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Document related concepts
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Transcript 
Recombinant DNA
Isolation / Digestion / Fractionation
Purification of the target fragment
Cloning into vectors / Ligation
Transformation of host cell / Selection
Replication / Analysis
Expression of DNA
Recombinant DNA
Recombination
Specifically cut and join DNA
Cut: digestion
Join: ligation
First steps for cloning
Non Specific DNA breakage
Mechanical shearing
Chemical
Non-specific enzyme
Exonuclease
Endonuclease
Restriction Endonuclease
Mg2+, ATP and SAM as cofactors
Specific recognition site on dsDNA
Move along 1-5 kb
Type I
Cut randomly on 1 strand
Require 2nd enzyme to cut another strand
Restriction Endonuclease
Intermediate properties between types I and II
Mg2+ and ATP as cofactors
Specific recognition site
Type III
Cut both strands
24-26 bp from a recognition site
Restriction Endonuclease
Mg2+
Type II
Specific recognition site
Specific cleavage site
within or near recognition site
Cut both strands
Fragments with defined length & sequence
Nomenclature
3 Letters (italic)
host genus in upper case
host species in lower case
strain or type (non italic)
restriction or modification system (Roman numeral)
Nomenclature
EcoRI - from Escherichia coli
BamHI - from Bacillus amyloliquefaciens
HindIII - from Haemophilus influenzae
PstI - from Providencia stuartii
Sau3AI - from Staphylococcus aureus
AvaI - from Anabaena variabilis
Target Site of REII
4-8 bases
Frequency of the cut
4-base cutter
8-base cutter
Rotational symmetry
palindrome
Target Site of REII
Palindrome
Restriction Enzyme
Break phosphodiester bond
Produce 5’P and 3’OH ends
Enzyme: homodimer
1 subunit cut 1 strand
away from the axis: overhang / sticky / protruding
at the axis: blunt end
5’ P and 3’ OH ends
5’ sticky end
3’ sticky end
blunt end
Source microorganism
Enzyme
Rec. Site
Ends
Arthrobacter luteus
Alu I
AGCT
Blunt
Bacillus amyloiquefaciens H
Bam HI
GGATCC
Sticky
Escherichia coli
Eco RI
GAATTC
Sticky
Haemophilus gallinarum
Hga I
GACGC(N)5
Sticky
Haemophilus infulenzae
Hind III
AAGCTT
Sticky
Providencia stuartii 164
Pst I
CTGCAG
Sticky
Nocardia otitiscaviaruns
Not I
GCGGCCGC
Sticky
Staphylococcus aureus 3A
Sau 3A
GATC
Sticky
Serratia marcesans
Sma I
CCCGGG
Blunt
Thermus aquaticus
Taq I
TCGA
Sticky
Restriction Enzyme
Sequence-specific tails
DNA with compatible ends: join
Different sources
Different enzymes
Restriction Enzyme
Different enzymes : Different recognition sites
Produce compatible ends: Get rDNA
Sau3AI 5’ NNN”GATCNNN 3’
BamHI
5’ NNNG”GATCCNNN 3’
Recombinant DNA
Sau3AI
5’ NNN GATCNNN 3’
3’ NNNCTAG
NNN 5’
BamHI
5’ NNNG GATCCNNN 3’
3’ NNNCCTAG GNNN 5’
rRNA
5’ NNN
GATCCNNN 3’
3’ NNNCTAG
GNNN 5’
5’ NNNGATCCNNN 3’
3’ NNNCTAGGNNN 5’
recut by Sau3AI / BamHI ?
Restriction Enzyme
Methylation
Modification of recognition site
Effect on cutting
BamHI
*GGATCm5C
*GGm6ATCC
**GGATCm4C **GGATm5CC
Restriction Enzyme
Isoschizomer
Different host
same recognition site
same or different cleavage site
Restriction Enzyme
Isoschizomer
XhoI / PaeR7I
5’ NNNC”TCGAGNNN 3’
SmaI 5’ NNNCCC”GGGNNN 3’
XmaI 5’ NNNC”CCGGGNNN 3’
Restriction Enzyme
Isoschizomer: methylation sensitivity
HpaI (X) and MspI (/)
Cm5CGG
SmaI (X) and XmaI (/)
CCm5CGGG
Restriction Enzyme
Applications
Basic tool for creating rDNA
Restriction Map
Restriction Map
Locations of recognition sites on DNA
Highly specific fragments
Digestion with 6-8 base cutter
Size fractionation on gel
Different patterns from different enzymes
Single and Double digests
Restriction Map
Restriction Map
Restriction Map
Ligation
To ligate by Ligase
E. coli ligase
NAD+ as cofactor
Sticky ends
T4-infected E. coli ligase
ATP as cofactor
Blunt or sticky ends
Ligation
Seal nicks on dsDNA
Form phosphodiester bond
Require 5’ P and 3’ OH
Ligation
Ligation
Example???
Ligation
Intramolecular ligation
(re)circularization
Ligation
For recombinant DNA
increase DNA concentration
increase temperature (Ti)
dephosphorylation
Dephosphorylation
Other Enzymes
DNA polymerase
RNA / DNA dependent DNA polymerase
Other Enzymes
E. coli DNA polymerase
DNA dependent DNA polymerase
5’-->3’ polymerase
5’-->3’ exonuclease
3’-->5’ exonuclease
E. coli DNA Polymerase
E. coli DNA Polymerase
Klenow Fragment
DNA polymerase: Klenow fragment
5’-->3’ polymerase
no 5’-->3’ exonuclease
3’-->5’ exonuclease
Active on ds DNA
T4 polymerase
DNA polymerase: T4 polymerase
5’-->3’ polymerase
no 5’-->3’ exonuclease
3’-->5’ exonuclease
Active on ss DNA
Taq polymerase
DNA polymerase: Taq polymerase
thermostable
75-80 C
PCR reaction
Reverse transcriptase
RNA dependent
DNA polymerase
Exonuclease III
Kinase
Phosphatase
Vector
Cloning vehicle
Carry / Multiply specific DNA fragments
Cloning site
multiple cloning region / polylinker
Origin of replication (ori)
Selectable marker
Plasmid vector
Bacterial minichromosome (2-20 kb)
not linked to main chromosome
Autonomous replication (replicon)
Mostly ds circular form
Some with linear form (actinomycete / spirochete)
Take up 100 bp – 10 kb
Plasmid vector
Carry antibiotic-resistance genes
providing selectable phenotype to host
Other selectable markers
sugar fermentation
heavy metal resistance
hydrogen sulfide production
enterotoxin production
Plasmid vector
Insertional inactivation
when MCR in selectable-marker gene
High copy number plasmid
replicate 10-200 copies per bacterial cycle
Low copy number plasmid
one or a few copies
Plasmid vector
Ideal properties
Low molecular weight
easy to handle, separate & purify
High copy number
Unique restriction sites
Disabled: no survival outside lab
Plasmid vector
Plasmid cloning
Bacteriophage vector
Bacterial virus: forming plaque
Linear or Circular shape
Cohesive ends (cos, short ss 5’ protruding)
Lytic / Lysogenic cycle
Phage cycle
Bacteriophage vector
Central section of phage DNA
For integration into host chromosome
Not necessary for replication
Replaced by foreign insert
Left and Right arms: easily isolated
Essential for replication and packaging
Bacteriophage vector
Bacteriophage vector
Require certain size for maturation
and packaging
Engineered to be safe and
have MCR
Available for big DNA insert
Phage packaging
Phage cloning
Plaque lift / Hybridization
Cosmid
Plasmid / Phage hybrid
plasmid: ori and selectable marker
phage: cos site for packaging
For large insert (32-47 kb)
Cosmid
Cosmid cloning
Cosmid cloning
Yeast Artificial Chromosome
Big inserts: hundreds of kb
Cloning elements
Yeast sequences
Selectable markers
MCR
Yeast Artificial Chromosome
YAC cloning
Expression vector
Available for screening of gene product
of cDNA insert
MCR within transcription regions
between promoter and terminator
Bidirectional cloning for correct orientation
Foreign or Fusion proteins
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