8.4.1Recombinant Gene technologies ( 8.0 The control of gene expression)

Question 1

what is recombinant DNA technology

Answer 1

transfer of DNA fragments from one organism or species to another

Question 2

explain why transferred DNA can be translated within cells of recipient (transgenic ) organisms

Answer 2

1) generic code is universal
2) transcription and translation mechanisms are universal

Question 3

Describe how DNA fragments can be produced using restriction enzymes

Answer 3

1) restriction enzymes cut DNA at specific base recognition sequence either side of the desired gene
- shape or recognition site complementary to active site
2) many cut in a staggered fashion forming sticky ends

Question 4

Describe how DNA fragments can be produced from mRNA

Answer 4

1) isolate mRNA from a cell that readily synthesises the protein coded for by the desired gene
2) Mix mRNA and with DNA nucleotides and reverse transcriptase - reverse transcriptase uses mRNA as a template to synthesise a single strand of complementary DNA (cDNA)
3) DNA polymerase can form a second strand of DNA using cDNA as a template

Question 5

Suggest two advantages from obtaining genes from mRNA rather than directly from the DNA removed from the cells

Answer 5

• much more MRNA in cells making the protein than DNA - easily extracted
• in MRNA introns have been removed by splicing whereas DNA contains introns
  • so can be transcribed and translated by prokaryotes who can’t remove introns by splicing

Question 6

Describe how fragments of DNA can be produced using a gene machine

Answer 6

• synthesises fragments of DNA quickly and accurately from scratch without need for a DNA template
  • amino acid sequence of protein determined , allowing base sequence to be established
• these do not contain introns so can be transcribed and translated by prokaryotes

Question 7

Name an in vitro and in vivo technique used to amplify DNA fragments

Answer 7

•in vitro ( outside a living organism) = polymerase chain reaction
• in vivo ( inside a living organism ) = culturing transformed host cells e.g bacteria

Question 8

Explain how DNA fragments can be amplified by PCR

Answer 8

Reaction mixture : DNA fragment , DNA polymerase (e.g taq polymerase), primers and DNA nucleotides
1) Mixture heated to 95 degrees :
• this separates DNA strands
• breaking hydrogen bonds between bases
2) Mixture cooled to 55 degrees :
• this allows primers to bind to DNA fragments template strand
• by forming hydrogen bonds between complementary bases
3) Mixture heated to 72 degrees :
• nucleotides align next to complementary exposed bases
• DNA polymerase joins adjacent DNA nucleotides, forming phosphodiester bonds
Cycle is repeated - in every cycle , the amount of DNA doubles causing an exponential increase ( 2^n)

Question 9

Explain the role of primers in PCR

Answer 9

• primers are short , single stranded DNA fragments
• Complementary to DNA base sequence at edges of region to be copied / start of desired gene
• Allowing DNA polymerase to bind to start synthesis
• Two different primers ( forward and reverse ) are required as base sequences at ends are different

Question 10

Suggest one reason why DNA replication eventually stops in PCR

Answer 10

There are limited number of primers and nucleotides which are eventually used up

Question 11

Summarise the steps involved in amplifying DNA fragments in vivo

Answer 11

1) Add promoter and terminator regions to DNA fragments
2) Insert DNA fragments and marker genes into vectors ( e.g. plasmids) using restriction enzymes and ligases
3) Transform host cells (e.g. bacteria) by inserting these vectors
4) Detect genetically modified / transformed cells / organisms by identifying those containing the marker gene
5) Culture these transformed host cells , allowing them to divide and form clones

Question 12

Explain why promotor and terminator regions are added to DNA fragments that are used to genetically modify organisms

Answer 12

promoter regions :
• allow transcription to start by allowing RNA polymerase to bind to DNA
• can be selected to ensure gene expression happens only in specific cell types
Terminator regions :
• ensure transcription stops at the end of a gene , by stopping RNA polymerase

Question 13

what are the role of vectors in recombinant DNA technology

Answer 13

to transfer DNA into host cells / organisms

Question 14

Explain the role of enzymes in inserting DNA fragments into vectors

Answer 14

1) restriction endonucleases / enzymes cut vector DNA
• same enzyme used that cut the gene out so vector DNA and fragments have sticky ends that can join by complementary base pairing
2) DNA ligase joins DNA fragments to vector DNA
• forming phosphodiester bonds between adjacent nucleotides

Question 15

Describe how host cells are transformed using vector

Answer 15

• plasmids enter cells
• viruses inject their DNA into cells which is then integrated into host DNA

Question 16

Explain why marker genes are inserted into vectors

Answer 16

• To allow detection of genetically modified / transgenic cells / organisms
- if marker gene codes for antibiotic resistance, cells that survive antibiotic exposure = transformed
- if marker gene codes for fluorescent proteins , cells that fluoresce under UV light = transformed
• As not all cells / organisms will take up the vector and be transformed

Question 17

Suggest how recombinant DNA technology can be useful

Answer 17

medicine :
• GM bacteria produce human proteins => more ethically acceptable than using animal proteins and less likely to cause allergic reactions
• GM animals / plants produce pharmaceuticals => cheaper
• Gene therapy
Agriculture :
• GM crops resistant to herbicides => only weeds killed when crop sprayed with herbicide
• GM crops resistant to insect attack => reduce use of insecticide
• GM crops with added nutritional value
• GM animals with increased growth hormone production
Industry :
• GM bacteria produce enzymes used in industrial processes and food production

Question 18

Describe gene therapy

Answer 18

• introduction of new DNA into cells , often containing healthy / functional alleles
• to overcome effect of faulty / nonfunctional alleles in people with genetic disorders

Question 19

Suggest some issues associated with gene therapy

Answer 19

• effect is short lived as modified cells have a limited lifespan => requires regular treatment
• immune response against genetically modified cells or viruses due to recognition of antigens
•Long term effect not known - side effects e.g could cause cancer
- DNA may be inserted into other genes , disrupting them => interfering with gene expression

Question 20

Suggest why humanitarians might support recombinant DNA technology

Answer 20

• GM crops increase yields => increased global food production => reduced risk of famine / malnutrition
• Gene therapy has a potential to cure many genetic disorders
• Pharming makes medicines available to more ppl as medicines are cheaper

Question 21

Suggest why environmentalists and antiglobalisation activists might oppose recombinant DNA technology

Answer 21

• recombinant DNA may be transferred to other plants => potential herbicide resistant
• potential effects on food webs reduce biodiversity
• large biotech companies may control the technology and own patents