Transcript Chapter 9 – DNA-Based Information Technologies • Recombinant DNA molecules are constructed with DNA from different sources • Recombinant DNA molecules are created often in.

Chapter 9 – DNA-Based Information
Technologies
• Recombinant DNA molecules are
constructed with DNA from different sources
• Recombinant DNA molecules are created
often in nature
• Used in the lab for many purposes
•One is to clone genes
DNA Cloning – making many copies of a
segment of DNA by attaching it to a
smaller, replicating piece of DNA
Five basic steps in cloning
experiment
1. Preparation of DNA to be cloned (target)
Needs to be cut from source.
2. Selection of vector – self-replicating piece of
DNA
3. Joining (Ligation) of target and vector DNA
fragments. (Use of enzymes)
Product is recombinant DNA
Five basic steps (cont)
4. Introduction of recombinant DNA into
compatible host cells and growth therein.
Genetic transformation is the uptake of foreign
DNA by a host cell
5. Selecting & Identifying of host cells that contain
recombinant DNA of interest. (screening)
Cutting of target and vector
DNA uses Nucleases
• Nucleases - hydrolyze phosphodiester bonds
RNases (RNA substrates)
DNases (DNA substrates)
• May cleave either the 3’- or the 5’- ester bond
of a 3’-5’ phosphodiester linkage
• Exonucleases start at the end of a chain
• Endonucleases hydrolyze sites within a chain
• Nuclease cleavage sites
• Cleavage at bond A
generates a 5’-phosphate
and a 3’ OH terminus
• Cleavage at bond B
generates a 3’-phosphate
and a 5’-hydroxyl terminus
Restriction Endonucleases
• Enzymes that recognize specific DNA sequences
• Cut both strands of DNA at the binding site,
producing fragments that can be degraded by
exonucleases
• Host cells protect their own DNA by covalent
modification of bases at the restriction site
(e.g. methylation)
Restriction endonuclease
properties
• Type I - catalyze both the methylation of host
DNA and cleavage of unmethylated DNA at a
specific recognition sequence
• Type II - cleave double-stranded DNA only, at or
near an unmethylated recognition sequence
• More than 200 type I and type II are known
• Most recognize “palindromic sequences” (read
the same in either direction)
Nucleases leave either:
sticky ends- staggered cut leaves an
overhang of ssDNA on each strand
blunt ends – cut directly across both
strands leaving all dsDNA
Cutting with EcoRI
Cloning Vectors
• Cloning vectors can be: plasmids, bacteriophages,
viruses, small artificial chromosomes
• Vectors have at least one unique cloning site: a
sequence cut by a restriction endonuclease to allow
site-specific insertion of foreign DNA
• Restriction enzymes
can generate
recombinant DNA
Plasmid Vectors
• Plasmids are small, circular DNA molecules
used as vectors for DNA fragments to 20kb
• Replicate autonomously within a host cell
• Carry genes conferring antibiotic resistance,
used as marker genes for cells carrying vectors
• pBR322 was one of the first plasmid vectors
Plasmid vector pBR322
• pBR322 has 4361
base pairs
• Origin of replication
(ori)
• Antibiotic resistance
genes amp and tet
• Rop gene regulates
replication for ~20
copies of the
plasmid per cell
B. Bacteriophage l Vectors
• Efficient, commonly used vector for delivering
DNA into a bacterial cell
• Advantage over plasmid vectors is that
transfection is more efficient than
transformation
• Disadvantage: DNA must be packaged into
phage particles in vitro
C. Yeast Artificial Chromosomes
as Vectors
• Large DNA fragments can be inserted
into artificial chromosomes that are
replicated in eukaryotic cells
• Such chromosomes must be linear and
contain a eukaryotic replication origin
• Yeast artificial chromosome (YAC)
Yeast artificial chromosome (YAC)
D. Bacterial Artificial
Chromosomes (BAC’s)
• Special Plasmids designed for cloning
large DNA fragments (100-300 kbp)
Identification of Host Cells
Containing Recombinant
DNA
• After a cloning vector and insert DNA have been
joined in vitro, recombinant DNA is introduced into
a host cell such as E. coli (transformation)
• Only a small percentage of cells take up the DNA
• Selection -cells are grown under conditions in
which only transformed cells survive
• Screening - transformed cells are tested for the
presence of the recombinant DNA
A. Selection Strategies Use Marker
Genes
• Bacterial plasmid vectors can carry a
b-lactamase marker gene (marker genes allow
detection of cells)
• b-Lactamase hydrolyzes b-lactam antibiotics
(e.g. ampicillin)
• Only cells transformed with plasmids expressing
the b-lactamase gene are ampicillin resistant and
can grow in media containing ampicillin (ampR)
Selection or screening by
insertional activation
• Insertional inactivation - insertion of a DNA
fragment within the coding region of a gene on a
vector results in inactivation of that gene
• If the gene product can be detected, this can be
used for selection and screening
• bBR322 gene for tetracycline resistance (tetR)
can be inactivated by DNA insertion making them
tetracycline sensitive (tetS)
Visual Markers: Insertional
Inactivation of the b-Galactosidase
Gene
• The lacZ gene of E. coli encodes b-galactosidase
and cleavage of an artificial substrate produces a
blue dye (X-gal)
• Vectors without inserts in the lacZ gene give rise
to blue colonies in the presence of X-gal
• Vectors with DNA inserted in the lacZ gene do not
produce the enzyme and yields colonies which
are white
Blue/white screen
• Blue colonies: cells
transformed with cloning
vectors not containing inserts
(b-galactosidase is active)
• White colonies: cells
transformed with recombinants.
b-Galactosidase gene disrupted
by insert
Genomic Libraries
• A method for isolating large quantities of
specific DNA fragments from organisms
• DNA library consists of all the recombinant
DNA molecules generated by ligating all the
fragments of a particular DNA into vectors
• Recombinant DNA molecules are then
introduced into cells for replication
Genomic library properties
• Genomic libraries represent all the DNA from
an organism’s genome
• Partial (rather than total) restriction digestion is
used to ensure that every gene is represented
• All types of vectors used
• Genomic libraries include both expressed and
non-expressed DNA from the organism
cDNA Libraries Are Made
from Messenger RNA
• cDNA libraries represent all the mRNAs made
in a given cell or tissue
• cDNA (complementary DNA) is double-stranded
DNA made with reverse transcriptase
• Purification of mRNA relies on the polyA tails on
mature eukaryotic mRNA
• The more abundant rRNA and tRNA lack tails
Preparation of cDNA
Properties of cDNA libraries
• Using a cDNA library from a specific tissue
with abundant protein of interest increases
the chances of successfully cloning the gene
for that protein
• Specialized phage l vectors and plasmids are
used in constructing cDNA libraries
• cDNA libraries from mRNA do not include
introns or flanking sequences (much less
complex than genomic libraries)
Expression of Proteins Using
Recombinant DNA
Technology
• Cloned or amplified DNA can be purified and
sequenced or used to produce RNA and protein
• Such DNA can also be introduced into organisms
to change their phenotype
• Purification of proteins begins with
overproduction of the protein in a cell containing
the expression vector
A. Prokaryotic Expression
Vectors
• Expression vectors - plasmids that have been
engineered to contain regulatory sequences for
transcription and translation
• Eukaryotic genes can be expressed in
prokaryotes
• Expression of a
eukaryotic protein in
E. coli
B. Expression of Proteins in
Eukaryotes
• Prokaryotic cells may be unable to produce
functional eukaryotic genes
• Some expression vectors are for eukaryotes
• Recombinant DNA molecules can also be
integrated into the genomes of large
multicellular organisms
• Creates transgenic organisms
• Technique for creating
a transgenic mouse
Effect of an extra growth
hormone gene in mice
• Transgenic mouse
(left) carries a
gene for rat
growth hormone
• Normal mouse
(right)