was significantly higher than in NT soils. We also observed a significant, soil type- and depth-dependent effect of tillage on the incorporation rates of labelled C to the labile carbon pool. Concentrations of labelled C in the carbon pool significantly decreased with soil depth, irrespective of tillage. Additionally, quantitative PCR assays revealed that for most soils, total bacteria and cbbL-carrying bacteria were less abundant in CT versus NT treatments, and tended to decrease in abundance with increasing depth. However, specific CO2 fixation activity was significantly higher in CT than in NT soils, suggesting that the abundance of cbbL-containing bacteria may not always reflect their functional activity. This study highlights the positive effect of tillage on soil microbial CO2 fixation, and the results can be readily applied to the development of sustainable agricultural management.

Ecological and physiological analyses of Pseudomonad species within a phenol remediation system.

A diverse collection of 700 bacteria obtained from an operational phenolic remediating industrial treatment plant was made to select potential strains as microbial biosensors. Pseudomonads were the most abundant group, of which 48 selected from the liquor or suspended solids were assessed for their physiological response to phenolic pollutant loading and niche specialisation. By FAME-MIS identification the Pseudomonads were clustered into six major species groups. Those isolates able to utilise phenol as a sole carbon source predominantly belonged to a non-clonal Pseudomonas pseudoalcaligenes cluster determined by REP-PCR genotyping. Rapid microtitre based respiration assays were developed to contrast activity in response to increasing concentrations of phenol. A considerable range in response for both phenol degrader and non-degrader strains was observed. This natural phenotypic and physiological heterogeneity could facilitate the selection of isolates for the development of a suite of ecologically relevant, custom designed sensors with predictable toxicity susceptibilities to monitor process efficacy.

Microbial analysis of soil and groundwater from a gasworks site and comparison with a sequenced biological reactive barrier remediation process.

AIMS: To investigate the distribution of a polymicrobial community of biodegradative bacteria in (i) soil and groundwater at a former manufactured gas plant (FMGP) site and (ii) in a novel SEquential REactive BARrier (SEREBAR) bioremediation process designed to bioremediate the contaminated groundwater. METHODS AND RESULTS: Culture-dependent and culture-independent analyses using denaturing gradient gel electrophoresis (DGGE) and polymerase chain reaction (PCR) for the detection of 16S ribosomal RNA gene and naphthalene dioxygenase (NDO) genes of free-living (planktonic groundwater) and attached (soil biofilm) samples from across the site and from the SEREBAR process was applied. Naphthalene arising from groundwater was effectively degraded early in the process and the microbiological analysis indicated a dominant role for Pseudomonas and Comamonas in its degradation. The microbial communities appeared highly complex and diverse across both the sites and in the SEREBAR process. An increased population of naphthalene degraders was associated with naphthalene removal. CONCLUSION: The distribution of micro-organisms in general and naphthalene degraders across the site was highly heterogeneous. Comparisons made between areas contaminated with polycyclic aromatic hydrocarbons (PAH) and those not contaminated, revealed differences in the microbial community profile. The likelihood of noncultured bacteria being dominant in mediating naphthalene removal was evident. SIGNIFICANCE AND IMPACT OF THE STUDY: This work further emphasizes the importance of both traditional and molecular-based tools in determining the microbial ecology of contaminated sites and highlights the role of noncultured bacteria in the process.

Bacterial community structure and physiological state within an industrial phenol bioremediation system.

The structure of bacterial populations in specific compartments of an operational industrial phenol remediation system was assessed to examine bacterial community diversity, distribution, and physiological state with respect to the remediation of phenolic polluted wastewater. Rapid community fingerprinting by PCR-based denaturing gradient gel electrophoresis (DGGE) of 16S rDNA indicated highly structured bacterial communities residing in all nine compartments of the treatment plant and not exclusively within the Vitox biological reactor. Whole-cell targeting by fluorescent in situ hybridization with specific oligonucleotides (directed to the alpha, beta and gamma subclasses of the class Proteobacteria [alpha-, beta-, and gamma-Proteobacteria, respectively], the Cytophaga-Flavobacterium group, and the Pseudomonas group) tended to mirror gross changes in bacterial community composition when compared with DGGE community fingerprinting. At the whole-cell level, the treatment compartments were numerically dominated by cells assigned to the Cytophaga-Flavobacterium group and to the gamma-Proteobacteria. The alpha subclass Proteobacteria were of low relative abundance throughout the treatment system whilst the beta subclass of the Proteobacteria exhibited local dominance in several of the processing compartments. Quantitative image analyses of cellular fluorescence was used as an indicator of physiological state within the populations probed with rDNA. For cells hybridized with EUB338, the mean fluorescence per cell decreased with increasing phenolic concentration, indicating the strong influence of the primary pollutant upon cellular rRNA content. The gamma subclass of the Proteobacteria had a ribosome content which correlated positively with total phenolics and thiocyanate. While members of the Cytophaga-Flavobacterium group were numerically dominant in the processing system, their abundance and ribosome content data for individual populations did not correlate with any of the measured chemical parameters. The potential importance of the gamma-Proteobacteria and the Cytophaga-Flavobacteria during this bioremediation process was highlighted.

Rapid method for cell cycle analysis in a predatory marine dinoflagellate.

Oxyrrhis marina (Dujardin) is a predatory marine dinoflagellate that feeds phagocytically on live phytoplanktonic "prey" cells from the surrounding environment. A rapid method was developed to separate the cell cycle characteristics of these predators from their prey cells in order to study the cell cycle dynamics of this organism. Nuclei from Oxyrrhis were isolated in low salt buffer (PBS) using detergent and mechanical agitation and the DNA stained with Hoechst 33258 in a one step procedure. The method permitted the isolation of nuclei from the Oxyrrhis cells with > 95% efficiency. Discrimination between prey cell nuclei and those of Oxyrrhis was achieved during flow cytometric analysis which yielded routinely G1 CVs of 3-6% for exponentially growing cell populations and 2-3% for stationary phase cells. The method was used to demonstrate the changes in cell cycle dynamics during the exponential and stationary phases of growth. Results indicated that in contrast to most mammalian and phytoplankton cell types Oxyrrhis spent the major portion (ca. 50%) of its cell cycle in G2 + M when actively dividing. Analysis of stationary phase populations also suggests that specific cell cycle control (or restriction) points were present in both G1 and G2 in this species.

SYTO16 labelling and flow cytometry of Mycobacterium avium.

Mycobacterium avium cells were harvested from agar at different stages of their growth cycle, exposed to the minimum inhibitory concentration of isoniazid (INH) for 24 h and labelled with the fluorescent nucleic acid stain SYTO16. INH exposure led to a > 10-fold increase in the intensity of labelling in the majority of cells, and revealed discrete fluorescence peaks that were consistent with development of filamentous multinucleate cells during the growth cycle. Similar enhancement of labelling was observed in unfixed INH-treated cells viewed by fluorescence microscopy. INH appears to increase the permeability of Myco. avium cells to SYTO16. A combination of growth cycle-defined inocula, labelling with the new generation of fluorescent dyes and flow cytometry provides new opportunities to study the interrelationships between growth cycle events and antimicrobial susceptibility of mycobacteria.

Rapid method for coextraction of DNA and RNA from natural environments for analysis of ribosomal DNA- and rRNA-based microbial community composition.

A rapid protocol for the extraction of total nucleic acids from environmental samples is described. The method facilitates concomitant assessment of microbial 16S rRNA diversity by PCR and reverse transcription-PCR amplification from a single extraction. Denaturing gradient gel electrophoresis microbial community analysis differentiated the active component (rRNA derived) from the total bacterial diversity (ribosomal DNA derived) down the horizons of an established grassland soil.

Cytochemical colocalization and quantitation of phenotypic and genotypic characteristics in individual bacterial cells.

The widely accepted view that most bacterial species have yet to be cultivated in vitro has gained support from recent ribosomal DNA-based environmental studies. To enable elucidation of the phenotypes of organisms recognized solely by molecular genetic techniques, we developed and evaluated cytochemical methods which colocalize phenotypic properties with in situ rRNA probe hybridization signals. Application of these methods to artificial mixtures of Pseudomonas putida and Escherichia coli or Vibrio vulnificus showed that biochemical properties, such as the cytochrome oxidase reaction and specific substrate-enhanced tetrazolium salt reduction, can be assigned to cells identified by signals from determinative fluorescent rRNA probe binding. By doing the reactions directly on the stage of an inverted microscope and monitoring reaction product formation with a charge-coupled device video camera, it was possible to determine the kinetics of oxidizable substrate utilization in single cells. Analysis of digitized images permitted quantitative study of the relationship between rRNA signal strength and the rate of tetrazolium salt reduction. The approach used in this study opens up new opportunities to investigate the biochemistry, physiology, and behavior of both culturable and nonculturable bacteria in their natural environments.

Density gradient separation of active and non-active cells from natural environments.

We present a method for the selective, physical separation of active and non-active bacterial cells from natural communities. The method exploits the reduction of tetrazolium salts to form insoluble formazan crystals intracellularly in response to the addition of different oxidisable substrates. The intracellular deposition of formazan alters the bouyant density of active cells enabling them to be separated by density gradient centrifugation. The method has been successfully applied to the fractionation and collection of large whole cell sub-populations of active and non-active cells from sea-water samples. Removal of the bands from the density gradient, followed by PCR amplification and DGGE analyses showed distinct differences in the PCR amplicon diversity associated with the active and non-active cell fractions; an indication of changes in bacterial community structure in response to the addition of oxidisable substrate. Thus, based on their in situ respiration potential, the approach enables the cytochemical enrichment and molecular characterisation of mixed bacterial populations in natural environments.