Topic4 as Revision Notes
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Transcript of Topic4 as Revision Notes
AS Biology Unit 2 Topic 4 Revision notes
Plant Structure, properties and uses1) Compare the ultra-structure of plant cells (cell wall, chloroplasts, amyloplasts, vacuole,
tonoplast, plasmodesmata, pits and middle lamella) with that of animal cells.Plant cell structurePlant cell structure
Like animals cells, plants cells areLike animals cells, plants cells areEukaryotic.Eukaryotic.
They also have They also have
••a cell membranea cell membrane
••cytoplasm cytoplasm
••nucleusnucleus
••mitochondriamitochondria
••RER, SERRER, SER
••Golgi apparatusGolgi apparatus
••ribosomesribosomes
••lysosomeslysosomes
Cell wall layer of tough cellulose fibrils which surrounds all plant cells provides mechanical strength, rigidity and support for the cell prevents the cell from bursting
Chloroplasts ‘lens shaped’ many internal membranes (called lamellae) which contain chlorophyll (each lamella is
called a thylakoid, and a stack of thylakoids forms a granum) The sites of photosynthesis which traps light energy and uses it to produce
carbohydrates (sugar etc) from carbon dioxide and water.Vacuole
large central organelle in most plant cells, usually nearly fills the cell surrounded by a membrane called the tonoplast full of fluid (= cell sap; solution of sugars, mineral salts etc) used for storage e.g. sucrose; produce turgor pressure (essential for support)
Amyloplasts A type of membrane-bound organelle called a plastid containing starch (often called
starch grains)Plamosdesmata
Minute pores through the cell wall with cytoplasmic connections continuous with the cytoplasm in adjacent cells
Middle lamella Layer between cell walls of adjacent plant cells Joins the cells together Made of a glue-like material containing polysaccharides called pectins
2) Compare the structure and function of the polysaccharides starch and cellulose including the role of hydrogen bonds between β-glucose molecules in the formation of cellulose microfibrils.
Cellulose:
β-glucose molecules joined by 1,4 glycosidic bonds alternate β-glucose molecules are rotated through 180o
the chains can be very long with between 1000 – 10 000 glucose molecules this results in the cellulose molecule forming a very long straight unbranched chain the hydroxyl (-OH) groups project from both sides of the chain the strength of the cell wall comes from cellulose microfibrils (bundles of 60 – 70
straight unbranched cellulose molecules can lie parallel and held together by hydrogen bonds to form cellulose microfibrils)
spaces between the microfibrils make cell wall freely permeable and can also hold water and allow water to travel by microcapillary action
Starch
- Polymer of α-glucose- Composed of two a-glucose
polymers- Unbranched amylose and
branched amylopectin- Starch molecules form a helix- Compact 3D structure with lots
of ends- Acts as a store of glucose
molecules from which glucose can be released when required
Cellulose
- Polymer of β-glucose- Only one polymer
- Long straight unbranched chains
- Cellulose molecules are straight- Cellulose chains held together by
hydrogen bonds to form bundles- Acts as a strong flexible
structural component of cell walls
3) Explain how the arrangement of cellulose microfibrils in plant cell walls and secondary thickening contribute to the physical properties of plant fibres, which can be exploited by humans.
Location of cells for mechanical support Sclerenchyma and xylem are located in the vascular bundles around the outside edge of the
stem This provides maximum resistance to compression forces (from weight of shoot system) and
bending forces imposed by the wind
How are tall trees supported?As plants get taller they need more strengthening to withstand
compression from the increasing mass of the shoot bending forces from the effect of wind on the larger plant body
This is achieved by division of the cambium (in vascular bundles, between xylem and phloem) which produce more xylem, making wood, which produces the characteristic annual rings; one ring per year.
The distinction between one ring and the next is due to the differing sizes of the xylem vessels produced:
in spring the vessels are large but in summer they are smaller
Xylem cells are produced by differentiation of the unspecialised cells produced by the cambium - xylem cell genes are switched on to produce the characteristics of a xylem vessel
Water transport through xylem vessels
Learn this wording:
Water constantly evaporates from the surface of the cells in the substomatal cavity The water lost is replaced by water moving across the leaf by capillary action through the
cell walls This, in turn, draws water out of the xylem vessels Hydrogen bonding between water molecules, called cohesion, allows continuous columns of
water molecules to be pulled up the xylem by the transpiration stream to replace the water lost by the leaf.
Hydrogen bonding between the water molecules and the cellulose and lignin of the xylem vessel walls, called adhesion, prevents the column falling due to gravity
Water is constantly being removed from the roots into the xylem by diffusion to replace the water which has been transported upwards.
Water moves into and across the root from the soil by diffusion and osmosis.
Movement of water from soil to atmosphere through the plant is called the transpiration stream
4) Compare the structures, position in the stem and function of sclerenchyma fibres (support) and xylem vessels (support and transport of water and mineral ions).
Strengthening cells2 major types of elongated cells with thick, strong lignified walls and no living cell contents: Sclerenchyma and Xylem vesselsCharacteristics:
Cellulose microfibrils run lengthways cellulose cells walls are thickened by the addition of lignin which is impregnated
between the cellulose microfibrils this makes cells stiffer so less flexible and increases the tensile strength reduces the permeablity (so xylem vessels become waterproof) lignified cells are dead
Sclerenchyma cells: called fibres Long, narrow cells with pointed ends to allow fibres to interlock closely (unlike xylem,
they do not form tubes) Very thick lignified walls; strong and inflexible Dead cell (no living protoplast) Principal function is support
Xylem vessels Mature xylem tubes (called vessels have no living contents (i.e. no protoplast, so dead) –
form hollow tubes which consist of lignified wall only so water can flow freely in lumen Xylem vessels are elongated cells; these are joined end to end with no cross walls to
form long continuous tubes Wall thickened with lignin which is
waterproof (so prevents water leaking out) strong (so prevents vessel collapsing)
Water can pass into and out of xylem via pits (perforated holes) in the wall.Lignified walls provide support, strength and flexibility.
Hollow vessels forming continuous tubes allow for the transport of water and dissolved mineral ions
5) Describe how the uses of plant fibres and starch may contribute to sustainability, e.g. plant-based products to replace oil-based plastics.
Plant fibres are useful to us: because fibres = bundles of sclerenchyma and xylem which can be extracted intact from
plants plants from which fibres can be obtained are relatively easy to grow in quantity the fibres themselves are useful because they are long and thin, strong, flexible relatively easily and cheaply extracted, durable, resistant to decay (cellulose is difficult for
decomposers to break down)
Uses for plant fibres include:Clothing e.g. linen (from flax plants); Rope e.g. hemp and sisal; Sacking e.g. jute; Matting e.g. coir or coconut matting; Paper
Sustainability: Advantages of growing for fibres (e.g. nettles) a sustainable resource i.e. re-grow after they are cut so no need to plant more or harvest seeds and plant those so remnants of one crop sustains the next one i.e. it is self-
sustaining can be grown in poorer soils so won’t use up valuable agricultural land make profitable use of marginal land use of fibres (and other plant products made from starch) replace need for oil-based plastics
so reduce reliance of fossil fuels, and reduce CO2 emissions to reduce global warming natural products so biodegradable by decomposers
Sclerenchyma fibres and xylem vessels can be seen through a light microscope.
6) Describe how to determine the tensile strength of plant fibres practically.Core Practical.
The tensile strength of a fibre is a maximum load it can take before it breaks. Attach the fibre to a clamp stand and hang a weight from the other end. Keep adding weights, one at a time until the fibre breaks Record the mass needed to break the fibre, the higher the mass, the higher the tensile
strength. Repeat the experiment with different samples of the same fibre which increases reliability. Throughout the experiment all other variables like temperature and humidity must be kept
constant. Safety measure: wear goggles; leave area where the weight will fall clear so they don’t
squish your toes.
7) Explain the importance of water and inorganic ions (nitrate, calcium ions and magnesium ions) to plants. Inorganic ions are transported in the xylem dissolved in the water transported from root to
shoot in transpiration stream Taken up by roots from soil by a combination of diffusion and active transport. Ions are the source of the elements the plants need to manufacture the complex organic
molecules they needImportance of nitrate ions to plants Taken up as nitrate ion source of nitrogen atoms for making:
o amino acids and proteinso DNA and RNAo component of chlorophyll molecule
plants growing without nitrates are typically stunted, yellow
Importance of calcium ions to plants Taken up as calcium ion; source of calcium atoms for cell walls: forms calcium pectates in
middle lamella to hold cells together plants growing without calcium are typically very stunted, young leaves are yellow and
crinkly.
Importance of magnesium ions to plants Taken up as magnesium ion; source of magnesium atoms for reaction centre for chlorophyll
molecule plants growing without magnesium are typically yellow and growth are slowed down
Importance of phosphate ions to plants They are needed for phosphate groups in ADP and ATP which are involved in energy
transfers in cells. They are also integral to some structural molecules that offer support in plants cells and to
nucleic acids Plants lacking phosphates have very dark green leaves with purple veins and their growth is
stunted.
8) Describe how to investigate plant mineral deficiencies practically.Core practical: Investigation of plant mineral deficiencies.
9) Describe how to investigate the antimicrobial properties of plants.Core practical: Investigation of the antimicrobial properties of plants. Seven test tubes containing nutrient solution of: all nutrients solution, lacking
nitrogen, lacking magnesium, lacking phosphate, lacking calcium and lacking all nutrients and compare.
Cover the top of the tube in foil and push down on the covering so there is a ‘well’ in the centre. Make a hole in the foil
Gentle push the plantlet roots through the hole so it is in the solution below Repeat these steps using the other solutions. Place them in a holder and on a sunny window still. Leave for 24/ a week and
compare.
10) Compare historic drug testing with contemporary drug testing protocols, eg William Withering’s digitalis soup; double blind trials; placebo; three-phased testing.
Development of the use of Digitalis by William Withering in 1775
Digitalis is a natural toxin found in foxgloves (an insect antifeedant) which can be fatal in even quite small doses. But it had been used for centuries in herbal remedies to treat some heart conditions. William Withering rigorously tested digitalis and brought it into conventional medicine in 1785 as a treatment for dropsy (or congestive heart failure) which is the accumulation of fluid and swelling resulting from a weak heart:
o He gave 163 Dropsy sufferers an extract of foxgloveso He increased the dosage until the patient showed signs of side-effects (nausea,
vomiting, diarrhoea and yellow/green vision - some of his patients nearly died!)o He then reduced the dosage slightly => the most effective doseo Successful treatment was that the patient survived and there was an increase in the
effectiveness of the heart beat (digitoxin is a stimulant) and an increase in urine production to remove the excess fluid
What was ethically wrong with this?o An overdose of Foxglove is fatalo He gave more and more to his patients until they either showed signs of recovery or
nearly died
Modern drug testing
Stage Purpose of stage
Pre-clinical testing
Proposed drug is tested in a lab with cultured cells to see the general effects of the drugProposed drug is given to animals to see the effects on a whole animal. Any side effects away from target cells are noted.
Clinical Trials – Phase 1
A small group of healthy volunteers are given different doses of the drug. They are told what the drug does2. The distribution, absorbance rate, metabolism & excretion profile of the drug are assessed.3.The effects of the different doses are assessed to try and determine the optimum dose. An independent organisation (UK Medicines Control Agency) assesses whether it is appropriate to move to Phase 2
Clinical Trials – Phase 2
A small group of people with the disease are given the drug.Studies are very similar to Phase 1The optimum dose is worked out
Clinical Trials – Phase 3
A large group of people with the disease are given optimum doses of the drug [Reduces effects of chance/random variation]The patients are either given the drug or a placebo in a double-blind test [Neither patients nor doctors know who gets drug or placebo (avoids bias in ‘looking for results’) avoids patient/researcher bias in observing, recording and interpreting effectsPrevents subconscious prediction or influence of the outcome by both patient and researcher e.g. if know placebo used neither would expect any effect or if know drug used may feel/look for improvements that are not really there (psychosomatic influences).]The results are statistically analysed[Improves accuracy of conclusions as to whether or not drug actually does have an effect or not.]
If the drug has had a significant positive and safe effect in the treatment of the disease it is put forward to licensing authority
In what way is the current system of drug testing safer and more reliable than Wuthering’s?Safer: Use of specific active ingredient should allow a more precise dose to be given Any serious ill effects may be detected in the animal trials firstMore reliable: Uses larger samples reduces effects of chance/random variation Double blind testing avoids patient/researcher bias in observing, recording and interpreting
effects Statistical analysis of data improves accuracy of conclusions as to whether or not drug
actually does have an effect or not.
Evolution, Biodiversity and Classification
11) Explain the terms biodiversity and endemism and describe how biodiversity can be measured within a habitat using species richness and within a species using genetic diversity, e.g. variety of alleles in a gene pool.
Biodiversity Biodiversity is the number of different species, and the number of each species in a particular area.In a community in a particular habitat the biodiversity of organisms depends on
- the total number of organisms- the number of different species present = species richness- the number of organisms of each species present = species evenness
So to estimate biodiversity these need to be counted or estimated using sampling techniques.- High biodiversity = high species richness (lots of different species) + high species
evenness (numbers of each species roughly the same, rather than a few very common (dominant) and many very rare species)
Biodiversity within a species is measured by genetic biodiversity i.e., the variety of alleles in the gene pool (by measuring the genetic differences between individuals e.g. range of genotypes and estimating the number of different alleles)
Hotspots and endemism‘Hotspots’
- A biodiversity ‘hotspot’ is a region with a very high biodiversity.- A hotspot is defined in terms of a region having > 1250 different pants species and
must have > 0.5% of total global plant diversity present as endemic species
Endemism- Endemic organisms are those found only in a specific area and nowhere else on Earth;
i.e. they are unique and specifically adapted to a particular place o Endemic species are particularly vulnerable to extinction because they are only found in
one place, so if their habitat is threatened they can’t migrate and as natural selection is too slow they can’t move or adapt quick enough so their numbers a likely to decline.
12) Describe the concept of niche and discuss examples of adaptation of organisms to their environment (behavioural, physiological and anatomical).
Environment: This is the conditions in which an organism lives. It provides all essential resources an organism needs e.g. food, shelter, mates, nest sites, support, hiding places, suitable conditions for growth etc.
Habitat: The particular place with suitable environmental conditions where an organism lives.
Population: A group of individuals of the same species living and breeding together in the same habitat at the same time.
Community: All the organisms of the different species living and interacting together in the same habitat.
Niche: The niche is the way an organism is adapted to exploit the resources of its environment so it can survive to reproduce. In simple terms it describes what a species needs to survive and what is does.
Species: A species is a group of similar organisms which can interbreed to produce fertile offspring.
Adaptation Adaptation describes the ways in which an organism is best suited to exploit its environment. Ultimately on organism’s adaptations enables it to survive to breed.
Adapations can be:- Anatomical
An organism’s structures are specifically adapted to a particular function which enables the organism to exploit its environment more efficiently
- PhysiologicalAn organism’s physiology is adapted to survive particular conditions
- BehaviouralBehaviour is the adaptive responses an organism makes to changes in its
environment.(Use these to consider the way any organism given in a question is adapted to its niche.)
13) Describe how natural selection can lead to adaptation and evolution.
In all organisms that reproduce sexually, every individual has its own unique genotype i.e. combination of the alleles of all its genes: this is genetic diversity.
Genetic diversity describes the number of different combination of alleles (i.e. genotypes) within the gene pool of a population of a species.
All the alleles of all the genes in all the organisms in a population is called the GENE POOL. The greater the number of alleles in the gene pool the greater the number of genotypes in a
population, so the greater the genetic diversity.
Sources of variation Mutations
- produces new alleles i.e. new versions of genes Meiosis
- mixes up combinations of alleles of all the genes to produce different genotypes by crossing-over and independent assortment
What is the significance of genetic diversity?It enables populations of organisms to become adapted to changes in the environment over time by natural selection.
Natural selection Learn the wording! It can be applied to any situation given in a question.
Random mutations produce new variation (they add new alleles to gene pool of population) so individuals in populations have different genotypes and show genetic variation
If there is a change in the environment some genotypes with particular alleles may now make some organisms more likely to survive long enough to reproduce, to pass these genes on to their offspring i.e. they are better adapted to their environment. Others less well adapted will die from predation, competition for food, disease etc.
Those that reproduce will have offspring, some of which will inherit the favourable genotype and so themselves are more likely to survive to breed to pass their genes on
Over time the proportion of individuals with the favourable alleles in their genotype will increase in the population
NB: This can only happen if an advantageous allele of a gene already exists in the gene pool as a result of some random mutation
***The change in the environment does not cause the mutation ***
14) Discuss the process and importance of critical evaluation of new data by the scientific community, which leads to new taxonomic groupings (ie three domains based on molecular phylogeny).
Each species has its own individual and unique name which is internationally recognised.All organisms have a specific and unique biological name which all scientists use to avoid confusion; they are named using a universal scientific system known as the Binomial system, i.e. the binomial name consists of two parts.
Biological identification- To be able to estimate biodiversity we need to be able to recognise and name
individual species accurately.- One way of doing this is to use a branching or dichotomous identification key.- This uses pairs of particular characteristic features in a step-wise sequence which
ultimately leads to the name of the particular species.- Modern keys are computer-based – quicker, allow multiple access and easily
updated as new species are discovered
Why might identification keys not work?- Particular features required in the key may be absent because:
o damage to specimen
o wrong stage of development (e.g. very young)o previously unknown species
- Characteristics used are difficult to identify or interpret- Rare species may not be included
Organisation of biodiversity: Biological classification.
Why are organisms classified? To produce a universal 'filing system' to put groups of similar organisms together. To show evolutionary relationships To allow identification of different species and to give them a formal name To allow the recognition of new species Allows us to catalogue biodiversity (i.e. recognise and count the numbers of different species) To allow predictions to be made about individual members of a group, e.g. if a particular plant
produces medicinal chemicals it is likely that other members of the same group will also do so. To show evolutionary relationships
Features used in classification Those that are easy to see/measure Those that do not change Those that are present in all members of a group
How are organisms classified? Classification puts organisms into groups where all the members of one group resemble each
other (share more common features) more than they do members of other groups.
Organisms are grouped together to reflect evolutionary relationships because they share common ancestors. So all the organisms in one group are more closely related to each other than to members of other groups.
Five Kingdom system of classification. The Kingdoms are: Prokaryotae Protoctista Fungi Plantae Animalia.
(Learn three diagnostic features for each Kingdom.)Prokaryotae (Bacteria and blue-green bacteria)
• Cells are prokaryotic (no nucleus, no organelles) and very small (< 10 mm)• Cell walls made of petidoglycan (not cellulose)
Protoctista• Autotrophic i.e. photosynthetic (e.g. seaweeds)
and heterotrophic (feed on ‘ready made food’) (e.g. Plasmodium)• Eukaryotic; unicellular and multicellular (but limited differentiation into tissues, organs etc).• (Organisms are classed here if they do not fit into any other Kingdom)
Fungi• Unicellular or multicellular eukaryotes• Heterotrophic – absorb food, either as a result of external digestion (=decay) or as parasites• Some unicellular (e.g. yeasts) but usually body is a multicellular (but often no separate cells,
so more accurately multinucleate)) mass (mycelium) of thread-like filaments (hyphae)• Cell walls made of chitin
Plantae• Multicellular eukatyotes• Complex body structures; specialised cells, tissues, organs• Cell walls made of cellulose• Autotrophic (‘make their own food’ by photosynthesis); contain chlorophyll
Animalia• Multicellular eukaryotes• Complex body structures; specialised cells, tissues, organs• Heterotrophic; most have a gut (digestive system)• Cells lack cell walls• Most are motile (but not all). • Have a nervous system
Three DomainsModern evidence based on DNA and RNA suggests the Kingdom Prokaryotae should be divided into two separate Domains
– the Archea (‘ancient’ bacteria found in extreme environments) – the Eubacteria (all the other bacteria).
All the eukaryotic organisms are found in the Domain Eucarya, so there are 3 Domains of living organisms: Archea, Bacteria, Eucarya.
15) Discuss and evaluate the methods used by zoos and seedbanks in the conservation of endangered species and their genetic diversity (eg scientific research, captive breeding programmes, reintroduction programmes and education).
Organisms could become endangered or extinct in the wild if:• Loss of habitat or habitat fragmentation – from deforestation, loss of hedgerows etc.,or
reduction in numbers from pollution, poaching, shooting, loss of prey species to feed on etc reduces the sizes of populations
• They will become endangered or extinct if remaining organisms are unable to adapt rapidly enough to a rapidly changing environment,
• or are unable to breed and produce sufficient new viable offspring to replace the ones that die (due to genetic drift or inbreeding and loss of vigour).
• This results in a loss of biodiversity
ConservationConservation is a way of maintaining the diversity of habitats and the living organisms that live there to prevent them from disappearing.
One of the ways vulnerable populations of endangered species can be supported so they do not become extinct in the wild is by the conservation work carried out by zoos (for animals) and seed banks (for plants)
Zoos provide for• Academic research• Education• Captive breeding• Reintroduction programmes
Zoos and captive breeding programmes
Aims of captive breeding programmes:• To increase the number of individuals of a species if numbers are low• To maintain genetic diversity within the captive population• To reintroduce animals into the wild if possible
Problems facing captive breeding programmes for the maintenance of genetic diversity:
Small populations tend to become genetically uniform because variation and genetic diversity is lost so all individuals have similar genotypes because of
• genetic drift • and inbreeding depression
Parents
Gametes
Off spring
Red Red
RR Rr
R R R r
RR RR
Genetic Drift checkConsider two rare animals in a zoo.
Their colour controlled by a gene with two alleles R = red, white = r
I f the parents only have two babies, and they are both RR, the r allele has been lost.
This random loss of alleles is called genetic drift and has reduced the variation in colour in the future population (these animals are not heterozygous so there won’t be
the possibility of any white babies).This reduces genetic diversity
Red Red
Genetic drift is the random loss of alleles from the gene pool since not passed on if individuals with a particular allele fail to breed which
reduces genetic diversity in the population. Learn!
I nbreeding
I n a small population the chance of closely related animals mating is high.
this leads to a reduction in the number of heterozygous individuals and an increase in the number of homozygous individuals
which will reduce the range of genotypes in subsequent generations.
I nbreeding depression
Many genetic diseases are caused by harmful recessive alleles and their frequency will increase in an increasingly homozygous population leading to a loss of vigour, lower disease resistance, and less ability to survive and adapt to a changing environment. This is inbreeding depression.
Summary:Genetic drift • in a small breeding population is the random loss of alleles from the gene pool which
reduces the amount of genetic diversity
Inbreeding depression • is the result of closely related animals mating in a small population leading to a reduction in
the number of heterozygous individuals and an increase in the number of homozygous individuals which reduces the range of genotypes in subsequent generations, and the expression of harmful recessive alleles leads to a reduction in viability.
Both reduce genetic diversity; population becomes more uniform
The maintenance of genetic diversityA wide range of different genotypes within populations of organisms is essential
• to enable natural selection to operate on this range of genotypes• to maintain populations of organisms adapted to the environment of the time• but also to maintain sufficient variation to allow for selection to cope with any changes in
the environment• it also ensures captive organisms are still genetically similar to wild populations so successful
breeding between wild and introduced animals can occur
How genetic diversity is maintained in zoos and captive breeding programmes.
Zoo sets up a breeding programme with its captive animals• Mates are carefully selected• Individual animals are only allowed to mate with unrelated individuals (can be checked by
use of DNA profiling – genetic testing), and different mates to any previous matings – so only animals with different genotypes are allowed to mate to increase genetic diversity
• Genetic diversity can be further increased by using animals from other zoo populations or animals captured in the wild
• This is monitored by the use of studbooks• basically, this is a family tree for the captive animals • are kept so that only non-related animals (often determined by analysis of their
DNA) are bred with each other. • this decreases the chance of genetic drift and inbreeding depression
Captured wild animals are introduced to mate with animals in captive populations (this is called out-breeding)• these will have with new genotypes (i.e. combinations of the alleles of all the genes)• the animals can introduce new alleles or reintroduce alleles to replace those lost as captive
animals die • this can
– increase the size of gene pool (i.e. more different alleles) so more variation– ensure captive animals remain heterozygous so recessive alleles are not expressed
SummaryStud books and the introduction of captured wild animals
• ensures the captive breeding population remains heterozygous• so decreases the chance of loss of genetic diversity due to:• genetic drift and inbreeding depression
Reintroducing zoo-bred animals into the wild• Reintroducing species into the wild has some success, but depends greatly on the species. • As a general rule of thumb, the more advanced the species the more difficult reintroduction
is. • This is because animals need to learn specific behaviours e.g. how to hunt, how to
reproduce, how / where to find shelter, group behaviours: if they can’t do this because of their experience of the zoo environment reintroduction is unlikely to be successful
• Breeding animals in captive environments that mimic the wild has more success because it allows some of these behaviours to be learned in captivity.
• Feeding the animals in the wild also helps survival rates e.g. orang-utan reintroduction programmes in Borneo.
• There is a remote risk that re-introduced animals may bring in a new disease which they may be immune to but the wild populations are not
Seed BanksMillennium Seed Bank ProjectConservation of plants is important too because plants are:
• Endangered from habitat destruction, climate change, agriculture• Potential sources of new medicines,• New plants for food and other products• Sources of genes for plant improvement etc
Seed Banks:• Seed samples (seeds contain genes!) from tens of thousands of different species are kept in seed
banks; some in their countries of origin, and many in the Millenium Seed Bank Project run by Kew Gardens.
• Initially set up to collect and store seeds from all the UK native species. • Another aim is to conserve 10% of the world flora, particularly focussing on those most
threatened with extinction.
At the MSP:
• Seeds collected, identified, cleaned and dried• screened using x-rays to check they have fully developed embryos (so are viable) • stored in cool (-20oC) and dry conditions (so don’t germinate) so can be stored for a long time• tests carried out at regular intervals to check seeds are still viable (i.e. will still germinate and
grow)• if evidence shows viability is reducing some seeds are ‘sacrificed’ to be grown into plants,
allowed to flower and cross-pollinate to produce seeds; the seeds are then collected and stored again.
Advantages of using storing seeds as the source of genes:
• Less space needed/less costly and less labour intensive to store large numbers of seeds than whole plants
• Seeds can all be stored in same environment, whereas whole plants need different and specific conditions to much easier to maintain
• Seeds less likely to be eaten by herbivores/killed by disease than whole plants• Enables a large stock of the genetic variation of the wild populations to be conserved
(especially if the plants are endangered in the wild) for possible future use in plant breeding programmes.
• Can also be used as a source of plants for re-introductions back into the wild.• Most plants produce many seeds so collecting seeds is unlikely to seriously harm the
numbers of plants in a vulnerable population• Seeds are easily transported• Seeds do not need to be stored in original habitat and are so less likely to damaged by
vandalism, pollution, disease, grazing or natural disasters
Some plants do not produce many seeds, or produce non-viable seeds, so their genomes need to be stored in different ways – e.g. as callus in tissue culture stored at very low temperatures (cryopreservation), or as the plants themselves growing in field gene banks e.g. used to store thousands of different cloned varieties of potato in Peru or rice in the Philippines.