Darrell P. Chandler

Effect of PCR template concentration on the composition and distribution of total community 16S rDNA clone libraries

Total DNA from sediment samples was isolated by a direct lysis technique. Purified DNA was used as template either undiluted or diluted 1 : 10 prior to polymerase chain reaction (PCR) amplification of 16S rRNA genes. Full‐length inserts were analysed for restriction fragment length polymorphisms (RFLP) with the enzyme Cfo1, and the resulting distribution and abundance of RFLP patterns compared between the undiluted and diluted PCR reactions. Results indicate that for low PCR template concentrations, in the range from a few picograms to tens of picograms DNA, proportional representation of specific RFLP types was not reproducible upon template dilution, confirming that PCR amplification of 16S rDNA cannot be used directly to infer microbial abundance. In particular, only 15–24% of the RFLP types recovered from a sample were present in both the undiluted and diluted extracts. We propose that very low template concentrations in the PCR generate random fluctuations in priming efficiency, which led to the contrast in the RFLP types observed in the libraries from the undiluted and diluted extracts.

Detecting and genotyping Escherichia coli O157:H7 using multiplexed PCR and nucleic acid microarrays

Rapid detection and characterization of food borne pathogens such as Escherichia coli O157:H7 is crucial for epidemiological investigations and food safety surveillance. As an alternative to conventional technologies, we examined the sensitivity and specificity of nucleic acid microarrays for detecting and genotyping E. coli O157:H7. The array was composed of oligonucleotide probes (25-30 mer) complementary to four virulence loci (intimin, Shiga-like toxins I and II, and hemolysin A). Target DNA was amplified from whole cells or from purified DNA via single or multiplexed polymerase chain reaction (PCR), and PCR products were hybridized to the array without further modification or purification. The array was 32-fold more sensitive than gel electrophoresis and capable of detecting amplification products from < 1 cell equivalent of genomic DNA (1 fg). Immunomagnetic capture, PCR and a microarray were subsequently used to detect 55 CFU ml(-1) (E. coli O157:H7) from chicken rinsate without the aid of pre-enrichment. Four isolates of E. coli O157:H7 and one isolate of O91:H2, for which genotypic data were available, were unambiguously genotyped with this array. Glass-based microarrays are relatively simple to construct and provide a rapid and sensitive means to detect multiplexed PCR products; the system is amenable to automation.

Taxonomic Study of Aromatic-Degrading Bacteria from Deep- Terrestrial-Subsurface Sediments and Description of Sphingomonas aromaticivorans sp. nov., Sphingomonas subterranea sp. nov., and Sphingomonas stygia sp. nov.

Phylogenetic analyses of 16S rRNA gene sequences by distance matrix and parsimony methods indicated that six strains of bacteria isolated from deep saturated Atlantic coastal plain sediments were closely related to the genus Sphingomonas. Five of the strains clustered with, but were distinct from, Sphingomonas capsulata, whereas the sixth strain was most closely related to Blastobacter natatorius. The five strains that clustered with S. capsulata, all of which could degrade aromatic compounds, were gram-negative, non-spore-forming, non-motile, rod-shaped organisms that produced small, yellow colonies on complex media. Their G + C contents ranged from 60.0 to 65.4 mol%, and the predominant isoprenoid quinone was ubiquinone Q-10. All of the strains were aerobic and catalase positive. Indole, urease, and arginine dihydrolase were not produced. Gelatin was not liquified, and glucose was not fermented. Sphingolipids were present in all strains; 2OH14:0 was the major hydroxy fatty acid, and 18:1 was a major constituent of cellular lipids. Acid was produced oxidatively from pentoses, hexoses, and disaccharides, but not from polyalcohols and indole. All of these characteristics indicate that the five aromatic-degrading strains should be placed in the genus Sphingomonas as currently defined. Phylogenetic analysis of 16S rRNA gene sequences, DNA-DNA reassociation values, BOX-PCR genomic fingerprinting, differences in cellular lipid composition, and differences in physiological traits all indicated that the five strains represent three previously undescribed Sphingomonas species. Therefore, we propose the following new species: Sphingomonas aromaticivorans (type strain, SMCC F199), Sphingomonas subterranea (type strain, SMCC B0478), and Sphingomonas stygia (type strain, SMCC B0712).

Phylogenetic Diversity of Archaea and Bacteria in a Deep Subsurface Paleosol

A bstractA low-biomass paleosol 188 m below the ground surface at the Department of Energys Hanford Site in south-central Washington State was recovered and maintained at the in situ temperature (17°C) as an intact core or homogenized sediment for 0, 1, 3, 10, and 21 weeks post-sampling. Bacterial and archaeal 16S rRNA genes were amplified by PCR and cloned. Of 746 bacterial and 190 archaeal clones that were categorized by restriction fragment length polymorphism (RFLP), 242 bacterial and 16 archaeal clones were partially sequenced and compared against the small subunit ribosomal RNA database (RDP) and GenBank. Six bacterial and 16 archaeal clones sequences, with little similarity to those in public databases, were sequenced in their entirety, and subjected to more detained phylogenetic analysis. The most frequently occurring clones types were related to Pseudomonas, Bacillus, Micrococcus, Clavibacter, Nocardioides, Burkholderia, Comamonas, and Erythromicrobium. Clone sequences whose RDP similarity value was ≥0.6 consistently grouped with their nearest RDP neighbor during phylogenetic analysis. Six truly novel eubacterial sequences were identified; they consistently cluster with or near the Chloroflexaceae and sequences recovered from the Sargasso Sea. Sixteen unique archaeal RFLP groups were identified from 190 randomly-sampled clones. The novel archaeal rDNA clones formed a coherent clade along the major Crenarchaea branch containing all previously described mesophilic crenarchae clones, but remained firmly associated with 16S rDNA clones previously obtained from a thermal Fe/S spring in Yellowstone National Park. The wealth of group-specific genetic information identified during this study will now allow us to address specific hypotheses related to in situ stimulation of these deep subsurface microorganisms and changes in microbial community composition resulting from subsurface contamination or remediation processes at the Hanford Site.

Automated immunomagnetic separation and microarray detection of E. coli O157:H7 from poultry carcass rinse

We describe the development and application of an electromagnetic flow cell and fluidics system for automated immunomagnetic separation (IMS) of Escherichia coli O157:H7 directly from poultry carcass rinse. We further describe the biochemical coupling of automated sample preparation with nucleic acid microarrays. Both the cell concentration system and microarray detection method did not require cell growth or enrichment from the poultry carcass rinse prior to IMS. Highly porous Ni foam was used to enhance the magnetic field gradient within the flow path, providing a mechanism for immobilizing immunomagnetic particles throughout the fluid rather than the tubing wall. A maximum of 32% recovery efficiency of non-pathogenic E. coli was achieved within the automated system with 6 s cell contact times using commercially available antibodies targeted against the O and K antigens. A 15-min protocol (from sample injection though elution) provided a cell recovery efficiency that was statistically similar to > I h batch captures. O157:H7 cells were reproducibly isolated directly from poultry carcass rinse with 39% recovery efficiency at 10(3) CFU ml(-1) inoculum. Direct plating of washed beads showed positive recovery of O157:H7 directly from poultry carcass rinse at an inoculum of 10 CFU ml(-1). Recovered beads were used for direct polymerase chain reaction (PCR) amplification and microarray detection, with a process-level detection limit (automated cell concentration though microarray detection) of < 10(3)CFU ml(-1) in poultry carcass rinse.

Renewable Microcolumns for Automated DNA Purification and Flow-through Amplification: From Sediment Samples through Polymerase Chain Reaction

Abstract There is an increasing need for field-portable systems for the detection and characterization of microorganisms in the environment. Nucleic acids analysis is frequently the method of choice for discriminating between bacteria in complex systems, but standard protocols are difficult to automate and current microfluidic devices are not configured specifically for environmental sample analysis. In this report, we describe the development of an integrated DNA purification and polymerase chain reaction (PCR) amplification system and demonstrate its use for the automated purification and amplification of Geobacter chapellei DNA (genomic DNA or plasmid targets) from sediments. The system includes renewable separation columns for the automated capture and release of microparticle purification matrices, and can be easily reprogrammed for new separation chemistries and sample types. The DNA extraction efficiency for the automated system ranged from 3 to 25%, depending on the length and concentration of the DNA target. The system was more efficient than batch capture methods for the recovery of dilute genomic DNA even though the reagent volumes were smaller than required for the batch procedure. The automated DNA concentration and purification module was coupled to a flow-through, Peltier-controlled DNA amplification chamber, and used to successfully purify and amplify genomic and plasmid DNA from sediment extracts. Cleaning protocols were also developed to allow reuse of the integrated sample preparation system, including the flow-through PCR tube.

Automated nucleic acid isolation and purification from soil extracts using renewable affinity microcolumns in a sequential injection system

We have combined affinity purification concepts with novel renewable-surface microcolumns in a sequential injection system for the automated and rapid isolation and purification of nucleic acids directly from crude soil extracts. Geobacter chapellii DNA was spiked at femtomolar concentrations into clean solutions or crude soil extracts containing picomolar concentrations of competitive DNA, humic acids and other soluble soil constituents. The 16S rDNA targets (indigenous and spiked) were purified and eluted in less than 20 min in a form suitable for direct polymerase chain reaction (PCR) amplification and detection. The extraction efficiency of the automated system was equivalent to a 4-h batch reaction using identical reagents. The estimated efficiency of isolation and purification was maximally 30% under the conditions employed here, with levels comparable to those obtained with soils/sediments processed by standard techniques, and a detection limit of 1.7 attamoles (10(6) copies) Geobacter target in a soil extract containing a competitive background of 10(9) genomes. This manuscript represents the first report of automated nucleic acid purification from an environmental sample using sequential injection fluidic systems and renewable microcolumn technology, and provides an excellent platform from which to optimize and accelerate the development of an integrated microbial/nucleic acid detector.

Renewable microcolumns for solid-phase nucleic acid separations and analysis from environmental samples

Abstract This article summarizes the convergence of sequential injection–renewable separation columns (SI–RSC) and techniques with nucleic acid analysis at the Pacific Northwest National Laboratory. New renewable microcolumn designs, functional principles and their analytical and practical utility are presented within the context of automated nucleic acid extraction and purification from environmental samples.

Electroelution to remove humic compounds from soil DNA and RNA extracts

The application of nucleic acid techniques to detect, identify, and monitor specific genes or organisms in soils or sediments is often complicated by the inhibitory effects of humic compounds that copurify with nucleic acids. A rapid electroelution technique was developed to separate inhibitory compounds from extracts of soil DNA and RNA. This technique was used in conjunction with PCR to detect nifH, terrestrial ammonia-oxidizer (TAO) 16S rRNA genes and TAO 16S rRNA from a variety of surface soils and contaminated sediments. After electroelution of crude nucleic acid extracts, PCR sensitivity was increased up to a factor of 104 relative to DNA templates that had not been electroeluted. Without electroelution of crude DNA extracts, target genes often remained undetected. Likewise, electroelution of crude RNA extracts increased RT-PCR sensitivity (for TAO 16S rRNA) by a factor of 103 relative to RNA extracts that had not been further purified. The electroelution technique will therefore be useful for rendering environmental nucleic acids extracted from soil and sediment more amenable to PCR methods and nucleic acid analysis.

Automated Sample Preparation method for suspension arrays using renewable surface separations with multiplexed flow cytometry fluorescence detection

In this paper, we describe a new method of automated sample preparation for multiplexed biological analysis systems that use flow cytometry fluorescence detection. In this approach, color-encoded microspheres derivatized to capture particular biomolecules are temporarily trapped in a renewable surface separation column to enable perfusion with sample and reagents prior to delivery to the detector. This method provides for separation of the biomolecules of interest from other sample matrix components as well as from labeling solutions. After sample preparation, the beads can be released from the renewable surface column and delivered to a flow cytometer for direct on-bead analysis one bead at a time. Using mixtures of color-encoded beads derivatized for various analytes yields suspension arrays for multiplexed analysis. Development of this approach required a new technique for automated capture and release of the color-encoded microspheres within a fluidic system. We developed a method for forming a renewable filter and demonstrate its use for capturing microspheres that are too small to be easily captured in previous flow cells for renewable separation columns. The renewable filter is created by first trapping larger beads in the flow cell, and then smaller beads are captured either within or on top of the bed of larger beads. Both the selective microspheres and filter bed are automatically emplaced and discarded for each sample. A renewable filter created with 19.9 μm beads was used to trap 5.6 μm optically encoded beads with trapping efficiencies of 99%. The larger beads forming the renewable filter did not interfere with the detection of color-encoded 5.6 μm beads by the flow cytometer fluorescence detector. The use of this method was demonstrated with model reactions for a variety of bioanalytical assay types including a one-step capture of a biotinylated label on Lumavidin beads, a two-step sandwich immunoassay, and a one-step DNA binding assay. A preliminary demonstration of multiplexed detection of two analytes using color-encoded beads was also demonstrated. The renewable filter for creating separation columns containing optically encoded beads provides a general platform for coupling renewable surface methods for sample preparation and analyte labeling with flow cytometry detectors for suspension array multiplexed analyses.