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IGP Methodology Class

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... work well with non-adherent cells. Mechanism is unclear. Calcium ... Can be used with adherent and suspension cultures. Disadvantages. Efficiency is often low ... – PowerPoint PPT presentation

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Title: IGP Methodology Class


1
IGP Methodology Class
  • Transfection Methods
  • Jared Boustead
  • Molecular Physiology and Biophysics
  • Extension 6-1629

2
Purpose of Transfection
  • Introduction of exogenous DNA into cells in
    culture
  • Analysis of expression regulation
  • Effects of gene on cellular growth
  • Overexpression of gene for purification of product

3
Types of Transfection
  • Transient
  • DNA not integrated into host genome
  • Expression usually peaks 24-72 hours after
    introduction of DNA
  • Efficiency 1-90 of cells
  • Stable
  • DNA integrates into host genome
  • Expression is constant or inducible
  • Efficiency 100 after selection

4
Transient Transfection
5
Types of Transfection
  • Transient
  • DNA not integrated into host genome
  • Expression usually peaks 24-72 hours after
    introduction of DNA
  • Efficiency 1-90 of cells
  • Stable
  • DNA integrates into host genome
  • Expression is constant or inducible
  • Efficiency 100 after selection

6
Stable Transfection
7
Considerations for Transfection
  • Methods
  • Calcium Phosphate
  • DEAE-Dextran
  • Liposome-mediated
  • Electroporation
  • Optimization
  • Preparation of Reagents
  • DNA
  • Amount
  • Method of preparation
  • Standing Time
  • Culture conditions

8
Calcium Phosphate
  • Advantages
  • Relatively inexpensive
  • Can accommodate high mass of DNA
  • Representative sampling of DNA in precipitate
  • Disadvantages
  • Efficiency is often low
  • Can be toxic to cells
  • Does not work well with non-adherent cells
  • Mechanism is unclear

9
Calcium Phosphate
  • Method
  • Mix DNA suspension with CaCl2 solution
  • Alternatively, DNA can be precipitated and
    resuspended in CaCl2 solution
  • Add HEPES buffered saline (contains sodium
    phosphate)
  • Allow to stand in order to form precipitate
  • Add cells to CaPO4 or add CaPO4 to dish
  • Incubate with precipitate (time is variable).
    Some protocols call for DMSO or glycerol shock
  • After appropriate time for expression, harvest
    and assay

10
Calcium Phosphate
  • Variables
  • Amount of DNA
  • Time precipitate is left on cells
  • To shock or not to shock?
  • pH
  • Controls
  • Transfection of vector lacking cDNA of interest
  • Internal control plasmid

11
DEAE-Dextran
  • Advantages
  • Relatively inexpensive
  • Requires small amount of DNA
  • Can be used with adherent and suspension cultures
  • Disadvantages
  • Efficiency is often low
  • Can induce morphological changes in cells
  • Does not work well for stable transfections
  • Works best when added in presence of
    reduced-serum concentration
  • Mechanism is by endocytosis

12
DEAE-Dextran
  • Method
  • Mix DNA suspension with DEAE-Dextran in DMEM and
    add chlorquine
  • Add DEAE-Dextran-DNA containing medium to dish
  • Incubate with medium (time is variable). Some
    protocols call for DMSO or glycerol shock
  • After appropriate time for expression, harvest
    and assay

13
DEAE-Dextran
  • Variables
  • Concentration of DEAE-Dextran
  • Ratio of DEAE-Dextran to DNA
  • Duration of transfection
  • Presence and timing of chloroquine
  • Controls
  • Transfection of vector lacking cDNA of interest
  • Internal control plasmid

14
Liposome-Mediated Transfection
  • Advantages
  • Higher transfection efficiencies than other
    chemical methods
  • Works with wide variety of cells
  • Low cell toxicity
  • Can be used to transfect RNA and oligonucelotides
  • Disadvantages
  • Higher cost than other chemical methods which
    often precludes large-scale use
  • Mechanism was originally thought to be by
    membrane fusion but is now thought to be by
    endocytosis

15
Liposome-Mediated Transfection
  • Method
  • Mix DNA with lipid in serum-free medium
  • Add to cells
  • Incubate for several (3-5) hours
  • Switch to normal growth medium
  • After appropriate time for expression, harvest
    and assay

16
Liposome-Mediated Transfection
  • Variables
  • Type of lipid mixture
  • Amount of DNA
  • Amount of lipid
  • Length of incubation
  • Controls
  • Transfection of vector lacking cDNA of interest
  • Internal control plasmid

17
Electroporation
  • Advantages
  • Can be used with most cell types
  • High efficiency
  • Requires few steps
  • Disadvantages
  • Requires special equipment
  • High fraction of cells die during electroporation
  • Mechanism is by exposing cells to high-voltage
    impulse that is thought to induce transient
    breakdown of cell membrane

18
Electroporation
  • Method
  • Harvest cells and wash
  • Resuspend in electroporation buffer (low ionic
    strength) and put in cuvette
  • Add DNA
  • Mix well
  • Electroporate
  • Transfer to dish and add medium
  • After appropriate time for expression, harvest
    and assay

19
Electroporation
  • Variables
  • Electric field strength and pulse duration
  • Temperature
  • Ionic strength of buffer in which cells are
    suspended
  • DNA concentration
  • Controls
  • Transfection of vector lacking cDNA of interest
    or mock transfected cells
  • Internal control plasmid

20
Viral Transduction
  • Advantages
  • High efficiency delivery of gene of interest
    leading to high levels of expression
  • Can often be used for delivery of gene in vivo
  • Disadvantages
  • Increased time and cost involved in preparation
    of virions
  • Some viruses present special safety
    considerations. Careful selection of viral
    system can minimize safety concerns.

21
Electroporation Equipment
22
Viral Transduction
  • Method
  • Generate construct with gene of interest and part
    of viral genome
  • Transfect into packaging cell line and collect
    supernatents or produce stable packaging cell
    lines
  • Purify virus
  • Infect cell line of interest with virus
  • Allow time for expression and perform desired
    assay

23
Viral Transduction
  • Variables
  • Type of virus
  • Retrovirus
  • Adenovirus
  • Baculovirus
  • Amount of virus
  • Controls
  • Infection with virus not carrying cDNA of interest

24
Reporters and Selectable Markers
  • Reporters
  • Green fluorescent protein
  • Luciferase
  • ?-galactosidase
  • Cell-surface antigen for FACS
  • Selectable Markers
  • Neor G418
  • Hygromycin

25
Cotransfection of Internal Control
26
Use of Bicistronic Vector
IRES
Bicistronic vector
assay transfected cells
transfect
Allow reporter expression of your protein and
GFP protein in the same cell. (24-72 hrs)
27
Inducible Expression
(
-
)
T
E
T
tet
tAK
tAK
tAK
Ptet
tAK
Ptet
tAK
reporter
reporter
Ptet
Ptet
28
References
  • Ravid K and Freshney RI, Eds. 1998. DNA
    transfer to cultured cells. New York
    Wiley-Liss.
  • Ausubel F, et al. Eds. 2003. Current protocols
    in molecular biology. New York Wiley.
  • Sambrook J and Russell DW, Eds. 2001. Molecular
    cloning a laboratory manual, 3rd ed. Cold
    Spring Harbor Cold Spring Harbor Laboratory
    Press
  • Notes If you are transfecting a cell line with
    which you have no experience, look at the primary
    literature to see what others have done.
    Manufacturers of commercial reagents often have
    helpful literature available. There are also
    some other methods that have not been discussed
    here.
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