Polymerase Chain Reaction and Southern Blot.

Question 1

Define a polymorphism?

Answer 1

When more than 1 allele occupies a genes locus.

Question 2

Define a point mutation?

Answer 2

A mutation that only affects a single nucleotide.

Question 3

Define a restriction fragment length polymorphism

Answer 3

It is the variation of length in a DNA fragment that is produced by a specific restriction enzyme

Question 4

Define a VNTR?

Answer 4

A variable nucleotide tandem repeat.

Question 5

Where are VNTR’s most likely to be found?

Answer 5

They are found all over the chromosome but are most often found near the centromere.

Question 6

What does the combination of an RFLP and Southern blot analysis allow scientists to identify?

Answer 6

Insertions and deletions within a gene.

Question 7

What does Southern blot analysis allow us to identify?

Answer 7

A specific gene in a genome when the genes have been separated by electrophoresis and transferred to a Southern blot membrane.

Question 8

How is the specific DNA sequence on a Southern blot membrane recognised?

Answer 8

A probe in the Southern blot will recognise a matching sequence within the DNA.

Question 9

What does Southern blot analysis help to locate within a persons genome?

Answer 9

To locate insertions and deletions within a persons genome.

Question 10

What are the 4 steps of Southern blot?

Answer 10

The DNA is digested by restriction endonuclease’s and the fragments are sorted by gel electrophoresis.

DNA is transferred to a Southern blot membrane which is made of nitrocellulose.

A specific probe is then added to the membrane and this probe it hybridises to a specific DNA fragment.

The membrane is analysed via X-ray and it will show the radioactive probe bound to the gene of interest.

Question 11

How are the DNA fragments from a Southern blot compared with each other?

Answer 11

From the position of each specific gene on the gel that is used for electrophoresis.

Question 12

Where do the genes that are compared via Southern blot come from?

Answer 12

From different people, there is also a control gene that represents the standard gene.

Question 13

How will DNA strands that have suffered from deletions or insertions differ from each other?

Answer 13

DNA that has had deletions will move further up the gel than the control as it will be lighter and will move faster.

DNA that has had insertions will be located below the control as it will be heavier and more slowly.

Question 14

What are VNTR’s?

Answer 14

They are repeating sequences of DNA that often lie close to the centromere on a chromosome.

Question 15

What part of a genome is used for Southern blot in a paternity test?

Answer 15

VNTR’s.

Question 16

Why are VNTR’s used for performing a paternity test via Southern blot?

Answer 16

As each person contains a different number of base’s within their VNTR’s.

Question 17

What is analysed in the VNTR’s when performing a paternity test via Southern blot?

Answer 17

The number of base’s within the VNTR’s.

Question 18

Why are VNTRs used when performing a paternity test via Southern blot?

Answer 18

As one chromosome comes from the mother and the other comes from the father.

Therefore, one of the babys VNTR’s should be the same on the Dad the other should be the same on the Mum.

Question 19

How is a paternity test via Southern blot carried out?

Answer 19

DNA is isolated from the suspected father, the mother and the child and compared via Southern blotting.

It is spearated by electrophoresis and then placed on the filter.

Once on the Southern blot filter, the probes can be compared.

Question 20

How will the DNA samples look if the suspected father is the father of the baby in a paternity test via Southern blot?

Answer 20

The electrophoresis picture will contain 2 bands for each person.

If the baby belongs to the father then 1 band should be identical to 1 of the fathers bands.

The other band should be identical to 1 of the mothers band.

Question 21

Can point mutations destroy restriction sites within DNA?

Answer 21

Yes.

Question 22

How can the absence of restriction sites be tested for?

Answer 22

Via Southern blot.

Question 23

What is the point mutation that causes sickle cell anaemia?

Answer 23

The change of a single nucleotide that codes for valine instead of glutamic acid.

Question 24

Does the point mutation that leads to sickle cell destroy a restriction site?

Answer 24

Yes.

Question 25

Can sickle cell be proven via Southern blot analysis?

Answer 25

Yes.

Question 26

What genetic samples are removed used to test for sickle cells disease?

Answer 26

The samples are cleaved at a restriction site that is upstream of the restriction site of interest.

Question 27

The genetic sample that is used to test for sickle cell is removed from the DNA strand via the use of what enzyme?

Answer 27

MST-2.

Question 28

How will the genetic samples of person who has scikle cell compare with the sampe of a person who does not have sickle cell when analysed via Southern blot?

Answer 28

A person who does not have sickle cell has a sample that is higher up the electrophoresis graph as it contains fewer base pairs.

A person who has sickle cell will have a sample that is lower down the electrophoresis graph as it contains more DNA.

Question 29

How many base pairs are usually found in the Southern blot sample of a person who does not have sickle cell?

Answer 29

Around 1150 base pairs

Question 30

How many base pairs are usually found in the Southern blot sample of a person who has sickle cell?

Answer 30

Around 1350 base pairs

Question 31

Why is the Southern blot sample of a person who does not have sickle cell have fewer base pairs?

Answer 31

Because their genome contains the complete restriction site, meaning that the sample is cleaved at that site.

Question 32

Why is the Southern blot sample of a person who has sickle cell have more base pairs?

Answer 32

As the genome does not have the restriction site, meaning that the sample is cleaved at the next site so it contains more BPs.

Question 33

Where are the cleavage sites on a Southern blot sample from a person that has sickle cell?

Answer 33

At the upstream site.

At the site that is downstream from where the gene of interest should be.

Question 34

How many sequences will a Southern blot sample for a person who is heterozygous for sickle cell contain?

Answer 34

There are 2 sequences.

One chromosome will contain the short sequence and the restriction site of interest.

The other with have the heavy sequence and no restriction site.

Question 35

Why can a person who does not have sickle cell have 2 possible sequences on a Southern blot sample?

Answer 35

As the probe can bind upstream or downstream of the restriction site of interest.

Question 36

What are the 2 possible amounts of base pairs that can be found on a Southern blot sample of a person who does not have sickle cell?

Answer 36

If the probe binds upstream of the site of interest it will be 1150 BPs.

If the probe binds downstream of the site of interest then there will be 200 base pairs.

Question 37

Who invented the PCR reaction?

Answer 37

Kary Mullis in 1983.

Question 38

What is the PCR reaction used for?

Answer 38

For the rapid production of large amounts of specific DNA sequences.

Question 39

Is the process of PCR automatic?

Answer 39

Yes.

Question 40

How does the amount of DNA increase after each round of PCR?

Answer 40

It doubles the amount of DNA.

Question 41

What are the 6 components required for successful PCR?

Answer 41

DNA polymerase.

Primers.

DNTPs.

Magnesium chloride.

A buffer.

DNA.

Question 42

What is the DNA polymerase used for in PCR?

Answer 42

To synthesise a new strand of DNA that is complimentary to an existing single strand of DNA.

Question 43

What is the primer used for in PCR?

Answer 43

Their presence on the DNA strand will help DNA polymerase attach to the strand.

Question 44

What are the DNTPs that used for in PCR?

Answer 44

These are de-oxynucleotide triphosphate’s and they differ in 4 ways depending on their base pair.

Question 45

What are the 4 DNTPs used in PCR?

Answer 45

DATP.

DGTP.

DCTP.

DTTP.

Question 46

What is magnesium chloride used for in PCR?

Answer 46

As a co-factor for DNA polymerase.

Question 47

What is the buffer used for in PCR?

Answer 47

To ensure that reaction conditions remain stable.

Question 48

What is the DNA used for in PCR?

Answer 48

As a complimentary template for the sequence of new DNA.

Question 49

What are the 4 steps of PCR?

Answer 49

Denaturation.

Annealing.

Primer extension.

Repetition.

Question 50

What occurs in the denaturation step of PCR?

Answer 50

The target DNA is heated to 95 degrees and denatured.

Question 51

What happens when the DNA is denatured during the 1st step of PCR?

Answer 51

The hydrogen bonds are broken and the 2 strands separate to form 2 single strands.

Question 52

What happens in the annealing stage of PCR?

Answer 52

The DNA is cooled to between 45 and 65 degrees.

This allows the RNA primers to bind to a complimentary strand.

Question 53

The optimum temperature for the binding of the primers to the DNA during PCR depends on what?

Answer 53

The properties of the primer.

Question 54

What are the names of the 2 primers invovled in PCR?

Answer 54

The forward and reverse primers.

Question 55

How does the forward primer read the DNA strand?

Answer 55

From left to right.

Question 56

How does the reverse primer read the DNA strand?

Answer 56

From right to left.

Question 57

What areas of the DNA strand will the primers bind to during PCR?

Answer 57

The primers bind to flanking sequences that are on each side of the target sequence.

Question 58

What happens during primer extension in PCR?

Answer 58

DNA polymerase II use’s MgCl as a co-factor.

The polymerase will extend the primer in the 5 to 3 direction and it will read the strand in the 3 to 5 direction.

Question 59

What type of polymerase is used in PCR?

Answer 59

A TAQ polymerase as it is capable of withstanding all of the temperatures in this process.

Question 60

What is the optimum temperature of a TAQ polymerase?

Answer 60

72 degrees.

Question 61

How many DNA molecules are formed at the end of the primer extension phase of PCR?

Answer 61

2 molecules of double stranded DNA.

Question 62

What happens during the repetition phase of PCR?

Answer 62

The previous steps are repeated as many times as necessary.

Question 63

What happens to the amount of DNA molecules after every cycle of PCR?

Answer 63

The number of DNA molecules doubles.

Question 64

What is the TAQ polymerase isolated from?

Answer 64

A bacteria that lives in hot springs and hydrothermal vents.

Question 65

What part of the PCR reaction allows for automation and why?

Answer 65

The TAQ polymerase as other polymerase’s denature at 95 degrees meaning that they have to be replaced.

Question 66

What is the half life of a TAQ polymerase?

Answer 66

Around 40 minutes at 95 degrees.

Question 67

What does TAQ polymerase add to a newly synthesised DNA strand?

Answer 67

An overhang that consists of a single adenine residue.

Question 68

When can the overhang added to a DNA strand by TAQ polymerase be exploited?

Answer 68

When the fragment is being cloned into vectors as it serves as a natural sticky end.

Question 69

Which TAQ polymerase has proof reading ability?

Answer 69

Hi-fidelity TAQ

Question 70

What are the 3 phases that are involved in the overall PCR reaction?

Answer 70

Exponential phase.

Linear phase.

Endpoint.

Question 71

What occurs during the exponential phase of PCR?

Answer 71

The product is doubling at every cycle.

Question 72

What occurs during the linear phase of PCR?

Answer 72

The reaction substrates are slowly consumed and accumulation of the product slows.

Question 73

What occurs during the endpoint phase of PCR?

Answer 73

Substrates are exhausted and no more product accumulates.

Question 74

The substrates used in PCR usually last for how many cycles?

Answer 74

Around 30 cycles.

Question 75

What is a good primer that can be used for PCR?

Answer 75

It must be long enough to be specific, but short enough to easily bind to the target sequence.

Question 76

What should the melting point of a PCR primer be?

Answer 76

Between 52 and 58 degrees.

Question 77

What should the GC content of a PCR primer be?

Answer 77

Between 40-60%. as this ensures that the melting temperature is correct.

Question 78

What are 5 applications of PCR?

Answer 78

Re-sequence a gene from any DNA sample.

Test blood for the presence of a virus.

Embryo genotyping.

Surveillance of mutated cancer cells.

Forensic sciences.

Question 79

What are 4 molecular applications of PCR?

Answer 79

PCR based mutagenesis.

Cloning strategies.

Gene expression analysis.

Genomics.

Question 80

Where must the primers for PCR be designed and why is this a drawback?

Answer 80

They must be designed in a lab.

This there must be knowledge about the sequence information on the target DNA.

Question 81

Is PCR easy to contaminate?

Answer 81

Yes, as a result it needs strict controls.

Question 82

When is it difficult to amplify DNA in PCR?

Answer 82

When the DNA is longer than 1500 BP.

Question 83

Why does PCR have limitations when involved in electrophoresis?

Answer 83

As PCT has low sensitivity, meaning that a certain amount of DNA must be used at the beginning if it is to show up after electrophoresis.

Question 84

What is the major drawback of using PCR and electrophoresis?

Answer 84

Electrophoresis only gives size based discrimination, so the results are not expressed quantitatively.

Question 85

What is real time PCR based around?

Answer 85

The detection and quantification of a fluorescent reporter that increase’s every time the sample doubles in size.

Question 86

What is the baseline in real time PCR?

Answer 86

The baseline consists of all of the components in the reaction except for the template.

Question 87

What is the threshold in real time PCR?

Answer 87

It is ten times the rate of the baseline.

Question 88

What is CT in real time PCR?

Answer 88

CT is the cycle number which is when the fluorescence crosse’s the threshold.

Question 89

What is the plateau determined by in real time PCR?

Answer 89

The amount of primers in the experiment.

Question 90

Does real time PCR require gel based analysis?

Answer 90

No, as analysis is based around the computer detection of fluorescence.

Question 91

What are the 2 major adavantages of using real time PCR?

Answer 91

Amplification can be monitored in real time.

It does not have low sensitivity so it can begin with small amounts of DNA as a template.

Question 92

What are the 3 types of probes used in PCR?

Answer 92

Hydrolysis probes.

Hybridisation or FRET probes.

DNA binding agents.

Question 93

What kind of PCR probe is the TAC man probe?

Answer 93

A hydrolysis probe.

Question 94

What 2 molecules does the PCR TAC man probe contain?

Answer 94

A 5-reporter molecule and a 3-quencher molecule.

Question 95

How does the PCR TAC man probe work?

Answer 95

The probe binds to a PCR product and degrades.

The degradation of the probe separates the quencher and reporter allowing fluorescent emissions to be detected.

Question 96

How does the BEACON fluoresent probe work during PCR?

Answer 96

The beacon probe forms a hairpin loop structure when it is not bound to the DNA of interest.

When it comes into contact with the DNA of interest, the loop structure will be lost and it will bind to the DNA.

Question 97

What happens if the BEACON probe is not fully complimentary to the gene of interest?

Answer 97

It will not lose its hairpin loop and no bonds will be formed.

Question 98

How does the FRET fluoresent probe work during PCR?

Answer 98

The probe consists of a pair of primers that hybridise close to each other on the target DNA.

The upstream primer is labelled at the 3 prime end with a donor fluorescent molecule and the downstream primer is labelled at the 5 prime end with an acceptor fluorescent molecule.

The donor fluorescent molecule is excited by an external light source and it will pass on its excretory energy to the acceptor molecule which will emit light at a different wavelength which can be detected and measured.

Question 99

How does the SYBR green fluoresent probe work during PCR?

Answer 99

This probe binds to double stranded DNA and emits light after excitation.

Question 100

What is the amount of fluoresence in a SYBR green probe proportional to?

Answer 100

The amount of fluorescence emitted is directly proportional to the amount of product that is generated in the PCR reaction.

Question 101

When should the SYBR green fluoresent probe not be used for PCR?

Answer 101

if the PCR has not been optimised.

It should not be used to detect low level transcripts.

It should never be used in multiplex reactions.

Question 102

Is PCR or Soiuthern blot better at diagnosing sickle cell?

Answer 102

PCR.

Question 103

How is PCR used to diagnose sickle cell?

Answer 103

The gene of interest is amplified to create many copies.

The specific fragment is removed and placed on a gel.

The amount of base pairs is analysed to determine whether a person has sickle cell.

Question 104

What enzyme is used to remove the specific DNA fragment when diagnosing sickle cell via PCR?

Answer 104

dDE-1.