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PCR - Polymerase Chain Reaction

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PCR - Polymerase Chain Reaction PCR is an in vitro technique for the amplification of a region of DNA which lies between two regions of known sequence. – PowerPoint PPT presentation

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Title: PCR - Polymerase Chain Reaction


1
PCR - Polymerase Chain Reaction
  • PCR is an in vitro technique for the
    amplification of a region of DNA which lies
    between two regions of known sequence.
  • PCR amplification is achieved by using
    oligonucleotide primers.
  • These are typically short, single stranded
    oligonucleotides which are complementary to the
    outer regions of known sequence.
  • The oligonucleotides serve as primers for DNA
    polymerase and the denatured strands of the large
    DNA fragment serves as the template.
  • This results in the synthesis of new DNA strands
    which are complementary to the parent template
    strands.
  • These new strands have defined 5' ends (the 5'
    ends of the oligonucleotide primers), whereas the
    3' ends are potentially ambiguous in length.

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  • http//ocw.mit.edu/NR/rdonlyres/Civil-and-Environm
    ental-Engineering/1-89Fall-2004/321BF8FF-75BE-4377
    -8D74-8EEE753A328C/0/11_02_04.pdf

5
Primer selection
  • Primer is an oligonucleotide sequence will
    target a specific sequence of opposite base
    pairing (A-T, G-C only) of single-stranded
    nucleic acids
  • For example, there is a
  • ¼ chance (4-1) of finding an A, G, C or T in any
    given DNA sequence there is a
  • 1/16 chance (4-2) of finding any dinucleotide
    sequence (eg. AG) a
  • 1/256 chance of finding a given 4-base sequence.
  • Thus, a sixteen base sequence will statistically
    be present only once in every 416 bases (4 294
    967 296, or 4 billion) this is about the size of
    the human or maize genome, and 1000x greater than
    the genome size of E. coli.

6
Primer Specificity
  • Universal amplifies ALL bacterial DNA for
    instance
  • Group Specific amplify all denitrifiers for
    instance
  • Specific amplify just a given sequence

7
Forward and reverse primers
  • If you know the sequence targeted for
    amplification, you know the size which the
    primers should be anealing across
  • If you dont know the sequence What do you
    get?

8
DNA Polymerase
  • DNA Polymerase is the enzyme responsible for
    copying the sequence starting at the primer from
    the single DNA strand
  • Commonly use Taq, an enzyme from the
    hyperthermophilic organisms Thermus aquaticus,
    isolated first at a thermal spring in Yellowstone
    National Park
  • This enzyme is heat-tolerant ? useful both
    because it is thermally tolerant (survives the
    melting T of DNA denaturation) which also means
    the process is more specific, higher temps result
    in less mismatch more specific replication

9
RFLP
  • Restriction Fragment Length Polymorphism
  • Cutting a DNA sequence using restriction enzymes
    into pieces ? specific enzymes cut specific places

Starting DNA sequence 5-TAATTTCCGTTAGTTCAAGCGTTA
GGACC 3-ATTAAAGGCAATCAAGTTCGCAATAATGG
Enzyme X 5-TTC- 3-AAG-
Enzyme X 5-TTC- 3-AAG-
5-CAAGCGTTAGGACC 3-GTTCGCAATAATGG
5-TAATTT 3-ATTAAA
5-CCGTTAGTT 3-GGCAATCAA
10
RFLP
  • DNA can be processed by RFLP either directly (if
    you can get enough DNA from an environment) or
    from PCR product
  • T-RFLP (terminal-RFLP) is in most respects
    identical except for a marker on the end of the
    enzyme
  • Works as fingerprinting technique because
    different organisms with different DNA sequences
    will have different lengths of DNA between
    identical units targeted by the restriction
    enzymes
  • specificity can again be manipulated with PCR
    primers

Liu et al. (1997) Appl Environ Microbiol
634516-4522
11
Electrophoresis
  • Fragmentation products of differing length are
    separated often on an agarose gel bed by
    electrophoresis, or using a capilarry
    electrophoretic separation

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DGGE
  • Denaturing gradient gel electrophoresis
  • The hydrogen bonds formed between complimentary
    base pairs, GC rich regions melt
    (meltingstrand separation or denaturation) at
    higher temperatures than regions that are AT
    rich.
  • When DNA separated by electrophoresis through a
    gradient of increasing chemical denaturant
    (usually formamide and urea), the mobility of the
    molecule is retarded at the concentration at
    which the DNA strands of low melt domain
    dissociate.
  • The branched structure of the single stranded
    moiety of the molecule becomes entangled in the
    gel matrix and no further movement occurs.
  • Complete strand separation is prevented by the
    presence of a high melting domain, which is
    usually artificially created at one end of the
    molecule by incorporation of a GC clamp. This is
    accomplished during PCR amplification using a PCR
    primer with a 5' tail consisting of a sequence of
    40 GC.

Run DGGE animation here from http//www.charite.
de/bioinf/tgge/
14
RFLP vs. DGGE
  • RFLP
  • Advantages
  • Relatively easy to do
  • Results can be banked for future comparisons
  • Limitations
  • Less sensitive phylogenetic resolution than
    sequencing
  • Each fragment length can potentially represent a
    diversity of microorganisms
  • Cannot directly sequence restriction
    fragments,making identification indirect
  • DGGE
  • Advantages
  • Very sensitive to variations in DNA sequence
  • Can excise and sequence DNA in bands
  • Limitations
  • Somewhat difficult
  • One band-one species isnt always true
  • Cannot compare bands between gels
  • Only works well with short fragments (lt500 bp),
    thus limiting phylogenetic characterization

15
FISH
  • Fluorescent in-situ hybridization
  • Design a probe consisting of an oligonucleotide
    sequence and a tag
  • Degree of specificity is variable!
  • Hybridize that oligonucleotide sequence to the
    rRNA of an organism this is temperature and
    salt content sensitive
  • Image using epiflourescence, laser excitation
    confocal microscopy
  • Technique DIRECTLY images active organisms in a
    sample

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B Drift Slime Streamer
10 µm
DAPI
FER656
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Oligunucleotide design
20
FISH variations
  • FISH-CARD instead of a fluorescent probe on
    oligo sequence, but another molecule that can
    then bond to many fluorescent probes better
    signal-to-noise ratio
  • FISH-RING design of oligo sequence to specific
    genes image all organisms with DSR gene or nifH
    for example

21
Clone Library
  • http//ocw.mit.edu/NR/rdonlyres/Civil-and-Environm
    ental-Engineering/1-89Fall-2004/321BF8FF-75BE-4377
    -8D74-8EEE753A328C/0/11_02_04.pdf

22
http//www.ifa.hawaii.edu/UHNAI/NAIweb/presentatio
ns/astrobiol6.pdf
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