Mendelian Genetics 2

Question 1

What does a chi squared test do?

Answer 1

tells us whether the data are consistent with expectation

Question 2

Chi Squared Formula

Answer 2

Χ² = Σ (O-E)²/E

Question 3

Linkage

Definition

Answer 3

genes that are carried on the same chromosome are said to be linked they tend to segregate together, ie. they do not assort independently of each other

Question 4

Linkage

Example

Answer 4

• 3 loci: A, B and C each with to alleles Aa, Bb and Cc respectively
• if not linked meiosis in the will generate gametes; ABC, abc, Abc, aBC, aBc, AbC, abC, ABcc
• but if they are linked. e.g if A and C are on the same chromosome, then the heterozygote genotype could be either AC/ac B/b, OR Ac/aC B/b
• for Mendelian segregation, we treat the linked alleles as if they are a single locus
  i. e. if the genotype is Ac/aC B/b, then A and c will always segregate together as will a and C
• BUT, we also have to take into account the effects of recombination

Question 5

Coupling

Definition

Answer 5

two alleles are said to be in coupling if they are on the same chromosome

Question 6

Repulsion

Definition

Answer 6

two alleles are said to be in repulsion if they are on different chromosomes

Question 7

Haplotype

Definition

Answer 7

the genotype of a chromosome

Question 8

Recombination Frequency

Definition

Answer 8

• recombination is more likely to occur between two linked loci if they are further apart on the chromosome than if they are closer together
• recombination frequencies of more than 50% cannot occur as this is independent assortment

Question 9

Linkage Mapping

Answer 9

using the frequency with which recombinant offspring occur to determine the relative positions of genes on a chromosome

Question 10

Recombination Frequency

Equation

Answer 10

number of recombinants / total number of offspring
-multiply this by 100 to find a percentage the ercentage is also equal to the distance between the genes on the chromosome in centiMorgans

Question 11

Recombination With 3 Point Crosses

Rules

Answer 11

1. Identify the parental combinations of alleles (most frequent classes)
2. Identify the middle locus (which allele has ‘changed partners’ in the least frequent classes)
3. Calculate the recombination frequnce between each pair of loci

Question 12

Three Point Test Cross

Random Assortment

Answer 12

if unlinked, the genes will independently segregate producing the 8 different phenotypes in a 1:1:1:1:1:1:1:1 ratio

Question 13

Three Point Test Cross

Linkage and Recombination

Answer 13

if linked, 8 different phenotypes will be produced, but the ratio will depend on the distance between the genes on the chromosome

Question 14

Three Point Test Cross

Linkage and No Recombination

Answer 14

if the genes are linked but no recombination occurs, then 2 different phenotypes will be produced from two different phenotypes giving a 1:1 ratio

Question 15

Three Point Test Cross

Answer 15

A+B+C+/abc x abc/abc

homozygous recessive individual crossed with an individual heterozygous for all three genes

Question 16

Three Point Test Cross

How to determine the distance and arrangement of the genes?

Answer 16

1) the genotype for the phenotype that is the least frequent will be the one where two recombination events have taken place, this allows you to identify the middle gene e.g. if least common is A+bC+/aBc, then B is the middle gene
2) from here calculate the distance between the middle gene and the two outside genes separately
3) add together the frequency off all the times that A+ and B+ have segregated together, divide by total number of progeny and x100 to find the distance in cM
4) do the same for B+and C+, add together the frequency of the phenotypes where B+and C+ have segregated together and divide by the total number of progeny then multiply by 100 to find the distance in cM

Question 17

Recombination Interference

Answer 17

Cross over at one point on a chromosome reduces the chance of crossing over occurring at nearby points on the same chromosome, to lower than would be mathematically predicted

Question 18

Three Point Test Cross

Most Frequent Progeny

Answer 18

parental combinations

Question 19

Three Point Test Cross

Least Frequent Progeny

Answer 19

double recombinations

Question 20

1cM

Answer 20

1cM = one centimorgan
relative measure of distance so depends on the genome and rate of recombination in that particular organism
1cM in one genome does not equate to 1cM in another

Question 21

Genotypic Sex Determination

Answer 21

based on organism having specific sex chromosomes that segregate from one another during meiosis

Question 22

Sex Determination

Mammals

Answer 22

XX = female
XY = male

Question 23

Sex Determination

Butterflies

Answer 23

ZZ = male
ZW = female

Question 24

Sex Determination

Amphibians

Answer 24

ZZ = male
ZW = female

Question 25

Sex Determination

Insects

Answer 25

XX = female
XY = male

Question 26

Sex Determination

Some Plants

Answer 26

XX = female
XY = male

Question 27

Sex Determination

Birds

Answer 27

ZZ = male
ZW = female

Question 28

Sex Determination

Nematodes

Answer 28

XX = hermaphrodite
X0 = male

Question 29

Hermaphrodite

Definition

Answer 29

has the reproductive organs of both the male and the female sex

Question 30

XY Sex Determination

Answer 30

50% of offspring will be male and 50% will be female

-each cell in the body has a 50:50 chance of displaying the maternal or paternal sex chromosome

Question 31

Examples of Sex Linked Traits

Answer 31

• tortoiseshell cats

- barred plumage in chickens

Question 32

Epistasis

Definition

Answer 32

interaction between two different genes so that an allele of one of them (the epistatic gene) interacts with or inhibits the phenotypic expression of the other (the hypostatic gene)

Question 33

Sex Determination

Dominant Y Systems

Answer 33

• the presence of the Y chromosome is what determines sex

e. g. even XXY individuals are male (Klinefelter’s syndrome)

Question 34

X Inactivation

Answer 34

-because the heterogametic sex has only one copy of the sex chromosomes whereas the homogametic sex has two copies, there has to be a mechanism to prevent overexpression of genes on the diploid chromosome

Question 35

X Inactivation in Mammals

Answer 35

• known as dosage compensation
• achieved by inactivation of one or other of the X-chromosomes in females
• occurs randomly in different cells during development of the embryo
• its effects can be seen when the X chromosomes are heterozygous for traits like coat colour

Question 36

Tortoiseshell Cats

Answer 36

• colour gene O located on the X chromosome
• two alleles, a recessive allele, ob which results in normal production of melanin (black coat pigment) and a dominant allele, O which results in the formation of an altered form of melanin which is orange
• if a female cat is X0/Xob, in some cells the XO will be inactivated, cells will be black and in others, Xob ill be inactivated so the cells will be ornage
• the sizes of the patches depend on how early in development that the X-chromosome was inactivated
• male cats only have one copy of the X chromosome so can only be either all black or all orange

Question 37

How to determine how many genes control a phenotype?

Answer 37

-collect a population of mutants showing the SAME mutant trait
-interbreed all combinations of the mutant
-

Question 38

Heterogametic Sex

Answer 38

produces two types of gametes, each carrying a different sex chromosome

Question 39

Homogametic Sex

Answer 39

produces one type of gamete all carrying the same sex chromosome

Question 40

Lethal Alleles

Recessive Lethal

Answer 40

absence of gene product results in death of homozygotes

e.g. yellow mice

Question 41

Lethal Alleles

Dominant Lethal

Answer 41

both homozygotes and heterozygotes carrying the allele will die
e.g. Huntingdons

Question 42

Recessive Epistasis

Answer 42

Aabb and AAbb mice have the same phenotype as aabb, epistasis of bb convers A-

Question 43

Duplicate Recessive Epistasis

Answer 43

the two genes code for two proteins e.g. enzymes that take part in successive stages of a pathway i.e. both are required for the final product
-characterised by a 9:7 ratio in the progeny

Question 44

Different Mutations in the Same Gene vs Mutations in Different Genes

Answer 44

• interbreed the mutants
• if any offspring are wildtype, then the mutations are in different genes
• this is the complementation test
• the wildtype allele in one mutant compliments the muntant allele in the other and vice versa at the second locus

Question 45

Different Mutations in the Same Gene vs Mutations in Different Genes

Answer 45

• interbreed the mutants
• if any offspring are wildtype, then the mutations are in different genes
• this is the complementation test
• the wildtype allele in one mutant compliments the muntant allele in the other and vice versa at the second locus

Question 46

Complementation Group

Answer 46

all carry mutations in the same gene

Question 47

Codominance / Incomplete Dominance

Answer 47

a heterozygous individual shows a third phenotype, not the ‘dominant’ or ‘recessive’

Question 48

What is the difference between codominance and incomplete dominance?

Answer 48

• incomplete dominance gives a blending of the ‘dominant’ and ‘recessive’ traits
• codominance is when the ‘recessive’ and ‘dominant’ traits appear together in the phenotype of the hybrid organism