chapter 13 human heredity by michael cummings ©2006 brooks/cole-thomson learning chapter 13 an...
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Chapter 13 Human Heredity by Michael Cummings ©2006 Brooks/Cole-Thomson Learning
Chapter 13An Introduction to Cloning and
Recombinant DNA
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Chapter 13 Human Heredity by Michael Cummings ©2006 Brooks/Cole-Thomson Learning
Clones
• Genetically identical organisms or molecules derived from a common ancestor
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Chapter 13 Human Heredity by Michael Cummings ©2006 Brooks/Cole-Thomson Learning
Cloning Plants from Single Cells
Fig. 13.1
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Chapter 13 Human Heredity by Michael Cummings ©2006 Brooks/Cole-Thomson Learning
Cloning Animals
• Animals were cloned more than 20 years ago
• Two techniques– Embryo splitting– Nuclear transfer
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Chapter 13 Human Heredity by Michael Cummings ©2006 Brooks/Cole-Thomson Learning
library.thinkquest.org
animalscience.ucdavis.edu
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Chapter 13 Human Heredity by Michael Cummings ©2006 Brooks/Cole-Thomson Learning
Embryo Splitting• Egg collected• Fertilized by in vitro fertilization (IVF)• Embryo is grown to 8–16 cells• Cells are separated• Separated cells grown into separate
embryos • Embryos transplanted into surrogate
mothers• May be used to clone any mammalian
embryos, including humans
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Chapter 13 Human Heredity by Michael Cummings ©2006 Brooks/Cole-Thomson Learning
www.biotechnologyonline.gov.au
Cloning by nuclear transfer
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Chapter 13 Human Heredity by Michael Cummings ©2006 Brooks/Cole-Thomson Learning
www.pnas.org
Cloning by nuclear transfer
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Chapter 13 Human Heredity by Michael Cummings ©2006 Brooks/Cole-Thomson Learning
Nuclear Transfer
• First done in 1986• More difficult• Nucleus is removed from an egg• Enucleated eggs are fused with other
cells• Embryos are transplanted into a
surrogate mother• In 1997, Dolly the sheep was the first
mammalian clone from an adult donor cell
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Chapter 13 Human Heredity by Michael Cummings ©2006 Brooks/Cole-Thomson Learning
Cloned animals
Second addition
Second chance
at Texas A&M
Also cloned animals about to go extinct - gaur etc
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Chapter 13 Human Heredity by Michael Cummings ©2006 Brooks/Cole-Thomson Learning
Cloning Mice by Injection of Nuclei from Adult Cells
Fig. 13.5
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Chapter 13 Human Heredity by Michael Cummings ©2006 Brooks/Cole-Thomson Learning
Problems -
don’t live as long
not carbon copies/identical
develop diseases early
very low success rate - 0.1 - 3%
Dedifferentiation/reprogramming may not be completeor accurate
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Chapter 13 Human Heredity by Michael Cummings ©2006 Brooks/Cole-Thomson Learning
Gene Cloning
All identical to starting gene - CLONES
Gene
Host
Cloning vector Recombinant DNA
Started with: few copies
GOAL: To get enough copies of the gene to manipulate
Multiply
Ended with: Many copies.
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Chapter 13 Human Heredity by Michael Cummings ©2006 Brooks/Cole-Thomson Learning
Restriction enzymes
Nobel Prize
Werner Arber, Daniel Nathans and Hamilton O. Smith
1978
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Chapter 13 Human Heredity by Michael Cummings ©2006 Brooks/Cole-Thomson Learning
Restriction Enzymes
Fig. 13.6
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Chapter 13 Human Heredity by Michael Cummings ©2006 Brooks/Cole-Thomson Learning
G
CCTAG
GATCC
G
GATCC
G
G
CCTAG
Inserting foreign DNA using restriction enzymes
GATCC
G
G
CCTAG
BamHI BamHI
Ligase
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Chapter 13 Human Heredity by Michael Cummings ©2006 Brooks/Cole-Thomson Learning
Frequency of occurrence of restriction sites
If DNA sequence has equal amounts of each base
If bases are distributed randomly
6 base cutter (1/4)6 = 1 site in ~4000 bp
4 base cutter (1/4)4 = 1 site in 256 bp
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Chapter 13 Human Heredity by Michael Cummings ©2006 Brooks/Cole-Thomson Learning
Common Restriction Enzymes
Fig. 13.8
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Chapter 13 Human Heredity by Michael Cummings ©2006 Brooks/Cole-Thomson Learning Fig. 13.11a-d
Cloning DNA in Plasmid Vectors
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Chapter 13 Human Heredity by Michael Cummings ©2006 Brooks/Cole-Thomson Learning
Fig. 13.11e-g
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Chapter 13 Human Heredity by Michael Cummings ©2006 Brooks/Cole-Thomson Learning
Plasmid Used to Carry DNA Fragments
= Vectors
Fig. 13.10
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Chapter 13 Human Heredity by Michael Cummings ©2006 Brooks/Cole-Thomson Learning Table 19.2
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Chapter 13 Human Heredity by Michael Cummings ©2006 Brooks/Cole-Thomson Learning
EcoRI EcoRI EcoRI EcoRI
4.0 kb 2.0 kb 3.0 kb
Problem: How to get the 2.0 kb piece to subclone into vector
Randomly Isolate specific fragmentShotgun cloning
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Chapter 13 Human Heredity by Michael Cummings ©2006 Brooks/Cole-Thomson Learning
Steps in cloning a single piece of DNA
1. Appropriate restriction sites
2. Cut vector and foreign DNA with RE
3. Run on gel to separate fragments
4. Isolate specific fragment
5. Ligate with cut vector
6. Transform host bacteria. Selection.
7. Grow up colonies.
8. Isolate plasmid DNA.
9. Cut with RE to confirm presence of foreign DNA.
10. Run on gel to identify recombinant plasmids.
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Chapter 13 Human Heredity by Michael Cummings ©2006 Brooks/Cole-Thomson Learning
Gel electrophoresis
-ve
+ve
Size separation
4.0 kb
3.0 kb
2.0 kb
5.0
3.5
2.8
2.4
1.5
2.1
Log
(kb
)
Distance migrated
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Chapter 13 Human Heredity by Michael Cummings ©2006 Brooks/Cole-Thomson Learning
Gel electrophoresis system or “gel box”
gel stained with ethidium bromide
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Chapter 13 Human Heredity by Michael Cummings ©2006 Brooks/Cole-Thomson Learning UV illumination of stained DNA fragments separated in an agarose gel by electrophoresis.
Credit: © Michael Gabridge/Visuals Unlimited 34173
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Chapter 13 Human Heredity by Michael Cummings ©2006 Brooks/Cole-Thomson Learning
Selecting Cells with Vectors Vectors carry antibiotic resistance genes
Growing antibiotic-sensitive cells on media with antibiotics ensures that all growing cells must carry the vector
Selecting Cells with Recombinant Vectors While inserting the donor DNA, an existing gene in the
vector is inactivated
OR
In addition to the Donor gene a marker gene is added
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Chapter 13 Human Heredity by Michael Cummings ©2006 Brooks/Cole-Thomson Learning
Original vector - 4 kb with one RE (EcoRI) site
DNA to be inserted - 2 kb, flanked by same RE
Cut plasmids isolated from colonies. Run gel
Vector alone (no insert) - 1 band 4 kb
How to tell that plasmid now contains insert
Vector + insert - 2 bands 4 kb AND 2 kb