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Transcript
DNA-based Methods for Quantifying Microbes in Atmospheric Samples Tom Hill, Helen Ahern and Bruce Moffett University of East London Quantitative PCR: theory qPCR exploits the amplifying power of the Polymerase Chain Reaction to count the number of genes in a sample •It uses the number of cycles of amplification required to first detect the amplified gene: the more PCR cycles needed the fewer copies of the gene were present at the start qPCR: theory (general DNA fluorophore or specific probe) Light output from PCR reaction •Standards (red to yellow) with known numbers of copies of a gene are used to generate a standard curve •The number of gene copies in an unknown (blue) can then be calculated 54,000 1,000,000 0 5 10 100,000 10,000 15 PCR cycle number 1,000 20 100 25 30 qPCR: DNA fluorophores A non-specific DNA stain, such as Sybr Green I (which binds to double stranded DNA) can be used to make any PCR reaction quantitative •Advantages: rapid start-up (ie, no probe design), cheap, high light output •Disadvantages: false positives can result if the PCR reaction is not completely specific for the target gene Pseudomonas-specific qPCR (using Sybr Green I) of winter heath phyllosphere DNA. Sample (dotted line) contained 15,100 copies of the Pseudomonas 16S rRNA gene. qPCR: DNA probes A light-emitting DNA probe can also be used for detection of the PCR product. Various probe designs exist but use the bringing together or separation of two fluorophores (when the DNA probe binds to the target) and exploit the transfer of fluorescence resonance energy between them (excitation of one fluorophore by another) •Examples include TaqMan, Hyb-probe, molecular beacons and scorpion probes •Advantages: highly-specific and reliable detection of the amplified target gene •Disadvantages: design and optimisation needed, cost Shown over the next two slides is the action of a Scorpion probe we use to quantify ammonia-oxidizing bacteria Probe Probe is both a PCR primer and probe Fluorophore PCR primer Quencher Primer part of Scorpion binds to 16S rRNA gene Taq polymerase copies the single stranded DNA Heat drives off lower DNA strand Probe binds to target, fluorophore held apart from quencher, and light is emitted qPCR: potential uses Detection levels using qPCR can be very low (eg, down to 10 copies of a gene in a sample) if the primers amplify efficiently. Our primers for Pseudomonads and inaW show this potential. We will use them on cloud and phyllosphere samples to: •quantify total bacteria (using universal bacterial 16S primers with DNA) •quantify active bacteria (using universal bacterial 16S primers with RNA) •quantify total Pseudomonads (using Ps-specific 16S primers with DNA) •quantify active Pseudomonads (using Ps-specific 16S primers with RNA) •quantify total IN genes (eg, using inaW-specific primers with DNA) •quantify expressed IN genes (eg, using inaW-specific primers with RNA)
