Genetic diversity and adaptation - Chapter 9

Question 1

What is gene mutation ?

Answer 1

Any change to one or more nucleotide bases or a change in the sequence of bases in the DNA

Question 2

When can gene mutation arise, and what do they include ?

Answer 2

They can arise spontaneously during DNA replication and include base substitution, base deletion or base addition

Question 3

What is location ?

Answer 3

Germline in gametes or somatic in body cells

Question 4

What are the two types of gene mutations ?

Answer 4

1) Point mutation
2) Frameshift mutations

Question 5

What is a point mutation ?

Answer 5

A change in a single nucleotide (also known as substitution)

Question 6

What is a frameshift mutation ?

Answer 6

Addition or deletion of nucleotides resulting in a shift of the reading frame

Question 7

What are the three types of point mutations ?

Answer 7

1) Silent point mutation
2) Nonsense point mutation
3) Missense point mutation

Question 8

What is a silent mutation ?

Answer 8

There is no change to the primary structure of the polypeptide despite the change in a nucleotide base
[If a substitution does not change the amino acid)

Question 9

Why is a silent mutation possible?

Answer 9

Due to the degenerate nature of the genetic code.
Mutation would have no effect on the production of the final polypeptide

Question 10

What is a missense mutation ?

Answer 10

There is a change to a single amino acid at the point of the mutation
[If a substitution changes the amino acid ]

Question 11

What is the effect of a missense mutation ?

Answer 11

It will be determined by the role of the amino acid in the final polypeptide.
( May be that it was involved in the formation of bonds to structure the active site of an enzyme )

Question 12

What does a missense mutation occur due to ?

Answer 12

A mutation in the hameoglobin gene

Question 13

What is a nonsense mutation ?

Answer 13

The new codon is now a stop codon so translation stops at the point of mutation
[If a substitution changes the amino acid to a “stop” ]

Question 14

What does a nonsense mutation lead to ?

Answer 14

The premature end to the synthesis of a polypeptide

Question 15

What is a reading frame?

Answer 15

A way of dividing the sequence of nucleotides on a DNA/RNA molecule into consecutive,
non- overlapping triplets

Question 16

What is deletion mutation (type of frameshift mutation) ?

Answer 16

A base is lost /deleted
This occurs when a nucleotide is lost from the DNA sequence

Question 17

What can deleting a base lead to ?

Answer 17

The codons not being read properly.
This is due to the fact bases are read in triplets, therefore the subsequent bases would all be shifted forward by one base ( a frameshift )
Usually the amino acid sequence of the ‘new’ code will be entirely different

Question 18

What will happen to the reading frame + bases when deleting a base ?

Answer 18

The reading frame changes, the bases don’t move

Question 19

What is base insertion (type of frameshift mutation) ?

Answer 19

The insertion (addition) of a single nucleotide base

[ an extra base is added/ inserted ]

Question 20

What will happen to the amino acid sequence in base insertion + deletion mutation ?

Answer 20

The amino acid sequence codes for something different

Question 21

Define the term mutagenic agent ?

Answer 21

A factor that increases the rate of mutations

Question 22

What is the importance of meiosis?

Answer 22

In sexual reproduction, two gametes fuse to give rise to new offspring.
It is responsible for the formation of gametes

Question 23

What are the gametes in humans ?

Answer 23

Egg + sperm

Question 24

What are the gametes in plants ?

Answer 24

Egg + pollen

Question 25

What is the difference between meiosis compared to mitosis?

Answer 25

Meiosis: two nuclear divisions, haploid cells (one set of chromosomes), introduces genetic variation
Mitosis: one nuclear division, diploid cells ( two sets of chromosomes ), create genetically identical cells

Question 26

What is the process in crossing over of chromatids ?

Answer 26

1. Homologous pairs of chromosomes associate/form a bivalent
2. Chiasmata form
3. Equal lengths of (non-sister) chromatids / alleles are exchanged
4. Producing new combinations of alleles

[When homologous chromosome pairs line up opposite each other at the equator in meiosis 1, the non -sister chromatids of the two chromosomes wrap around each other : called crossing -over
- This puts tension on the chromatids, causing pairs of the chromatids to break off, and exchange between the homologous chromosomes
- because the chromosomes have exchanged DNA, that means they exchange alleles, so crossing over results in new combinations of alleles ]

Question 27

What is a bivalent ?

Answer 27

The attached pair of chromosomes

Question 28

What is chiasmata ?

Answer 28

The points where the chromatids are joined

Question 29

What causes genetic variation in meiosis?

Answer 29

[Chiasmata can form at multiple points so a large number of alleles can be exchanged]
This exchange of alleles is a major source of genetic variation in meiosis

Question 30

Unlike mitosis, where does cell division by meiosis only take place in ?

Answer 30

Sex organs, producing gametes

Question 31

What does meiosis produce

Answer 31

4 haploid cells from a single diploid cell

Question 32

What type of chromosomes do gametes have ?

Answer 32

Individual chromosomes, not pairs

Question 33

Why is it important that gametes are haploid cells?

Answer 33

During fertilisation, gametes fuse together to produce a fertilised egg (zygote)

Question 34

What are homologous chromosomes ?

Answer 34

Chromosomes of similar length with the same genes at the same loci

Question 35

What is independent segregation (detailed explanation ) ?

Answer 35

In meiosis 1, homologous pairs of chromosomes line up opposite each other at the equator of the cell.
It is random which side of the equator the paternal + maternal chromosomes from each homologous pair lie.
These pairs separated, so one of each homologous pair ends up in the daughter cell

Question 36

What does independent segregation create?

Answer 36

A large number of possible combinations of chromosomes in the daughter cells produced

Question 37

How are the large number of possible combinations of chromosomes in the daughter cells produced calculated ?

Answer 37

2^n

2= chromosome pairs (2 chromosomes each time )
n = number of homologous pairs

Question 38

What happens in meiosis 1 and 2?

Answer 38

In meiosis 1, homologous chromosomes are separated from each other
In meiosis 2, sister chromosomes are separated from each other, producing 4 haploid cells

Question 39

What are the stages of meiosis ?

Answer 39

Interphase 1, prophase 1, metaphase 1, anaphase 1, telophase 1, cytokinesis, prophase 2, metaphase 2, anaphase 2, telophase 2, cytokinesis

Question 40

What is interphase 1 ?

Answer 40

[same stage as mitosis stage ]
Before meiosis starts, the cell will have been through interphase
During interphase, DNA replicates (S phase), the cell copies the chromosomes and the organelles (chromosomes not visible)

First the cell enters meiosis 1

Question 41

What happens in prophase 1?

Answer 41

• the chromosomes condense and become visible
• homologous chromosomes link together forming chiasmata
• At this point, crossing over can take place, exchanging alleles between homologous chromosomes
• the nuclear membrane also breaks down
• the centrioles move to opposite poles of the cell
• spindle fibres also start to assemble into the spindle apparatus

Question 42

What happens in metaphase 1?

Answer 42

The pairs of homologous chromosomes are now lined up on the equator of the spindle apparatus

Question 43

What happens in anaphase 1?

Answer 43

• The spindle fibres shorten and the homologous chromosomes move towards opposite poles
  ~~> for this to happen, the chiasmata between homologous chromosomes break

Question 44

What happens in telophase 1?

Answer 44

• The chromosomes have now reached the poles of the cell
• At this point, the nuclear membranes reform and the chromosomes uncoil back to their chromatin state

Question 45

What happens in cytokinesis?

Answer 45

• cell undergoes cytokinesis, dividing into two cells
  ~~> these cells are haploid, because they no longer contain pairs of homologous chromosomes

Question 46

What happens in prophase 2?

Answer 46

• the chromosomes condense + become visible again
• Again the nuclear membrane breaks down and spindle fibres begin to develop

Question 47

What happens in metaphase 2?

Answer 47

• the chromosomes are lined up on the equator of the spindle apparatus

Question 48

What happens in anaphase 2?

Answer 48

• the centromere of each chromosome divides
• the spindle fibres shorten
• the sister chromatids are now pulled towards opposite poles of the cell

Question 49

What happens in telophase 2 ?

Answer 49

• the sister chromatids have reached the poles of the cells : chromosomes
• the nuclear membranes reform + the chromosomes uncoil back to their chromatin state

Question 50

What happens in cytokinesis, after meiosis 2 ?

Answer 50

Each cell undergoes cytokinesis to produce 2 haploid cells

Question 51

How can mutations in the number of chromosomes arise spontaneously by ?

Answer 51

Chromosome non-disjunction during meiosis

Question 52

What does non - disjunction mean?

Answer 52

When the chromosomes or chromatids do not split equally during anaphase

(Detailed explanation :
Sometimes the homologous pairs of chromosomes/chromatids - depending on stage of meiosis
fail to separate leading to the production of gametes with one too many or one too few chromosomes

Question 53

What are 2 possibilities of chromosome mutation ?

Answer 53

1. Aneuploidy
2. Polyploidy

Question 54

What is aneuploidy ?

Answer 54

Changes in the number of individual chromosomes leads to aneuploidy (n+1 or n-1) , happens usually in anaphase

Question 55

What is polyploidy ?

Answer 55

Changes in the number of whole sets of chromosomes can lead to polyploidy (2n gametes)

Question 56

What happens to the chromosomes when it is polyploidy for non-disjunction in meiosis 1 ?

Answer 56

Look at notes for diagram

Each homologous pair is doubled due to DNA replication in interphase
Non-disjunction in meiosis 1 : all chromosomes fail to separate equally
Normal division in meiosis 2 : chromosomes separate equally

Results:
2n gamete (diploid), 2n gamete (diploid), and 2x no chromosomes in gamete

Question 57

How does triploid (3n) happen ?

Answer 57

When 2n gamete (mutated gamete- diploid) fuses with n gamete (normal haploid gamete - 1 copy of homologous pair) creating a triploid (3n)

Changes in whole sets of chromosomes occur when organisms have 3 or more sets of chromosomes rather than the usual 2
(If it happened again, ends up with 4 sets)

Question 58

What happens to the chromosome when it is polyploidy for non-disjunction in meiosis 2?

Answer 58

Look at notes for diagram

3 homologous chromosomes
Each homologous pair is doubled due to DNA replication in interphase

Normal division in meiosis 1 : chromosomes separate equally
Non-disjunction in meiosis 2 : all chromatids fail to separate equally

Results : n gamete (haploid), n gamete (haploid), no chromosomes, 2n gamete (diploid)

Question 59

Where does polyploidy occur mostly in ?

Answer 59

Occurs mostly in plants (e.g. ferry) but can happen in animals e.g. salamonelles + frogs are polyploids (if in humans, the zygote created wouldn’t survive)
Occurs when organisms have three or more sets of chromosomes

Question 60

What does non-disjunction in aneuploidy result in ?

Answer 60

A gamete having one more or one fewer chromosome.
One fertilisation with a gamete that has the normal number of chromosomes, the resultant zygote will have more or fewer chromosomes than normal in all their body cells

Question 61

What is an example of trisomy ?

Answer 61

Down Syndrome ~> gametes which have an extra chromosome (3 copies of 21 - trisomy), as a result of non-disjunction will cause Down Syndrome

Question 62

What happens to the chromosomes in aneuploidy for non-disjunction in meiosis 1?

Answer 62

-Each homologous pair is doubled due to DNA replication in interphase
- non-disjunction in meiosis 1: one chromosome does not separate equally
- normal division in meiosis 2 : chromatids separate equally

Results :
n+1 (haploid gamete with 1 additional chromosome), n+1 (haploid gamete with 1 additional chromosome), n-1 ( haploid gamete missing one chromosome), n-1 (haploid gamete missing one chromosome )

Question 63

What happens to the chromosomes in aneuploidy for non-disjunction in meiosis 2?

Answer 63

-3 homologous chromosomes
- each homologous pair is doubled due to DNA replication in interphase
- Normal division in meiosis 1
- non-disjunction in meiosis 2 - one chromatid fails to separate equally

Results:
n-1 (haploid gamete missing one chromosome), n+1 (haploid gamete with one additional chromosome), n (haploid gamete), n (haploid gamete)

Question 64

What are mutagenic agents?

Answer 64

A factor that increases the rate of mutations;

Question 65

What are some examples of mutagenic agents?

Answer 65

• UV light
• ionising particles (alpha, beta, gamma)
• carcinogens

Question 66

Genetic diversity and adaptation

Question 67

What is a species?

Answer 67

2 alleles that can produce fertile offspring
~> variation occurs due to difference in the alleles present

Question 68

What is genetic diversity?

Answer 68

The total number of different alleles in a population

Question 69

What is population ?

Answer 69

A group of individuals of the same species that live in the same place + can interbreed

Question 70

What is a gene pool ?

Answer 70

The number of different alleles across all the genes in a population

Question 71

When can natural selection only occur ?

Answer 71

If there is genetic diversity within a population

Question 72

What happens when genetic diversity is reduced ?

Answer 72

The species has fewer different alleles.
This means that the phenotypes of the organisms are all very similar

Question 73

What does genetic variation allow for ? (What would happen if a sudden change was to take effect in genetic diversity?)

Answer 73

The survival of an offspring

If a sudden change was to take effect, there is a greater chance that the whole population would be wiped out

Question 74

What does natural selection lead to ?

Answer 74

Evolution in populations

Question 75

What is evolution ?

Answer 75

The change in allele frequency over many generations in a population

Question 76

What does natural selection result in ?

Answer 76

Species becoming better adapted to their environment.

Adaptations may be anatomical, physiological or behavioural
(Behavioural, structural, functional )

Question 77

What is the process of natural selection ?

Answer 77

1. New alleles for a gene are created by random mutations, creating variation
2. [A random mutation of alleles within this gene pool can make a new phenotype]
   If the new alleles increases the chances of the individual to survive in that environment (if the new allele is advantageous) , they are more likely to
   survive + reproduce
3. This reproduction passes on to the advantageous allele to the next generation (the advantageous allele is inherited by members of the next generation )
4. As a result, over many generations, the new allele increases in frequency in the population.

Question 78

What does structural adaptation to species (as a result of natural selection) mean ?

Answer 78

Changes to the physical features of an organism
E.g. shorter ears

Question 79

What does a functional adaptation of a species (as a result of natural selection ) mean?

Answer 79

Changes to the biological processes to the organism
E.g. oxidising fat rather than carbohydrate in kangaroo rats to produce additional water in a dry desert environment

Question 80

What does a behavioural adaptation of a species (as a result of natural selection ) mean?

Answer 80

Changes to the behaviour of a species
E.g. In Autumn, migration of swallows from the UK to Africa avoid food shortages in the UK winter

Question 81

What is directional selection ?

Answer 81

Selection that favours individuals that vary in one direction from the mean of the population

Particular traits that have the selective advantage

Question 82

What are some key points of directional selection ?

Answer 82

• one of the extremes has the selective advantage
• occurs when there is a change in the environment
• the model trait changes

Question 83

What is stabilising selection ?

Answer 83

Preserves the average characteristics of population and favours average individuals

Question 84

What are some key points if stabilising selection ?

Answer 84

• the model trait has a selective advantage
• occurs when there is no change in the environment
• the modal trait remains the same
• standard deviation decreases, as individuals with the extreme trait decrease

Question 85

What is an example of directional selection ?

Answer 85

• population of birds which use their breaks to open seeds for food
• Beak size varies around the mean, with some birds having a relatively small beak + some having a relatively large beak
• climate is drier ~> plants produce hard seeds
• birds with a smaller beak size struggle to open the seeds for food
• birds with a larger beak size have a selective advantage + are more likely to survive and reproduce
• overtime, the alleles for larger beak size become more common in the gene pool : shifts mean to larger beak size

Summary : as a result of a drought, only large seeds survive to finches with a large beak depth are more likely to survive and reproduce. The average beak depth will eventually shift to be deeper

Question 86

What is a second example of directional selection - antibiotic resistance in bacteria

Answer 86

• in the absence of antibiotic, resistant bacteria have no advantage over non-resistant bacteria. So number of bacteria with antibiotic resistance is low, in a sense of antibiotic
• However, in the presence of antibiotic, resistant bacteria have a selective advantage. Resistant bacteria can survive + reproduce in the presence of antibiotic, whereas non-resistant bacteria are killed by the antibiotic
• so overtime, the gene for antibiotic resistance becomes more common in the population

So, in directional selection, one phenotype is selected over another phenotype. This takes place when the environment changes.

Environmental change = presence of antibiotic

Question 87

What is a third example of directional selection ?

Answer 87

-white-winged moths were more numerous than dark-winged moths.
After industrialisation, dark -winged moths became more numerous than white.
Because, during industrialisation, tree trunks covered by white lichen became dark due to deposition of soot
- white -winged moths can easily be picked up by predators from the dark background + dark -winged moths mostly survived

Question 88

Other stabilising selection key points?

Answer 88

-any extremes of phenotype are selected against
- the individuals with phenotypes closest to the mean are favoured
Alleles closer to the mean become more frequent over time.
-extreme phenotypes are less likely to reproduce
~> so stabilising selection tends to eliminate the phenotypes at the extremes

Question 89

What is an example of stabilising selection ?

Answer 89

• scientists found that babies with a very low or high birth weight were less likely to survive than those with a birth weight around the mean
• As the graph shows, those at the extremes have higher infant mortality rates
• in this case, the extremes of phenotype are very low birth weight and very high birth weight
  Babies born with these birth weights have a higher mortality rate than those born with a birth weight around the mean (genetics play a major role in birth rate)
• babies with a very low/very high birth weight are less likely to survive, the alleles contributing to these birth weights are less likely to be passed on,
  This means that over time, birth weights will stabilise towards the mean with less variation at the extremes

Question 90

Directional selection in bacteria

Question 91

After antibiotics, what strains did we start to see?

Answer 91

Strains of bacteria arising that were not killed by antibiotics. At the time penicillin was the stable antibiotic

Question 92

How did a mutation lead to antibiotic resistance ?

Answer 92

The bacterium that had developed resistance happened, by pure chance, to be in a situation where penicillin was being used to treat a person’s illness

Use of antibiotics puts directional selection pressure on the bacterial population

Question 93

Why is antibiotics an example of natural selection ?

Answer 93

• Bacterium survived was able to divide
• introduction of antibiotics cause frequency of alleles to increase, mutations cause antibiotic resistance
• mutations occur randomly + very rare, occasionally they are advantageous, depends on the circumstance
• the advantageous mutation means the mutants will outcompete + replace the original population

Question 94

What is the transfer of resistant genes?

Answer 94

The genes can be passed down through generations of dividing bacteria (binary fission) once the random mutation has arisen. Through selection, only those with beneficial mutations may survive.

Question 95

What happens if a gene for resistance is found on a plasmid ?

Answer 95

The gene is passed horizontally to another bacterium through conjugation. A conjugation tube is formed between two bacteria, through which a copy of the donor’s plasmid is passed to the recipient

Question 96

Biodiversity

Question 97

What is a species ?

Answer 97

A group of organisms that are capable of breeding to produce living, fertile offspring

Question 98

What is the binomial system ?

Answer 98

First name is GENUS, second name is SPECIES
Same genus shows close relationship

Question 99

What do you write if a species is unknown ?

Answer 99

S.p

Question 100

Why do different species look similar ?

Answer 100

1. Live in a similar environment
2. Have similar selection pressures
3. Similar alleles will have the selective advantage
4. Produces similar/same proteins and therefore have similar characteristics

Question 101

What is a hierarchy ?

Answer 101

Smaller groups arranged within larger groups
No overlaps between groups

Question 102

What is the classification system?

Answer 102

Domain - Eukarya
Kingdom - Animalia
Phylum - Chordata
Class - Mammalia
Order - Carnivora
Family - eanidae
Genus - vulpes
Species - vulpes vulpes

Question 103

What is the acronym for the classification system

Answer 103

King Philip Came Over For Good Soup

Question 104

Why do we need to organise species?

Answer 104

-understand relationships between organisms and keep track of changes
- the system used needs to be universal
- system is based on putting organisms into groups

Question 105

What was the original way to classify ?

Answer 105

Originally, based on visible similarities - e.g appearance, behaviour

Question 106

What are more modern and accurate classification methods ?

Answer 106

Comparing genetic diversity :
- DNA sequence (base sequence of DNA)
- mRNA sequence (base sequence of RNA)
- Amino acids sequence
- Immunological - comparing similarity in self - antibody shape

Question 107

What is phylogenetic classification + what does it tell us ?

Answer 107

Arranges species into groups according to their evolutionary origins and relationships
Phylogeny tells us who’s related to whom and how closely related they are

Question 108

What have all organisms evolved from ?

Answer 108

Shared common ancestors (relatives).
This is shown on a phylogenetic tree

Question 109

What are phylogenetic classifications based on ?

Answer 109

Homologous characteristics

Question 110

What are homologous characteristics ?

Answer 110

These are characteristics in multiple species that all have similar evolutionary origins, regardless of what their function is in adult life.

Question 111

What is artificial classification ?

Answer 111

Organisms are divided into groups based on physical differences such as colour, size, number of legs, or leaf shape
- these are called analogous characteristics

Question 112

What are analogous characteristics + an example ?

Answer 112

Characteristics that have the same function but they do not have the same evolutionary origins.

E.g. the wings of butterflies and birds are both used for flight, but they originated in different ways

Question 113

What is courtship behaviour ?

Answer 113

Behaviours aimed to facilitate attraction and mating with the opposite sex and are very common across the animal kingdom

Question 114

How do animals keep their species alive?

Answer 114

Animals must mate with other members of their own species if they are able to produce viable, fertile offspring