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Prokaryote Evolution

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Title: Prokaryote Evolution


1
Prokaryote Evolution Diversity
  • Dr Gillian Baker

2
Genetic Mutation
  • REVISION What is mutation ?
  • 5 types of mutation
  • Transition/Transversion
  • Mutations in Protein-coding
  • Synonymous/Non-synonymous
  • Deleterious, Advantageous, Neutral

3
Natural Selection
  • Evolution is driven by 3 factors mutation,
    inheritance and selection.
  • Natural Selection is the differential
    reproduction of genetically distinct genotypes
    within a population.
  • e.g. a pool of water gets hotter due to global
    warming a bacterium with a mutation that allows
    it to live in hotter temperatures will survive
    and have more surviving offspring than those
    individuals that are less adapted.
  • Darwinism - survival of the fittest

4
Fixation of Mutations
  • The rate at which mutations occur is not entirely
    random. Hotspots exist (e.g. 5-TT-3 and
    pallindromes). The mutations that can be detected
    are only the neutral or advantageous ones
  • Mutations can be fixed by selection OR genetic
    drift.
  • Genetic Drift is solely due to chance effects.

5
Selectionist v Neutral Theory Arguments
  • Neo-darwinsim selectionism is the only force
    able to drive evolutionism.
  • Neutral theory (Kimura 1968) majority of
    molecular changes in evolution are due to the
    random fixation of neutral or nearly neutral
    mutations.
  • The middle ground most variation is caused
    through neutral mutations, but selection plays a
    role in fixation of advantageous mutations and
    extinction of deleterious mutations.

6
Conserved and Variable Sites
  • See Variability Map of ssu rRNA gene.
  • CONSERVED positions - nucleotides do not vary in
    these positions. Mutations here may led to
    destruction of the molecule so are wiped out by
    selection.
  • VARIABLE positions - these nucleotides are not
    essential to the function of the molecule and can
    vary in a clock-like manner.

7
Molecular Chronometers
  • The number of base pair differences between two
    organisms is directly proportional to the time
    since the two organisms had a common ancestor.

Starts plateauing off when there are multiple
hits
(convergent, parallel and back
substitutions.)
Number bp differences
Years since divergence
8
Molecular Taxonomy
  • 1960s amino acid sequencing (Zuckerandl
    Pauling).
  • 1970s nucleic acid sequencing
  • 1980s Universal Phylogenetic Tree (Woese)
  • 1990s Refinement of PCR Technologies
  • MOLECULAR TAXONOMY DATA
  • re-evaluation of major branching patterns -
    Margulis - Woese
  • re-assignment of taxonomic groups
  • identification of new organisms and level of
    biodiversity

9
Universal Phylogenetic Tree
10
Molecular Microbial Taxonomy
  • Dr Gillian Baker

11
Species Concept
  • The Biological Species Concept
  • One species CAN NOT breed with another species
    and produce fertile offspring
  • BUT microbes DO NOT breed. So how do we define
    microbial species?
  • 1. Morphological Biochemical Similarity
  • 2. Genetic Similarity

12
Traditional Taxonomy
  • What does it look like? (microscopy)
  • Where does it live?
  • What does it do? (assimilation studies)
  • PROBLEM
  • they all look the same!
  • Some look the same, but are different.
  • Some are different, but look the same.

13
Molecular Taxonomy
  • To identify an organism on the basis of its
    proteins, RNA or DNA.
  • A new species or strain arises as the result of
    a mutation(s) becoming fixed in a population.
  • These mutations can be detected using Molecular
    Methods.

14
Culturability
  • Microbes are small! To identify them you need to
    have more than one (or more than one copy of
    their DNA)
  • Culturing microbes in vitro is a good way of
    making enough cells to work on.
  • BUT - Less than 1 of the worlds microbes are
    culturable ! ......

15
The PCR Age
  • Polymerase Chain Reaction - Cary Mullis - 1980s
  • recipe for replicating DNA
  • dNTPs (ATP, GTP, CTP TTP) occurs naturally
  • Original Template in genome
  • DNA Polymerase (see DNA replication
  • Appropriate ions (especially Mg) in
    standard text book)
  • Primase (to form primer)
  • PCR is based on the natural process of DNA
    replication but allows specific and logarithmic
    replication of particular fragments or genes.

16
How to do a PCR
  • 1 . Design a set of primers complementary to the
    DNA at either end of the gene/fragment of interest

F
R
AGGCCTGCATGGTCAA CCTTTCCGGACGTACCAGTTCCGT
17
How to do a PCR
  • 2. Mix together ingredients Genomic DNA
    Primers dNTPs Salts and Buffers DNA
    Polymerase.
  • 3. Put into a PCR machine _at_ 94C to denature
    genomic DNA into single-strands.
  • 4. Cool to 50C to primers anneal to
    complementary genomic DNA.

18
How to do a PCR
  • 5. Warm up to 72C to cause polymerase to
    catalyse elongation reaction (adding in
    complementary A, G, C T)
  • 6. Start AGAIN. This time primers will also
    anneal to the newly synthesised strands

19
How to do a PCR
  • 7. As this process continues cycle after cycle
    the number of small fragments increases
    proportionally to the original template until the
    majority of the product is copies of the gene or
    fragment between the two primers.

20
Thermostable Polymerase
  • Normal DNA Polymerases found in humans and
    mesophilic microorganisms would not stand the
    heating and cooling needed to denature the DNA.
    (In the beginning they had to keep adding fresh
    polymerase after each annealing reaction.) So
    thermostable polymerases are used. Taq and Vent
    Polymerases are obtained from bacteria (Thermus
    aquaticus and hydrothermal vent bacteria) which
    live in environments of 70 - 95C.

21
So why did PCR make such a difference to
Microbiology?
  • PCR has allowed us to amplify the genes of
    bacteria that do not grow in culture - i.e. most
    of them!
  • Particularly useful for studying organisms that
    are difficult to grow in the lab - such as
    thermophiles, barophiles and psychrophiles.
  • In theory we can amplify and use DNA from a
    single cell!

22
Methods for Identifying Organisms at Molecular
Level
  • There are three main types of methods for
    identifying the differences (fixed mutations)
    between organisms
  • 1. Total Genome Methods - e.g. DNA-DNA
  • hybridisation chromosomal studies. ONLY
    suitable for higher organisms and culturable
    microbes.
  • 2. Fragment length methods - infer differences
    in genomic DNA prep (from culture) or PCR product
    by measuring mutations at specific marker regions
    e.g. restriction sites.
  • Methods include REA RAPDs DGGE, VNTRs.
  • 3. Sequencing - reading the actual DNA sequence
    of a gene.

23
REA (restriction enzyme analysis)
  • DNA is digested with restriction enzymes
  • Restriction digest is run out on an agarose gel.
  • Restriction patterns are identified.
  • Can identify REA types by sequencing or just make
    measure of diversity by numbers of patterns
  • If two organisms have different restriction
    enzyme patterns there is at least 1 difference in
    DNA sequence between them.
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