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Recombinant DNA technology
Lecture by:
Anne Wöhr
anne.wohr@gu.se
Recombinant DNA technology
Molecular cloning Transformation Selection and
Replication
Performed during this lab
Plasmids
• Commonly found in bacteria as extra-chromosomal
circular dsDNA molecules
• Able to self-replicate during cell division
• Often carry beneficial genes like antibiotic resistance
• Bacteria can share genetic information through
plasmid transfer
By: Maya Kostman
How could this be useful for us?
Applications of recombinant DNA
technologies
Khan S., 2016
Biopharmaceuticals:
Vaccines eg hepatitis B vaccine
recombinant proteins eg Insulin (Diabetes), Factor VIII (hemophilia)
Genetically modified organisms:
Organisms that have been genetically modified to exhibit specific traits eg
herbicide-resistant crop plants
Gene Therapy:
In some genetic disorders, patients lack the functional form of a gene. Gene
therapy attempts to provide a normal copy of the gene to the cells of the
patient.
Gene Analysis:
build artificial, recombinant versions of genes that help understand how
genes in an organism function
• Scissors: DNA restriction enzymes (DNA digestion)
• Cutting sites: multiple cloning sites (MCS)
• Glue: DNA ligase (DNA ligation)
• Host: bacterial cells (Transformation)
• Environment: LB medium or LB agar plates (Culturing)
• Goal: making more identical copies, or expression (making proteins)
Toolbox for molecular cloning
✓ DNA molecule that acts as a vehicle to carry foreign genetic materials
into another cell, where it can be replicated or expressed.
Vectors
Ori (origin of replication):
Replication is initiated here, enabling the plasmid to reproduce itself.
MCS (multiple cloning site):
Short segment of DNA which contains many restriction sites. This
allows a piece of DNA to be inserted into that region. The used
plasmid contains a BamHI cleavage site in its MCS.
AmpR gene:
encodes the enzyme beta-Lactamase, which inactivates ampicillin.
Cells containing a plasmid vector which expresses AmpR can be
selected from those that do not by growth in an ampicillin-containing
medium.
Lac promoter:
binding site of RNA polymerase to initiate expression. IPTG binds
and inactivates the LacI repressor protein and thereby enables
expression of genes downstream of the promoter.
LacZ gene:
encodes the alpha-peptide of the enzyme beta-galactosidase.
Functional beta-galactosidase consits of the alpha- and omega-
peptide. The used E-coli strain carries the lacZ deletion mutant
which contains the omega-peptide but lacks the alpha-peptide. The
activity of mutant beta-galactosidase is rescued by the presence of
the alpha-peptide present in the plasmid (alpha-complementation).
Restriction enzymes (Scissors)
✓ Sequence-specific DNA endonucleases
✓ Recognise and cleave DNA sequences at specific restriction sites
✓ Generate “sticky end” or “blunt end”
Escherichia coli (Host)
✓ Model organism in molecular biology
✓ Gram negative, rod shaped bacteria
✓ Located in lower intestine
The History of Insulin Production
1921: Discovery of insulin
1922: Leonard Thompson became the first person with diabetes ever
treated through administration of insulin
1923: Insulin is commercialized
Insulin sales kit, Eli Lilly and Company, 1940s
14 cows or 70 pigs to sustain a diabetic
patient for 1 year
1970: Recombinant DNA technology is
developed
1982: Recombinant insulin is commercialized
Production of Insulin
Adapted from “From DNA to Beer: Harnessing Nature in Medicine & Industry”
Purpose of this lab:
Determine whether a gene of interest has
been successfully cloned into a vector.
Transformation
Transformation
During the incubation
on ice, DNA binds to
the surface of the
bacterium as a calcium-
phosphate-DNA
complex
Following a sudden
increase in
temperature, one or
more DNA molecules
bound to the surface of
the cell is taken up by
the competent cell
How can we selectively grow bacteria
that have taken up the plasmid?
Selection pressure
✓ ampR gene encodes for beta-lactamase
✓ Inactivates ampicilin antibiotics
✓ Only cells containing vector DNA will grow
in the presence of ampicilin
Selection based on antibiotic resistance
How do we select for bacteria with the plasmids
carrying the inserts?
By: Maya Kostman
More detailed info: thermofisher.com
LacZ gene naturally found in E. coli, encodes β-galactosidase.
We use an E.coli strain that carries the LacZ deletion mutant which
contains the omega-peptide but lacks the alpha-peptide and is therefore
non-functional. The plasmid we use carries the alpha-peptide, rescuing the
function of mutant beta-galactosidase.
Blue-white screening
Lab Schedule
• Monday (11/24)
Introductory lecture 12:15 13:00
Lab 13:15 14:00 Groups 1-19
Lab 14:15 15:00 Groups 20-38
• Tuesday (11/25)
Lab 11:15 11:45 Groups 1-19
Lab 12:00 12:30 Groups 20-38
• Wednesday (11/26) Groups 1-19
Introductory lecture 8:15 9:00
Lab 09:15 16:00
• Thursday (11/27) Groups 20-38
Introductory lecture 8:15 9:00
Lab 9:15 16:00
Deadline for submitting lab reports: 07/12/2025
Working in the lab
✓ Work in groups of 2 people, stick to your assigned partner
✓ Always wear gloves and lab coat to protect you and your samples,
wash your hands thoroughly before leaving the lab
✓ When using the pipette, check the volume limits (0.1-10μl, 10-200μl,
and 100-1000μl)
✓ Pipette into the bottom of the tube, do not ”shoot” it (especially when
working with very low volumes)
Transformation of competent cells
→ performed during this lab (day 1)
✓ 1 tube of plasmids (P) (with/without insert)
✓ 1 tube of competent bacteria (C)
Day 1: Selection of transformed cells
→ performed during this lab (day 1)
✓ Pick up bacterial colonies (2 white, 2 blue) from plate
✓ Grow in LB medium with antibiotics (expand the colony and replicate plasmids)
Day 2: Picking & expansion of blue and white
colonies
→ performed during this lab (day 2)
Day 1: Materials for Transformation
Falcon tube (50ml) LB-agar plate Eppendorf tube
Day 1: Spread plate method
o Apply light pressure to not tear or stab the agar
Day 3 - work overview
✓ Purify plasmids
✓ Restriction enzyme digestion
✓ Run on agarose gel
✓ Interpret results
Lab reports
✓ Write according to the guidelines on the handout on Canvas
✓ One lab report per group (your names and project group number on
the cover page)
✓ In English
✓ Upload your lab reports on CANVAS deadline on 07/12/2025
Lecture Questions
1. Name three applications of molecular cloning.
2. What is a plasmid?
3. Name the three main steps involved in recombinant DNA technology?
4. What is a restriction enzyme?
5. What are the bacteria used in your protocol?
6. Explain the calcium/phosphate (heat-shock) method and what it is used for.
7. How can we selectively grow bacteria that have taken up the plasmid?
8. Explain the principle behind blue and white screening and its purpose in this
lab.
References
Kehoe A (1989). "The story of biosynthetic human insulin". In Sikdar SK, Bier M, Todd PW (eds.).
Frontiers in Bioprocesssing. Boca Raton, FL: CRC Press. ISBN 978-0-8493-5839-5.
https://www.sigmaaldrich.com/SE/en/technical-documents/technical-article/genomics/cloning-and
expression/blue-white-screening
https://www.nlm.nih.gov/exhibition/fromdnatobeer/exhibition-interactive/recombinant
DNA/recombinant-dna-technology-alternative.html
Khan, S., Ullah, M. W., Siddique, R., Nabi, G., Manan, S., Yousaf, M., & Hou, H. (2016). Role of
Recombinant DNA Technology to Improve Life. International journal of genomics, 2016, 2405954.
https://doi.org/10.1155/2016/2405954
https://www.thermofisher.com/se/en/home/life-science/cloning/cloning-learning-center/invitrogen
school-of-molecular-biology/molecular-cloning/cloning/traditional-cloning-basics.html

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Recombinant DNA technology
Lecture by:
Anne Wöhr
anne.wohr@gu.se
Molecular Cloning
→ Performed beforehand (not done during this lab)
Molecular Cloning
→ Performed beforehand (not done during this lab)
We aim to isolate/separate
these two plasmids to
select the recombinant
plasmid and to verify the
presence of the gene of
interest
Day 1: Transformation of competent cells
→ performed during this lab (day 1)
Day 1: Selection of transformed cells
→ performed during this lab (day 1 + day 2)
Day 2: Picking & expansion of blue
and white colonies
→ performed during this lab (day 2)
Revision
Blue-white screening
Plasmid:
• AmpR: Ampicillin resistance (β-lactamase)
• LacZ: α-peptide for functional β-galactosidase
enzyme
• BamHI restriction site in LacZ gene for
insertion of DNA
Growth medium:
• Ampicillin: Only successfully transformed
bacteria carrying plasmids can survive in the
presence of ampicillin
• IPTG : activates transcription of the LacZ gene
by binding its repressor
• X-gal: β-galactosidase degrades X-gal. The
product has a blue colour!
Day 3 - work overview
✓ Purify plasmids
✓ Restriction enzyme digestion
✓ Run on agarose gel
✓ Interpret results
Day 3: Material
Spin column
Tubes labeled with
A1; A2; A3; A4; H2O
Plasmid preparation kit
Collection tube &
spin column (blue)
Day 3: Plasmid purification
→ performed during this lab (day 3)
Buffer A1 (Cell Suspension)
Tris/HCl (pH 8.0), EDTA, RNase A
Buffer A2 (Cell Lysis)
NaOH; SDS
Buffer A3 (Neutralization/Binding)
Contains acetate and guanidine
hydrochloride
Buffer A4 (Wash, reconstituted)
Contains ethanol, NaCl, EDTA, and
Tris/HCl
cells grown in LB-
media overnight
Transfer 2x 750 µl into
microcentrifuge tube
Bacterial pellet = cells + plasmid
→ Discard superatant
Balance the centrifuge
Day 3: harvest cells & purify plasmids
A1 - resuspension buffer
A2 cell lysis buffer
A3 neutralization/
binding buffer
Plasmid in supernatant
cell debris as pellet
transfer supernatant
to column
Plasmid binding
Discard
flow-through
Wash with A4
Transfer column to new tube
add H2O to elute plasmid
QIAprep Miniprep Handbook, Appendix A: Background Information, Preparation of cell lysates, p 43
Plasmid purification
Buffer A1:
Bacterial cells are resuspended in a buffer containing Rnase A.
Buffer A2:
Bacteria are lysed under alkaline conditions (NaOH). SDS solubilizes the phospholipid
and protein components of the cell membrane
Lysis and release of cells contents. Alkaline conditions: denaturation of chromosomal
and plasmid DNA as well as proteins.
Buffer A3:
The lysate is neutralized and adjusted to high-salt-binding conditions. The high salt
concentration causes denatured proteins, chromosomal DNA, cellular debris, and SDS
to precipitate, while the smaller plasmid DNA renatures correctly and stays in solution.
DNA is bound to silica membrane of spin columns in high-salt buffer. RNA, cellular
proteins and metabolites are not retained on the membrane.
Buffer A4:
Washing and reconstitution of DNA. Salts are efficiently removed by this wash step.
H2O:
The purified plasmid DNA is eluted from silica membrane by addition of water. The
elution is pe is dependent on a low salt concentration and a stable pH (pH 7-8.5).
Restriction enzyme working solution:
Restriction enzyme buffer
H2O
Restriction enzyme (keep it cold!)
Add restriction enzyme to a portion of eluted plasmid
KEEP THE REST OF UNDIGESTED PLASMID AS CONTROLS FOR
LATER USE Incubate at 37°C for 60 min
Day 3: Restriction enzyme digestion
Day 3: Restriction enzyme digestion
Plasmid without insert (2700 bp)
Plasmid with insert in BamHI site (4200 bp)
Cut with BamHI → bands at 2700 bp and 1500 bp
• Samples are mixed with 6x loading
dye to make them ”heavier” to stay
in wells
• Separation of DNA molecules
based on their size
• DNA negatively charged
• Agarose gel for separation
• Shorter molecules move faster and
migrate farther than longer ones
• Visualization of DNA with SYBR
safe DNA stain
Day 3: Agarose Gel Electrophoresis
GeneRuler 1kb DNA ladder = size marker
marker
2700 bp
1500 bp
4200 bp
Day 3: Expected Results
• Relaxed/linear: intact circle but “nick” in one strand
• Linear: both strands are cut (at the same location)
• Supercoiled: fully intact with both strands uncut, appears in a compact
form
Plasmid conformation affects migration
Lab schedule
✓ Purify plasmids
✓ Restriction enzyme digestion
1-2h incubation time → lunchbreak and
everyone will be back at the same time
✓ Run on agarose gel
approximately 1h → go through the
expected results to be able to ask
appropriate questions
✓ Interpret results
make sure to ask a lot of questions while you have
the chance!!!
Lab reports
✓ Write according to the guidelines on the handout on Canvas
✓ One lab report per group (Names and group number on the cover page)
✓ In English
✓ Upload your lab reports on CANVAS, deadline 07/12/2025
Lecture Questions
1. What are the sites the plasmid contains that allow for this experiment?
2. What are the 3 compounds in the LB plates that allow for selection of
bacteria with plasmid and the distinction of plasmids with and without
the inserted gene?
3. What are the six steps in plasmid preparation and purification?
4. What is a restriction enzyme and why was it used in this experiment?
5. Explain the principle of Gel Electrophoresis, what is it for?
6. What´s the compound that allows for the visualization of the DNA in
the gel?
7. How many times does BamHI cut the plasmid without the insert? And
the plasmid with the insert?
8. Explain the different plasmid conformations that exist.