1. DNA Technologies (Introduction)
Cloning
PCR
Gel Electrophoresis
DNA Sequencing
DNA fingerprinting
GMO : Genetically Modified Organism ……

2. Biotechnology Biotechnology
Any technique applied to biological systems to manipulate processes
DNA technologies isolate purify, analyze and manipulate DNA sequences
DNA fingerprinting used in forensics
Genetic engineering uses DNA technologies to alter genes for practical purposes

3. DNA Cloning
Bacterial enzymes (restriction endonucleases) form the basis of DNA cloning
Bacterial plasmids illustrate the use of restriction enzymes in cloning
DNA libraries contain collections of cloned DNA fragments
Polymerase chain reaction (PCR) amplifies DNA in vitro

4. Recombinant DNA DNA cloning provides many copies of a gene
Used for research or manipulation
Recombinant DNA contains DNA from multiple sources joined together
Recombinant plasmids containing gene of interest can be cloned in E. coli

5. Cloning DNA Fragments

6. interest from cells and cut the DNA into fragments.
Gene of interest
Plasmid from
bacterium
Cell 1
Cut a circular
bacterial plasmid
to make it linear. 2
Isolate genomic
DNA containing gene of
interest from cells and cut
the DNA into fragments.
Figure 18.2
Overview of cloning DNA fragments in a bacterial plasmid.
Insert the genomic DNA fragments into the plasmid to make recombinant
DNA molecules. Recombinant DNA is DNA from two different sources joined together. Here, the recombinant DNA molecules are the recombinant plasmids. 3

7. Introduce recombinant molecules into bacterial cells; each bacterium
Inserted genomic
DNA fragment
Recombinant
DNA molecules
Introduce recombinant molecules
into bacterial cells; each bacterium
receives a different plasmid. As the
bacteria grow and divide, the
recombinant plasmids replicate,
thereby amplifying the piece of DNA
inserted into the plasmid. 4
Bacterium
Bacterial
chromosome
Progeny
bacteria
대부분의 경우는 원하는 gene이 없음.
Identify the bacterium containing
the plasmid with the gene of interest
inserted into it. Grow that bacterium
in culture to produce large amounts
of the plasmid for experiments with
the gene of interest. 5

8. Restriction Enzyme EcoRI Restriction site for EcoRI DNA1
EcoRI restriction enzyme cleaves sugar–phosphate
backbones at arrows.
Sticky end
Sticky end
DNA fragments with the same sticky ends can pair. Shown here is a DNA fragment inserting between two other DNA fragments, as happens when inserting a DNA fragment into a bacterial plasmid. 2
Another DNA fragment
produced by EcoRI digestion
제한효소와 ligase를 이용하여 recombination 완성  어느정도 control 되고 있음.
자를 때와 붙일 때 palindrom sequence가 유리...
Nick in sugar–phosphate backbone
Nicks in sugar–
phosphate backbones
are sealed by DNA ligase. 3
Recombinant DNA molecule

9. Endonucleases (Restriction Enzymes)
Restriction enzymes (endunucleases) cut DNA at specific sequences in restriction sites
Restriction fragments result
Sticky ends have unpaired bases at cuts which will hydrogen bond
Ligase stitches together paired sticky ends

10. Plasmid Cloning Gene of interest Restriction site lacZ+ gene Cell ampR
vector
DNA fragments with sticky ends
Cut plasmid cloning vectors with a restriction
enzyme to produce sticky ends
Stick end : 점착성 말단

11. Plasmid Cloning No transfection No recombination
Inserted DNA fragments with gene of interest
Inserted DNA fragment without gene of interest
Resealed plasmid cloning vector with no inserted DNA fragment
Recombinant plasmids
Nonrecombinant plasmid
빨간색
No transfection
No recombination

12. Untransformed bacterium containing ampicillin.
Plasmid Cloning
Bacteria not transformed
with a plasmid
Bacteria transformed with plasmids
Selection:
Transformed bacteria grow on medium containing ampicillin because of ampR gene on plasmid.
Untransformed bacterium
cannot grow on medium
containing ampicillin.
Screening:
Blue colony contains bacteria with a non-recombinant plasmid; that is, the lacZ+
gene is intact.
Plate containing
ampicillin and X-gal
그래도 확실하지 않다…  추가적인 실험이 필요함.
White colony contains bacteria with a recombinant plasmid; that is, the vector with an inserted DNA fragment. Once the white colony with the gene
of interest is identified, it can be grown in culture to produce large quantities of the plasmid.
lacZ(가수분해)
X-gal(white)
Blue

13. Plasmid Cloning Vectors
Engineered to contain gene of interest and sorting genes
Sorting genes identify E. coli with cloned plasmid
 E. coli with appropriate plasmid are
1. ampicillin resistant (transformation check by survival)
2. and blue-white screened on X-gal
(recombination check by color change)
 then, DNA hybridization (probe) finds the gene of interest

14. DNA Hybridization
Uses nucleic acid probe to identify gene of interest in set of clones
Probe has tag (표지) for detection
Identified colony produces large quantities of cloned gene
Tag: radioactive or fluroscent

15. DNA Hybridization

16. Single strand, 흡착 Bacterial Culture medium containing ampicillin
colony
Filter paper
Replica of bacterial
colonies
Filter paper
Single strand, 흡착

17. Labeled probe (single stranded) Plasmid DNA (single stranded) Bag
Labeled single-stranded DNA
probe for the
gene of interest
Bag
Filter
Hybridization has occurred between the labeled probe and the plasmids released from the bacteria in this colony. The hybridization is detected in subsequent steps.
DNA probe:

18. Corresponds to Developed one colony on photographic master plate film
Figure 18.5: Research Method.
DNA Hybridization to Identify a DNA Sequence of Interest
Original master plate

19. Polymerase Chain Reaction
Polymerase chain reaction (PCR)
Produces many sequence copies without host cloning
Amplifies known DNA sequences for analysis
Only copies sequence of interest
Primers bracket sequence
Agarose gel electrophoresis
Separates fragments by size and charge
Gel molecular sieve

20. Polymerase Chain Reaction
Cycle 1
Cycle 2
Cycle 3
2 molecules produced
Produces 4 molecules
Produces 8 molecules
Target
sequence
Template
DNA
primers
DNA containing
target sequence
to be amplified
DNA
primer
New DNA
These 2
molecules
match
target DNA
sequence
DNA
primer
New DNA
Target
sequence
Target
sequence
Template
In solution,
target sequence(2), DNA primer(2), free nucleotides, Taq DNA – polymerase

21. Agarose Gel Electrophoresis항상

22. DNA Sequencing Used for small DNA sequences to genomes
Dideoxy (Sanger) method of sequencing
Dideoxyribonucleotides have –H bound to 3’ C instead of –OH
DNA polymerases place dideoxyribonucleotides in DNA, stops replication
Polyacrylamide gel separates strands varying by one nucleotide

23. Dideoxy (Sanger) Method

24. Deoxyribonucleo-tide precursors Dideoxyribonucleotide (dd) precursors
DNA strand to
be sequenced
DNA
polymerase
DNA primer
dATP
ddATP
Deoxyribonucleo-tide precursors
Dideoxyribonucleotide
(dd) precursors
(fluorescently labeled)
Figure 18.18: Research Method.
Dideoxy (Sanger) Method for Sequencing DNA

25. DNA to be sequenced
Insertion of
dideoxyribonucleotide
stops synthesis
Primer bound
to template
New DNA synthesis
in 5' 3' direction
An electrophoretic gel
Dye-labeled fragments
of DNA migrating
through the gel
Detector registers
fluorescence from
DNA as laser
beam hits them
Laser
Laser beam
pass through gel
Visualization of the DNA sequence
Sequence obtained
from experiment

26. Whole-Genome Shotgun Sequencing
Genomic DNA
DNA fragments
Genomic DNA
fragment
and so on
Plasmid cloning
vector
DNA sequence of genomic DNA
fragment (actual sequence is
several hundred base pairs)
Assembled
sequence