4.4 Biotechnological Tools and Techniques Recombinant DNA & Gel electrophoresis.
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Transcript of 4.4 Biotechnological Tools and Techniques Recombinant DNA & Gel electrophoresis.
4.4 Biotechnological Tools and 4.4 Biotechnological Tools and TechniquesTechniques
Recombinant DNA & Gel electrophoresis
Recombinant DNARecombinant DNA
Cutting DNA fragments from different sources and recombining them together
4.4.7: State that, when genes are transferred between species, the amino acid sequence of polypeptides translated from them is unchanged because the genetic code is universal. [Obj. 1]
Purpose–To investigate genetic disorders–Production of drugs (ie. insulin)
Cutting DNA fragments from different sources and recombining them together
What complications do you What complications do you foresee?foresee?
Consider:– The size of DNA– Where to cut?– How to put back together?
4.4.8: Outline a basic technique used for gene transfer involving plasmids a host cell (bacterium, yeast or other cell), restriction enzymes (endonucleases) and DNA ligase. [Obj. 2]
1. Restriction Endonucleases1. Restriction Endonucleases
Also known as restriction enzymes Essentially are molecular scissors Recognize a specific DNA sequence and cuts the
strands at a particular position or “recognition site” Isolated and purified only from bacteria
– Name reflects which bacteria the enzyme originates– ie. EcoRI Escherichia coli, strain R, 1st r.e. isolated
HindII Haemophilus influenzae, strain Rd, 2nd r.e.
1. Restriction Endonucleases: 1. Restriction Endonucleases: Recognition siteRecognition site
Each restriction endonuclease recognizes its own specific recognition site (specific DNA sequence)
Usually 4-8 base pairs long, characterized by a complementary palindromic sequence
Bacteria Restriction Enzyme
Recognition Site
Escherichia coli EcoRI 5’-GAATTC-3’
3’-CTTAAG-5’
Haemophilus parainfluenzae
HindIII 5’-AAGCTT-3’3’-TTCGAA-5’
Arthrobacter luteus
AluI 5’-AGCT-3’3’-TCGA-5’
1. Restriction Endonucleases: 1. Restriction Endonucleases: FunctionFunction
Scans DNA and binds to its specific recognition sequence
Disrupts the phosphodiester bonds between particular nucleotides through a hydrolysis reaction
Hydrogen bonds of the complementary base pairs in between the cuts are disrupted
Result: 2 DNA fragments
http://www.scq.ubc.ca/?p=249
1. Restriction Endonucleases: 1. Restriction Endonucleases: DNA Fragment EndsDNA Fragment Ends
Different DNA fragment ends are produced after digestion by different restriction enzymes– Sticky ends: DNA fragment ends with short single-
stranded overhangs (ie. EcoRI, HindIII)– Blunt ends: DNA fragment ends are fully base paired
(ie. AluI)
Bacteria Restriction enzyme
Recognition site After digestion by restriction enzyme
Escherichia coli EcoRI 5’-GAATTC-3’
3’-CTTAAG-5’
5’-G AATTC-3’
3’-CTTAA G-5’
Haemophilus parainfluenzae
HindIII 5’-AAGCTT-3’3’-TTCGAA-5’
5’-A AGCTT-3’3’-TTCGA A-5’
Arthrobacter luteus
AluI 5’-AGCT-3’3’-TCGA-5’
5’-AG CT-3’3’-TC GA-5’
1. Restriction Endonucleases: 1. Restriction Endonucleases: DNA Fragment Ends DNA Fragment Ends (continued)(continued)
Palindrome
Restriction site
Fragment 1 Fragment 2
http://www.bio-rad.com/LifeScience/docs/Official_Crime_Scene_PowerPoint_Spring_2005_rev_B.ppt
Animation
http://highered.mcgraw-hill.com/olc/dl/120078/bio37.swf
How do we control the snips?How do we control the snips?
Consider:– What about the organisms own DNA?– Frequency of recognition sequences within the
DNA sequence
1. Restriction Endonucleases: 1. Restriction Endonucleases: Length of recognition sitesLength of recognition sites
Longer recognition sites result in lower frequency of cuts
– EcoRI 5’-GAATTC-3’ = ¼ × ¼ × ¼ × ¼ × ¼ × ¼ = 1/4096– AluI 5’-AGCT-3’ = ¼ × ¼ × ¼ ×¼ = 1/256
Higher frequency of cuts – may cut gene into several fragments
Lower frequency of cuts – may produce large fragments than desired
http://highered.mcgraw-hill.com/olcweb/cgi/pluginpop.cgi?it=swf::535::535::/sites/dl/free/0072437316/120078/bio38.swf::Early Genetic Engineering Experiment
1. Restriction Endonucleases: 1. Restriction Endonucleases: MethylasesMethylases
Enzymes that add a methyl group to a nucleotide in a recognition site to prevent restriction endonuclease from cutting DNA
Distinguishing between foreign (viral) DNA and bacteria’s own DNA
1. Restriction Endonucleases: 1. Restriction Endonucleases: DNA LigaseDNA Ligase
Enzyme that rejoins cut strands of DNA together by reforming a phosphodiester bond
DNA ligase joins sticky endsT4 DNA ligase (from T4 bacteriophage)
joins blunt ends
How do we sort out the DNAHow do we sort out the DNA
DNA is chopped into many pieces
How to differentiate one piece from other
2. Gel Electrophoresis2. Gel ElectrophoresisTechnique used to separate charged
molecules based on their size4.4.3: State that gel electrophoresis of DNA
is used in DNA profiling [Obj. 1]
Acts like a molecular sieve
http://www.biotech.iastate.edu/ppt_presentations/html/Fingerprinting/StudentInstruction-gel/images/image08.jpg
http://www.solve.csiro.au/1105/img/sieve-bloke.jpg
DNA ProfilingDNA Profiling 4.4.4: Describe the application of
DNA profiling to determine paternity and also in forensic investigations. [Obj. 2]
A process of using DNA fragments to identify a person, or other organism. The DNA fragments have distinct bands separated by spaces and these band patterns are so distinct that they can be used like fingerprints.
2. Gel Electrophoresis: 2. Gel Electrophoresis: DNA PreparationDNA Preparation
Restriction enzymes digest DNA into smaller fragments of different lengths
Different DNA samples are loaded into wells of the gel (agarose or polyacrylamide)
http://www.oceanexplorer.noaa.gov/explorations/03bio/background/molecular/media/gel_plate_600.jpg
2. Gel Electrophoresis: 2. Gel Electrophoresis: Attraction MigrationAttraction Migration
Negatively charged electrode at the end where wells are located
Positively charged electrode at opposite endNegatively charged DNA migrate towards
positive end due to attraction
2. Gel Electrophoresis: 2. Gel Electrophoresis: Rate of MigrationRate of Migration
4.4.2: State that, in gel electrophoresis, fragments of DNA move in an electric field and are separated according to their size. [Obj. 1]
Shorter/smaller DNA fragments migrate through gel faster since they can move through the pores in the gel more easily
Longer/larger DNA fragments migrate through gel slower
Rate of migration = 1/log(size)
Different DNA fragment lengths are separated
http://www.answers.com/topic/agarosegel-jpg
A = kilobase DNA ladder
B = uncut plasmid DNA
C = single digestion of the plasmid with EcoRI
D = single digestion with XhoI
E = double digestion - both EcoRI and XhoI.
A B C D E
2. 2. Gel ElectrophoresisGel Electrophoresis: : Visualizing DNA FragmentsVisualizing DNA Fragments
Ethidium bromide is a fluorescent dye that makes DNA fragments visible by staining the gel
DNA fragments can then be isolated and purified
http://www.answers.com/topic/agarosegel-jpg
4.4.5: Analyse DNA profiles to draw conclusions about paternity or forensic investigations. [Obj. 3]
AnimationsAnimations
http://www.sumanasinc.com/webcontent/animations/content/gelelectrophoresis.html
http://learn.genetics.utah.edu/content/labs/gel/
http://www.dnalc.org/resources/animations/gelelectrophoresis.html
2. Gel Electrophoresis: 2. Gel Electrophoresis: Proteins too!Proteins too!
Gel electrophoresis can also be used to separate proteins, usually using polyacrylamide gels
http://www.biotechlearn.org.nz/var/biotech/storage/images/multimedia/images/protein_electrophoresis/48251-4-eng-GB/protein_electrophoresis_medium.jpg
http://www.bio-link.org/vlab/Graphics/Tools/ProteinGel2.jpg
3. Plasmids3. Plasmids
Small, circular double-stranded DNA that can enter and exit bacterial cells
Lack a protein coatIndependent of bacterial chromosome1000-200,000 base pairs
3. Plasmids: 3. Plasmids: EndosymbiosisEndosymbiosis
Use host bacterial enzymes and ribosomes to replicate and express plasmid DNA
Carry genes that express proteins to protect bacteria against antibiotics and heavy metals
3. Plasmids3. Plasmids Foreign genes (ie. insulin) can be inserted into plasmids,
so bacteria can express gene and make its respective protein
Higher copy number of plasmids (number of individual plasmids) in bacteria– results in larger number of gene copies, thus more of its
respective protein is synthesized
3. Plasmids3. Plasmids Restriction
endonucleases splice foreign genes into plasmids
DNA ligase reforms phosphodiester bond between the fragments, resulting in recombinant DNA
http://www.accessexcellence.org/RC/VL/GG/inserting.html
http://www.learner.org/courses/biology/archive/animations/hires/a_gmo1_h.html
4. Transformation4. TransformationIntroduction of foreign DNA (usually a
plasmid) into a bacterium
Plasmids can be used as a vector (vehicle that DNA can be introduced to host cells) to carry a specific gene into a host cell
http://www.bio.davidson.edu/Courses/Molbio/MolStudents/spring2003/Siegenthaler/fig2.gif
4. Transformation: 4. Transformation: CompetenceCompetence Competent cell - Bacterium that readily takes up foreign
DNA (ie. able to undergo transformation) Most cells are not naturally competent, but can be
chemically induced to become competent
–Calcium ion in calcium chloride stabilizes negatively charged phosphates on bacterial membrane
4.4.9: State two examples of the current uses 4.4.9: State two examples of the current uses of genetically modified crops or animals. [Obj. 1]of genetically modified crops or animals. [Obj. 1]
The transfer of a gene for factor IX which is a blood clotting factor, from humans to sheep so that this factor is produced in the sheep’s milk.
The transfer of a gene that gives resistance to the herbicide glyphosate from bacterium to crops so that the crop plants can be sprayed with the herbicide and not be affected by it.
Issues Surrounding Genetically Modified (GM) Products
by Subhuti Dharmananda, Ph.D., Director, Institute for Traditional
Medicine, Portland, Oregon
4.4.10: Discuss the potential benefits and 4.4.10: Discuss the potential benefits and possible harmful effects of one example of possible harmful effects of one example of
genetic modification. [Obj. 3]genetic modification. [Obj. 3]Benefits Crops Enhanced taste and quality, Reduced maturation time, Increased nutrients, yields, and stress
tolerance, Improved resistance to disease, pests, and herbicides, New products and growing techniques
Animals Better yields of meat, eggs, and milk Improved animal health and diagnostic methods Increased resistance, productivity, hardiness, and feed efficiency
Environment "Friendly" bioherbicides and bioinsecticides Conservation of soil, water, and energy Bioprocessing for forestry products Better natural waste management More efficient processing
Society Increased food security for growing populations
Controversies Controversies Safety Potential human health impact: allergens, transfer of antibiotic resistance, unknown effects. Potential environmental impact: unintended transfer of transgenes through cross-pollination,
unknown effects on other organisms (e.g., soil microbes), and loss of flora and fauna biodiversity Access and Intellectual Property Domination of world food production by a few companies Increasing dependence on industrialized nations by developing countries Biopiracy-foreign exploitation of natural resources Ethics Violation of natural organisms' intrinsic values Tampering with nature by mixing genes among species Objections to consuming animal genes in plants and vice versa Stress for animalsLabeling Not mandatory in some countries (e.g., United States) Mixing GM crops with non-GM confounds labeling attempts Society New advances may be skewed to interests of rich countries
Dharmananda, S. Issues Surrounding Genetically Modified (GM) Products. Online: http://www.google.ca/imgres?imgurl=http://www.itmonline.org/image/gmo1b.jpg&imgrefurl=http://www.itmonline.org/arts/gmo.htm&usg=__y5yFCjq561X8N0vAy5g8nid85NM=&h=453&w=400&sz=32&hl=en&start=5&zoom=1&tbnid=Kqfgq2YL9RdYEM:&tbnh=127&tbnw=112&ei=k9TfTpasGsfL0QG8hdCuBw&prev=/search%3Fq%3Dgmo%26um%3D1%26hl%3Den%26safe%3Dactive%26sa%3DN%26gbv%3D2%26tbm%3Disch&um=1&itbs=1