Applications of molecular biology

Question 1

What is DNA cloning?

Answer 1

It is essentially making many copies of DNA. Isolation and amplification of a specific gene or DNA sequence

Question 2

What does DNA cloning involve?

Answer 2

Separating a specific gene or DNA segment from a larger chromosome, attaching it to a small molecule of carrier DNA, and then replicating this modified DNA many times through a) increase in host cell number and b) the creation of multiple copies of the cloned DNA in each cell.

Question 3

What are the five general procedures entailed in cloning DNA from any organism?

Answer 3

1. Cutting DNA at precise locations
2. Selecting a cloning vector, a small molecule of DNA capable of self-replication. (plasmid, phage, etc.)
3. Joining the two DNA fragments covalently. Composite DNA molecules comprising covalently linked segments from two or more sources are called recombinant DNAs.
4. Moving recombinant DNA from the test tube to a host cell, which will provide the enzymatic machinery for DNA replication. (e.g E.Coli)
5. Selecting or identifying host cells that contain the DNA.

Question 4

What is the result of DNA cloning?

Answer 4

The result is the selective amplification of a particular gene or DNA segment.

Question 5

What is the main organism used in recombinant DNA work, and why?

Answer 5

• E.Coli* , as it has many advantages:
• well understood
• many naturally-occurring cloning vectors (plasmids, phages) are associated with it
• techniques are available for moving DNA from one cell to another

Question 6

Why can’t DNA be isolated biochemically, like proteins?

Answer 6

Different DNA molecules do not differ in chemical properties like proteins do, and thus there are no differences to be exploited for separation methods.

Question 7

Which two enzymes lie at the heart of the classic recombinant DNA approach?

Answer 7

• Restriction endonucleases
• DNA ligases

Question 8

What do RE do?

Answer 8

They recognise and cleave DNA at specific sequences (restriction sites/recognition sequences) to generate a set of smaller fragments.

Question 9

What does DNA ligase do?

Answer 9

Joins the DNA fragment to be cloned and the suitable cloning vector covalently.

Question 10

What is the natural biological function of RE?

Answer 10

It is to recognise and cleave foreign DNA, e.g viral genetic material. They are naturally occurring bacterial enzymes that serve as defense mechanisms.

The host cell’s DNA is protected from RE digestion by methylation of DNA, catalysed by DNA methylase.

Question 11

What do type II RE do?

Answer 11

Cleave DNA within specific recognition sequences.

Question 12

Why are type I and type III RE not used?

Answer 12

Type I: cleaves at approx. 1000 bp from recognition sequence

Type III: cleaves at approx. 25bp from recognition sequence

So they are less reliable/predictable, more complicated and require ATP for movement along the DNA molecule.

Question 13

Give two features of recognition sequences

Answer 13

• 4-6 bp long
• palindromic

Question 14

What does DNA pol I do?

Answer 14

Fills gaps in duplexes by stepwise addition of nucleotides to 3’ end

Question 15

What does reverse transcriptase do?

Answer 15

Makes a DNA copy of an RNA molecule

Question 16

What is the function of polynucleotide kinase and why is it useful?

Answer 16

Adds a phosphate to the 5’ OH end of a polynucleotide to label it or permit ligation. It is useful as this enzyme enables to label the polynucleotide with a radioactive phosphate.

Question 17

What does terminal transferase do?

Answer 17

Adds homopolymer tails to 3’OH of a linear duplex

Question 18

What does exonuclease III do?

Answer 18

Removes nucleotides from 3’ end

Question 19

What does bacteriophage lambda exonuclease do?

Answer 19

Removes nucleotides from the 5’ ends of a duplex to expose single stranded 3’ ends

Question 20

What does alkaline phosphatase do?

Answer 20

Removes terminal phosphates from either or both ends.

Question 21

What does ribonuclease H do?

Answer 21

They are endonucleases that catalyse the cleavage of RNA via a hydrolytic mechanism. In DNA replication, RNase H is responsible for removing the RNA primer, allowing completion of the newly synthesized DNA.

Question 22

What is a cDNA library?

Answer 22

A library that includes only those genes that are expressed, i.e that are transcribed into RNA, in a given organism or even in certain cells or tissues. Such a library is designed to focus on those portions of a genome relevant to the function of a tissue or cell type.

Question 23

How is a cDNA library constructed?

Answer 23

1. Choose tissue of interest (as genes follow tissue-specific gene expression).
2. Isolate mRNA (mRNA expressed << total DNA in cell), using affinity chromatography column linked to thymine (polyA tail)
3. Copy mRNA into cDNA in a multistep reaction catalysed by reverse transcriptase.
4. Introduce cDNA into a cloning vector and clone.

Result = creation of a population of clones called a cDNA library.

Question 24

Why is a cDNA library useful?

Answer 24

By focusing on a CDNA library generated from the mRNAs of a cell known to expressa certain gene, the search for a particular gene is made easier.

Question 25

Outline the 5 steps of the synthesis of duplex cDNA from mRNA

Answer 25

1. mRNA template is annealed to a synthetic oligo dT DNA primer.
2. Complementary strand yielded by reverse transcriptase, giving a DNA-RNA hybrid
3. mRNA strand is degraded with alkali
4. A DNA oligonucleotide of known sequence is annealed to the 3’ end of the cDNA to prime synthesis of second DNA strand.
5. DNA pol I extends the primer to yield double-stranded DNA.

Question 26

What happens after this?

Answer 26

Question 27

What are the three main features of a plasmid cloning vector?

Answer 27

• Multiple cloning site (MCS, polylinker): contains lots of restriction sites.
  2. Origin of replication (ori)
  3. Selectable marker (e.g Amp R)

Question 28

Where is the foreign DNA inserted in the plasmid cloning vector?

Answer 28

Into one of the sites within the MCS, depending on the RE with which it has been digested.

Question 29

How can a plasmid be taken up by a host cell (E.Coli)?

Answer 29

Two ways of making membrane permeable to large molecules:

• Transformation: treatment with calcium chloride followed by rapid heat shock
• Electroporation: cells subjected to high voltage pulse, which transiently renders the bacterial membrane permeable to large molecules

Question 30

How are host cells that have taken up the plasmid selected for?

Answer 30

Question 31

After a cDNA library has been constructed, what is the next step?

Answer 31

Screening the library with an appropriate probe, to detect clones with a particular DNA segment.

Question 32

What is a probe?

Answer 32

It is a labeled (e.g radioactive) DNA or RNA fragment complementary to the DNA being sought.

Question 33

Describe one classic approach to screen a DNA library, 5 steps

Answer 33

1. Take agar plate with transformed bacterial colonies, and press nitrocellulose paper onto the agar plate. In this way, some cells from each colony stick to the paper.
2. Treat the nitrocellulose paper with the cells on it with alkali in order to disrupt cells and expose denatured DNA. The result is DNA bound to the nitrocellulose paper.
3. Incubate the paper with radiolabeled DNA probes, then wash. The probes will hybridise with the complementary sequence on the paper and thus will be bound to the colonies of interest.
4. Expose X-Ray film to paper and obtain an autoradiograph to detect colonies of interest.

Question 34

What comes after this?

Answer 34

Question 35

How are oligonucleotide probes created?

Answer 35

They are designed from a protein sequence. However, due to the degenerate nature of the genetic code, the DNA sequence for a known amino acid sequence cannot be known in advance. Thus, the probe is designed to be complementary to a region of the gene with minimal degeneracy, that is, a region with the fewest possible codons for the amino acids (e.g choose a region of aa for which there are two codons at most for each aa).

Synthetic probes are created with selectivley randomised sequences, so that they contain either of the n possible sequences at each position of the potential degeneracy.

Question 36

How is the possible number of oligonucletoide sequences calculated?

Answer 36

For a minimal degeneracy region with k amino acids:

Nº possible sequences = Nº codon aa1 + Nº codons for aa2 + …….+ Nº codons for aaK

Question 37

What are expression vectors?

Answer 37

Cloning vectors with transcription and translation signals needed for the regulated expresion of a cloned gene.

Used because sometimes it is the product of the cloned gene, rather than the gene itself, that is of primary interest, particularly if the gene product (protein) has commercial, therapeutic or research value.

Question 38

What elements does a typical expression vector have? (7)

Answer 38

• Polylinker: contains the gene to be expressed.
• Promoter (P): allows efficient transcription of the inserted gene.
• Transcription termination sequence: improves amount and stability of mRNA produced.
• Operator (O): permits regulation by means of a repressor that binds to it.
• Ribosome binding site: provides sequence signals needed for efficient translation of the mRNA derived from the gene.
• Selectable marker: allows selection of cells containing recombinant DNA.
• ori
• gene encoding repressor that binds O and regulates P

Question 39

What is an alternative way of screening a cDNA library, particularly when interseted in a gene product?

Answer 39

Even if DNA is present (known froms screening with DNA probes), it doesn’t mean that the cell is expressing the protein, so in some cases we are better off screening directly for that by using antibodies.

Question 40

How is a cDNA library screened with antibodies for a particular gene product? (4)

Answer 40

1. Press nitrocellulose paper onto plate with transformed bacterial colonies. The proteins will bind to the nitrocellulose paper.
2. Incubate the paper with primary antibody, made specifically for the protein that we’re trying to express using an organism such as a mouse.
3. Incubate with secondary antibody which recognises the primay antibody (commercially available, produced in mass) and is enzyme-linked.
4. Add enzyme substrate, identify product of enzymatic reaction and identify which colonies are expressing the gene.

Question 41

What is an important element to have when carrying out expression of foreign protein in bacteria?

Answer 41

A “switch” to turn expression on/off to not slow down growth, or in case the protein we’re trying to express is toxic to the host cell.

Question 42

What is an example of this expression switch?

Answer 42

IPTG: turns on promoter, looks like lactose.

Lac promoter: when there is hi [glucose], or no lactose, transcription of lac genes doesn’t occur.

So when IPTG is present (looks like lactose), transcription of lac genes occur. If we put our cDNA in the lacZ gene’s place, we can regulate its expression by adding/removing IPTG.

Question 43

What is blue white selection?

Answer 43

It is a screening technique that allows for the rapid and convenient detection of recombinant bacteria in vector-based molecular cloning experiments. DNA of interest is ligated into a vector. The insert disrupts the lacZ gene, meaning that no alpha-peptide is made, and by extension no functional B-galactosidase is formed. The vector is then inserted into a competent host cell viable for transformation, which are then grown in the presence of X-gal. X-gal is hydrolysed by B-galactosidase to yield an insoluble blue compound. Cells transformed with vectors containing recombinant DNA will produce white colonies; cells transformed with non-recombinant plasmids (i.e. only the vector) grow into blue colonies.

Question 44

What are markers and what are they used for?

Answer 44

It is a gene that researchers attach to a regulatory sequence of another gene of interest in bacteria, cell culture, animals or plants. A cDNA library can be made even more specialised by cloning cDNAs fragments into a vector that fuses each cDNA sequence with the sequence for a marker, or reporter gene; the fused genes form a “reporter construct”.

Question 45

What is GFP?

Answer 45

Green fluorescent protein, used as useful marker: the gene for GFP is fused with the target gene, which generates a fusion protein that is highly fluorescent and thus can be easily visualised microscopically, allowing the study of its location and movement in a cell.

Question 46

What is an epitope tag?

Answer 46

Epitope = part of antigen recognised by immune system

A short protein sequence that is bound tightly by a well-characterised monoclonal antibody. This allows for the tagged protein to be specifically precipitated from a crude protein extract by interaction with the antibody. The precipitated proteins can then be separated by means of gel electrophoresis, and new proteins in the preicpitate can then be identified (see below).

In addition, any other proteins that interact with the tagged protein also precipitate, helping to elucidate protein-protein interactions.

Question 47

How can recombinant DNA-technology be applied to the production of proteins important for medicine or industry?

Answer 47

Aim: synthesise a human protein in bacteria, as these are difficult to isolate from naturally-occurring sources (humans).

How is it done?

• clone human gene into bacteria in a vector that has all the elements that the host cell needs to express the protein (promoter, operator, ribosome binding site, etc.) and then trick the bacteria into thinking they are producing their own protein.

Question 48

Nam 3 proteins made in bacteria for medical use

Answer 48

• Insulin: recombinant insulin has many advantages, one of which is that it can be used instantly after injection, generally more effective
• Growth hormone
• Factors VIII and IX

Question 49

What is oligonucleotide site-directed mutagenesis?

Answer 49

Cloning techniques can be used not only to overproduce proteins but also to produce protein products slightly altered from their native forms. Site-directed mutagenesis is a technique used to replace specific amino acids in order to make gene product more efficient.

It is used when a gene is not flanked by appropriate restriction sites and thus the DNA segment cannot simply be removed and replaced with a synthetic one that is identical to the original except for the desired change.

Question 50

What is (a), what is (b)?

Answer 50

(a) A synthetic DNA segment replaces a DNA fragment that has been removed by cleavage with an RE.
(b) Oligonucleotide site-directed mutagenesis: a synthetic oligonucleotide with a desired sequence change at one position is hybridised to a single-stranded copy of the gene to be altered. This acts as a primer for synthesis of a duplex DNA which is then used to transform cells. Cellular DNA repair systems will convert about 50% of the mismatches to reflect the desired sequence change.

Question 51

In OSDM, under which conditions is annealing possible?

Answer 51

• If a single bp is altered
• If T is appropriate

Question 52

What are the 3 steps/requirements of OSDM?

Answer 52

1. Decide which codons to change (site-specific)
2. Synthesise a primer (oligonucleotide) for DNA synthesis which includes the change
3. Prepare a single-strand DNA template.

Question 53

How is the single-stranded template for OSDM prepared?

Answer 53

1. Recombinant M13 vector (double stranded DNA) is transfected into E.Coli
2. Phage are releasesd, a recombinant M13 phage has a DNA core wrapped in a protein coat.
3. Protein coat is removed: single stranded DNA is obtained, which can be used in the experiment.

Question 54

What is a trick used in OSDM?

Answer 54

Used of modified deoxynucleotides to synthesise the new strand. The sulphur-substituted DNA strand cannot be cut by RE, but these enzymes can cut the strand on the outside. So a RE with a RS downstream from the region we want to change is used, followed by exonuclease III which removes nucleotides to an extent dependent on enzyme and incubation time, then DNA is synthesised with appropriate change.

Question 55

Which aa is subsituted in Subtilisin by means of OSDM?

Answer 55

AUG (met222) —-> GCG (ala222)

Question 56

What is the most efficient way of purifying recombinant proteins?

Answer 56

Affinity chromatography- requires a specificity tag to be incorporated into cloning strategy.

Question 57

What is the advantage of adding a (His)6 tag, and what is its immobilised ligand?

Answer 57

• Doesn’t require correct folding
• Ni2+: the imidazole group has a great affinity for chelated metals.

Question 58

What is the immobilised ligand for GST?

Answer 58

Glutathione (GSH). GST catalyses the conjugation of electrophilic substrates to glutathione (GSH).

GST can be added to a protein of interest to purify it from solution. This is accomplished by inserting the GST DNA coding sequence next to that which codes for the protein of interest. Thus, after transcription and translation, the GST protein and the protein of interest will be expressed together as a fusion protein. Because the GST protein has a strong binding affinity for GSH, beads coated with the compound can be added to the protein mixture; as a result, the protein of interest attached to the GST will stick to the beads, isolating the protein from the rest of those in solution. The beads are recovered and washed with free GSH to detach the protein of interest from the beads, resulting in a purified protein. This technique can be used to elucidate direct protein-protein interactions

Question 59

Give the name of two tags used in affinity chromtography

Answer 59

• Maltose binding protein (IL: maltose)
• Chitin binding domain (IL: chitin)

Question 60

How can GST be cleaved off the target protein after affinity chromatography?

Answer 60

Protease cleavage site between protein of interest and GST. This is done to ensure that the observed properties are of the protein and not of the tag.

Question 61

How can each step in the purification procedure be monitored?

Answer 61

By means of gel electrophoresis.

Question 62

What is

a) Southern blotting
b) Northern blotting
c) Western blotting

Answer 62

Question 63

How does Southern blotting work?

Answer 63

Question 64

How can Southern blotting be used in forensic medicine?

Question 65

What is shown in the image?

Answer 65

The Southern blot procedure, as applied to RFLP DNA fingerprinting.

Question 66

What is PCR?

Answer 66

If we know the sequence of at least the flanking parts of a DNA segment to be cloned, we can hugely amplify the number of copies of that DNA segment, using the polymerase chain reaction (PCR). The amplified DNA can be cloned directly or used in a variety of analytical procedures.

Question 67

What are the requirements for PCR? (5)

Answer 67

1. Two primers, complimentary to the sequene to be amplified. In order to synthesise these primers, the sequence of the DNA that we need to amplify must be known.
2. Template DNA (that which is going to get copied)
3. Thermostable DNA polymerase (TAC polymerase)
4. dNTPs
5. Thermal cycler

Question 68

What is the annealing temperature?

Answer 68

Tm = 4* (G+C) + 2* (A+T) (ºC)

Question 69

What are the three steps in the PCR procedure?

Answer 69

1. Heat to separate strands
2. Anneal primers containing noncomplementary regions with cleavage site for restriction endonuclease.
3. DNA synthesis catalysed by TAC polymerase.

Repeat for 25-30 cycles, after which the target sequence will have been amplified a million fold

Question 70

In what procedure are fluorescent dye-labeled PCR primers used?

Answer 70

In PCR analysis of an STR locus.

1. Conduct PCR of STR locus.
2. Run PCR fragments on a capillary gel (very thin, polyacrylamide)
3. Scan of PCR product bands derived from locus, generates a series of peaks (as each allele in the locus might have different number of repeats, the PCR can generate two products of slightly different size).
4. Combining the scans for different loci gives a multiplex pattern.

Question 71

What is a DNA microarray and what is it used for?

Answer 71

A DNA microarray is a collection of microscopic DNA spots attached to a solid surface. Scientists use DNA microarrays to measure the expression levels of large numbers of genes simultaneously or to genotype multiple regions of a genome.

Essentially, it is used to analyse gene expression in 2 different places (e.g 2 different points of development, or differences between 2 people to look at disease)

Question 72

What are the 3 steps for a DNA microarray?

Answer 72

1. Isolate mRNAs from cells (each mRNA represents all the genes expressed in the cells at that particular stage)
2. Convert inot cDNAs, using fluorescently labeled dNTPs.
3. Add cDNAs to a microarray; fluorescent cDNAs anneal to complementary sequences on the microarray.

More detailed explanation:

A microarray can be prepared from any known DNA sequence, from any source, generated by chemical synthesis or by PCR. The DNA is positioned on a solid surface (usually specially treated glass slides) with the aid of a robotic device capable of depositing very small (nanoliter) drops in precise patterns. UV light cross-links the DNA to the glass slides. Once the DNA is attached to the surface, the microarray can be probed with other fluorescently la- beled nucleic acids. Here, mRNA samples are collected from cells at two different stages in the development of a frog. The cDNA probes are made with nucleotides that fluoresce in different colors for each sam- ple; a mixture of the cDNAs is used to probe the microarray. Green spots represent mRNAs more abundant at the single-cell stage; red spots, sequences more abundant later in development. The yellow spots indicate approximately equal abundance at both stages

Question 73

What are the implications of cloning in plants?

Answer 73

Allows to enhance natural properties (e.g increase nutritional content), and allows to give other properties: herbicide resistance, pathogen resistance, biofuels, bioremediations, etc.

Question 74

What is one method used for cloning in plants?

Answer 74

Using Agrobacterium tumefaciens

Lives in soil, attached to the root of a plant, forms “tumor” on plant via transformation with Ti plasmid (pk to ek DNA transfer).

It can invade plants at the site of a wound, transform nearby cells, induce them to form a tumor called crown gall.

Question 75

What are the main features of the Ti plasmid, found in agrobacterium tumefaciens?

Answer 75

vir genes: involved in transfer of genes from bacteria, together with the 25bp repeats that flank DNA. Encode enzymes necessary to introduce TDNA segment of Ti plasmid into genome of neraby cells.

T DNA: transferred from plasmid into plant cell chromosome. It encodes enzymes that convert plant metabolites into 2 compounds that benefit the bacterium: plant growth hormones, to form the crown gall tumor, and opines (aa), which serve as a food source for the bacterium

Question 76

How does AT work?

Answer 76

Question 77

How can the natural process mediated by AT be exploited?

Answer 77

Require: transfer ability, ability to make recombinant plasmids

We do not need: additional cell growth, production of opines

Question 78

How is a recombinant plant created?

Answer 78

One plasmid is a modified Ti plasmid that contains the vir genes but lacks T DNA. The other plasmid contains a segment of DNA that bears both a foreign gene (the gene of interest) and an antibiotic-resistance element (here, kanamycin resistance), flanked by the two 25 bp repeats of T DNA that are required for transfer of the plasmid genes to the plant chromosome. This plasmid also contains the replication origin needed for propagation in Agrobacterium.

When bacteria invade at the site of a wound (the edge of the cut leaf), the vir genes on the first plasmid mediate transfer into the plant genome of the segment of the second plasmid that is flanked by the 25 bp repeats. Leaf segments are placed on an agar dish that contains both kanamycin and appropriate levels of plant growth hormones, and new plants are generated from segments with the transformed cells. Non- transformed cells are killed by the kanamycin. The foreign gene and the antibiotic-resistance element are normally transferred together, so plant cells that grow in this medium generally contain the foreign gene.

Question 79

What is this?

Answer 79

A two-plasmid strategy to create a recombinant plant.

Question 80

What are the forward and reverse PCR primers for this sequence? (—– is the gene of interest)

5’ ATGCTGACCGTGCATGTA——–GTCACCTGGTGATTACGT 3’

3’ TACGACTGGCACGTACAT——–CAGTGGACCACTAATGCA 5’

Answer 80

In order to amplify the gene of interest, two replication primers must be designed, complementary to sequences on opposite strands of the target DNA at positions defining the ends of the segment to be amplified. In this case, the two PCR primers are:

Forward: 5’ ATGCTGACCGTGCATGTA 3’

Reverse: 5’ ACGTAATCACCAGGTGAC 3’

Question 81

What features should you try and avoid when designing primers?

Answer 81

The Tm of both primers needs to be similar enough to enable to set an annealing temperature that is suitable for both. Thus, very dissimilar Tm values between both primers should be avoided.(if too low, allows for non-specific binding, if high enough, E is put into the system, only strongest interactions reisst, i.e the specific ones).

In addition, the sequences of the primers must be designed so as to avoid self- annealing (arises from the fact that it is easier for it to close on itself because it’s closer, even though binding to complementary strand is much more favourable)

The length of the primers is another feature that must be taken into account. Ideally, the primers should be 18-30 nucleotides long. Shorter sequences should be avoided because they largely decrease the specificity of the primer.

Runs of the same nucleotide or dinucleotide repeats should also be avoided (can potentially cause a frameshift)