Neuroscience Research Methods 1

Question 1

Give four techniques used to perform functional research in neuroscience. (4)

Answer 1

• Microscopy
• Electrophysiology
• Behavioural testing
• Imaging

Question 2

What is the difference between a naive animal and an animal model in the context of neuroscience research? (2)

Answer 2

Naive animal - no changes, used to understand normal function

Animal model - idealised or modified to represent a disease or physiological condition

Question 3

A researcher is looking at hippocampal function. Her research question can be answered using a mouse model, but she would prefer to use a sheep because it would be better applied to humans. Is this possible for her to do? Why? (2)

Answer 3

No - the lowest sentient being possible should always be used

Question 4

Give five advantages and one disadvantage of using drosophila/zebrafish models in neuroscience research. (6)

Answer 4

ADVANTAGES:
- Less complex nervous system
- Cheap
- Quick
- No licence
- Can answer fundamental questions

DISADVANTAGE:
- Harder to apply to humans

Question 5

Give three advantages and one disadvantage of using mouse/rat (rodent) models in neuroscience research. (4)

Answer 5

ADVANTAGES:
- Mammalian nervous system
- Cheaper than larger mammals
- Quicker than larger mammals

DISADVANTAGE:
- Do not have folded cortex

Question 6

Which types of rodent models are more suited to mice, and which to rats in neuroscience research? (2)

Answer 6

• Mice commonly used for genetic models
• Rats easier to train and larger

Question 7

In which two ways are sheep brains similar to human brains (in the context of neuroscience research)? (2)

Answer 7

• Folded cortex
• Dura mater

Question 8

Sheep brains contain a dura mater.
How can this fact be exploited when using sheep models in neuroscience research? (1)

Answer 8

Solid tentorium means that they can be used to investigate intracranial pressure.

Question 9

Give three ways that animal models can be produced for neuroscience research. (3)

i.e. how can we manipulate animals to show features of a disease?

Answer 9

• Genetic modification
• Chemical/pharmacological
• Surgery

Question 10

Give an example of a genetic modification being used to create an animal model for use in neuroscience research. (1)

Answer 10

Inserting CAG repeats into Huntingtin gene

Question 11

Give an example of a chemical/pharmacological modification being used to create an animal model for use in neuroscience research. (1)

Answer 11

Inducing cell death of dopaminergic neurones using MPTP for Parkinson’s disease

Question 12

Give an example of a surgical modification being used to create an animal model for use in neuroscience research. (1)

Answer 12

Occlusion of MCA with monofilament for stroke

Question 13

Describe how a lesion-based animal model would be produced for use in neuroscience research.

Which category/categories does this model come under in terms of genetic/chemical/surgery? (2)

Answer 13

Create a lesion in a specific part of the brain using chemicals.

Comes under surgical and chemical/pharmacological categories.

Question 14

Give four licences that must be obtained before beginning a research project involving the use of animals. (4)

Answer 14

• Establishment licence (PCD)
• AWERB (authorises need for project)
• Project licence (need for each experimental technique)
• Personal licence

Question 15

In stereotactic neurosurgery, define bregma. (1)

Answer 15

Point where coronal and sagittal sutures intersect.

Question 16

In stereotactic neurosurgery, what value is given to bregma. (1)

Answer 16

0

Question 17

In stereotactic neurosurgery, define lambda. (1)

Answer 17

Point where the sagittal and lambdoid sutures intersect.

Question 18

Describe the coordinate values moving anterior to bregma in stereotactic neurosurgery. (1)

Answer 18

Positive

Question 19

Describe the coordinate values moving posterior to bregma in stereotactic neurosurgery. (1)

Answer 19

Negative

Question 20

Describe the coordinate values moving lateral to bregma in stereotactic neurosurgery. (1)

Answer 20

Positive

Question 21

Describe the coordinate values moving ventral to bregma in stereotactic neurosurgery. (1)

Answer 21

More positive moving downwards.

Question 22

Define ‘cell culture’. (1)

Answer 22

The growth of cells from an animal or plant in an artificial, controlled environment.

Question 23

Give two challenges faced when culturing neurones. (2)

Answer 23

• Mature neurones do not undergo cell division
• Neurones have complex morphologies and connections

Question 24

Describe three considerations to take into account regarding the environment when performing cell cultures. (3)

Answer 24

• Components needed for cellular metabolism
• Need for incubators
• Avoidance of contamination

Question 25

Give three different neuronal cell models that can be used for cell culture. (3)

Answer 25

• Immortalised cell lines (neuroblastoma)
• Primary neurones
• Induced pluripotent stem cells

Question 26

Give two advantages and two disadvantages of using neuroblastoma immortalised cell lines in cell cultures. (4)

Answer 26

ADVANTAGES:
- Continuous cell division
- Can use a human model

DISADVANTAGES:
- Differentiated state does not produce a typical neuronal structure
- Cannot be used in compartmentalised systems

Question 27

Describe how primary neurones would be obtained to be cultured and used in neuroscience research. (1)

Answer 27

Cells derived from embryonic neuronal tissue

Question 28

Give three advantages and one disadvantage of using primary neurones in culture for neuroscience research. (4)

Answer 28

ADVANTAGES:
- More typical neuronal morphology
- Can develop neuronal networks in vitro
- Can adapt to cultures which grow multiple different cells

DISADVANTAGE:
- No more cell division

Question 29

Describe what is meant by an ‘induced pluripotent stem cell’, as applied to neuronal culture and neuroscience research. (2)

Answer 29

• Adult somatic cells which have been genetically reprogrammed to a state similar to embryonic stem cells.
• Cells then stimulated to differentiate into neurones.

Question 30

Give one advantage and two disadvantages of using iPSCs to culture neurones and carry out neuroscience research. (3)

Answer 30

ADVANTAGE:
- Can create a human model which accurately represents a specific disease state

DISADVANTAGES:
- Expensive
- Variability in results (due to differences in human cells)

Question 31

Describe why neuronal cell cultures cannot just be grown as a sheet of cells in a petri dish.
Why do we need to use special types of neuronal cell culture systems? (2)

Answer 31

Neurones have complex morphologies

and different culture platforms may be required for different parts of the cell.

(eg, cell bodies, and axons, and dendrites may need different conditions to grow)

Question 32

Give three types of cell culture system which may be ideal to grow neurones. (3)

Answer 32

• Microfluidic cultures
• 3D systems
• Brain organoids (which are another type of 3D system)

Question 33

Describe the principles behind the microfluidic cell culture technique, and explain why it might be an ideal environment to culture neurones. (2)

Answer 33

• A compartmentalised system which is used to culture primary neurones.
• Ideal to grow neurones because different drugs/reagents can be added to each side (ie. dendrites vs axons)

Question 34

Describe the principles behind the 3D cell culture technique, and explain why it might be an ideal environment to culture neurones. (2)

Answer 34

Different cell types cultured on a model of extracellular matrix.

May be ideal to grow neurones because it attempts to mimic the anatomical structure of the nervous system.

Question 35

Give two disadvantages of the 3D cell culture technique. (2)

Answer 35

• Expensive
• Powerful microscopy techniques required for visualisation

Question 36

Describe the principles behind the brain organoid cell culture technique. (1)

Answer 36

3D culture produced of neural cell aggregates.

(Mini brain containing neurones and glia)

Question 37

Give an advantage and disadvantage of the brain organoid cell culture system. (2)

Answer 37

ADVANTAGE:
- More accurate model for brain development

DISADVANTAGE:
- More difficult to view individual cells

Question 38

Briefly name the steps involved in the trizol method of RNA isolation. (4)

Answer 38

• Lyse cells
• Separate RNA via mixing or shaking
• Centrifuge
• Precipitate RNA

Question 39

When isolating RNA using the trizol method, what reagent is used to lyse/homogenise the tissue? (1)

Answer 39

Trizol

Question 40

When isolating RNA using the trizol method, how can the trizol reagent help preserve the integrity of the RNA? (1)

Answer 40

Inhibiting RNase enzymes

Question 41

When isolating RNA using the trizol method, which reagent is used to help the RNA separate from the DNA/proteins in the sample? (1)

Answer 41

Chloroform

Question 42

When isolating RNA using the trizol method, which layer produced after centrifugation will contain the RNA? (1)

Answer 42

Top

Question 43

When isolating RNA using the trizol method, what reagent is added to precipitate RNA molecules after centrifugation? (1)

Answer 43

Ethanol

Question 44

Briefly name the steps involved in DNA isolation. (4)

Answer 44

• Lyse and homogenise cells
• Treat with proteases
• Centrifugation
• Precipitate DNA

Question 45

When isolating DNA, why do cells have to be lysed/homogenised? (1)

Answer 45

To dissolve plasma and nuclear membranes and release cell contents.

Question 46

When isolating DNA, why is the sample treated with proteases? (1)

Answer 46

To destroy proteins such as histones and allow DNA to unwind

Question 47

When isolating DNA, what reagent is used after centrifugation to precipitate the DNA? (1)

Answer 47

Ethanol

Question 48

Give two uses of PCR. (2)

Answer 48

• Measure gene/RNA expression
• Manipulate the genome/transcriptome

Question 49

Give four techniques which are commonly paired with PCR in neuroscience research. (4)

Answer 49

• QPCR
• DNA Microarrays
• In situ hybridisation
• Sequencing

Question 50

Name the enzyme usually used in PCR.

Where does this enzyme come from, and why is it ideal for use in PCR? (3)

Answer 50

Taq polymerase (form of DNA polymerase)

First discovered in bacteria

Ideal because it is very heat resistant (optimum temp = 75-80C)

Question 51

Briefly describe the fundamental principle of PCR. (2)

Answer 51

Uses a temperature cycle

to theoretically produce infinite copies of a small sample of DNA.

Question 52

Describe the three steps in PCR, and the rough temperatures that they are carried out at. (3)

Answer 52

Denaturation (92-94)

Annealing (50-70)

Elongation (~72)

Question 53

Describe what is meant by ‘hot start PCR’, and describe why it is used. (3)

Answer 53

• Specific form of Taq polymerase only active at high temperatures
• So amplification can only start once temperature is raised and first denaturation has occurred
• Which can help unwanted/random amplifications and primer dimers forming during PCR setup at room temperature

Question 54

Is PCR performed on DNA or RNA?

Give two reasons why? (3)

Answer 54

DNA

• RNA too unstable
• Taq polymerase does not work on RNA, but cannot use RNA polymerase as it would not withstand heat

Question 55

If PCR can only be performed on DNA, how can RNA expression for a specific gene be measured, as the original sample will consist of RNA? (1)

Answer 55

Reverse transcription to form DNA from RNA

Question 56

Give five ‘ingredients’ that must be added together in an eppendorf when performing PCR. (5)

Answer 56

• 2x primers (forward and reverse)
• Nucleotides
• Taq polymerase
• DNA template of interest
• Buffer

Question 57

Describe the denaturation step in PCR. (2)

Answer 57

High temperature causes hydrogen bonds between DNA strands to break.

DNA separates into single strands.

Question 58

Describe the annealing step of PCR. (1)

Answer 58

The primer binds to complementary sequence on DNA.

Question 59

Describe what affects the temperature that annealing must be carried out at when performing PCR. (2)

Answer 59

Base composition and length of primer.

Also, temp must be ideal for both forward and reverse primers.

Question 60

Describe (in reasonable detail) the elongation step in PCR. (3)

Answer 60

• Taq polymerase binds to 3’ end of DNA
• Polymerase copies complementary sequence
• New DNA strand formed 5’ to 3’

Question 61

Describe how a sample of material may be visualised after performing PCR.
How would the sample look when it comes out of the thermocycler? (3)

Answer 61

Run on agarose gel.

Visualise using UV light.

(Gel electrophoresis)

• The sample appears as a transparent liquid

Question 62

What is QPCR used for? (1)

Answer 62

Quantify the amount of RNA (and therefore specific genes/gene expression) in a sample.

Question 63

Describe simply the basic principles surrounding QPCR. (4)

Answer 63

• DNA detected via fluorescent probe
• Detection threshold set (intensity of fluorescence)
• More DNA (and therefore RNA) in original sample = less cycles to reach threshold
• Cycles to threshold can be compared to known control

Question 64

What is meant by the term Ct, in QPCR? (1)

Answer 64

Cycles to threshold - higher Ct means less RNA in original sample

Question 65

Describe how you can work out the fold-change in RNA expression by looking at the Ct of two samples in QPCR.

Answer 65

Every Ct difference = changed by a factor of 2

Eg - Ct 17 and Ct19 means that expression will have changed by a factor of 4.

Question 66

Describe the three phases of QPCR, in terms of how fast the reaction occurs.
In which phase of the reaction should the detection threshold be set in? (4)

Answer 66

• First exponential phase
• Then linear phase (contains detection threshold)
• Then plateau phase

Question 67

Why does a PCR/QPCR reaction eventually plateau? (2)

Answer 67

May be due to denaturation of Taq polymerase or depletion of primers.

However noone really knows.

Question 68

What factor limits the linear phase of a PCR/QPCR reaction? (1)

Answer 68

Number of Taq polymerase molecules

Question 69

What is DNA called if it has been produced from an RNA sample via reverse transcription? (1)

Answer 69

cDNA

Question 70

Name two methods of QPCR. (2)

i.e. 2 ways to add fluorescent probes to the DNA for detection

Answer 70

SYBRGreen

TAQMan

Question 71

Give a brief overview of how SYBRGreen QPCR works to produce a signal. (3)

Answer 71

• Add SYBRGreen molecules to solution undergoing PCR
• Molecules intercalate nonspecifically into dsDNA molecules
• When molecules are incorporated into dsDNA they fluoresce

Question 72

Give two advantages and one disadvantage of the SYBRGreen method of QPCR as opposed to TAQMan. (3)

Answer 72

ADVANTAGES:
- Cheaper
- Easier
(regular, non-modified primers can be used)

DISADVANTAGE:
- SYBRGreen binding is nonspecific so you may be picking up DNA contaminants as well as gene of interest

Question 73

After QPCR with SYBRGreen has been carried out, give another step of the experiment which is performed. (1)

Answer 73

Melt analysis

Question 74

Why is melt analysis performed after SYBRGreen QPCR? (1)

Answer 74

To determine whether a single product or multiple products have been obtained.

Question 75

Describe the principles behind melt analysis for SYBRGreen QPCR. (4)

Answer 75

• Temp slowly increased
• dsDNA will denature and stop fluorescing
• However different products will denature at different temperatures
• So if >1 product produced, multiple different melting profiles will be observed

Question 76

Describe the principles behind the TAQMan method of QPCR. (3)

Answer 76

• In addition to regular primers, a probe primer is added (attached to fluorescent probe)
• Probe primer has base sequence complementary to gene of interest (but different from regular primers)
• When Taq polymerase reaches probe primer during elongation, it digests fluorescent molecule, which begins to fluoresce

Question 77

Give one advantage and one disadvantage of TAQMan QPCR compared to SYBRGreen. (2)

Answer 77

ADVANTAGE:
- High specificity for gene of interest (contamination will not affect signal)

DISADVANTAGE:
- Requires special and expensive primer probes

Question 78

What are DNA microarrays used for in neuroscience research? (1)

Answer 78

Measure gene expression/amount of RNA/amount of DNA

Question 79

Describe the principles behind a DNA microarray. (4)

Answer 79

• Glass or silicone slide containing spots filled with ssDNA probes of known base sequence
• Sample of interest fluorescently labelled and incubated with microarray
• Sample binds to complementary DNA spot and unbound sample washed away
• Measure fluorescence of each spot and compare relative expression between samples

Question 80

Describe how a sample of interest DNA can be compared to a sample of control DNA with known expression using a spotted DNA array.

Describe how the results would be interpreted. (5)

Answer 80

• Control and sample labelled with different fluorescent colours (eg. control red and sample green)
• Control and sample hybridised to same spot on DNA array
• Colour closer to red = more control
• Colour closer to green = more sample
• Yellow = equal

Question 81

Give a disadvantage of using spotted DNA arrays to measure gene expression. (1)

Answer 81

Can only compare results from the 2 samples hybridised to the same spot.

Question 82

Describe how affymetrix gene chips work to compare expression between different DNA samples. (3)

Answer 82

• Gene chips contains many short probes for many different genes
• Samples of interest loaded onto gene chip
• Signal of bound DNA measured and gene expression can be compared between many samples

Question 83

Describe an advantage of affymetrix gene chips compared to spotted DNA arrays for comparing levels of gene expression. (2)

Answer 83

Can compare many control/treatment samples

because affymetrix oligonucleotides normalise expression between chips.

Question 84

Describe how DNA microarrays can be used to measure gene expression, given that DNA is the same in all cells. (2)

Answer 84

Take an original RNA sample

and reverse transcription to make cDNA.

(More RNA in original sample = more DNA in test sample, then measure amount of DNA using microarray)

Question 85

What is in-situ hybridisation used for in neuroscience research? (1)

Answer 85

Localising specific nucleic acid targets within tissues, cells, and chromosomes.

Question 86

True or false? (1)

In situ hybridisation is good for measuring gene expression in a tissue sample.

Answer 86

False - it is used to see WHERE a gene or nucleotide sequence is expressed

Question 87

Briefly describe how a tissue or cell sample would be prepared prior to in-situ hybridisation. (3)

Answer 87

• Samples preserved (fixed/frozen)
• Thinly sliced
• Attached to glass slide for support

Question 88

Describe how targets are localised and detected in in-situ hybridisation. (4)

Answer 88

Complementary probes produced

Labelled with fluorescence or radioactivity

Probes hybridised with tissue samples, and they bind to complementary DNA/RNA

Fluorescence or radioactivity then measured in sample

Question 89

Describe the main difference between in-situ hybridisation and immunohistochemistry. (2)

Answer 89

In-situ hybridisation identifies nucleotide targets.

Immunohistochemistry identifies protein targets.

Question 90

Briefly describe how sanger sequencing is carried out. (4)

Answer 90

• PCR carried out with both normal base pairs and chain-terminating base pairs
• Chain-terminating bases labelled a different colour or carried out using only one base at a time
• Fragments separated by size (eg. electrophoresis)
• Colour of each fragment indicates last base in sequence

Question 91

Describe the principles behind pyrosequencing. (3)

Answer 91

• Based on the principle that each time a base pair is added, pyrophosphate is released
• Pyrophosphate undergoes chain of events, including luciferase reaction, to produce light
• Each possible base pair is added separately, and if light is emitted, it confirms that the base has bound and is the next in the sequence

Question 92

Briefly describe emulsion PCR - a technique that is used in second generation sequencing. (4)

Answer 92

• One DNA strand attached to solid base (eg. microbead)
• DNA strand and base contained in droplet (eg. aqueous droplet in an oil emulsion)
• Multiple droplets can then be put in one mixture as they are separated
• They can undergo PCR at the same time

Question 93

Define ‘recombinant DNA technology’. (2)

Answer 93

The creation of new DNA molecules,

or the transfer of genetic information to/from an organism.

Question 94

Name the steps required for making recombinant DNA. (6)

Answer 94

• Isolate DNA
• Cut DNA
• Join DNA
• Introduce DNA into host cell
• Allow cells to multiply and select clones containing target DNA
• Express target DNA

Question 95

Give three enzymes that may be used for recombinant DNA technology, and briefly describe their role. (6)

Answer 95

• Restriction endonuclease (cleave DNA at specific sites)
• Ligase (join bits of DNA together)
• Phosphorylase (turn genes on/off)

Question 96

Why is mechanical shearing NOT commonly used to cut DNA molecules during recombinant DNA technology? (1)

Answer 96

Mechanical shearing only cuts the DNA at random locations.

Question 97

In recombinant DNA technology, describe how restriction endonucleases are used to cut the DNA molecule. (3)

Answer 97

DNA cut at a unique site recognised by the enzyme.

Sometimes 2 different enzymes are used on the same piece of DNA

to allow the right ends to fit into the vector.

Question 98

In recombinant DNA technology, how are the two (or more) pieces of cut DNA joined together? (1)

Answer 98

Using ligases

Question 99

In recombinant DNA technology, give another name for introducing the new DNA molecule into a host cell. (1)

Answer 99

Transfection

Question 100

Name four methods of transfection used in recombinant DNA technology to insert a new piece of DNA into a cell. (4)

Answer 100

• Chemical transformation
• Electroporation
• Lipofectamine
• Injection

Question 101

Describe how chemical transformation can be used to insert new DNA molecules into cells during recombinant DNA technology. (2)

Answer 101

DNA plasmids and cells are mixed

then exposed to heat shock treatment.

Question 102

Describe how electroporation can be used to insert new DNA molecules into cells during recombinant DNA technology. (1)

Answer 102

Short high-voltage pulses used to break down cell membrane.

Question 103

Describe how lipofectamine can be used to insert new DNA molecules into cells during recombinant DNA technology. (2)

Answer 103

Spheres of phospholipids containing DNA

are fused with the cell membrane.

Question 104

Describe what is meant, and what is used as a vector in recombinant DNA technology. (2)

Answer 104

• Bacterial plasmid used

Vector is the DNA sequence into which cut section of DNA will be inserted to be carried into new cell or organism.

Question 105

True or false? (1)

Recombinant DNA technology uses viruses to insert foreign DNA into a cell.

Answer 105

False - uses plasmids as a vector

Question 106

What is the role of RNAi (RNA interference)? (1)

Answer 106

Turn genes off

Question 107

What is the difference between RNAi and miRNA? (2)

Answer 107

RNAi is a way to manipulate cells.

miRNA occurs naturally in cells.

Question 108

Briefly describe the steps in RNAi, not including the enzymes and proteins involved. (5)

Answer 108

• Synthetic precursor dsRNA enters cell
• dsRNA cut into short fragments
• Fragments split into passenger strand and guide strand
• Guide strand guides enzyme to target mRNA
• mRNA cleaved

Question 109

In RNAi, name the enzyme which cuts the precursor dsRNA into short fragments. (1)

Answer 109

Dicer

Question 110

In RNAi, name the protein complex which cleaves the target mRNA.
Name the enzyme associated with this complex and state its role. (3)

Answer 110

RNA-induced silencing complex (RISC)

The AGO2 enzyme is associated with RISC,

and it binds to the dsRNA fragments and splits them into guide and passenger strands.

Question 111

In RNAi, after the dsRNA has been cleaved to form fragments by dicer, what is the RNA now referred to as? (1)

Answer 111

short interfering RNA (siRNA)

Question 112

What is a viral vector, and what is it used for? (1)

Answer 112

Viral vectors are delivery systems used to introduce foreign genetic material into specific cells.

Question 113

Describe the steps required to build a viral vector. (4)

Answer 113

• Design gene of interest
• Insert gene into shuttle vector (eg. plasmid)
• Insert gene/plasmid plus virus packaging mix into a eukaryotic cell
• Harvest the virus once it has been assembled inside the cell

Question 114

Name four viral vectors which can potentially be used in neuroscience research. (4)

Answer 114

• Adeno Associated Virus (AAV)
• Retrovirus
• Adenovirus
• Herpes Virus

Question 115

Give two neurological conditions which are currently being clinically investigated using viral vectors. (2)

Answer 115

• Parkinson’s
• Alzheimer’s

Question 116

Name a viral vector which is commonly used to manipulate the genome in neuroscience research, but cannot be used clinically due to vector toxicity. (1)

Answer 116

Adenovirus

Question 117

Define what is meant by a ‘transgenic animal’. (1)

Answer 117

An animal whose genome has been modified.

Question 118

Give three general ways in which a transgenic animal’s genome can be modified. (3)

Answer 118

• Knock out (gene removed)
• Knock in (new gene inserted)
• Knock down (gene expression reduced)

Question 119

Describe what is meant by…

a) inducible
b) constitutive

gene alterations. (2)

Answer 119

a) Activation/inactivation of a gene only in specific cells at specific times

b) Continuous on/off change to a gene

Question 120

Give four ways that transgenic animals may be created. (4)

Answer 120

• DNA microinjection
• Transposons
• Lentiviral vectors
• Chimerae

Question 121

Briefly describe the DNA microinjection technique for creating transgenic animals. (1)

Answer 121

• DNA directly introduced into cell via a microinjection

Question 122

Briefly describe the transposon technique for creating transgenic animals. (1)

Answer 122

Using genes that can transport to a different location in the genome to transport the new gene

Question 123

Briefly describe the lentiviral vector technique for creating transgenic animals. (1)

Answer 123

Using viral transduction to introduce the new DNA into a cell.

Question 124

What is a chimeric animal? (1)

Answer 124

An animal containing cells with more than one genotype.

ie. an animal with genes from two or more different species

Question 125

Describe simply how you could clone a transgenic animal. (3)

Answer 125

Egg donor from one animal with genetic material removed.

Genetic material from readily-produced transgenic cells inserted into enucleated eggs.

Inject cells into host to develop.

Question 126

What is CRISPR Cas9 used for? (1)

Answer 126

Editing the genome at a precise location

Question 127

How was CRISPR Cas9 first discovered? (1)

Answer 127

In a bacterial immune system

Question 128

Describe the two components which make up CRISPR Cas9. (4)

Answer 128

Cas9 (DNA cutting enzyme)

Guide RNA (scaffolding sequence which binds to Cas9 plus a sequence which is complementary to DNA target)

Question 129

Describe how CRISPR Cas9 works. (4)

Answer 129

• Short nucleotide sequence in DNA called PAM binds to Cas9
• PAM close to cleavage site so guide RNA can unwind complementary/target dsDNA
• Cas9 enzyme cleaves DNA and causes double strand break
• As cell tries to fix the cleaved DNA it can incorporate ‘false’ DNA which has been injected containing mutations/insertions/deletions

Question 130

What is the importance of the CRISPR Cas9 technique making a double stranded break in the DNA of a cell? (2)

Answer 130

A double strand break would usually be fatal for a cell’s genetic material.

So the cell will always try to fix the cleaved DNA (and can therefore incorporate inserted DNA).

Question 131

What is gel electrophoresis used for? (1)

Answer 131

Gel electrophoresis is used to separate DNA, RNA, or proteins by their molecular weight/size.

Question 132

Describe the process and interpretation of the results for gel electrophoresis. (5)

Answer 132

• Load samples into wells/columns
• Current produced which moves samples (negative to positive)
• Smaller molecules move faster through the gel
• So when the reaction stops the molecules which have moved furthest are smaller
• Sample with known sizes can be run as a ladder for quantitative analysis

Question 133

What would happen if a sample of organic material containing molecules of different charges was separated using gel electrophoresis? (2)

Answer 133

• Molecules separated by both size and charge
• Movement based on charge:mass ratio

Question 134

Describe the gels which would be used in gel electrophoresis to separate:

a) DNA/RNA
b) proteins

Why do different gels have to be used?

(3)

Answer 134

a) agarose gel

b) polyacrylamide gel

Proteins too small to be run on an agarose gel.

Question 135

Complete the passage regarding the separation of DNA fragments via gel electrophoresis. (3)

DNA fragments will move towards the …………………… electrode, because they are ………………….. charged due to the presence of …………………… groups.

Answer 135

Positive

Negatively

Phosphate

Question 136

How are bands of DNA visualised after performing gel electrophoresis? (1)

Answer 136

Original samples mixed with fluorescent dye

Question 137

What is an epitope? (1)

Answer 137

Specific area of an antigen where the antibody binds.

Question 138

Briefly describe how a polyclonal antiserum would be produced for use in neuroscience research. (2)

Answer 138

• Inject antigen into mouse
• Isolate serum

Question 139

Briefly describe how monoclonal antibodies would be produced for use in neuroscience research. (6)

Answer 139

Inject antigen into mouse.

Isolate immune cells which form antibodies.

Fuse immune cell with tumour cell to form hybridomas.

Hybridomas screened for production of desired antibody.

Antibody-producing hybridomas cloned.

Isolate antibodies.

Question 140

Describe the difference between monoclonal antibodies and polyclonal antiserum. (2)

Answer 140

MONOCLONAL ANTIBODIES bind specifically to just one epitope of an antigen.

POLYCLONAL ANTISERUM contains a number of different antibodies, so all epitopes of an antigen will end up being bound.

Question 141

Give two advantages and one disadvantage of using monoclonal antibodies in neuroscience research, as opposed to polyclonal antiserum. (3)

Answer 141

ADVANTAGES:
- Very specific - less noise in experiments
- Unlimited supply - hybridoma cells continue replicating

DISADVANTAGES:
- Expensive

Question 142

Give one advantage and one disadvantage of using polyclonal antiserum in neuroscience research, as opposed to monoclonal antibodies. (2)

Answer 142

ADVANTAGE:
- cheaper

DISADVANTAGE:
- binding less specific - produces more background noise

Question 143

What is ELISA used for? (1)

Answer 143

Detecting antibodies or antigens present in a liquid (eg. serum) or homogenised tissue.

Question 144

Briefly, how can levels of an antibody or antigen be quantified in ELISA? (1)

Answer 144

Change in colour

Question 145

Briefly describe how to perform indirect ELISA. (4)

Answer 145

Well coated with antigen (complementary to antibody of interest)

Sample containing antibody of interest added to well

Second antibody (against first antibody), conjugated with enzyme, is added

Substrate added and will change colour if second antibody has bound

*wash between each step

Question 146

In indirect ELISA, describe the results. (2)

ie. what is measured, does darker colour mean more/less?

Answer 146

Measures antibodies of interest.

Darker colour means more antibodies present in original sample.

Question 147

Briefly describe how to perform sandwich ELISA. (4)

Answer 147

Antibody (complementary to antigen of interest) attached to well.

Sample containing antigen of interest added.

Secondary antibody (enzyme conjugated) added.

Substrate added and changes colour.

*Wash in between steps

Question 148

In sandwich ELISA, describe the results. (2)

ie. what is measured, does darker colour mean more/less?

Answer 148

Measures antigens of interest.

Darker colour = more antigens present in sample

Question 149

Briefly describe how to perform competitive ELISA. (5)

Answer 149

Excess of antibody incubated with antigen of interest.

Well coated with antigen which also binds to antibody.

Add antigen-antibody complexes to well (only free antibodies not already occupied will bind to antigens in well)

Enzyme-conjugated secondary antibodies added.

Substrate added and changes colour.

*Wash between each step

Question 150

In competitive ELISA, describe the results. (2)

ie. what is measured, does darker colour mean more/less?

Answer 150

Technique measures antigens.

The lower the signal, the more antigens present in the original sample
(more primary antibodies occupied by antigens of interest, so less bind to well)

Question 151

Describe what immunoprecipitation is and what it is used for. (2)

Answer 151

Specific separation (by precipitation) of molecules in a liquid or homogenised tissue

using antibodies.

Question 152

What kinds of molecules can be separated from a mixture using immunoprecipitation? (3)

Answer 152

• Proteins
• DNA
• Post-translational modifications

Question 153

Briefly describe the principles of how immunoprecipitation is performed. (3)

Answer 153

• Specific antibodies modified to allow easy separation
• Antibodies added to liquid/homogenate (and bind to targets)
• Antibodies and bound products precipitated to separate them from rest of molecules

Question 154

Describe two ways in which antibodies are modified for easy separation and separated from the sample in immunoprecipitation. (4)

Answer 154

ANTIBODIES LINKED TO AGAROSE BEADS
- agarose beads give Abs higher density so can use centrifugation

ANTIBODIES LINKED TO MAGNETIC BEADS
- magnet can be used (outside tube) to attract and remove antibodies bound to magnetic beads