co 06
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CO 06. Four requirements for DNA to be genetic material. Must carry information Cracking the genetic code Must replicate DNA replication Must allow for information to change Mutation Must govern the expression of the phenotype Gene function. - PowerPoint PPT PresentationTRANSCRIPT
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CO 06CO 06
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Four requirements for DNA Four requirements for DNA to be genetic materialto be genetic material
Must carry informationMust carry information Cracking the genetic codeCracking the genetic code
Must replicateMust replicate DNA replicationDNA replication
Must allow for information to changeMust allow for information to change MutationMutation
Must govern the expression of the phenotypeMust govern the expression of the phenotype Gene functionGene function
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•Much of DNA’s sequence-specific information is accessible only when the double helix is unwound
•Proteins read the DNA sequence of nucleotides as the DNA helix unwinds. Proteins can either bind to a DNA sequence, or initiate the copying of it.
•Human genome is believed to be 250 million nucleotides long. Four possible nucleotides. Thus 4250,000,000 possible sequences in the human genome.
•An average single coding gene sequence might be about 10,000 bases long. Thus, 410,000 possibilities for an average gene.
•Some genetic information is accessible even in intact, double-stranded DNA molecules
•Some proteins recognize the base sequence of DNA without unwinding it.•One example is a restriction enzyme.
DNA stores information in the sequence of its bases
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Some viruses use RNA as the Some viruses use RNA as the repository of genetic informationrepository of genetic information
Fig. 6.13
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Mutations: key tool in Mutations: key tool in understanding understanding biological functionbiological function
What mutations areWhat mutations are How often mutations occurHow often mutations occur What events cause mutationsWhat events cause mutations How mutations affect survival and evolutionHow mutations affect survival and evolution
Mutations and gene structureMutations and gene structure Experiments using mutations demonstrate a gene is a discrete Experiments using mutations demonstrate a gene is a discrete
region of DNAregion of DNA Mutations and gene functionMutations and gene function
Genes encode proteins by directing assembly of amino acidsGenes encode proteins by directing assembly of amino acids How do genotypes correlate with phenotypes?How do genotypes correlate with phenotypes?
Phenotype depends on structure and amount of proteinPhenotype depends on structure and amount of protein Mutations alter genes instructions for producing proteins Mutations alter genes instructions for producing proteins
structure and function, and consequently phenotypestructure and function, and consequently phenotype
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Mutations are Mutations are heritable changesheritable changes in base sequences that in base sequences that modify the information contentmodify the information content of DNA of DNA
Substitution – base is replaced by one of the other Substitution – base is replaced by one of the other three basesthree bases
Deletion – block of one or more DNA pairs is lostDeletion – block of one or more DNA pairs is lost Insertion – block of one or more DNA pairs is Insertion – block of one or more DNA pairs is
addedadded Inversion 1800 rotation of piece of DNAInversion 1800 rotation of piece of DNA Reciprocal translocation – parts of Reciprocal translocation – parts of
nonhomologous chromosomes change placesnonhomologous chromosomes change places Chromosomal rearrangements – affect many Chromosomal rearrangements – affect many
genes at one timegenes at one time
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7Fig. 7.2
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Spontaneous mutations influencing Spontaneous mutations influencing phenotype occur at a very low ratephenotype occur at a very low rate
Mutation rates from wild-type to recessive alleles for five coat color genes in mice
Fig. 7.3 b
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Are mutations spontaneous or Are mutations spontaneous or induced?induced?
Most mutations are spontaneous.Most mutations are spontaneous. Luria and Delbruck experiments - a simple Luria and Delbruck experiments - a simple
way to tell is mutations are spontaneous or way to tell is mutations are spontaneous or if they are induced by a mutagenic agentif they are induced by a mutagenic agent
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10Fig. 7.4
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Replica plating verifies preexisting Replica plating verifies preexisting mutationsmutations
Fig. 7.5 a
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Fig. 7.5b
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Interpretation of Luria-Delbruck fluctuation Interpretation of Luria-Delbruck fluctuation experiment and replica platingexperiment and replica plating
Bacterial resistance arises from mutations Bacterial resistance arises from mutations that exist before exposure to bacteriocidethat exist before exposure to bacteriocide
After exposure to bacteriocide, the After exposure to bacteriocide, the bacteriocide becomes a selective agent killing bacteriocide becomes a selective agent killing the nonresistant cells, allowing only the the nonresistant cells, allowing only the preexisting resistant cells to survive.preexisting resistant cells to survive.
Mutations do not arise in particular genes as Mutations do not arise in particular genes as a direct response to environmental changea direct response to environmental change
Mutations occur randomly at any timeMutations occur randomly at any time
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Mistakes during replication alter Mistakes during replication alter genetic informationgenetic information
Errors during replication are exceedingly Errors during replication are exceedingly rare, less than once in 10rare, less than once in 1099 base pairs base pairs
Proofreading enzymes correct errors made Proofreading enzymes correct errors made during replicationduring replication DNA polymerase has 3’ – 5’ exonuclease DNA polymerase has 3’ – 5’ exonuclease
activity which recognizes mismatched bases and activity which recognizes mismatched bases and excises itexcises it
In bacteria, methyl-directed mismatch repair In bacteria, methyl-directed mismatch repair finds errors on newly synthesized strands and finds errors on newly synthesized strands and corrects themcorrects them
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DNA polymerase proofreadingDNA polymerase proofreading
Fig. 7.8
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Methyl-Methyl-directed directed
mismatch mismatch repairrepair
Fig. 7.9
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Chemical and Physical agents cause Chemical and Physical agents cause mutationsmutations
Hydrolysis of a purine Hydrolysis of a purine base, A or G occurs 1000 base, A or G occurs 1000 times an hour in every celltimes an hour in every cell
Deamination removes –NH2 Deamination removes –NH2 group. Can change C to U, group. Can change C to U, inducing a substitution to and inducing a substitution to and A-T base pair after replicationA-T base pair after replication
Fig. 7.6 a,b
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X rays break the X rays break the DNA backboneDNA backbone
UV light produces UV light produces thymine dimersthymine dimers
Fig. 7.6 c, d
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Oxidation from free radicals formed by irradiation damages individual bases
Fig. 7.6 e
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Repair enzymes fix errors created by Repair enzymes fix errors created by mutationmutation
Excision repair Excision repair enzymes enzymes release release damaged damaged regions of regions of DNA. Repair DNA. Repair is then is then completed by completed by DNA DNA polymerase polymerase and DNA ligaseand DNA ligase
Fig. 7.7a
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Unequal crossing over creates one Unequal crossing over creates one homologous chromosome with a duplication homologous chromosome with a duplication
and the other with a deletionand the other with a deletion
7.10 a
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Trinucleotide repeat in people with Trinucleotide repeat in people with fragile X syndromfragile X syndrom
Fig. A, B(2) Genetics and Society
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Trinucleotide instability causes Trinucleotide instability causes mutationsmutations
FMR-1 genes in FMR-1 genes in unaffected people unaffected people have fewer than have fewer than 50 CGG repeats. 50 CGG repeats.
Unstable Unstable premutation premutation alleles have alleles have between 50 and between 50 and 200 repeats.200 repeats.
Disease causing Disease causing alleles have > 200 alleles have > 200 CGG repeats.CGG repeats.
Fig. B(1) Genetics and Society
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Mutagens induce mutationsMutagens induce mutations
Mutagens can be used to increase mutation Mutagens can be used to increase mutation ratesrates
H. J. Muller – first discovered that X rays H. J. Muller – first discovered that X rays increase mutation rate in fruitfliesincrease mutation rate in fruitflies Exposed male Drosophila to large doses of X Exposed male Drosophila to large doses of X
raysrays Mated males to females with balancer X Mated males to females with balancer X
chromosome (dominant Bar eyed mutation and chromosome (dominant Bar eyed mutation and multiple inversions)multiple inversions)
Could assay more than 1000 genes at once on Could assay more than 1000 genes at once on the X chromosomethe X chromosome
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Muller’s experimentMuller’s experiment
Fig. 7.11
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Mutagens increase mutation rate Mutagens increase mutation rate using different mechanismsusing different mechanisms
Fig. 7.12a
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28Fig. 7.12 b
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29Fig. 7.12 c
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Consequences of mutationsConsequences of mutations
Germ line mutations – passed on to next Germ line mutations – passed on to next generation and affect the evolution of generation and affect the evolution of speciesspecies
Somatic mutations – affect the survival of Somatic mutations – affect the survival of an individualan individual Cell cycle mutations may lead to cancerCell cycle mutations may lead to cancer
Because of potential harmful affects of Because of potential harmful affects of mutagens to individuals, tests have been mutagens to individuals, tests have been developed to identify carcinogensdeveloped to identify carcinogens
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The Ames test The Ames test for carcinogens for carcinogens
using hisusing his-- mutants of mutants of Salmonella Salmonella
typhimuriumtyphimurium
Fig. 7.13
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What mutations tell us about gene What mutations tell us about gene structurestructure
Complementation testing tells us whether two Complementation testing tells us whether two mutations are in the same or different genesmutations are in the same or different genes
Seymour Benzer’s phage experiments demonstrate Seymour Benzer’s phage experiments demonstrate that a gene is a linear sequence of nucleotide pairs that a gene is a linear sequence of nucleotide pairs that mutate independently and recombine with that mutate independently and recombine with each other, down to the adjacent-nucleotide level.each other, down to the adjacent-nucleotide level.
Some regions of chromosomes and even individual Some regions of chromosomes and even individual bases mutate at a higher rate than others – hot bases mutate at a higher rate than others – hot spotsspots
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Complementation testing:Complementation testing:the cis-trans test identifies gene bordersthe cis-trans test identifies gene borders
Fig. 7.15 a
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Five complementation groups (different genes) for eye color.Recombination mapping demonstrates distance between genes and alleles.
Fig. 7.15 b,c
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A gene is a linear sequence of A gene is a linear sequence of nucleotide pairsnucleotide pairs
Seymore Benzer mid 1950s – 1960sSeymore Benzer mid 1950s – 1960s If a gene is a linear set of nucleotides, If a gene is a linear set of nucleotides,
recombination between homologous chromosomes recombination between homologous chromosomes carrying different mutations within the same gene carrying different mutations within the same gene should generate wild-type should generate wild-type
T4 phage as an experimental system – the rII geneT4 phage as an experimental system – the rII gene Can examine a large number of progeny to detect rare Can examine a large number of progeny to detect rare
mutation eventsmutation events In the appropriate host, could allow only recombinant In the appropriate host, could allow only recombinant
phage to proliferate while parental phages diedphage to proliferate while parental phages died
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Hershey and Chase Waring blender Hershey and Chase Waring blender experimentexperiment
Fig. 6.5 a,b
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Fig. 6.5Fig. 6.5
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Benzer’s experimental procedureBenzer’s experimental procedure
Generated 1612 spontaneous point mutations and Generated 1612 spontaneous point mutations and some deletionssome deletions
Mapped location of deletions relative to one Mapped location of deletions relative to one another using recombinationanother using recombination
Found approximate location of individual point Found approximate location of individual point mutations by deletion mappingmutations by deletion mapping
Then performed recombination tests between all Then performed recombination tests between all point mutations known to lie in the same small point mutations known to lie in the same small region of the chromosomeregion of the chromosome
Result – fine structure map of the Result – fine structure map of the rIIrII gene locus gene locus
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Working with T4 phageWorking with T4 phage
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How recombination within a gene How recombination within a gene could generate wild-typecould generate wild-type
Fig. 7.16
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Phenotpyic properties of T4 phagePhenotpyic properties of T4 phage
Fig. 7.17 b
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Complementation test: are 2 mutations in the Complementation test: are 2 mutations in the same or different genes?same or different genes?
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Detecting recombination between Detecting recombination between two mutations in the same genetwo mutations in the same gene
Fig. 7.17 d
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Deletions for rapid mapping of point Deletions for rapid mapping of point mutations to a region of the chromosomemutations to a region of the chromosome
Fig. 7.18 a
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Recombination Recombination mapping to identify mapping to identify the location of each the location of each
point mutation point mutation within a small within a small
regionregion
Fig. 7.18 b
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Fine structure map of Fine structure map of rIIrII gene gene regionregion
Fig. 7.18 c
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Fig. 7a.p221Fig. 7a.p221
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What mutations tell us about gene What mutations tell us about gene functionfunction
One gene, one enzyme hypothesis: a gene contains One gene, one enzyme hypothesis: a gene contains the information for producing a specific enzymethe information for producing a specific enzyme Beadle and Tatum use Beadle and Tatum use auxotrophicauxotrophic and and prototrophicprototrophic
strains of strains of NeurosporaNeurospora to test hypothesis to test hypothesis Genes specify the identity and order of amino Genes specify the identity and order of amino
acids in a polypeptide chainacids in a polypeptide chain The sequence of amino acids in a protein The sequence of amino acids in a protein
determines its three-dimensional shape and determines its three-dimensional shape and functionfunction
Some proteins contain more than one polypeptide Some proteins contain more than one polypeptide coded for by different genescoded for by different genes
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Beadle and Tatum – One gene, one Beadle and Tatum – One gene, one enzymeenzyme
1940s – isolated mutagen induced mutants that 1940s – isolated mutagen induced mutants that disrupted synthesis of arginine, an amino acid disrupted synthesis of arginine, an amino acid required for required for NeurosporaNeurospora growth growth AuxotrophAuxotroph – needs supplement to grow on minimal – needs supplement to grow on minimal
mediamedia PrototrophPrototroph – wild-type that needs no supplement; can – wild-type that needs no supplement; can
synthesize all required growth factorssynthesize all required growth factors Recombination analysis located mutations in four Recombination analysis located mutations in four
distinct regions of genomedistinct regions of genome Complementation tests showed each of four Complementation tests showed each of four
regions correlated with different complementation regions correlated with different complementation group (each was a different gene)group (each was a different gene)
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50Fig. 7.20 a
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Fig. 7.20 b
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Interpretation of Beadle and Tatum Interpretation of Beadle and Tatum experimentsexperiments
Each gene controls the synthesis of one of the Each gene controls the synthesis of one of the enzymes involved in catalyzing the conversion of enzymes involved in catalyzing the conversion of an intermediate into arginine.an intermediate into arginine.
These enzymes function sequentially.These enzymes function sequentially.
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Genes specify the identity and order of Genes specify the identity and order of amino acids in a polypeptide chainamino acids in a polypeptide chain
Proteins are linear polymers of amino acids linked Proteins are linear polymers of amino acids linked by peptide bonds by peptide bonds 20 different amino acids are building blocks of proteins20 different amino acids are building blocks of proteins NHNH22-CHR-COOH – carboxylic acid is acidic, amino -CHR-COOH – carboxylic acid is acidic, amino
group is basicgroup is basic R is the side chain that distinguishes each amino acidR is the side chain that distinguishes each amino acid
Fig. 7.21 a
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R is the side group that distinguishes each R is the side group that distinguishes each amino acidamino acid
Fig. 7.21 b
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56Fig. 7.21 b
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N terminus of a protein contains a free amino groupN terminus of a protein contains a free amino groupC terminus of protein contains a free carboxylic acid groupC terminus of protein contains a free carboxylic acid group
Fig. 7.21 c
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Fig. 7.22Fig. 7.22
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Sequence of amino acids determine a proteins Sequence of amino acids determine a proteins primary, secondary, and tertiary structureprimary, secondary, and tertiary structure
Fig. 7.23
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Some proteins are multimeric, containing subunits Some proteins are multimeric, containing subunits composed of more than one polypeptidecomposed of more than one polypeptide
Fig. 7.24
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Dominance relations between alleles depend on the Dominance relations between alleles depend on the relation between protein function and phenotyperelation between protein function and phenotype
Alleles that produce nonfunctional proteins are usually recessiveAlleles that produce nonfunctional proteins are usually recessive Null mutationsNull mutations – prevent synthesis of protein or promote synthesis of – prevent synthesis of protein or promote synthesis of
protein incapable of carrying out any functionprotein incapable of carrying out any function Hypomorphic mutationsHypomorphic mutations – produce much less of a protein or a protein – produce much less of a protein or a protein
with weak but detectable function; usually detectable only in with weak but detectable function; usually detectable only in homozygoteshomozygotes
Incomplete dominance – phenotype varies in proportion to Incomplete dominance – phenotype varies in proportion to amount of proteinamount of protein Hypermorphic mutationsHypermorphic mutations – produces more protein or same amount of a – produces more protein or same amount of a
more effective proteinmore effective protein Dominant negativeDominant negative – produces a subunit of a protein that blocks the – produces a subunit of a protein that blocks the
activity of other subunitsactivity of other subunits Neomorphic mutationsNeomorphic mutations – generate a novel phenotype; example is ectopic – generate a novel phenotype; example is ectopic
expression where protein is produced outside of its normal place or timeexpression where protein is produced outside of its normal place or time
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Fig. 6.17bFig. 6.17b
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Fig. 6.17cFig. 6.17c
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Fig. 6.17dFig. 6.17d
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Fig. 6.17eFig. 6.17e
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Fig. 6.17fFig. 6.17f
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Fig. 6.18abcFig. 6.18abc
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Fig. 6.18defFig. 6.18def
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Fig. 6.19Fig. 6.19
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Fig. 6.20abFig. 6.20ab
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Fig. 6.20cFig. 6.20c
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Fig. 6.21Fig. 6.21
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Fig. 6.22aFig. 6.22a
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Fig. 6.22bFig. 6.22b
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Fig. 6.22cFig. 6.22c
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Fig. 6.22dFig. 6.22d
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Fig. 6.22eFig. 6.22e
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Fig. 6.22fFig. 6.22f
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Fig. 6.22gFig. 6.22g
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Fig. 6.22hFig. 6.22h