Chapter 9 Genetic Diversity

Question 1

What is a mutation?

Answer 1

A random change in the DNA which results in a change to the sequence of bases.

Question 2

How many bases in a codon?

Answer 2

Codons have 3 bases.

Question 3

What strand is a codon on?

Answer 3

Codons are found on mRNA.

Question 4

What base replaces Thymine in RNA?

Answer 4

Uracil

Question 5

Where are anticodons found?

Answer 5

tRNA molecules

Question 6

Explain the term degenerate in terms of the genetic code.

Answer 6

Although each codon is specific for only one amino acid (or one stop signal), the genetic code is described as degenerate, or redundant, because a single amino acid may be coded for by more than one codon.

Question 7

What is a substitution mutation?

Answer 7

Replacement of a base of DNA.

Question 8

What is a deletion mutation?

Answer 8

Removal of one of the bases in DNA.

Question 9

What is an insertion mutation?

Answer 9

The insertion of one base in the DNA.

Question 10

What is a frameshift mutation?

Answer 10

When an insertion or deletion results in the entire code being shifted by one base.

Question 11

Which type of mutation is most likely to result in no amino acid change and why?

Answer 11

Substitution because the maximum change will be one incorrect amino acid in the entire protein. Due to the degenerate nature of DNA it is possible that the substitution will result in no changes to the amino acid sequence.

Question 12

Describe the effects of a frameshift mutation on the amino acid sequence and the final protein.

Answer 12

Frameshift mutations result in errors in the codons for all amino acids following the mutation. This results in incorrect amino acid sequences and usually non-functional proteins.

Question 13

What do mutagenic agents do to the probability of mutations occurring?

Answer 13

Mutagenic agents increase the probability of mutations occurring.

Question 14

With no mutagenic agents present would you still get mutations? Why/why not?

Answer 14

Yes. Mutations randomly occur at a relatively constant rate.

Question 15

Describe a positive effect of mutations.

Answer 15

The formation of new beneficial alleles. Mutations are the drivers of evolution.

Question 16

What types of cells are produced by meiosis?

Answer 16

Gametes.

Question 17

What are gametes?

Answer 17

Gametes are sex cells such as eggs, sperm, pollen and ovules.

Question 18

What is an allele?

Answer 18

An allele is a different form of a gene. Alleles are created through mutation.

Question 19

Name the stages in meiosis.

Answer 19

Prophase I, Metaphase I, Anaphase I, Telophase I, Prophase II, Metaphase II, Anaphase II, Telophase II

Question 20

Briefly describe what happens at each stage in meiosis.

Answer 20

Interphase

Interphase is technically not a part of meiosis but it must take place before meiosis.
It involves the replication of DNA to produce genetically identical chromatids.
Prophase I

Chromosomes condense
Nuclear envelope disintegrates
Spindle fibres begin to form
Homologous chromosomes pair up
Crossing over occurs
Metaphase I

Chromosomes align on the cell equator
Spindle fibres attach to the kinetochore on the centromeres
Independent assortment occurs
The position of each homologous pair is independent of all the other chromosomes
The maternal and paternal chromosomes can be on either side of the equator
Anaphase I

Homologous chromosomes are pulled by the spindle fibres to the poles
This causes the genetic variation
Telophase I

Nuclear envelopes reform
Chromosomes uncoil
The cells undergo cytokinesis
These cells are now haploid cells
Prophase II

Beginning of second division:
Chromosomes re-condense
Nuclear envelope breaks down again
Spindle fibres reform
Metaphase II

Chromosomes are aligned on the equator by the spindle fibres
Independent assortment occurs again
More genetic variation is caused
Spindle fibres begin to attach to centromere
Anaphase II

Chromatids are split apart by the spindle fibres
Chromatids move to the poles of the cells
This is the same as anaphase in mitosis
Telophase II

Chromatids uncoil
Nuclear envelopes reform
The cell undergoes cytokinesis
4 haploid daughter cells are produced

Question 21

Draw diagrams to show the stages in meiosis.

Answer 21

Question 22

How many chromatids does a chromosome at Prophase I have?

Answer 22

2

Question 23

What significant process happens during prophase I?

Answer 23

Crossing over

Question 24

What significant process happens during metaphase I?

Answer 24

Independent assortment

Question 25

Explain how independent assortment takes place. Use diagrams to illustrate it.

Answer 25

The way that a pair of chromosomes line up at the equator during metaphase I is independent of the way other chromosomes line up.

Question 26

In a diploid organism with 16 chromosomes, how many combinations of chromosomes could there be after meiosis I? How can you work this out?

Answer 26

Use the formula combinations = 2n
With n = number of homologous pairs
If there are 16 chromosomes there are 8 pairs
Total combinations = 28
= 256

Question 27

When does independent assortment of chromosomes occur during meiosis?

Answer 27

Metaphase I, Metaphase II

Question 28

How many chromatids does a daughter chromosome have after they have been split in meiosis II?

Answer 28

Each daughter cell has 1 chromatid.

Question 29

Describe a haploid nucleus. Which cells have a haploid nucleus?

Answer 29

A haploid cell only has one set of chromosomes in its nucleus. Gametes are haploid.

Question 30

Describe a diploid nucleus. Which cells have a diploid nucleus?

Answer 30

A diploid cell has 2 sets of chromosomes in its nucleus. These are homologous pairs. Each pair codes for the same genes. All cells aside from gametes in humans are diploid.

Question 31

What processes result in the 4 gametes produced being genetically different from each other?

Answer 31

Independent assortment

Crossing over

Question 32

Give three differences between mitosis and meiosis.

Answer 32

Meiosis is reductive division - it produces 4 haploid cells. Mitosis results in 2 daughter cells that are diploid.

Meiosis involves 2 cell divisions, mitosis involves 1 cell division.

Meiosis produces cells that are genetically different from each other. Mitosis produces cells genetically identical to each other and also identical to the original cell.

Question 33

What is nondisjunction and when does it happen?

Answer 33

Nondisjunction occurs during anaphase I or anaphase II when gametes are produced. It is caused by a failure of chromosomes to separate due to spindle fibre failure. It results in cells with an incorrect number of chromosomes.

Question 34

Name 4 syndromes that are the result of nondisjunction.

Answer 34

Down Syndrome is also known as trisomy 21 and involves having an extra copy of chromosome 21.
Edwards’ Syndrome is also called trisomy 18 and involves having an extra copy of chromosome 18.
Turner Syndrome only affects females and involves missing one X chromosome.
Jacob’s Syndrome only affects males and involves having an extra copy of the Y chromosome.

Question 35

Which stage of meiosis does crossing over occur?

Answer 35

Crossing over occurs during prophase I.

Question 36

What is a chiasma?

Answer 36

A chiasma is a point of crossing over. It physically links the homologous chromosomes to each other.

Question 37

What does the term ‘bivalent’ refer to?

Answer 37

Bivalent is a term used to describe a pair of homologous chromosomes linked by chiasmata.

Question 38

Describe what happens during crossing over.

Answer 38

During crossing over chromatids from sister chromosomes form chiasmata. At each chiasma the DNA is broken, a section of DNA is swapped and the DNA joins together resulting in recombinant chromatids.

Question 39

Why would happen if crossing over takes place between non-homologous chromosomes?

Answer 39

Non-homologous chromosomes do not code for the same genes. Crossing over between non-homologous chromosomes results in a mutation called a translocation.

Question 40

What would happen if two chromatids from the same chromosome crossed over?

Answer 40

Genetically identical sections of DNA would be swapped leading to no change in the DNA and no recombinants produced.

Question 41

What is the name for a crossover point?

Answer 41

Chiama (singular)
Chiamata (plural)

Question 42

How does crossing over increase genetic variation ?

Answer 42

Crossing over results in recombinants with a different combination of alleles than either original chromosome. All 4 gametes produced are genetically different from each other.

Question 43

How can you identify where meiosis has occurred in a lifecycle?

Answer 43

You can tell if meiosis has occurred because the chromosome number has halved (2n → n) or if a diploid individual is producing haploid cells.

Question 44

Name three gametes apart from sperm and eggs.

Answer 44

Ovules, pollen, spores

Question 45

What is genetic diversity?

Answer 45

Genetic diversity is the number of different alleles of genes in a population.

Question 46

What is genetic variation?

Answer 46

Genetic variation is the variation in the DNA sequence in each of our genomes. Essentially the genetic differences between individuals.

Question 47

How do mutations lead to genetic variation?

Answer 47

Mutations result in the formation of new alleles. This increases the variation between individuals of the same species.

Question 48

How does meiosis lead to genetic variation?

Answer 48

During meiosis independent assortment of chromosomes during anaphase I and II and crossing over during prophase I lead to recombinations of alleles and increase variation.

Question 49

How does sexual reproduction lead to genetic variation?

Answer 49

Sexual reproduction involves a random fertilisation event. This increases variation as no 2 zygotes produced from the same parents will be the same.

Question 50

Give 3 environmental factors that can result in variation within a population.

Answer 50

Climate

Food availability

Light intensity

Question 51

What are the steps involved in natural selection?

Answer 51

Random mutation can result in new alleles of a gene.

There is variation within a population.

Many mutations are harmful but, in certain environments, the new allele of a gene might benefit its possessor, leading to increased reproductive success.

The advantageous allele is inherited by members of the next generation.

As a result, over many generations, the new allele increases in frequency in the population.

Question 52

What is a selection pressure?

Answer 52

A selection pressure is an external agent which affects an organism’s ability to survive in a given environment. Selection pressures can be negative (decreases the occurrence of a trait) or positive (increases the proportion of a trait).

Question 53

Give 8 examples of selection pressures.

Answer 53

PANDA PAW
Predation

Availability of resources

Nutrient supply

Disease

Accumulation of waste

Phenomena (Natural disasters)

Abiotic conditions

Weather

Question 54

What is meant by selective advantage?

Answer 54

A selective advantage increases an organism’s ability to survive and therefore pass on its advantageous alleles to the next generation.

Question 55

Define evolution.

Answer 55

Evolution is the gradual change in the frequency of alleles in a population over time due to natural selection.

Question 56

What does ‘survival of the fittest’ mean?

Answer 56

“Fitness” means how well suited an organism is to its environment. Those best suited to their environment are more likely to survive long enough to reproduce and pass on their genes.

Question 57

What is another name for a Normal Distribution?

Answer 57

Gaussian distribution.

Question 58

What is the symbol for ‘population mean’?

Answer 58

µ

Question 59

What is standard deviation?

Answer 59

Standard deviation is represented by sigma σ. It shows how dispersed the data is relative to the mean.

Question 60

What type of graph do we often use to show the spread of the phenotype of a population?

Answer 60

We use histograms to show the spread of phenotypes in a population.

Question 61

What are the features of a histogram?

Answer 61

Histograms have bars that are the same width and without gaps between them.

Question 62

Give the 3 types of selection.

Answer 62

Stabilising, directional and disruptive.

Question 63

Draw a graph to show the effect of stabilising selection.

Answer 63

Question 64

Give an example of stabilising selection in action.

Answer 64

Human birth weights show stabilising selection. The mean is favoured. Extremes in birth weight increase the chance of death. Low birth weights increase the risk of stillbirth. High birth weights increase complications during labour and increase risk of death.

Question 65

Draw a graph to show the effect of directional selection.

Answer 65

Question 66

Give an example of directional selection in action.

Answer 66

Antibiotic resistance in bacteria is an example of directional selection. Use of antibiotics is selected for bacteria with resistance.

Question 67

Draw a graph to show the effect of disruptive selection.

Answer 67

Question 68

What are adaptations?

Answer 68

Adaptation, in biology, is the process by which a species becomes suited to its environment; it is the result of natural selection acting upon heritable variation over several generations.

Question 69

What are the three types of adaptation?

Answer 69

Anatomical
Behavioural
Physiological

Question 70

Why is adapting to live in extreme climates an advantage?

Answer 70

There is less competition in extreme environments.

Question 71

What is an anatomical adaptation?

Answer 71

Anatomical adaptations are physical features. These can be internal or external. They occur in plants and animals.

Question 72

What is a behavioural adaptation?

Answer 72

Behavioural adaptations are to do with the actions of an animal.. These can be innate or learned behaviours.

Question 73

What is a physiological adaptation?

Answer 73

Physiological adaptations are biochemical and happen inside the organism. Often these cannot be observed easily.

Question 74

Give examples of anatomical adaptations in plants.

Answer 74

Sunken stomata, waxy cuticle, seed shape, spines, swollen stems.

Question 75

Give examples of anatomical adaptations in animals.

Answer 75

Body covering (shells or fur), camouflage, teeth or beaks, mimicry, thick blubber, large body size.

Question 76

Give examples of behavioural adaptations in plants.

Answer 76

Phototropism, geotropism, ability to eat insects.

Question 77

Give examples of behavioural adaptations in animals.

Answer 77

Survival, hibernation, courtship.

Question 78

Give examples of physiological adaptations in plants.

Answer 78

Toxin production, CAM photosynthesis, seed dormancy.

Question 79

Give examples of physiological adaptations in animals.

Answer 79

Homeostasis, reflexes.

Question 80

How do bacteria reproduce?

Answer 80

Binary fission

Question 81

How is the nutrient agar medium sterilised when preparing to grow microorganisms?

Answer 81

Using an autoclave.

Question 82

What substances need to be present in a bacterial broth or nutrient agar?

Answer 82

The nutrient medium contains vitamins, nitrogen, carbohydrates and salts.

Question 83

Describe and explain the conditions in an autoclave.

Answer 83

The autoclave subjects the contents to high pressure, high temperature and steam.
This kills all microbes.

Question 84

Give the steps you would take to work aseptically.

Answer 84

Close windows and doors to reduce draughts and prevent sudden movements which might disturb the air.

Make transfers over a disinfected surface.

Start the operations only when all apparatus and materials are within immediate reach.

Complete all operations as quickly as possible, but without any hurry.

Vessels must be open for the minimum amount of time possible.

While vessels are open, all work must be done close to a Bunsen burner flame where air currents are drawn upwards.

On opening a test tube or bottle, the neck must be immediately warmed by flaming with the vessel held as near to horizontal as possible and so that any movement of air is outwards from the vessel.

During manipulations involving a Petri dish, limit exposure of the sterile inner surfaces to contamination from the air.

The parts of sterile pipettes which will be put into cultures or sterile vessels must not be touched or allowed to come into contact with other non-sterile surfaces, such as clothing, the surface of the working area, or the outside of bottles/test tubes.

All items which come into contact with microorganisms must be sterilised before and after each such exposure.

Question 85

Explain why you would work near a Bunsen burner when working aseptically.

Answer 85

Always work within 20 cm of a Bunsen flame. The convection current produced reduces the changes of environmental microbes contaminating your plate.

Question 86

How is the equipment sterilised during the practical?

Answer 86

Flaming in the Bunsen flame or disinfecting with ethanol.

Question 87

Describe the lawn plate spreading technique.

Answer 87

Add a few drops of the sample to the plate. Use a sterile L spreader to cover the plate evenly.

Question 88

What are two hazards of plating bacteria?

Answer 88

Contamination of microbes from the environment. These would then be cultured and could be harmful.

Release of sample microbes into the environment due to spills or poor technique.

Question 89

How is the agar plate stored after inoculation?

Answer 89

Plates are stored upside down in an incubator at 25°C.

Question 90

Why are plates stored upside down after inoculation?

Answer 90

Storing plates upside down reduces the formation of condensation on the lid. It also reduces the chances of bacteria landing on the agar surface.

Question 91

Explain the reasons for not sealing the lid to the agar plate using sticky tape after inoculation.

Answer 91

Sticky tape is used to keep lids closed. Closed lids are never opened in a school. We do not completely seal the plates because this creates an anaerobic environment that promotes the growth of dangerous pathogenic anaerobic bacteria such as E. coli.

Question 92

Explain the reasons for incubating at 25°C after inoculation.

Answer 92

A temperature of 25°C promotes growth as enzymes will work faster at warmer temperatures. We do not heat above 25°C because incubating at temperatures near to human body temperature may promote the growth of human pathogens.

Question 93

Describe how you would make a serial dilution of a bacterial culture that has a dilution factor of 10.

Answer 93

Question 94

What is the zone of inhibition?

Answer 94

The area around an antimicrobial disc where there is no growth of microbes.

Question 95

What can the zone of inhibition be used for?

Answer 95

To measure the effectiveness of microbial agents on reducing microbe growth.

Question 96

Give three examples of antibiotics.

Answer 96

Antibiotics
Amoxicillin, Ampicillin and Penicillin —inhibit steps in cell wall synthesis (prevents the building of new cell walls so cells cannot divide)

Norfloxacin – inhibits DNA replication so cells cannot divide

Erythromycin—inhibits RNA translation for protein synthesis so the cell cannot function

Question 97

Why do we use the disc diffusion method for determining the effectiveness of antibiotics?

Answer 97

It allows multiple antibiotics to be tested at once allowing the results to be more valid.

Question 98

What is a CFU?

Answer 98

A CFU is a colony forming unit. Basically it is a living bacterial cell that is capable of dividing and forming a colony on a plate.

Question 99

Why is a multidisc better to use than individual pre-soaked discs of antibiotics?

Answer 99

For the comparisons to be valid the concentration of antibiotic on each disc must be the same. Multi Discs are prepared industrially ensuring the concentrations are the same.

Question 100

How does the antibiotic get into the agar?

Answer 100

The antibiotic diffuses into the agar. This results in antibiotic concentrations being higher closer to the disc and decreasing as the distance from the disc increases.

Question 101

What is the MIC?

Answer 101

The minimum inhibitory concentration. This is the lowest concentration of antibiotic needed to inhibit the growth of the bacteria. It is used to determine dosage to give patients.

Question 102

Give 4 reasons why the dosage given to patients is always more than the MIC?

Answer 102

It is possible that not all of the antibiotics are absorbed.

Some of the antibiotics may get metabolised in the body or excreted.

A higher dosage ensures that all of the bacteria will be killed.

There may be some bacteria that possess antibiotic resistance