7A - Genetics

Question 1

Define a gene.

Answer 1

A sequence of bases on a DNA molecule that codes for a protein (polypeptide) which results in a characteristic.

Question 2

Define an allele.

Answer 2

A different version of a gene.

Question 3

How many alleles can there be for a gene?

Answer 3

Several.

Question 4

What makes different alleles different?

Answer 4

The order of bases in the gene.

Question 5

Define genotype.

Answer 5

The alleles an organism has for a certain gene.

Question 6

Define phenotype.

Answer 6

An organism’s characteristics as a result of the expression of the genotype.

Question 7

Define dominant.

Answer 7

The allele that is expressed in the heterozygous genotype.

Question 8

Define recessive.

Answer 8

The allele that is expressed only in the homozygous genotype.

Question 9

How are dominant alleles represented?

Answer 9

Uppercase letters

Question 10

How are recessive alleles represented?

Answer 10

Lowercase letters

Question 11

Define codominant.

Answer 11

Alleles that are both expressed in the heterozygous. Neither one is recessive.

Question 12

Define locus.

Answer 12

The fixed position of a gene on a chromosome.

Question 13

Define homozygote.

Answer 13

An organism that carries two copies of the same allele.

Question 14

Define heterozygote.

Answer 14

An organism that carries two different alleles.

Question 15

Define carrier.

Answer 15

A person carrying an allele which is not expressed in the phenotype but that can be passed on to offspring.

Question 16

Are humans haploid or diploid?

Answer 16

Diploid - We have two sets of chromosomes, so we have two alleles for each gene.

Question 17

What can be used to predict the genotypes and phenotypes of offspring produced in genetic crosses?

Answer 17

Genetic diagrams

Question 18

What is monohybrid inheritance?

Answer 18

The inheritance of a characteristic controlled by a single gene.

Question 19

What things must be shown in a Punnet square question?

Answer 19

1) List the parents’ genotypes.
2) List the gametes’ alleles.
3) Draw the square to show the cross between the gametes.
4) Write out the proportions of resulting genotypes and phenotypes.
5) Answer the question.

Question 20

Remember to revise monohybrid cross diagrams.

Answer 20

Pg 168 and 169 of revision guide.

Question 21

What are the F1 and F2 phenotypes?

Answer 21

• F1 - First generation phenotypes

* F2 - Second generation phenotypes

Question 22

Give an example of codominance.

Answer 22

Sickle-cell anaemia

Question 23

How is codominance represented in genetic diagrams?

Answer 23

• A large, capital letter is given for the gene (e.g. H)
• A superscript capital latter is given for each allele

Example genotypes: HSHN (where S and N are superscript)

Question 24

Explain genetic inheritance for sickle-cell anaemia.

Answer 24

• Homozygous for normal haemoglobin = HNHN -> Don’t have the disease
• Homozygous for sickle haemoglobin = NSHS -> All blood cells are sickle-shaped
• Heterozygous = HNHS -> Sickle-cell trait with some normal and some sickle haemoglobin

Question 25

What are multiple alleles?

Answer 25

When there are more than two alleles of the same gene.

Question 26

Give an example of multiple alleles.

Answer 26

Blood groups (ABO system).

Question 27

How are multiple alleles represented in genetic diagrams?

Answer 27

• A large, capital letter is given for the gene (e.g. I)
• A superscript capital latter is given for each allele

Example genotypes: IAIB (where A and B are superscript)

Question 28

Explain genetic inheritance for blood groups.

Answer 28

• IO is the allele for blood group O.
• IA is the allele for blood group A.
• IB is the allele for blood group B.
• IO is recessive, IA and IB are codominant.

Question 29

What blood group does IAIO code for?

Answer 29

A

Question 30

What blood group does IBIO code for?

Answer 30

B

Question 31

What blood group does IAIA code for?

Answer 31

A

Question 32

What blood group does IBIB code for?

Answer 32

B

Question 33

What blood group does IAIB code for?

Answer 33

AB

Question 34

What blood group does IOIO code for?

Answer 34

O

Question 35

Remember to revise codominance and multiple allele genetic diagrams.

Answer 35

Pg 169 of revision guide.

Question 36

What is a dihybrid cross?

Answer 36

A diagram that shows how two different genes are inherited at the same time.

Question 37

Describe how to approach a dihybrid cross diagram question.

Answer 37

Just like monohybrid, except the gametes will contain an allele for each of the two genes.

Question 38

What is phenotypic ratio?

Answer 38

The ratio of different phenotypes in offspring.

Question 39

Give the phenotypic ratio for a monohybrid cross between two heterozygous parents.
(e.g. Rr x Rr)

Answer 39

3 : 1

Dominant : Recessive

Question 40

Give the phenotypic ratio for a dihybrid cross between two heterozygous parents.
(e.g. RrYy x RrYy)

Answer 40

9 : 3 : 3 : 1

Dominant both : Dominant 1st, Recessive 2nd : Recessive 1st, Dominant 2nd : Recessive both

Question 41

Give the phenotypic ratio for a codominant cross between two heterozygous parents.
(e.g. HNHS x HNHS)

Answer 41

1 : 2 : 1

Homozygous for one allele : Heterozygous : Homozygous for second allele

Question 42

Give the phenotypic ratios for these crosses of heterozygous parents:
• Monohybrid
• Dihybrid
• Codominant

Answer 42

• Monohybrid - 3 : 1
• Dihybrid - 9 : 3 : 3 : 1
• Codominant - 1 : 2 : 1

Question 43

For what reasons may the phenotypic ratios not be as expected?

Answer 43

• Sex linkage
• Autosomal linkage
• Epistasis

Question 44

What sex chromosomes do females have?

Answer 44

XX

Question 45

What sex chromosomes do males have?

Answer 45

XY

Question 46

Which sex chromosome is smaller?

Answer 46

Y - It carries fewer genes.

Question 47

What are sex-linked genes?

Answer 47

Genes that are only found on the X chromosome and not on the Y chromosome.

Question 48

How many alleles for sex-linked genes do males carry?

Answer 48

1

Question 49

How does sex-linked gene expression work in males and females?

Answer 49

MALES:
• Have only 1 allele for each sex-linked gene
• This allele is always expressed, whether it is dominant or recessive
FEMALES:
• Have 2 alleles for each sex-linked gene
• Alleles are expressed as with normal genes

Question 50

Give two examples of sex-linked genetic disorders.

Answer 50

• Colour blindness

* Haemophilia

Question 51

Which gender is more likely to inherit sex-linked genetic disorders and why?

Answer 51

• Males have only 1 allele for the gene, while females have 2
• This means males only have to inherit one recessive allele to show the recessive phenotype, while females have to inherit two
• Therefore, males are more likely to show the recessive phenotype

Question 52

Remember to revise colour blindness.

Answer 52

Diagram pg 171 of revision guide

Question 53

How are sex-linked characteristic symbolised in genetic diagrams?

Answer 53

Either:
• X with a superscript upper or lowercase letter
• Y

Question 54

What are the phenotypic ratios for sex-linked genetic disorders?

Answer 54

It depends on the parent genotypes.

Question 55

Define autosome.

Answer 55

Any chromosome that isn’t a sex chromosome.

Question 56

Define autosomal genes.

Answer 56

Genes located on the autosomes.

Question 57

What can be said about genes on the same autosome?

Answer 57

They are linked.

Question 58

Describe how linkage works.

Answer 58

Genes that are on the same autosome stay together during the independent segregation of chromosomes during meiosis I and their alleles will be passed on to the offspring together.

Question 59

What can disrupt autosomal linkage?

Answer 59

Crossing over in meiosis I before independent segregation.

Question 60

What determines how closely genes are linked and why?

Answer 60

• The closer together the genes are on the autosome, the more closely they are linked.
• This is because they are less likely to be separated during crossing over.

Question 61

What is the result of autosomal linkage?

Answer 61

The phenotypic ratios are not as expected.

Question 62

Explain how autosomal linkage changes a dihybrid cross of NnRr x NnRr.

Answer 62

• The normal phenotypic ratios are 9 : 3 : 3 : 1
• The actual phenotypic ratios are about 3 : 1
• This is because the two linked alleles are inherited together so it essentially becomes like a monohybrid cross.
• NOTE: The ratio may actually be a bit different because of some crossing over in meiosis I. There will be some unexpected genotypes: Nnrr and nnRr.

Question 63

Why does a dihybrid autosomal linkage cross not give perfect ratios?

Answer 63

There is some crossing over during meiosis I, giving 4 genotypes instead of the expected 2.

Question 64

In autosomal linkage questions, which alleles will be linked?

Answer 64

Generally, you can assume that the two dominant alleles are inherited together and the two recessive alleles are inherited together.

Question 65

In the cross NnRr x nnrr, a ratio of 8 : 1 : 1 : 8 suggests what?

Answer 65

Autosomal linkage

Question 66

Remember to revise autosomal linkage genetic diagrams.

Answer 66

Pg 172 of revision guide.

Question 67

What is the name for when one gene masks the expression of another?

Answer 67

Epistasis

Question 68

Is a characteristic controlled by only 1 gene?

Answer 68

No, it can be many different genes combining to control the same characteristic.

Question 69

Give an example of epistasis in humans.

Answer 69

• Widow’s peak in hair is controlled by one gene and baldness by others
• If you have the genes that code for baldness, it doesn’t matter whether you have the allele for widow’s peak or not since you have no hair.
• The baldness genes are epistatic to the widow’s peak gene.

Question 70

If gene A masks the expression of gene B, which gene is epistatic to which?

Answer 70

Gene A is epistatic to gene B.

Question 71

Remember to revise epistasis examples.

Answer 71

Pg 172 of revision guide

Question 72

Does epistasis affect phenotypic ratios?

Answer 72

Yes

Question 73

In a dihybrid cross, how does a recessive epistatic allele work?

Answer 73

Having two copies of that allele masks the expression of the other gene.

Question 74

In a dihybrid cross, how does a dominant epistatic allele work?

Answer 74

Having at least one copy of the dominant epistatic allele masks the expression of the other gene.

Question 75

Give the phenotypic ratios for a dihybrid cross involving a recessive epistatic allele and heterozygous parents.
(e.g. YyRr x YyRr)

Answer 75

9 : 3 : 4

Question 76

Give the phenotypic ratios for a dihybrid cross involving a dominant epistatic allele and heterozygous parents.
(e.g. YyRr x YyRr)

Answer 76

12 : 3 : 1

Question 77

Remember to revise epistatic genetic diagrams and examples.

Answer 77

Pg 173 of revision guide

Question 78

What are all the different types of genetic inheritance you need to know about?

Answer 78

• Monohybrid
• Dihybrid
• Codominance
• Multiple alleles
• Sex linkage
• Autosomal linkage
• Epistasis

Question 79

What type of inheritance does a ratio of 3 : 1 suggest?

Answer 79

Monohybrid (or could be autosomal linkage if dihybrid)

Question 80

What type of inheritance does a ratio of 9 : 3 : 3 : 1 suggest?

Answer 80

Dihybrid

Question 81

What type of inheritance does a ratio of 1 : 2 : 1 suggest?

Answer 81

Codominance

Question 82

What type of inheritance does a ratio of 8 : 1 : 1 : 8 suggest?

Answer 82

Autosomal linkage

Question 83

What type of inheritance does a ratio of 9 : 3 : 4 suggest?

Answer 83

Recessive epistatic allele

Question 84

What type of inheritance does a ratio of 12 : 3 : 1 suggest?

Answer 84

Dominant epistatic allele

Question 85

What is the chi-squared test?

Answer 85

A statistical test used to see if the results of an experiment support a theory.

Question 86

What is the expected result in the chi-squared test?

Answer 86

The result that is predicted using a theory.

Question 87

What is the observed result in the chi-squared test?

Answer 87

The result that is actually recorded.

Question 88

What is the null hypothesis in the chi-squared test and what does it state?

Answer 88

• A hypothesis that states that there is no difference between the observed and expected values.
• Rejecting the null hypothesis shows that the difference is significant.

Question 89

How is the chi-squared test used in genetics questions?

Answer 89

To see if the observed phenotypic ratios are different to the expected ones for a certain genetic cross. This helps determine the type of inheritance.

Question 90

What is the equation for the chi-squared test?

Answer 90

x² = Σ((O-E)²/E)

Question 91

Do you need to learn the chi-squared test equation and be able to use it?

Answer 91

No, you do not, but you need to be able to understand how it works.

Question 92

"Wing length in fruit flies is controlled by a single gene with two alleles (monohybrid inheritance). The dominant allele (N) gives normal wings and the recessive allele (n) gives vestigial wings. Two heterozygous parents are bred."
For this theory, give:
• The test
• Expected result
• Observed result
• Null hypothesis

Answer 92

• The test - Chi-squared test
• Expected result - 3 : 1 phentoypic ratio of normal : vestigial wings
• Observed result - The number of each phenotype counted after the cross
• Null hypothesis - There is no significant difference between the observed and expected results.

Question 93

What does p=0.05 mean?

Answer 93

The 5% probability that a result is due to chance.

Question 94

What is the critical value?

Answer 94

The value of x² that corresponds to a 5% probability that the difference between observed and expected is due to chance.

Question 95

What does an x² value greater than the critical value show in the chi-squared test?

Answer 95

• There is a less than 5% probability that the difference between observed and expected is due to chance.
• Null hypothesis can be rejected.

Question 96

What does an x² value smaller than the critical value show in the chi-squared test?

Answer 96

• There is a greater than 5% probability that the difference between observed and expected is due to chance.
• There is no significant difference between the observed and expected values.
• Null hypothesis cannot be rejected.

Question 97

How is the critical value in the chi-squared test found?

Answer 97

• Look at a table.
• Find the right degree of freedom by taking away 1 from the number of classes (e.g. the number of phenotypes).
• Find the critical value at the p=0.05 level that corresponds to that degree of freedom.

Question 98

Remember to practice interpreting chi-squared tests and finding critical values.

Answer 98

Pgs 174 and 175 of revision guide

Question 99

Remember to practice accepting or rejecting null hypotheses in the chi-squared test, then drawing conclusions.

Answer 99

Exercise books + pgs 174 and 175 of revision guide