1. Recombinant DNA Technology
Chapter 8
Recombinant DNA Technology

2. The Role of Recombinant DNA Technology in Biotechnology
Intentional modification of organisms’ genomes for practical purposes
Three goals
Eliminate undesirable phenotypic traits
Combine beneficial traits of two or more organisms
Create organisms that synthesize products humans need
© 2012 Pearson Education Inc. 2

3. Figure 8.1 Overview of recombinant DNA technology
Bacterial cell
DNA containing gene of interest
Bacterial chromosome
Plasmid
Isolate plasmid.
Gene of interest
Enzymatically cleave DNA into fragments.
Isolate fragment with the gene of interest.
Insert gene into plasmid.
Insert plasmid and gene into bacterium.
Culture bacteria.
Harvest copies of gene to insert into plants or animals
Harvest proteins coded by gene
Eliminate undesirable phenotypic traits
Create beneficial combination of traits
Produce vaccines, antibiotics, hormones, or enzymes

4. The Tools of Recombinant DNA Technology
Mutagens
Physical and chemical agents that produce mutations
Scientists utilize mutagens to
Create changes in microbes’ genomes to change phenotypes
Select for and culture cells with beneficial characteristics
Mutated genes alone can be isolated
© 2012 Pearson Education Inc. 4

5. The Tools of Recombinant DNA Technology
The Use of Reverse Transcriptase to Synthesize cDNA
Isolated from retroviruses
Uses RNA template to transcribe molecule of cDNA
Easier to isolate mRNA molecule for desired protein first
mRNA of eukaryotes has introns removed
Allows cloning in prokaryotic cells
© 2012 Pearson Education Inc. 5

6. The Tools of Recombinant DNA Technology
Synthetic Nucleic Acids
Molecules of DNA and RNA produced in cell-free solutions
Uses of synthetic nucleic acids
Elucidating the genetic code
Creating genes for specific proteins
Synthesizing DNA and RNA probes to locate specific sequences of nucleotides
Synthesizing antisense nucleic acid molecules
© 2012 Pearson Education Inc. 6

7. The Tools of Recombinant DNA Technology
Restriction Enzymes
Bacterial enzymes that cut DNA molecules only at restriction sites
Categorized into two groups based on type of cut
Cuts with sticky ends
Cuts with blunt ends
© 2012 Pearson Education Inc. 7

8. Figure 8.2 Actions of restriction enzymes-overview

9. The Tools of Recombinant DNA Technology
ANIMATION Recombinant DNA Technology
© 2012 Pearson Education Inc. 9

10. The Tools of Recombinant DNA Technology
Vectors
Nucleic acid molecules that deliver a gene into a cell
Useful properties
Small enough to manipulate in a lab
Survive inside cells
Contain recognizable genetic marker
Ensure genetic expression of gene
Include viral genomes, transposons, and plasmids
© 2012 Pearson Education Inc. 10

11. Figure 8.3 Producing a recombinant vector
mRNA for human growth hormone (HGH)
Antibiotic resistance gene
Restriction site
Reverse transcription
cDNA for HGH
Plasmid (vector)
Restriction enzyme
Restriction enzyme
Sticky ends
Gene for human growth hormone
Ligase
Recombinant plasmid
Introduce recombinant plasmid into bacteria.
Bacterial chromosome
Recombinant plasmid
Inoculate bacteria on media containing antibiotic.
Bacteria containing the plasmid with HGH gene survive because they also have resistance gene.

12. The Tools of Recombinant DNA Technology
Gene Libraries
A collection of bacterial or phage clones
Each clone in library often contains one gene of an organism’s genome
Library may contain all genes of a single chromosome
Library may contain set of cDNA complementary to mRNA
© 2012 Pearson Education Inc. 12

13. Figure 8.4 Production of a gene library-overview
Genome
Isolate genome or organism.
Generate fragments using restriction enzymes.
Insert each fragment into a vector.
Introduce vectors into cells.
Culture recombinant cells; descendants are clones.

14. Techniques of Recombinant DNA Technology
Multiplying DNA in vitro: The Polymerase Chain Reaction (PCR)
Large number of identical molecules of DNA produced in vitro
Critical to amplify DNA in variety of situations
Epidemiologists use to amplify genome of unknown pathogen
Amplified DNA from Bacillus anthracis spores in 2001 to identify source of spores
© 2012 Pearson Education Inc. 14

15. Techniques of Recombinant DNA Technology
Multiplying DNA in vitro: The Polymerase Chain Reaction (PCR)
Repetitive process consisting of three steps
Denaturation
Priming
Extension
Can be automated using a thermocycler
© 2012 Pearson Education Inc. 15

16. Techniques of Recombinant DNA Technology
ANIMATION Polymerase Chain Reaction: Overview
© 2012 Pearson Education Inc. 16

17. Techniques of Recombinant DNA Technology
ANIMATION Polymerase Chain Reaction: Components
© 2012 Pearson Education Inc. 17

18. Figure 8.5a The use of PCR to replicate DNA, steps 1-3
Original DNA molecule 3´ 3´ 5´ 5´
Heat to 94°C
Denaturation
DNA primer
Deoxyribonucleotide triphosphates
Priming
DNA polymerase
Cool to 65°C
DNA polymerase 3´ 5´ 5´
Extension
DNA primer 5´ 5´ 3´
72°C

19. Figure 8.5b The use of PCR to replicate DNA, step 4
First cycle
Second cycle
Third cycle
Fourth cycle
2 DNA molecules
4 DNA molecules
8 DNA molecules
Repeat
16 DNA molecules

20. Techniques of Recombinant DNA Technology
ANIMATION PCR: The Process
© 2012 Pearson Education Inc. 20

21. Techniques of Recombinant DNA Technology
Selecting a Clone of Recombinant Cells
Must find clone containing DNA of interest
Probes are used
© 2012 Pearson Education Inc. 21

22. Techniques of Recombinant DNA Technology
Separating DNA Molecules: Gel Electrophoresis and the Southern Blot
Gel electrophoresis
Separates molecules based on electrical charge, size, and shape
Allows scientists to isolate DNA of interest
Negatively charged DNA drawn toward positive electrode
Agarose makes up gel; acts as molecular sieve
Smaller fragments migrate faster than larger ones
Determine size by comparing distance migrated to standards
© 2012 Pearson Education Inc. 22

23. Figure 8.6 Gel electrophoresis-overview

24. Techniques of Recombinant DNA Technology
Separating DNA Molecules: Gel Electrophoresis and the Southern Blot
Southern blot
DNA transferred from gel to nitrocellulose membrane
Probes used to localize DNA sequence of interest
Northern blot: used to detect RNA
Uses of Southern blots
Genetic “fingerprinting”
Diagnosis of infectious disease
Demonstrate incidence and prevalence of organisms that cannot be cultured
© 2012 Pearson Education Inc. 24

25. Figure 8.7 The Southern blot technique-overview
DNA molecules
Restriction enzymes
Restriction fragments
Use gel electrophoresis to separate fragments by size; denature DNA into single strands with NaOH.
DNA
DNA bands
Gel
The DNA fragments are invisible to the investigators at this stage.
Nitrocellulose membrane
Absorbent material
Side view
Electrophoresis gel
Nitrocellulose membrane
Absorbent material
Nitrocellulose membrane with DNA fragments at same locations as in gel (still invisible) is baked to permanently affix DNA.
Add radioactive probes complementary to DNA nucleotide sequence of interest.
Probes bind to DNA of interest.
Incubate with film; radiation exposes film. Develop film.
Developed film

26. Techniques of Recombinant DNA Technology
DNA Microarrays
Consist of molecules of immobilized single-stranded DNA
Fluorescently labeled DNA washed over array will adhere only at locations where there are complementary DNA sequences
Variety of scientific uses of DNA microarrays
Monitoring of gene expression
Diagnosis of infection
Identification of organisms in an environmental sample
© 2012 Pearson Education Inc. 26

27. Figure 8.8 DNA microarray-overview

28. Techniques of Recombinant DNA Technology
Inserting DNA into Cells
Goal of DNA technology is insertion of DNA into cell
Natural methods
Transformation
Transduction
Conjugation
Artificial methods
Electroporation
Protoplast fusion
Injection: gene gun and microinjection
© 2012 Pearson Education Inc. 28

29. Figure 8.9a Artificial methods of inserting DNA into cells: electroporation
Pores in wall and membrane
Chromosome
Cell synthesizes new wall
Electrical field applied
Competent cell
Recombinant cell
DNA from another source
Electroporation

30. Figure 8.9b Artificial methods of inserting DNA into cells: protoplast fusion
Cell walls
Cell synthesizes new wall
Enzymes remove cell walls
Polyethylene glycol
Recombinant cell
New wall
Protoplasts
Fused protoplasts
Protoplast fusion

31. Figure 8.9c Artificial methods of inserting DNA into cells: gene gun
Blank .22 caliber shell
Nylon projectile
Vent
Plate to stop nylon projectile
DNA-coated beads
Target cell
Protoplasts
Nylon projectile
Gene gun

32. Figure 8.9d Artificial methods of inserting DNA into cells: microinjection
Micropipette containing DNA
Target cell’s nucleus
Target cell
Suction tube to hold target cell in place
Microinjection

33. Applications of Recombinant DNA Technology
Genetic Mapping
Locating genes on a nucleic acid molecule
Provides useful facts concerning metabolism, growth characteristics, and relatedness to others
Locating Genes
Until 1970, genes identified by labor-intensive methods
Simpler and universal methods now available
Restriction fragmentation
Fluorescent in situ hybridization (FISH)
© 2012 Pearson Education Inc. 33

34. Figure FISH

35. Figure 8.11 Automated DNA sequencing
Nucleotide bases: A T G C
Signal intensity
100
200
Number of bases

36. Applications of Recombinant DNA Technology
Environmental Studies
Most microorganisms have never been grown in a laboratory
Scientists know them only by their DNA fingerprints
Allowed identification of over 500 species of bacteria from human mouths
Determined that methane-producing archaea are a problem in rice agriculture
© 2012 Pearson Education Inc. 36

37. Applications of Recombinant DNA Technology
Pharmaceutical and Therapeutic Applications
Protein synthesis
Creation of synthetic peptides for cloning
Vaccines
Production of safer vaccines
Subunit vaccines
Genes of pathogens introduced into common fruits and vegetables
Injecting humans with plasmid carrying gene from pathogen
Humans synthesize pathogen’s proteins
© 2012 Pearson Education Inc. 37

38. Applications of Recombinant DNA Technology
Pharmaceutical and Therapeutic Applications
Genetic screening
DNA microarrays used to screen individuals for inherited disease caused by mutations
Can also identify pathogen’s DNA in blood or tissues
DNA fingerprinting
Identifying individuals or organisms by their unique DNA sequence
© 2012 Pearson Education Inc. 38

39. Figure 8.12 DNA fingerprinting

40. Applications of Recombinant DNA Technology
Pharmaceutical and Therapeutic Applications
Gene therapy
Missing or defective genes replaced with normal copies
Some patients’ immune systems react negatively
Medical diagnosis
Patient specimens can be examined for presence of gene sequences unique to certain pathogens
Xenotransplants
Animal cells, tissues, or organs introduced into human body
© 2012 Pearson Education Inc. 40

41. Applications of Recombinant DNA Technology
Agricultural Applications
Production of transgenic organisms
Recombinant plants and animals altered by addition of genes from other organisms
© 2012 Pearson Education Inc. 41

42. Applications of Recombinant DNA Technology
Agricultural Applications
Herbicide tolerance
Gene from Salmonella conveys resistance to glyphosate (Roundup™)
Farmers can kill weeds without killing crops
Salt tolerance
Scientists have inserted gene for salt tolerance into tomato and canola plants
Transgenic plants survive, produce fruit, and remove salt from soil
© 2012 Pearson Education Inc. 42

43. Applications of Recombinant DNA Technology
Agricultural Applications
Freeze resistance
Crops sprayed with genetically modified bacteria can tolerate mild freezes
Pest resistance
Bt toxin
Naturally occurring toxin harmful only to insects
Organic farmers used to reduce insect damage to crops
Gene for Bt toxin inserted into various crop plants
Genes for Phytophthora resistance inserted into potato crops
© 2012 Pearson Education Inc. 43

44. Applications of Recombinant DNA Technology
Agricultural Applications
Improvements in nutritional value and yield
Tomatoes allowed to ripen on vine and shelf life increased
Gene for enzyme that breaks down pectin suppressed
BGH allows cattle to gain weight more rapidly
Produce meat with lower fat content and produce 10% more milk
Gene for β-carotene (vitamin A precursor) inserted into rice
Scientists considering transplanting genes coding for entire metabolic pathways
© 2012 Pearson Education Inc. 44

45. The Ethics and Safety of Recombinant DNA Technology
Supremacist view: humans are of greater value than animals
Long-term effects of transgenic manipulations are unknown
Unforeseen problems arise from every new technology and procedure
Natural genetic transfer could deliver genes from transgenic plants and animals into other organisms
Transgenic organisms could trigger allergies or cause harmless organisms to become pathogenic
© 2012 Pearson Education Inc. 45

46. The Ethics and Safety of Recombinant DNA Technology
Studies have not shown any risks to human health or environment
Standards imposed on labs involved in recombinant DNA technology
Can create biological weapons using same technology
© 2012 Pearson Education Inc. 46

47. The Ethics and Safety of Recombinant DNA Technology
Ethical Issues
Routine screenings?
Who should pay?
Genetic privacy rights?
Profits from genetically altered organisms?
Required genetic screening?
Forced correction of “genetic abnormalities”?
© 2012 Pearson Education Inc. 47