Topic 4

Created by

Ross Adams

Cards (39)

Alfred Russel Wallace 
Developed the theory of speciation, and therefore evolution by natural selection
Alfred Russel Wallace 
Had the idea that the individuals who did not have characteristics to help them survive a change in the environment would die out
Published joint studies with Darwin
Continued to work across the world to collect evidence – one of his most important works was on warning colouration in animals
Charles Darwin 
Scientist and naturalist who put forward the theory of evolution
Charles Darwin 
His theory was supported by experimentation and his knowledge of geology and fossils that he discovered on a round the world expedition
Published 'On the Origin of Species' in 1859
Theory of Evolution
Variation exists within species as a result of mutations in DNA
Organisms with characteristics most suited to the environment are more likely to survive to reproductive age and breed successfully – called survival of the fittest
The beneficial characteristics are then passed on to the next generation
Over many generations the frequency of alleles for this advantageous characteristic increase within the population
There was lots of controversy surrounding Darwin's ideas for many reasons
Antibiotic resistance 
Bacteria are labelled resistant when they are not killed by antibiotics which previously were used as cures against them
Development of antibiotic resistance 
1. Bacteria reproduce at a fast rate
2. Mutations during reproduction can result in new genes, such as the gene for antibiotic resistance
3. Exposure to antibiotics creates a selection pressure, as those with antibiotic resistant genes survive and those without die
4. Those with antibiotic resistance can reproduce and pass on the advantageous gene to their offspring
5. The presence of these new, resistant bacteria supports Darwin's theory of natural selection
Antibiotic resistant bacteria
MRSA
Fossil evidence
Shows how developments in organisms arose slowly
Can be used to estimate when a fossil was formed, giving us a more complete picture of how an organism or species developed over time
Fossil evidence for human evolution 
Ardi - Ardipithecus ramidus, an early human ancestor
Lucy - a fossilised skeleton dating from 3.2 million years ago
Fossils discovered by the archaeologists Louis and Mary Leakey in the 1950s
Dating stone tools 
1. Radiometric carbon dating - by looking at the natural radioactive decay of an isotope of Carbon (Carbon-14) we can estimate how long ago an organism lived
2. Stratifying rock layers - looking at the layer of sediment in which a rock was found
Anatomical evidence for evolution 
Pentadactyl limb - a limb with five digits, implying a common ancestor
The human hand has five digits, but bats, cats, horses and birds also have this pattern within their limbs, suggesting distant relation via a common ancestor
Five Kingdoms system 
Splits all organisms into one of 5 groups: Animals, Plants, Fungi, Prokaryotes, Protists
Each kingdom is then subdivided into a phylum, class, genus, order and species
Three-domain system 
Archaea: primitive bacteria which live in extreme environments
Bacteria: true bacteria
Eukaryota: organisms who have a nucleus enclosed in membranes, includes the kingdoms protists, fungi, plants and animals
Selective breeding 
1. Parents with desired characteristics are chosen
2. They are bred together
3. From the offspring those with desired characteristics are bred together
4. The process is repeated many times until all the offspring have the desired characteristic
Inbreeding 
Breeding those with similar desirable characteristics means it is likely you are breeding closely related individuals
This results in the reduction of the gene pool, as the number of different alleles reduce
This means if the environment changes or there is a new disease, the species could become extinct as they all have the same genetic make-up
Inbreeding 
Breeding those with similar desirable characteristics means it is likely you are breeding closely related individuals
Gene pool 
The number of different alleles reduce (as they mostly have the same alleles)
If the environment changes or there is a new disease 
The species could become extinct as they all have the same genetic make-up (so the chance of a few organisms having a survival advantage and not dying is reduced)
This is particularly relevant in selective breeding of plants, as one disease could spread rapidly and destroy the entire population of crops
Small gene pool 
Greater chance of genetic defects being present in offspring, as recessive characteristics are more likely to present
This is particularly relevant in domesticated animals, which have a much higher frequency of genetic conditions than normal
Tissue culture 
1. Take the plant
2. Remove a piece of tissue from a fast-growing region
3. Place the tissue on a special growth medium
4. Transfer to compost for further growth
Tissue culture 
Culturing living tissue, i.e making it grow outside the organism, within a growth medium
Genetic engineering 
Modifying the genome of an organism by introducing a gene from another organism to give a desired characteristic
Genetic engineering applications 
Plant cells engineered for disease resistance or larger fruits
Bacterial cells engineered to produce substances useful to humans, such as human insulin to treat diabetes
Benefits of tissue culture 
Produces lots of offspring with a specific desirable feature
Increasing the number of crops resistant to bad weather can increase crop yields
Can help extremely endangered species, or even bring back species that have become extinct
Risks of tissue culture 
The gene pool is reduced through producing clones, meaning it is less likely that the population will survive if a disease arises with low diversity in the population
Clones have a low survival rate, and tend to have some genetic problems
It may lead to human cloning
Stages of genetic engineering 
1. Genes from chromosomes are 'cut out' using restriction enzymes
2. The same restriction enzymes are used to cut the vector (such as a virus or bacterial plasmid) into which the genes will be placed
3. Ligase enzyme is used to attach the sticky ends of the gene and the vector together, to produce a recombinant gene product
4. The vector is placed in another organism at an early stage in development so the desired gene moves into its cells and cause the organism to grow with the desired characteristics
In plants the vector is put into meristematic cells (unspecialised cells) which can then produce identical copies of the modified plant
Perceived benefits of genetic engineering 
It can be very useful in medicine to mass produce certain hormones in microorganisms (bacteria and fungi)
It can be used in agriculture to improve yields by improving growth rates, introducing modifications that allow crops to grow in different conditions, and introducing modifications that allow plants to make their own pesticide or herbicide
Crops with extra vitamins can be produced in areas where they are difficult to obtain
Greater yields can help solve world hunger
Perceived risks of genetic engineering 
GM crops might have an effect on wild flowers and therefore insects
GM crops are infertile and these genes could spread into wild plants, leading to infertility in other species, which affects the entire environment
Growing with herbicides and pesticides can kill insects and other plants, which would reduce biodiversity
People are worried that we do not completely understand the effects of GM crops on human health
Genetic engineering in agriculture could lead to genetic engineering in humans, which may result in people using the technology to have designer babies
They pose a selection pressure, which could lead to increased resistance in other species, creating super weeds and pests
Bt crops 
Bacillus thuringiensis is the name of a bacteria that produces toxins that kill insect larvae. Genes from the bacteria are inserted into crops to increase their insect resistance. The crop will then produce the toxin, and any insects that eat the crop will die
Bt crops 
As a result, less of the crop gets eaten by insects, increasing the crop yield and profits
There are concerns over Bt crops - we don't know if the toxin has any effect on human health, and killing insects results in a loss of biodiversity, which can affect the entire ecosystem
Agricultural solutions 
Fertilisers - provide useful nutrients (nitrates and phosphates) to plants, making them more resistant to environmental conditions and able to grow faster and larger, resulting in increased crop yields. However, excess fertiliser can often run off into rivers, killing fish and other wildlife and affecting biodiversity.
Biological control - the use of certain species to control population of other species. For example, Aphelinus abdominalis, the aphid killer wasp, has been used successfully to control aphid populations. However, this reduces biodiversity, and again, has a knock-on effect across the whole ecosystem.
Benefits of selective breeding
It is possible to greatly increase the yield of a particular crop by selectively breeding only individuals that produce higher quality or a larger mass of food
Individual plants or animals can be bred to be resistant to a particular disease, which could increase crop yield
Disadvantages of selective breeding 
Selecting for advantageous characteristics can sometimes cause severe health problems in the offspring
Lack of genetic variation - despite the bred population being able to have resistance to a particular disease (or multiple diseases), if one of them has susceptibility to a different disease then they all do - and the entire population could be wiped out as a result
There are ethical issues associated with selective breeding -many people consider it unethical to selectively breed for characteristics wanted by humans if it means that the offspring will suffer, or have a reduced quality of life as a result