Natural Selection and Genetic Modification COPY

Question 1

What is natural selection?

Answer 1

Individuals in a population show genetic variation because of differences in alleles from mutations. Predation, competition for resources and disease act as selection pressures. Individuals with beneficial characteristics have a better chance of survival so are more likely to breed. This means the alleles are more likely to be passed on, while worse alleles are less likely to survive. Beneficial characteristics become more common over time.

Question 2

How do bacteria provide evidence for evolution?

Answer 2

Bacteria sometimes develop random mutations in their DNA, creating new alleles and characteristics. The characteristic could be better resistance to antibiotics. This is a big advantage for bacteria, as it is more likely to survive, so it lives longer and reproduces many more times. This leads to antibiotic resistance being passed on to lots of offspring, so it spreads.

Question 3

How did Darwin come up with the theory of evolution by natural selection?

Answer 3

He spent 5 years on a voyage around the world studying plants and animals on a ship called HMS Beagle. He noticed variation in members of the same species and that characteristics most suited to the environment were more likely to survive. He also noticed that characteristics could be passed on to offspring. He wrote his theory to explain his observations.

Question 4

How did Wallace contribute to the theory of evolution?

Answer 4

He was a scientist working at the same time as Darwin. He independently came up with the idea of natural selection and they published their papers together, acknowledging each other’s work. He provided lots of evidence, such as warning colours used by some species to deter predators, an example of a beneficial characteristic that had evolved.

Question 5

How do fossils give us clues about human ancestors?

Answer 5

Evidence from fossils suggests that humans and chimpanzees evolved from a common ancestor that existed about 6 million years ago. Human beings and ancestors are known as hominids, with several species found. They have characteristics between apes and humans, allowing us to see how humans have evolved over time.

Question 6

Who is Ardi?

Answer 6

She is a fossil of the species Ardipithecus ramidus, found in Ethiopia and 4.4 million years old. Her feet structure suggests she climbed trees, with an ape like big toe. She had long arms and short legs, with a brain size about the same as a chimpanzee’s. she probably walked upright without using her hands for help.

Question 7

Who is Lucy?

Answer 7

She is a fossil of the species Australopithecus afarensis, found in Ethiopia and 3.2 million years old. She had arched feet and no ape like big toe, better adapted to walking. The size of her arms and legs was between apes and humans. Her brain was slightly larger and she walked upright more efficiently.

Question 8

What fossils did Leakey find?

Answer 8

Richard Leakey and his team organised an expedition to Kenya. One of their finds was Turkana Boy, a 1.6 million year old fossil skeleton of the species Homo erectus. He is more human like than Lucy, with short arms and long legs, and a much larger brain similar to human size. He was even better adapted to walking upright than Lucy.

Question 9

How does the development of stone tools provide evidence for human evolution?

Answer 9

From 2.5-1.5 million years ago Homo habilis made simple stone tools called pebble tools by hitting rocks together to make sharp flakes.
From 2-0.3 million years ago Homo erectus sculpted rocks into shapes to produce more complex tools like simple hand axes.
From 300,000-25,000 years ago Homo neanderthalis made more complex tools out of materials like flint.
From 200,000-present Homo sapiens used flint and pointed tools, more recently making hooks, buttons and needles.

Question 10

How can stone tools be dated?

Answer 10

Looking at structural features - simpler tools are likely to be older
Using stratigraphy - the study of rock layers. Older rock layers are normally found below younger layers
Using carbon-14 dating - tools found with carbon-containing material e.g. wood can be dated accurately

Question 11

How does the pentadactyl limb provide evidence for evolution?

Answer 11

A pentadactyl limb is a limb with five digits. It is found in many species of mammals, reptiles, amphibians and others. They all have a similar bone structure but different functions. This suggests all these species came from a common ancestor but evolved in different ways.

Question 12

How were organisms classified in the past and today?

Answer 12

Traditionally they were classified according to similarities and differences in their observable characteristics. Microscopes were then used to identify smaller characteristics e.g. cell structure. We can now determine the sequence of DNA bases in different organisms’ genes and compare them, and the same with RNA.

Question 13

What is the five kingdom classification system?

Answer 13

Organisms are divided into five kingdoms: animals, plants, fungi, prokaryotes, and protists. The system goes:
Kingdom, Phylum, Class, Order, Family, Genus, Species
King Phillip Came Over For Good Soup

Question 14

What is the domain system for classification?

Answer 14

Using RNA sequencing, Woese found that some members of the Prokaryote kingdom were not as closely related as first thought. He split this kingdom into Archaea and Bacteria. He created the domain classification first:
Archaea - look similar to bacteria but are different, first found in extreme places
Bacteria - true bacteria
Eukarya - fungi, plants, animals, and protists

Question 15

What is selective breeding?

Answer 15

When humans artificially select the plants or animals that are going to breed so that the genes for particular characteristics remain in the population. Organisms are selectively bred to develop features that are useful or attractive.

Question 16

What are some examples of selective breeding?

Answer 16

Animals that produce more meat or milk
Crops with disease resistance
Dogs with a good, gentle temperament
Plants that produce bigger fruit

Question 17

How does selective breeding work?

Answer 17

Select from your existing stock ones with the characteristics you want
Breed them with each other
Select the best of the offspring and breed them together
Continue this process over several generations and the desirable trait gets stronger and stronger

Question 18

What are the disadvantages of selective breeding?

Answer 18

It reduces the gene pool - the number of different alleles in a population. The ‘best’ animals used for breeding are closely related, so inbreeding occurs.
Inbreeding can cause health problems because there is more chance of inheriting harmful genetic defects. This leads to ethical considerations, particularly if negative characteristics are bred for research.
Less variation means there is less chance of resistance alleles being present for new diseases, so disease can wipe out lots of the population.

Question 19

What is tissue culture?

Answer 19

The growing of cells in an artificial growth medium

Question 20

What are the advantages of tissue culture in plants?

Answer 20

Whole plants can be grown via tissue culture. This is very easy, can happen very quickly, in very little space, and all year round. Plants produced are clones. This means you can replicate the same beneficial features, such as pesticide resistance or tasty fruit.

Question 21

How is tissue culture in plants carried out?

Answer 21

Choose a plant you want cloned and remove a small piece of tissue, ideally from fast growing root or shoot tips
Grow the tissue in a growth medium containing nutrients and growth hormones. This is done under aseptic (sterile) conditions to prevent growth of microbes
As the tissues produce shoots and roots they can be moved to potting compost to carry on growing

Question 22

What are the advantages of tissue culture in medical research?

Answer 22

You can carry out experiments in isolation, looking at the effects of a particular substance or environmental change on the cells of a single tissue, without complications from other processes in the whole organism.
You can use just a small layer of tissue, allowing you to see processes directly

Question 23

How is tissue culture in animals carried out?

Answer 23

A sample of the tissue you want to study is extracted from the animal
The cells in the sample are separated from each other using enzymes
They are placed in a culture vessel and bathed in a growth medium containing nutrients, allowing them to grow and multiply
After several rounds of cell division, the cells can be split up again and placed into separate vessels for further growth
Once the tissue culture has been grown, it can be stored for further use

Question 24

What are restriction enzymes?

Answer 24

Enzymes that recognise specific sequences of DNA and cut the DNA at these points, leaving them with sticky ends

Question 25

What are ligase enzymes?

Answer 25

Enzymes used to join two pieces of DNA together at their sticky ends

Question 26

What is recombinant DNA?

Answer 26

Two different bits of DNA stuck together

Question 27

What is a vector?

Answer 27

Something used to transfer DNA into a cell. There are two sorts: plasmids and viruses. Plasmids are small, circular molecules of DNA that can be transferred between bacteria. Viruses insert DNA into the organisms they infect.

Question 28

How does genetic engineering work?

Answer 28

Cut out the DNA you want to insert with a restriction enzyme. Cut open the vector DNA with the same restriction enzyme
Mix the vector and the desired DNA with ligase enzymes. They join the pieces to make recombinant DNA
The recombinant DNA is inserted into other cells e.g. bacteria
These cells can now use the gene you inserted to make the protein you want.

Question 29

How is genetic engineering useful in agriculture and medicine?

Answer 29

Crops can be modified to be resistant to herbicides. Farmers can them spray their crops to kill weeds without affecting the crop itself. This can increase yield
Bacteria can be made to produce human insulin for people with diabetes. Human genes can be transferred into sheep and cows, which can then be extracted e.g. from their milk. Animals producing suitable organs for human transplant might also be later produced.

Question 30

What are some disadvantages of genetic engineering?

Answer 30

It can be hard to predict what effect modifying its genome will have on an organism. Many GM embryos do not survive and some that do suffer from health problems.
Transplanted genes may get out into the environment e.g. herbicide resistance genes being passed to weeds. They could adversely affect food chains
Countries may become dependent on companies who sell GM seeds

Question 31

How can crops be modified to get insect resistance?

Answer 31

The bacterium Bacillus thuringiensis produces a toxin that kills many insect larvae that are harmful to crops. The gene can be inserted into crops, which they then produce in stems and leaves, making them resistant. The bacterium is harmless to humans, animals and other insects, although long term effects are not known. Insects could also become resistant.

Question 32

How can GMOs be used to provide more food?

Answer 32

Crops resistant to pests or better able to grow in drought conditions can help improve crop yields. Some crops can be engineered to combat deficiency disorders e.g. Golden Rice produces a chemical that is converted in the body to vitamin A

Question 33

What other techniques can be used to increase food production?

Answer 33

Fertilisers can be applied to poor soils
Pests can be controlled through biological control - introducing other organisms (including predators and parasites) to reduce pest numbers. E.g. cane toads were introduced into Australia to eat beetles that were damaging crops. This can have longer lasting effects and be less harmful to wildlife. However, it can have problems - cane toads are now a pest in Australia because they poison native species that eat them.