6.2.1 - Cloning and biotech

Question 1

Clones

Answer 1

Carry identical genetic material because they are derived from the same orig. DNA

Question 2

Cloning

Answer 2

Process of producing genetically identical cells or organisms from the cells of existing organisms through nonsexual means

Question 3

Examples of processes that form genetically identical organisms

Answer 3

Mitosis
Binary fission (bacteria)
Budding (yeast)

Question 4

Natural plant cloning

Answer 4

Vegetative propagation through runners or suckering

Question 5

Artificial plant cloning

Answer 5

Artificial vegetative propagation through cuttings or micropropagation (tissue culture)

Question 6

Vegetative propagation

Answer 6

Ability of plants to reproduce w/out sexual reproduction by producing new plants from existing vegetative structures

Question 7

Vegetative structures

Answer 7

Non-reproductive tissues e.g. roots, leaves and stems

Question 8

Cuttings

Answer 8

Cut stem 1/4 “ below internode at 45-60 degrees
Treat cut end w/ rooting hormones
Cover in clear plastic bag
Transfer to another growing medium

Question 9

Why do you cover cuttings w/ a clear plastic bag

Answer 9

To keep it moist and warm

Question 10

Explant

Answer 10

A small piece of tissue

Question 11

Callus

Answer 11

Undifferentiated mass of tissue containing totipotent cells

Question 12

Micropropagation

Answer 12

Cut out explant from vegetative structures (leaf)
Sterilise explant w. alcohol
Place explant in sterile agar w/ glucose, cytokinins and auxins
Subdivide callus and place on growth medium to induce root growth (prepares plant for transplanting)
Transferred to greenhouse to acclimatise before being planted outside

Question 13

Advantages of artificial plant cloning

Answer 13

Can produce large no. v. quickly
Can grow plants that dont reproduce easily
No need to wait for seed production
Reproduce sterile plant

Question 14

Disadvantages of artificial plant cloning

Answer 14

Labour intensive and requires skilled workers
Trial and error to find ideal conditions for growth
Undesirable traits also passed on
Can fail to microbial contamination

Question 15

Runners

Answer 15

Side stem grows out from bud at the base of the main stem

Creates new bud and grows a vertical stem

Question 16

Suckering

Answer 16

Grow from shallow roots from buds that are normally dormant
Duing times of stress, buds are activated and suckers form many metres away from parents tree (to avoid stress that triggered growth)
Eventually form clonal patch of new trees
Trees in clonal patch put out new sucker buds

Question 17

Advantages of natural plant cloning

Answer 17

Large colonies can form quickly

Allows species to survive catastrophic events

Question 18

Disadvantages of natural plant coning

Answer 18

No natural selection

Susceptible to gentic disease; no variation

Question 19

Runners vs. suckers

Answer 19

Runners are overground and suckers are underground

Question 20

Why must the agar used in micropropagation be sterile

Answer 20

Prevents infection

Competition of resources e.g. oxygen/nutrients if other organisms e.g bacteria and fungi are present

Question 21

Somatic cell

Answer 21

Biological cell forming the body of an organism

Question 22

Germline cell

Answer 22

Biological cell that gives rise to the gametes of an organism that reproduces sexually

Question 23

Natural animal reproductive cloning

Answer 23

Some animals can regenerate entire animals from fragments of the orig. (starfish)
Others fragment and form new identical animals as part of their normal reproductive process (flatworms and sponges)
MZ twins form when an early embryo splits and and two foetuses develop from two halves

Question 24

Artificial animal reproductive cloning

Answer 24

Somatic cell nuclear transfer

Artificial twinning

Question 25

Somatic cell nuclear transfer

Answer 25

Extract nucleus from somatic cell from Sheep A
Remove nucleus from egg cell from Sheep B
Insert nucleus from A into innoculated egg(electrofusion)
Stimulates to divide in vitro and implant embryo into sheep C

Question 26

Artificial embryo twinning

Answer 26

Get fertilised egg and allow to divide until 16 cell stage
Harvest embryo and split into smaller ones manually
Implant into surrogate mothers which give birth to identical high quality animals

Question 27

Advantages of artifical animal cloning

Answer 27

Produce identical clones w/ desirable traits
Stem cell research
Clones so offspring can be produced all year round

Question 28

Disadvantages of artificial animal cloning

Answer 28

Difficult and time consuming
Destruction of embryos unethical
Clones have shorter life expectancies
No genetic identity so selection pressures affects all

Question 29

Similarities between AT and SCNT

Answer 29

Produce clones 
Both have surrogates 
Divides by mitosis 
Unnateral 
Expensive

Question 30

Differences between AT and SCNT

Answer 30

AT forms several clones at once
Gametes meet outside the body is AT
SCNT involves only maternal DNA
No fertilisation in SCNT

Question 31

Biotechnology

Answer 31

Industrial exploitation of living micro-organisms (or parts of them) and biological process to produce useful substances for human use

Question 32

Why are microorganisms used in biotech

Answer 32

Easy/ not labour intensive
Obtain pure products if aseptic technique is followed
Can be easily genetically enginerred to produce spp products
Short life cycle
Simple requirements for growth - can be left w/ little intervention
Can be grown v. quickly
Can be grown on waste material from other processes

Question 33

Use of microorganism in biological processes

Answer 33

Brewing - anaerobic respiration of yeast
Baking - yeast
Cheese making - bacteria and rennin 
Penicillin production - fermentation by fungus 
Insulin production - GM bacteria
Bioremediation

Question 34

Bioremediation

Answer 34

Using microorganisms to clean up pollution

Convert toxic pollutants to less harmful substances

Question 35

Advantages of bioremediation

Answer 35

Uses natural systems 
Less labour and equipment required
Treatment can be carried out on site
Few waste products produced 
Less risk of harmful exposure to clean-up personnel

Question 36

Culturing microorganisms

Answer 36

Sterilisation - Sterilising equipment in an autoclave (15 mins at 121 degrees)
Inoculation - Introducing a sample of microorganisms to the growth medium
Incubation - Place in a warm environment and place agar plate upside down (condensation)

Question 37

Types of growth medium

Answer 37

Agar jelly in a petri dish

Nutrient broth in a bijoux bottle

Question 38

Standard procedure of aseptic techniques

Answer 38

Wash hands thoroughly
Disinfect working area
Light and keep Bunsen burner on
Flame neck of bottle before and after taking sample
Lift lid of petri dish slightly to introduce microbe by streaking
Close petri dish and tape (not completely)
Flame all equipment after use
Wash hands again

Question 39

Why do you keep the Bunsen burner on during aseptic procedures

Answer 39

Heats the air, causing it to rise so air-borne microbes don’t settle

Question 40

Why cant you seal the petri dish completely

Answer 40

Introduces O2 for aerobic respiration

Doesn’t introduce harmful anaerobically respiration organism

Question 41

Continuous culture

Answer 41

Culture is set up and nutrients are added and products removed from the culture at intervals - done at same rate to keep vol constant
Culture is maintained at exponential growth phase - grows and produces metabolites faster

Question 42

Metabolites

Answer 42

Substances produced by living organisms in order to survive e.g ATP synthase

Question 43

Batch culture

Answer 43

A starter population of the microorganism is given a fixed amount of nutrients and at the end of the time period products are extracted

Question 44

Examples of continuous culture

Answer 44

Insulin

Single-cell protein (from Fusarium)

Question 45

Examples of batch culture

Answer 45

Wine
Beer
Yogurt

Question 46

Advantages of continuous culture

Answer 46

Fermenter is always in use - increases efficiency
High growth rate as nutrient levels maintained
Useful for primary metabolites

Question 47

Disadvantages of continuous culture

Answer 47

Contamination is more likely
Difficult to maintain and control product consistency
In cases of contamination losses are great and all production halts

Question 48

Advantages of batch culture

Answer 48

Less likelihood of contamination
Can be left for a set time period
Useful for secondary metabolites
In the event of contamination, only one batch is lost

Question 49

Disadvantage of batch culture

Answer 49

Fermenter isn’t in use constantly - less efficient

Time spent cleaning

Question 50

Primary metabolites

Answer 50

Produced in the course of normal metabolism e.g. proteins, enzymes, alcohol
Produced in lag and log phase

Question 51

Secondary metabolites

Answer 51

Produced after main population growth has occurred, nutrients are in short supply and population isn’t growing rapidly
Produced in stationary and death phase

Question 52

How do fermenters maximise the yield

Answer 52

Tube for sterile air to provide oxygen for aerobic reactions
Sparger - diffuses air through culture medium
Powerful motors - mixes contents ensuring equal distribution of nutrients and so microbes don’t settle at base of fermenter
Acid-base injection site - controls pH
Culture broth - contains sources of carbon and nitrogen (NH3) and vitamins/minerals
Jacket - filled with hot/cold water to provide optimum temp as respiration releases heat (denaturing)

Question 53

Asepsis in fermenters

Answer 53

Washing. disinfecting and steam cleaning all equipment
Using fermenter made of polished stainless steel so microbes cant stick
Sterilising all nutrients w/ steam or heat
Only bubbling in sterile air- v. fine filters

Question 54

Phases in microorganim growth curves (bacteria/fungi)

Answer 54

Lag
Exponential
Stationary
Death

Question 55

Lag phase

Answer 55

Reproduction v. slow as cells acclimitase, absorb nutrients
Gene expresion for spp enzymes
Synthesis of enzymes and organelles

Question 56

Exponential phase

Answer 56

Reproduction is rapid
No limiting conditions
Few cells die

Question 57

Stationary phase

Answer 57

Population remains constant as death and reproduction rates are the same

Question 58

Death phase

Answer 58

Lack of resources

Build up of CO2 - fatal

Question 59

Culture

Answer 59

A method of multiplying microbial organisms by letting them reproduce in predetermined culture medium under controlled lab conditions

Question 60

Isolated enzymes

Answer 60

Taking enzymes out of microorganism

Question 61

Issue w/ isolated enzymes

Answer 61

Product must be seperated from enzymes and extraction is v. expensive

Question 62

Immobilised enzyme

Answer 62

Enzymes fixed to a surface and do not freely mix w/ the substrate

Question 63

Ways to immobilise enzymes

Answer 63

Covalent bonding
Encapsulation
Adsorption
Entrapment

Question 64

Covalent bonding to immobilise enzymes

Answer 64

Covalently bonded to a supporting surface

Enzymes are also covalently bonded together using a cross-linking agent

Question 65

Adsorption

Answer 65

Bound to supporting surface by a combination of hydrophobic interactions and ionic links
Bound w/ active site exposed and accessible to substrate

Question 66

Entrapment

Answer 66

Trapped in a matrix (often calcium alginate beads) that doesn’t allow free movement

Question 67

Encapsulation/membane separation

Answer 67

Separated from reaction mixture by a small permeable membrane - microcapsule

Question 68

A vs D of adsorption

Answer 68

Simple and cheap
Can be used in a variety of processes
Enzymes v. accessible

May distort active site
Enzymes can detach and leak into reaction mixture

Question 69

A vs D of covalent bonding

Answer 69

Enzyme less likely to become detached
pH and substrate conc have little effet on enzyme activty
Accessible to substrate

Expensive
Can distort active site, reducing activity

Question 70

A vs D of encapsulation

Answer 70

Relatively simple
Relatively small effect on enzyme activity
Widely apllicable to diff processes

Expensive
Substrate and product has to be small in order to diffuse through partially permeabe membrane
Diffusion is slow

Question 71

A vs D of entrapment

Answer 71

Widely applicable to diff processes

May be expensive
Difficult to entrap
Effect of entrapment on enzyme activity dpends on the matrix
Substrate and product needs to be small

Question 72

Examples of immobilised enzymes

Answer 72

Glucose isomerase 
Penicillin acylase
Lactase
Aminoacylase
Glucoamylase
Nitrile hydratase

Question 73

Penicillin acylase

Answer 73

Converts naturally produced penicillins to semi-synthetic penicillins
Some resistant microorganims arent resistant to semi-synthetic penicillins

Question 74

Glucose isomerase

Answer 74

V. commonly use to produce HFCS, sweeter than sucrose and can be used in diet fods
Glucose —> fructose

Question 75

Lactase

Answer 75

Hyrolyses lactose into glucose and galactose so lactose-intlerant people can drink milk and reduce the risks of developing osteoporosis as a lack of calcium

Question 76

Aminoacylase

Answer 76

N-acyl-amino acids —> pure sample of L-amino acids

Used in synthesising pharmaceutical compounds

Question 77

Glucoamylase

Answer 77

Dextrins —> glucose

Immobilised and used to digest sources of starch e.g. corn and cassava

Question 78

Nitrile hydratase

Answer 78

Nitriles —> amides
Acrylamide can be polymerised to form a plastic and a gel for electrophoresis
Used to treat water, helps to stick many small contaminanrts together so they can be filtered out

Question 79

Supporting surfaces

Answer 79

Glass
Porous carbon
Clay

Question 80

Advantages of immobilising enzymes

Answer 80

Lowers temp required
No contamination of end product
Reusable
Protected by immobilisng matrix so high temp or extreme pH has no effect

Question 81

Disadvanages of immobilising enzymes

Answer 81

Expensive to set up
Bonding may affect active site
Contamination is v. costly as whole system needs to stop
Slower process as enzymes and substrates don’t mix freely

Question 82

Making yoghurt

Answer 82

Milk is fermented by bacteria
Lactose—> lactic acid
Low pH denatures caesin, causing milk to coagulate and thicknes
Also adds flavour

Question 83

Makng cheese

Answer 83

Milk is fermented by bacteria
Lactose –> lactic acid, acidifies milk
Rennin coagulates caesin in the presence of Ca2+
Resulted curd separates from liquid whey by curdling, stirring and heating

Question 84

Microorganisms in baking

Answer 84

Flour is mxed w. water, salt and yeast

Respires anaerobically and produces CO2 bubbles, causing the dough to rise

Question 85

Making wine

Answer 85

Grapes have yeast on the surface

When crushed uses glucose and fructose to respire and produce CO2 and alcohol

Question 86

Making beer

Answer 86

Uses malted barley grains that are beginning to germinate
Stored starch to maltose, respiratory substrate for yeast
Produces CO2 and alcohol

Question 87

Making penicillin

Answer 87

Fermentation of fungus as a batch culture for 6-8 days
Secondary metabolite
Once fermentation is complete, culture is filtered to remove cells
Antibiotics precipitated and purified

Question 88

Making insulin

Answer 88

Genetic modification of bacteria

Grown in fermenters, continuous culture

Question 89

Why is the Sheep C treated w/ hormones

Answer 89

Increase thickness and vascularisation of uterine lining

Question 90

How can SCNT help save endangered species

Answer 90

Doesn’t require fertile females
Female not put at risk during mating
Can subdivide successfully formed embryo

Question 91

Economic advantages of immobilising enzymes

Answer 91

Reusable so less money required

Higher temp means profit from faster yield