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LINKAGE AND GENETIC MAPPING IN EUKARYOTES

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Title: LINKAGE AND GENETIC MAPPING IN EUKARYOTES


1
LINKAGE AND GENETIC MAPPING IN EUKARYOTES
  • Chapter 5

2
INDEPENDENT ASSORTMENT
  • Mendels law of independent assortment
  • Alleles of different genes assort themselves
    independently during meiosis
  • Genes reside upon chromosomes
  • Chromosomes assort themselves independently
    during meiosis
  • Chromosome theory of inheritance

3
INDEPENDENT ASSORTMENT
  • Each species contains thousands of genes
  • Most species have at most a few dozen chromosomes
  • Each chromosome must carry hundreds or thousands
    of genes
  • Genes located close to each other on a chromosome
    do NOT assort independently during meiosis

4
LINKAGE
  • Genes located on the same chromosome display
    unique patterns of inheritance
  • Data from such genetic crosses are used to
    construct genetic maps
  • Describe the order of genes along the chromosome
  • Newer strategies for gene mapping have largely
    replaced traditional means

5
LINKAGE
  • Eukaryotic chromosomes contain very long pieces
    of DNA
  • Contains numerous genes
  • Generally hundreds or thousands
  • Two or more genes located on the same chromosome
    are linked

6
LINKAGE
  • The term linkage has two related meanings
  • Two or more genes on the same chromosome are
    physically linked
  • Two ore more genes on the same chromosome are
    genetically linked
  • Tend to be transmitted as a unit

7
LINKAGE
  • The human karyotype has 46 chromosomes
  • All genes on a single chromosome are physically
    linked to each other
  • Chromosomes can be called linkage groups
  • 22 autosomal linkage groups
  • X linkage group
  • Y linkage group
  • Genes located far apart from each other on the
    same chromosome may assort independently
  • Crossing over can occur between these genes

8
LINKAGE
  • One can study the transmission of two or more
    traits in a genetic cross
  • e.g., Dihybrid cross, trihybrid cross, etc.
  • The outcome of such a cross is dependent upon
    whether these genes are linked to each other
  • Linkage affects the transmission of these alleles
    and traits

9
LINKAGE
  • Alleles for different genes may be linked along
    the same chromosome
  • This linkage can be altered during meiosis
  • Homologous chromosomes of diploid eukaryotic
    species can exchange pieces with each other
  • Crossing over
  • Occurs during prophase I of meiosis

10
LINKAGE
  • Sister chromatids associate with homologous
    sister chromatids
  • Two pairs of sister chromatids form a bivalent
  • A sister chromatid of one pair commonly crosses
    over with a sister chromatid from the other pair
  • Can alter arrangements of linked genes
  • Crossing over can lead to genetic recombination
  • Alteration of the arrangement of linked alleles

11
LINKAGE
  • AB and ab gametes are parental
  • Non-recombinant
  • Ab and aB gametes are non-parental
  • Recombinant

12
BATESON PUNNETT, 1905
  • Traits of sweet peas
  • Flower color can be either purple or red
  • Purple is dominant to red
  • Pollen shape can be either oblong or round
  • Oblong is dominant to round

13
BATESON PUNNETT, 1905
  • Purple, long (PPLL) x red, round (ppll)
  • F1 offspring are purple, long (PpLl)
  • F2 possess four different phenotypes
  • 296 Purple long
  • 19 Purple, round
  • 27 Red, long
  • 85 Red, round
  • Observed ratio is 15.6 1.0 1.4 4.5
  • Expected ratio of 9 3 3 1 is NOT seen!

14
BATESON PUNNETT, 1905
  • F2 generation
  • Parental phenotypes were overrepresented
  • Non-parental phenotypes were underrepresented
  • These two genes do not assort independently
  • Physically linked on the same chromosome
  • The nature of this physical linkage was not
    apparent to Bateson and Punnett at this time

15
THOMAS HUNT MORGAN
  • Thomas Hunt Morgan
  • Lord of the Flies
  • Investigated several traits following an
    X-linked inheritance pattern
  • Demonstrated that the genes governing these
    traits were located on the X chromosome
  • Provided the first direct evidence that
    different genes are physically linked on the
    same chromosome

16
THOMAS HUNT MORGAN
  • Traits in Morgans cross
  • The yellow body allele (y) is recessive to the
    gray body allele (y)
  • The white eyed allele (w) is recessive to the red
    eyed allele (w)
  • The miniature wing allele (m) is recessive to the
    normal winged allele (m)

17
THOMAS HUNT MORGAN
  • Traits in Morgans cross
  • P generation yy ww mm x y w m Y
  • F1 generation yy ww mm and y w m Y
  • F2 generation
  • 8 phenotypes present
  • NOT equally represented

18
THOMAS HUNT MORGAN
  • Traits in Morgans cross
  • P generation yy ww mm x y w m Y
  • F1 generation yy ww mm and y w m Y
  • F2 generation
  • 758 y_w_m_
  • 700 yywwmm
  • 401 y_w_mm
  • 317 yywwm_
  • 16 y_wwmm
  • 12 yyw_ m_
  • 1 y_ wwm_
  • 0 yy w_ mm

19
THOMAS HUNT MORGAN
  • High proportions of parental allele combinations
  • Nonparental combinations also did exist
  • 758 y_w_m_
  • 700 yywwmm
  • 401 y_w_mm
  • 317 yywwm_
  • 16 y_wwmm
  • 12 yyw_ m_
  • 1 y_ wwm_
  • 0 yy w_ mm

? Parental
? Parental
20
THOMAS HUNT MORGAN
  • Morgans conclusions
  • All three genes are located on the X chromosome
  • Tend to be transmitted together as a unit
  • Nonparental combinations of alleles resulted
    from crossing over
  • Physical exchange of segments between X
    chromosomes
  • Crossover frequency is dependent upon the
    distance between the genes
  • Fewer crossovers between genes very close
    together

21
THOMAS HUNT MORGAN
  • Morgans conclusions
  • Crossover frequencies between linked genes
    reflect the distance between these genes
  • 758 y_w_m_
  • 700 yywwmm
  • 401 y_w_mm
  • 317 yywwm_
  • 16 y_wwmm
  • 12 yyw_ m_
  • 1 y_ wwm_
  • 0 yy w_ mm

? Parental (no crossovers)
? Parental (no crossovers)
? Crossover between w and m
? Crossover between w and m
? Crossover between y and w
? Crossover between y and w
? Double crossover (y w, w m)
22
THOMAS HUNT MORGAN
  • Morgans conclusions
  • Crossover frequencies reflect the distance
    between these genes
  • No crossovers (most likely)
  • 758 y_w_m_
  • 700 yywwmm
  • Crossover between w and m (fairly likely)
  • 401 y_w_mm
  • 317 yywwm_
  • Crossover between y and w (unlikely)
  • 16 y_wwmm
  • 12 yyw_ m_
  • Double crossover (very unlikely)
  • 1 y_ wwm_
  • 0 yy w_ mm

23
CHI SQUARE ANALYSIS
  • Chi square analysis can evaluate the fit between
    a hypothesis and observed experimental data
  • Can be used to determine if data from a dihybrid
    vross is consistent with linkage or independent
    assortment
  • Standard hypothesis Genes are not linked
  • Determine whether data fit this hypothesis
  • Low chi square value
  • Cannot reject hypothesis
  • Infer that genes assort independently
  • High chi square value
  • Reject hypothesis
  • Conclude that the genes are linked

24
CHI SQUARE ANALYSIS
  • Insert chi square problem here

25
CREIGHTON McCLINTOCK
  • Obtained direct evidence that genetic
    recombination is due to crossing over
  • Performed crosses in maize (Zea mays)
  • Crosses involved parental chromosomes with
    unusual structural features
  • Homologous chromosomes could be microscopically
    distinguished
  • Recombinant offspring could be correlated with
    microscopically observable exchanges in segments
    of homologous chromosomes

26
CREIGHTON McCLINTOCK
  • Creighton and McClintock used a normal and an
    abnormal version of maize chromosome 9
  • Abnormal version possessed two microscopically
    detectable features
  • Darkly staining knob at one end
  • Extra piece of a chromosome at the other end
  • Translocation of a portion of chromosome 8

27
CREIGHTON McCLINTOCK
  • Creighton and McClintock studied genes at both
    ends of chromosome 9
  • A gene governing colored (C) or colorless (s)
    kernels was located near the knobbed end of the
    chromosome
  • A gene governing starchy (Wx) or waxy (wx)
    endosperm texture was located near the other end
    of the chromosome

28
CREIGHTON McCLINTOCK
  • Creighton and McClintocks cross
  • Parent A
  • Knobbed/translocated chromosome 9 (C wx)
  • Cytologically normal chromosome 9 (c Wx)
  • Parent B
  • Two cytologically normal copies of chromosome 9
  • Genotype cc Wxwx

29
CREIGHTON McCLINTOCK
  • Creighton and McClintocks cross
  • Parent A can produce four different gametes
  • Two are non-recombinant (parental)
  • Two are recombinant
  • Recombinant offspring always corresponded to
    microscopically observable exchanges between
    homologous chromosomes

30
CREIGHTON McCLINTOCK
  • Pairing chromosomes, heteromorphic in two
    regions, have been shown to exchange genes
    assigned to these regions

31
MITOTIC CROSSING OVER
  • Several rounds of mitosis generally follow
    fertilization in multicellular organisms
  • Mitosis normally does not involve the pairing of
    homologous chromosomes
  • Crossing over does not normally occur during
    mitosis
  • Mitotic crossing over does sometimes occur
  • Mitotic recombination

32
MITOTIC CROSSING OVER
  • Mitotic recombination
  • Rare
  • Produces recombinant chromosomes
  • May possess a new combination of alleles
  • Some happen early in development
  • Produces a patch of tissue in the adult
  • e.g., Unusual patches on Drosophila bodies are
    due to mitotic recombination

33
MITOTIC CROSSING OVER
  • yy snsn x y sn Y
  • Yellow vs. grey body
  • Singed vs. normal bristles
  • yy snsn zygote formed
  • Develops into embryo, then adult
  • Wild-type coloration and bristles

34
MITOTIC CROSSING OVER
  • yy snsn zygote develops into embryo
  • Mitotic recombination occurs in one embryonic
    cell
  • Recombinant chromosomes possess new
    combinations of alleles

35
MITOTIC CROSSING OVER
  • Mitotic recombination occurs in one embryonic yy
    snsn cell
  • Cell divides to produce two adjacent cells
  • Different genotypes
  • yy snsn yy snsn
  • Mitotic division expands each cell into a patch
    of cells
  • yy snsn ? grey, singed
  • yy snsn ? yellow, normal
  • Twin spot

36
GENETIC MAPPING
  • Genetic mapping
  • Gene mapping
  • Chromosome mapping
  • Determines linear order and distance between
    genes linked along the same chromosome
  • Each gene has its own locus at a particular
    site within a chromosome

37
GENETIC MAPPING
  • Genetic maps are useful in many ways
  • Allows an understanding of the overall complexity
    and genetic organization of a particular species
  • Comparison of genetic maps between different
    species improves our understanding of their
    evolutionary relationships

38
GENETIC MAPPING
  • Genetic maps are useful in many ways
  • Information can be used to diagnose and
    potentially to treat mapped human diseases
  • Helps genetic counselors predict the likelihood
    of couples transmitting inherited diseases
  • Can provide plant and animal breeders with
    important information for selective breeding
    programs

39
GENETIC MAPPING
  • The linear order of genes can be deduced from the
    frequency of non-parental offspring
  • Genetic linkage maps can be produced
  • Useful for analyzing organisms easily crossed to
    produce numerous offspring in short periods of
    time
  • e.g., Drosophila, several plant species, etc.
  • Traditional mapping approaches are difficult for
    many organisms
  • e.g., Humans, etc.
  • Alternative methods of gene mapping have been
    developed
  • See chapter 20

40
GENETIC MAPPING
  • The frequency of recombination is correlated to
    the distance between genes
  • Crossovers are unlikely between two genes very
    close together on a chromosome
  • Tightly linked genes
  • Few recombinant offspring will be produced
  • Crossovers are more likely between two genes
    located far apart on a chromosome
  • Alleles of such genes are more likely to
    recombine
  • Many recombinant offspring will be produced

41
GENETIC MAPPING
  • One can distinguish recombinant from parental
    offspring when conducting a testcross
  • An individual heterozygous for two or more genes
    is crossed to an individual homozygous
    recessive for these genes

42
GENETIC MAPPING
  • se se se se testcross
  • Parental offspring
  • 542 se se
  • 537 se se
  • Recombinant offspring
  • 76 se se
  • 75 se se

43
GENETIC MAPPING
  • Distances between genes are measured in map units
  • 1 map unit equals 1 recombination frequency
  • Also called centiMorgans
  • In honor of Thomas Hunt Morgan

44
GENETIC MAPPING
  • The map distance between two genes can be
    calculated
  • (Recombinant offspring / total offspring) x 100
  • (76 75 / 542 537 76 75) 100
  • (151 / 1230) 100
  • 12.3 map units
  • 12.3 centiMorgans

45
STURTEVANTS GENETIC MAPS
  • Alfred Sturtevant
  • Constructed the first genetic map in 1911
  • Undergraduate in T. H. Morgans lab
  • Studied the inheritance of six recessive X-linked
    alleles (of five different genes)
  • y (yellow body color)
  • w (white eye color)
  • w-e (eosin eye color)
  • v (vermilion eye color)
  • m (miniature wings)
  • r (rudimentary wings)

46
STURTEVANTS GENETIC MAPS
  • Sturtevants hypothesis
  • The distance between genes can be estimated from
    the proportion of recombinant offspring
  • Sturtevants experiment
  • Various crosses between females heterozygous for
    two genes and doubly recessive males
  • Pairwise testcrosses

47
STURTEVANTS GENETIC MAPS
  • Sturtevants data
  • Percent recombinant offspring calculated for each
    pair of alleles

48
STURTEVANTS GENETIC MAPS
  • Interpreting the data
  • Map distances likely to be more accurate between
    genes that are closely linked
  • y w are 1.0 map unit apart
  • v and r are 3.0 map units apart
  • r and m are 23.9 map units apart
  • w and v are 29.7 map units apart

49
STURTEVANTS GENETIC MAPS
  • Interpreting the data
  • Other features of the data allowed the
    determination of gene order
  • v is between w and r
  • w and r show a 33.7 recombinant frequency
  • w and v show a 29.7 recombinant frequency
  • v and r show a 3.0 recombinant frequency
  • etc.

50
STURTEVANTS GENETIC MAPS
  • Interpreting the data
  • As the percentage of recombinant offspring
    approaches 50, this value becomes less accurate
    as a measure of map distance

51
GENETIC MAPPING
  • Sturtevant used multiple dihybrid testcrosses to
    make his genetic maps
  • Trihybrid crosses can be used to determine the
    order and distance between linked genes

52
GENETIC MAPPING
  • Trihybrid crosses
  • Cross true-breeding strains differing in three
    alleles
  • Perform a testcross with an F1 female
  • Crossovers can produce recombinant gametes in F1
    females
  • Collect data from the F2 generation
  • Eight possible phenotypes
  • 2 parental, 6 recombinant
  • Construct linkage map

53
GENETIC MAPPING
  • Trihybrid testcrosses yield eight possible
    phenotypes in the F2 generation
  • 2 parental
  • 6 recombinant
  • 2 from a single crossover
  • 2 from another single crossover
  • 2 from a double crossover

54
GENETIC MAPPING
  • One can compute the likelihood of double
    crossovers in trihybrid testcrosses
  • Product rule is used
  • Observed numbers of double crossovers are often
    lower than expected numbers
  • Result of positive interference

55
GENETIC MAPPING
  • Interference
  • The occurrence of a crossover decreases the
    probability that a second crossover will happen
    nearby
  • The first crossover interferes with the ability
    to form a second crossover in the immediate
    vicinity
  • Interference 1 coefficient of coincidence (C)
  • C observed double crossovers / expected doubles

56
MAPPING IN HAPLOID EUKS
  • Certain species of lower eukaryotes have also
    been used in mapping studies
  • e.g., Unicellular algae and fungi
  • May be unicellular or multicellular
  • Spend part of their life cycle in a haploid state

57
MAPPING IN HAPLOID EUKS
  • Fugal cells are typically haploid
  • Reproduce asexually by mitosis
  • Can reproduce sexually by the fusion of two
    haploid cells to form a zygote
  • Zygote can proceed through meiosis to produce
    four haploid spores
  • This group of four spores is called a tetrad
  • (Not to be confused with a tetrad of four sister
    chromatids)
  • In some species, meiosis is followed by a single
    round of mitosis to produce eight spores

58
MAPPING IN HAPLOID EUKS
  • Fugal cells are typically haploid
  • Reproduce asexually by mitosis
  • Can reproduce sexually by the fusion of two
    haploid cells to form a zygote
  • Zygote can proceed through meiosis to produce
    four haploid spores
  • This group of four spores is called a tetrad
  • (Not to be confused with a tetrad of four
    sister chromatids)

This is an alga, not a fungus, but the life cycle
is similar.
59
MAPPING IN HAPLOID EUKS
  • Ascomycetes
  • Sac fungi
  • Products of a single meiotic division are
    contained within a sac known as an ascus
  • Each ascus contains four (or eight) spores
  • These spores are called ascospores
  • Asci can be dissected and each haploid spore
    studied

60
TETRADS
  • The arrangement of spores within an ascus varies
    between species
  • Unordered tetrads
  • Spores of a tetrad randomly mix together
  • e.g., Saccharomyces cerevisiae, Chlamydomonas
    rheinhardii, etc.
  • Ordered tetrads
  • Tight ascus prevents spores from mixing
  • e.g., Neurospora crassa, etc.

61
TETRADS
  • The arrangement of spores within an ascus varies
    between species
  • Unordered tetrads
  • Spores of a tetrad randomly mix together
  • e.g., Saccharomyces cerevisiae, Chlamydomonas
    rheinhardii, etc.
  • Ordered tetrads
  • Tight ascus prevents spores from mixing
  • e.g., Neurospora crassa, etc.

62
ORDERED TETRADS
  • Ordered tetrads
  • Position and order of spores within the ascus
    reflects their relationship to each other as they
    were produced
  • Allows mapping of genes relative to the
    centromere
  • Centromere is cytologically visible
  • Correlates a genes location with cytological
    characteristics of a chromosome

63
ORDERED TETRADS
  • Ordered tetrads
  • Segregation patterns can be used to map genes
    relative to the centromere

64
UNORDERED TETRADS
  • Unordered tetrads
  • Contain products of a single meiosis event
  • Spores are randomly arranged within ascus
  • Can be used to map genes in dihybrid crosses

65
UNORDERED TETRADS
  • Ura arg x ura-2 arg-3
  • Three possible combinations of four haploid cells
  • Four spores with the parental allele combination
  • Parental ditype (PD)
  • Four spores with the nonparental allele
    combination
  • Nonparental ditype (NPD)
  • Two parental and two nonparental allele
    combinations
  • Tetratype (T)

66
UNORDERED TETRADS
  • Independent assortment
  • 50 PD, 50 NPD are expected
  • Linkage
  • No crossover yields PD
  • Single crossover yields T
  • Double crossovers can yield PD, T, or NPD

67
UNORDERED TETRADS
  • Double crossovers can yield PD, T, or NPD
  • Four chromatid double crossover yields NPD
  • Three chromatid double crossover yields T
  • Two chromatid double crossover yields PD

68
UNORDERED TETRADS
  • Data from a tetrad analysis can be used to
    calculate the map distance between two linked
    genes
  • Map distance is calculated as the percentage of
    offspring that carry recombinant chromosomes
  • Map distance (NPD ½ T / total asci) 100
  • (single X tetrads 2 double X / total
    tetrads) 100
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