Manipulating genomes

Question 1

What is a DNA profile and how are they constructed?

Answer 1

A DNA profile is a genetic fingerprint that is unique to each person (except identical twins) and they are constructed using techniques such as the polymerase chain reaction (PCR) and electrophoresis

Question 2

How is a DNA profile produced?

Answer 2

DNA extracted (and many copies made using PCR)
Digested (broken into fragments) using restriction endonucleases
Separated using electrophoresis
Hybridised with probes (bind to fragments and enable them to be visualised
Visualised in banding patterns (bars)

Question 3

What is PCR and how is it used in DNA profiling?

Answer 3

Polymerase chain reaction - DNA amplification (copying).
DNA sample is placed in a thermocycler, which cycles through 3 temperatures:
95°C - breaks hydrogen bonds in the DNA, splitting it into two strands
55°C - primers bond to the end of each DNA strand
72°C - taq DNA polymerase joins free nucleotides to each strand

Question 4

What is electrophoresis and how is it used in DNA profiling?

Answer 4

Separation of DNA fragments - DNA fragments are placed at the end of a gel plate. A positive electrode is at the opposite end of the plate
DNA moves towards the positive electrode when a current is applied (because all DNA fragments have phosphate groups with negative charges)
Longer fragments move slower, shorter fragments move faster
DNA fragments therefore separated into bands based on size

Question 5

What are restriction endonucleases?

Answer 5

Enzymes found in bacteria - more than 50 are known, and each one cuts DNA at specific base sequences (recognition sites). As well as digesting DNA prior to electrophoresis, they are used for genetic engineering

Question 6

Why is taq DNA polymerase used, rather than human DNA polymerase?

Answer 6

It is obtained from a thermophilic bacterium (Taq) so this form of polymerase is tolerant to heat so does not denature during temperature cycling. Also easier to obtain and potentially more ethical than using human DNA polymerase.

Question 7

What are VNTRs?

Answer 7

Variable number tandem repeats. DNA profiles are often formed from these sections of DNA as the patterns of VNTRs differ between people - there is a very low probability of two unrelated individuals having the same VNTR profile.

Question 8

What are 3 uses of DNA profiling?

Answer 8

In forensics (legal applications) - such as criminal investigations and paternity testing
Disease risk analysis
Classification

Question 9

How is DNA sequenced?

Answer 9

PCR is conducted
However, some of the free nucleotides in PCR have been modified in two ways:
- when they bond to a DNA strand they terminate polymerisation
- They are fluorescently coloured - A, T, C and G have different colours
New DNA strands stop growing whenever a terminator base is added - PCR is interrupted
This results in every possible chain length being produced
Lasers detect the final base on each chain
The sequence of DNA bases can therefore be worked out

Question 10

How are DNA sequences used?

Answer 10

Disease analysis - particular gene variants can be sequenced and linked to the risk of inheriting certain diseases. Sequencing pathogen genomes enables identification of antibiotic-resistant bacteria, pinpointing genetic markers for vaccines, and identification of targets for drugs
Classification - identifying species by using DNA barcodes. Studying evolutionary relationships by comparing similarities and differences between species’ base sequences
Genotype-phenotype relationships - amino acid sequences do not always match those predicted from base sequences - several phenotypes are possible from the same genotype - knowledge of both amino acid and base sequences enables comparisons to be made
Synthetic biology - genetic engineering requires knowledge of base sequences

Question 11

What is the difference between bioinformatics and computational biology?

Answer 11

Bioinformatics is a toolkit - creation of databases and computer software that can be used to solve biological questions. Computational biology is the application of bioinformatics - e.g. sequencing of genomes relies on bioinformatics and is therefore an example of computational biology.

Question 12

What is the difference between DNA profiling and DNA sequencing?

Answer 12

DNA profiling produces a genetic fingerprint, unique to an individual, which is based on particular sections of DNA.
DNA sequencing determines the precise base sequences in DNA

Question 13

What is genetic engineering?

Answer 13

Altering genes and transferring them between species

Question 14

What are the 2 ways a desired gene can be extracted?

Answer 14

• Producing the gene from an mRNA template

- Cutting the gene out using restriction endonucleases

Question 15

Describe the use of reverse transcriptase in genetic engineering

Answer 15

mRNA (transcribed from desired gene) extracted from cells. Reverse transcriptase is used to convert mRNA to cDNA (a single strand of complementary DNA)

Question 16

Describe the use of restriction endonucleases in genetic engineering

Answer 16

Gene is cut from its source DNA - cutting the gene and plasmid with the same enzyme produces two sets of sticky ends with complementary base pairings, enabling the gene to be inserted into the plasmid

Question 17

What is recombinant DNA?

Answer 17

DNA combined from two different sources

Question 18

What are plasmids?

Answer 18

Small circular pieces of DNA found in prokaryotic cells

Question 19

What are sticky ends?

Answer 19

two short sequences of exposed, unpaired bases at ends of DNA that has been cut

Question 20

What are marker genes?

Answer 20

Indicate whether or not a gene (and therefore a plasmid) has been successfully taken up by bacterial cells. Marker genes are usually for antibiotic resistance or fluorescence

Question 21

What is used to transfer the gene into the organism that is being modified?

Answer 21

A vector

Question 22

Give two examples of vectors:

Answer 22

Plasmids - circular bacterial DNA; by far the most common vector. Bacterial artificial chromosomes (BACs) are synthetic structures based on plasmids. DNA ligase is used to seal the gene into the plasmid
Viruses (e.g. bacteriophages, which naturally infect bacterial cells)

Question 23

What is the process of transferring the donated gene into the recipient’s cells called?

Answer 23

Transformation

Question 24

Describe the culture heating method of transformation

Answer 24

Bacterial cell membranes become more permeable when heated in a calcium-rich solution. Plasmids are then able to diffuse into the cells

Question 25

Describe the electroporation method of transformation

Answer 25

Electric current disrupts the cell membrane, enabling plasmids to enter

Question 26

Describe the electrofusion method of transformation

Answer 26

Electric currents enable the cell and nuclear membranes of two different cells to fuse - used in plants

Question 27

Describe the viral transfer method of transformation

Answer 27

Viruses naturally infect cells, and this mechanism can be exploited to insert DNA directly into target cells

Question 28

Describe the Agrobacterium tumefaciens infection method of transformation

Answer 28

This bacterium naturally infects plant cells and can be used to introduce recombinant plasmids

Question 29

What are the potential ethical issues with genetically modified microorganisms?

Answer 29

The use of the technology for biological warfare

Question 30

What are the potential ethical issues with pest resistance in plants?

Answer 30

GM plants could produce toxins that might harm insects other than targeted pests, and also the pests may require the plants to survive

Question 31

What are the potential ethical issues of pharming (producing human medicines from GM animals)?

Answer 31

Is animal welfare compromised? Will genetic engineering damage the health and livilhoods of the animals?

Question 32

What are the potential ethical issues of patenting (i.e. legal ownership of GM technology)?

Answer 32

How available will technology be for those it might benefit? Companies are able to patent techniques and GM organisms, and farmers in poor countries are forced to pay for their use.
Making money put above welfare of people, e.g. with diseases or conditions that could be treated

Question 33

What is gene therapy?

Answer 33

Addition of beneficial alleles to the cells of people with disease-causing alleles

Question 34

Describe somatic cell therapy

Answer 34

Human body cells targeted - haemophilia, cystic fibrosis, immune diseases treated with this type of gene therapy.
Limitations:
- There are possible risks of additional health problems
- Introduced genes are non-inheritable
- requires repeat treatments

Question 35

Describe germline therapy

Answer 35

Gametes or early embryonic cells are targeted. No current examples - illegal in humans - ethical issues - changes are permanent, and who decides which genes are targeted?

Question 36

How can genes be transferred into target cells?

Answer 36

Using either harmless viruses or liposomes (hollow spheres of lipid molecules)

Question 37

What enzyme is used to seal the gene into the plasmid in genetic engineering (producing recombinant DNA)?

Answer 37

DNA ligase