Cell Culture All PPT PDF

Summary

This document is a presentation about cell culture, including details on cell biology and cell technology. It covers topics such as media formulation, cell dissociation techniques, and characteristics of transformed cells.

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BIOL3402
Cell Biology and Cell Technology

Dr. W. Y. Lui (6 lectures)
Office: Rm4N09 KBSB
Email: [email protected]
(use BIOL3402 as subject when email me)
BIOL3402 Cell Biology and Cell Technology (WYL lectures)

Learning outcomes:
Through the studies, you should be able to

Describe and explain the media formulation
Explain various cell dissociation and separation techniques
Distinguish different types of cell culture
(primary cell culture vs culture using cell line)
Describe the characteristics of transformed cells
Explain various methods for modification of cells in culture and the
corresponding selection methods
Explain how modification of cells in culture can help answering some
scientific questions
Describe the essential laboratory facilities for cell culture
Describe the method of cryopreservation
Why do we perform tissue/cell culture?
1. To study cell physiology
Without HGF With HGF

2. To synthesize valuable cell product

Gene cloning
+ ! Recombinant protein
Cell culture
 Metabolism
Energy
Food Cellular molecules
(Polymeric molecules) (Small)
Cellular
macromolecules

Cellular Cellular
structure functions

Energy
(i) Enables organism to carry out cellular physiology
(ii) Required for biosynthesis
(iii) Activation of biomolecules
(iv) Intermediate compounds of energy pathway are cellular
molecules
How to obtain energy?
Intermediate products in cellular respiration serve as precursors for
the synthesis of essential molecules
Culture medium

(1) Eagle’s Minimal Essential Medium (EMEM, MEM)
Used for a wide variety of cell lines (e.g. HeLa cell)
L-Amino Acid (mM) Vitamins (mM) Salts (mM)
(i) Glucose Arginine 0.1 Biotin 10
-3
NaCl 100
-3
Cysteine 0.05 Choline 10 KCl 5
-3
Glutamine 2 Folic acid 10 NaH2PO4·H20 1
(ii) 13 Essential amino acids Histidine 0.05 Nicotinamide 10
-3
-3
NaHCO3 20
Isoleucine 0.2 Pantothenic acid 10 CaCl2 1
-3
Leucine 0.2 Pyridoxal 10 MgCl2 0.5
-3
(iii) Vitamins Lysine
Methionine
0.2
0.05
Thiamine
Riboflavin
10
10
-4

Phenylalanine 0.1
Threonine 0.2
(iv) Salts Tryptophan 0.02
Tyrosine 0.1
Valine 0.2
Add if needed
Miscellaneous
(v) Antibiotics Glucose 5 mM
Penicillin* 0.005%
Streptomycin* 0.005%
(vi) Serum (e.g. FBS) Dialyzed horse serum 5%
*To prevent microbial contamination
Source: Science 1955 122:501
Culture medium
(2) From MEM to Ham’s F12 (R.G. Ham, 1965)
Satisfy the fastidious requirements of some cell lines

Basic components of MEM plus the following: Glucose
(i) Pyruvate Glycolysis

(ii) 7 non-essential amino acids Pyruvate

(iii) Trace elements (mM or nM) Krebs cycle
(e.g. Fe++, Cu++)
Oxidation
(iv) Organic compounds phosphorylation
(e.g. adenine, thymidine, hypoxanthine)

Add if needed
(v) Antibiotics
(vi) Serum
Culture medium

Disadvantages of using serum-supplemented media:
1. Serum is chemically undefined and variation between batches, inconsistent
results may occurs.
2. Serum is expensive and accounts for 70-80% of the cost of media.
3. Frequently contaminated by virus.

(3) From serum-supplemented media to serum-free media
Develop supplements of growth factors to replace serum
Not all cell lines are able to grow in serum-free condition
Culture medium

Why use growth factors-supplemented serum-free media ?
1. To study endocrine regulation

2. To simply product purification

3. Consistency (Reproducible)

Growth factors
Polypeptides stimulate the growth of particular cell types
Growth-promoting quality rather than its nutritional value
Not take part in metabolic pathway
Effective at very low concentration
Common supplements for most cell types:

(i) Insulin – glucose uptake and metabolism
amino acid uptake

(ii) Transferrin – iron-carrying protein

(iii) Epidermal growth factor – mitogen for epithelial and fibroblastic cells

(iv) Other growth factors (e.g. NGF, TGF)
High conc of Fe2+ Steroid
Low conc of Fe2+ No steroid
Attachment factors/extracellular matrix
Required by some cells to sandwiched between cell surface and the
substratum (surface of the plastic culture dish) in serum-free condition
Mimic in vivo situation

Common attachment factors/extracellular matrix
Source
(i) Collagen Rat tendons
(ii) Fibronectin Human blood plasma
(iii) Laminin Mouse sarcoma
(iv) Poly-lysine Synthetic
Cell dissociation and separation techniques
(1) Tissue culture
Tissue

Dissociation

Cell culture

Perfusion
‐ Prevent blood contamination
‐ e.g. Liver and kidney

Dissociation Methods:
(i) Mechanical
‐ e.g. Spleen and thymus
(ii) Enzymatic
‐ Trypsin, collagenase or hyaluronidase
Dissociation
Removal of blood from tissue by perfusion

Dissect and chop into small pieces

A series of enzymatic digestion (depend on cell types)

(i) Trypsin – non‐specific protease cleaves peptide bonds on the carboxyl side
of lysine and arginine residues
NH K A C K G R G COOH

(i) Collagenase and hyaluronidase – digest extracellular matrix containing
glycoprotein such as collagen and hyaluronic acid

(iii) DNase – disperse DNA released from lysed cells

Isolate a particular pool of cells
Primary culture
Isolation of testicular cells from the testis
Cross‐section of testis
Preparation of Sertoli cells for culture by enzymatic digestion
(i) Testes isolated from rats

(ii) Decapsulate testes

(iii) Chop tubules into small pieces by scissors

Wash and discard supernatant (x3)
(iv) Incubate with 0.1% trypsin/0.002% DNase solution (30 min, 37 oC)

Cent’ and discard supernatant (x1)
(v) Incubate with 0.01% soy bean trypsin inhibitor/0.002% DNase
in glycine/EDTA solution (10 min, Rm T)

Wash and discard supernatant (x2)
(vi) Incubate with 0.05% collagenase/0.0005% DNase solution
(10 min, 37 oC)
Cent’ and discard supernatant
Preparation of Sertoli cells for culture by enzymatic digestion
(vii) Incubate with 0.1% collagenase/0.0005% DNase solution
(30 min, 37 oC)
Wash and discard supernatant (x3)
(viii) Incubate with 0.1% hyaluronidase/0.0005% DNase solution
(30 min, 37 oC)

(ix) Wash by centrifugation at least five times

(x) Resuspend Sertoli cells in serum‐free F12/DMEM
containing insulin, transferrin, EGF

(xi) Check the purify of Sertoli cell culture
Preparation of Germ cells for culture by Mechanical method
(i) Testes isolated from rats

(ii) Decapsulate testes

(iii) Mince tubules into small pieces by scissors

(iv) Centrifuge at 300 rpm (2 min) and collect supernatant

(v) Repeat steps (iii) and (iv) to collect more supernatant

nylon mesh
(vi) Pool all supernatants and
filter using Mira cloth

(vii) Pool all supernatants and
filter through 100 μm nylon mesh
Preparation of Germ cells for culture by Mechanical Method
(viii) Filter the resulting suspension through glass wool
(Observe under the microscope)

(ix) Collect filtrate and centrifuge at 1000 rpm (10 min)
and discard supernatant

(x) Resuspend the pellet with media and wash the pellet three times

(xi) Filter the resulting suspension through 20 μm nylon mesh and centrifuge
at 1000 rpm (10 min)

(xii) Resuspend germ cells in in serum‐free F12/DMEM supplemented
with insulin, transferrin, EGF, sodium lactate and sodium pyruvate

Purify a pool of germ cells
Spermatogonia
Primary spermatocytes
Secondary spermatocytes
No spermatid
 Tissue/organ (e.g. testis)

Different separation methods (e.g. Enzymatic or Mechanical)

Enzymatic Mechanical

Sertoli cells Germ cells
Cell Counting
(i) Coulter Counter (ii) Hemocytometer
Five cell types can be isolated from animal
(1) Epithelial cells A
A layer of cells cover the organs
Polygonal and rectangular
B
(2) Fibroblasts
Cells are spindle‐like shape on attachment to a solid surface

(3) Muscle cells
Myoblasts are capable of differentiation to form the myotubes
Myotubes further differentiate to form muscle fiber

(4) Nerve cells
Highly differentiated and not divide in culture

(5) Blood cells
Culture in suspension
e.g. lymphocytes
From primary cell culture to cell lines
(1) Primary cell culture
Very few
Established when the cells taken
(2) Continuous cell line directly from animal tissue
Freshly isolated cells in culture – primary
cell culture
Majority of cells die within several days
or weeks (depend on cell types)

A very very small cell population
continues growing through many sub‐
culture
Unlimited proliferation – immortalized –
continuous cell line
 Normal cells Transformation Continuous cell line
(finite growth) (infinite growth)

Transformation
Cells lose their sensitivity to the stimuli associated with growth
control

How can cells be transformed or “immortalized”?
1. Spontaneous
2. Mutagens
3. Virus
‐ Infection by retrovirus express activated oncogenes (e.g. ras)
 Transformation
Normal cells Continuous cell line
(finite growth) (infinite growth)

Characteristics of transformed cells:
1. May lose anchorage dependence

shaking shaking

Anchorage dependence Anchorage independence
2. May lose contact inhibition features

3. Show chromosome fragmentation
4. Alteration from the normal diploid state
(e.g. increase in chromosome number)
5. High capacity for growth
Where to obtain cell lines?
(i) The American Type Culture Collection (ATCC)
(ii) The European Collection of Animal Cell Culture (ECACC)

What kinds of services they provided?
(i) Stock of commonly used cell lines such as CHO cells, MDCK cells
(ii) Provide safe storage service of private cell lines
(iii) Offer tests for contamination of cell lines
(iv) Characterize cell lines using isoenzyme analysis and DNA
fingerprinting
Growth Parameter
Several days later...................... Inoculate cells in growth
Cells stop growing
Cell line obtained (i) limited nutrient
medium at a density of (ii) toxic metabolite accumulated
from the culture (e.g. 104‐105 cell/cm2)
collection (iii) lacking growth surface

Sub‐culturing/passaging
‐ Trypsinize monolayer
‐ Dilute cells (1:2 to 1:10) in
fresh media.............

Passage number ‐ indicates the number of sub‐cultures performed since the
cells were obtained
Four phases of a culture

(i) Lag Phase

No apparent increase in cell
concentration
Synthesis of growth factors
Duration varies
Dependent on medium formulation
and the initial concentration
(ii) Growth/Log Phase

An exponential increase in cell number

N=N0∙2x
N= final cell concentration
N0= initial cell concentration
X = generation numbers of cell growth

Used to determine the doubling time of
cell line
Doubling time = Total time
x

The proportion of cells in cycle is high
A cell inoculum of 105 cells/ml which increases to a density of
106 cells/ml in 3 days, how many generations have been passed
through and what is the doubling time?

Log10N=log10N0+ xlog102
Log10106=log10105 + xlog102
x = 3.32

Doubling time = Total time
X
Doubling time = 3 x 24
3.32
= 21.69 hour
(iii) Stationary/Plateau Phase

No further increase in cell concentration
Cell growth=cell death
Cell growth is limited
(i) Depletion of nutrient
Unable to support further cell growth
(ii) Accumulation of toxic metabolic by‐product
(iii) No free growth surface
Cells stop growing when a single monolayer
covers the available substratum (confluence)
Cells are still metabolically active
(iv) Decline Phase
Cell death exceeds cell growth
Viable cell concentration decreases
Death is associated with the build‐up of toxic products
Via two pathways: Apoptosis and necrosis
Modification of cells in culture
(i) Cell fusion
(ii)Expression of cloned gene in cultured cells
(transfection or viral transduction)

(i)Cell Fusion
Production of somatic cell hybrid by fusion of cells to form heterokaryons
Combine their characteristics and form a hybrid cell with one fused nucleus
Fusion techniques: (A) Fusogen such as polyethylene glycol (PEG)
(B) Electrofusion
Application: Fusion of antibody-producing B lymphocyte with myeloma cell
line to produce antibody and chromosome mapping
(i) Cell Fusion
(A) Fusogen
myeloma B cell

Two cells (diploid each)
Fusogens
Membrane fusion
Heterokaryon
Heterokaryon
Nuclear fusion with
elimination of chromosome Nuclear fusion
Hybrid cell (one fused nucleus)
Mitosis

Cell line Hybrid cell
(B) Electrofusion
Non-specific
Apply current in low voltage to generate an electric field

myeloma
Two populations
B cell of cells

-ve +ve
Followed by higher voltage with longer duration

-ve +ve

Hybrid cell

Proliferate
(B) Electrofusion
Specific (biotin-avidin system)

Crosslink myeloma cells and antigen with biotin and avidin respectively

Biotin attached Avidin linked B cell
to myeloma to antigen

Antigen binds specifically to B cells
Biotin binds to avidin with high affinity

Two cells electrically fuse together to form hybrid cells
Application of cell fusion techniques
(a) Antibody production
Normal antibody-producing lymphocytes have limited life span
Myeloma have infinite growth capacity

Desire property of Infinite growth
antibody synthesis + capacity of
of B-lymphocyte myeloma
Fusion
A mixed population of cells
(lymphocytes, myelomas and hybridomas)

HAT Selection

Desire hybridomas

Unlimited antibody production
(b) Chromosome mapping
Fusion of human and mouse cells to form hybrid cell
Human chromosome are lost from the hybrid cell lines, usually only few
chromosomes are retained
A complement of hybrid cell lines retaining different human chromosomes
are developed
A DNA marker specific to a gene is used to perform PCR or hybridization,
the chromosome carrying that particular gene can be identified
(ii) Expression of cloned gene in cultured cells
(A) Transfection (transfer of “naked” DNA)
(A) Calcium phosphate method
- DNA co-precipitate with Ca3(PO4)2

(B) DEAE-dextran
- DNA complexed with the DEAE-dextran

(C) Liposome
- Liposome complex are formed positively
charged lipid and DNA
- DNA are encapsulated in liposome vesicle

(D) Microinjection
- Insert DNA by a microneedle into the nucleus of individual cell

(E) Electroporation
- Promote the uptake of DNA by electrical impulse
(B) DNA transfer by viral transduction
- Transfer DNA into mammalian cells : Extremely efficient
Reasons: (i) They replicate to high copy number, mean that several
copies of the required gene within each cell
(ii) Some viruses integrate efficiently into the animal cell
genome
- Widely used viruses for infection : Adenoviruses
Retroviruses
Selection System
Select the successful hybridomas or clones from the population

Selectable markers
- for hybridomas selection and stable transfection

Marker genes
(i) Thymidine kinase (TK)
(ii) Hypoxanthine guanine phosphoribosyltransferase (HGPRT)
(iii) Neomycin resistance gene (NeoR)
Two pathways in the biosynthesis of nucleotides
Folic acid

dihydrofolate

X Aminopterin de novo
biosynthesis
Glycine Tetrahydrofolate Aspartate

dGTP DNA dTTP
dATP

IMP TMP Salvage
pathway
HGPRT TK
Hypoxanthine Thymidine
 Folic acid
Selection System for hybridoma dihydrofolate

X Aminopterin de novo
biosynthesis
Glycine Tetrahydrofolate
B-lymphyocyte Aspartate
Myeloma preselected
preselected by
by 8-azaguanine dGTP
dATP
DNA dTTP
bromodeoxyuridine
IMP TMP Salvage
pathway
HGPRT TK
Hypoxanthine
TK- B-lymphocytes HGPRT- myeloma Thymidine

survive survive

Fusion (A) TK marker gene:
Bromodeoxyuridine
A mixed population of cells
TK+ Die
(lymphocytes, myeloma and hybridoma)
TK- Survive
HAT Selection (B) HGPRT marker gene:
8-Azaguanine
Hybridoma (TK+ and HGPRT+) survive HGPRT+ Die
HGPRT- Survive
Selection System
Neomycin resistance gene (NeoR)
NeoR gene codes for aminoglycoside phosphotransferase
Presence of this enzyme confers resistance to aminoglycoside group of
antibiotics such as G418
G418 prevents replication of mammalian cells
Cells carrying NeoR gene after transfection are able to replicate in medium
containing G418 and form cell clones
Geneticin NeoR gene Phosphorylated G418
(G418) (Unharmful compound to cells)
(Harmful to cells)
X
Transfection X X
Expression vector containing
desire protein and NeoR gene Selection medium Replicate
containing G418
Cells do not contain NeoR gene X Death
Expression vector containing desire protein and NeoR gene
Stable transfection

Clone the gene of interest into a vector containing NeoR
Generate the “Kill curve” for a particular cell line to determine the
dosage of G418 for selection
Transfection
Selection
Subculture those clones that survive in medium containing G418
Check whether the gene is overexpressed in those clones by PCR and
western blot
Laboratory facilities
(i) Water Source
(ii) Glassware/Plastic ware
(iii) Laminar Flow Hood
(iv) CO2 incubator
(v) Microscope
(vi) Sterilization and Disinfection
(a) Autoclaving
(b) Filtration
(c) Irradiation
(d) Chemicals
(vii) Culture contamination
(a) from culturing techniques
(b) Other sources: medium
serum
tissue or organ
equipment
(i) Water Source
Water is the most critical constituent of all media and reagent
Requires three‐ or four‐stage process
Recycling
Soft water

First Stage:
Second Stage: Third Stage: Fourth stage:
Distillation
Carbon High Grade Micropore
or
filtration deionization filtration
reverse osmosis

Softener Ultrapure water

Hard water
Media preparation

RO system (stage 1) Milli‐Q H2O system (stages 2‐4)
(ii) Glassware/Plastic ware
In the past, glassware were used and recycled
Washing and autoclaving are required
Pre‐sterilized plastic ware (flasks, dishes and pipettes) suitable for cell culture
– convenience and reduce contamination
The plastic is sulphonated, the surface suitable for cell attachment
(iii) Laminar Flow Hood
(a) Horizontal Flow Hood
Air filtered through High‐Efficiency
Particulate Air (HEPA) filter
Flows out from the hood
Provides an isolated area
Use if the culture is safe and not
infectious
Not suitable to handle hazardous
materials such as primate cell lines
This design cannot protect the operator
(iii) Laminar Flow Hood
(b) Vertical Flow Hood
A vertical flow of air is drawn into the
working area through a HEPA filter
70‐80% of the air is re‐circulated to form an
air curtain to maintain sterile operation and
protect the operator
The most common used cabinet:
Class II cabinet
Suitable for work with moderate toxic and
infectious agents
Class III cabinet: design to handle high‐risk
pathogens
(iv) Water jacketed CO2 Incubator
Maintains the optimal temperature and pH
for cell growth
Water jacket provides a constant
temperature environment
Carbon dioxide supplied from a gas cylinder
Bicarbonate‐CO2 buffering system
‐ +
H2O + CO2 HCO3 + H
The level of CO2 in gas phase of the
incubator is 5‐10%
(v) Microscope
Routine checking to determine if there are any significant morphological
changes
(A) Standard binocular microscope
Requires the specimen placed on a glass slide and covered by a cover slip
(B) Inverted microscope
Having the light source on the top, enable large object to be placed on the
stage for viewing

Binocular microscope Inverted microscope
(vi) Sterilization and Disinfection
Kill and remove micro‐organisms
(a) Autoclaving
Steam heat and dry heat
Steam heat: 121oC, at 1 kg/cm2 (15 psi) for 20‐30 min
Dry heat: 180oC for 20 min
(b) Filtration
Cellular ester filters (0.2 μm is considered‐the standard for removing
bacteria and fungi)
 4
5
3

(c) Irradiation 6
2
Induce covalent bonds
(i) Ultraviolet light (UV) 1

‐ Inactivate micro‐organisms and virus P
P P
‐ Acts on nucleic acid
UV
‐ Poor penetrating power
P
P
(ii) Gamma rays P Break phosphodiester
bonds
‐ Not actually performed in the laboratory
‐ Important method of sterilization XP XP XP
‐ Good penetrating power
‐ Acts on nucleic acids and produce free radicals that kill
bacteria
‐ Commonly used with items that cannot be heat‐sterilized
‐ Pre‐sterilized disposable plastic wares are exposed to γ‐rays
4
5
Induce covalent bond 3

4 2 1
6
Gamma radiation 1

P
P
P P
P
(d) Chemicals
(i) Gases
‐ Ethylene oxide and formaldehyde gas
‐ Effective against all types of micro‐organisms including virus
‐ Acts on nucleic acid and protein components of the micro‐organism
‐ Ethylene oxide is used for sterilizing items, particularly in hospital
‐ Formaldehyde gas is used to decontaminate or sterilize laminar flow
cabinet
‐ Both ethylene oxide and formaldehyde gas are very toxic

(ii) Solutions (Disinfection)
‐ Alcohol
‐ Optimal at a concentration of 70%
(vii) Culture contamination
(a) From culturing techniques
(b) Other sources: medium
serum
tissue or organ
equipment

(i) Bacterial

(ii) Mycoplasma

(iii) Fungi

(iv) Virus
Cryopreservation and freezing and thawing of cells

(i) Storage at low temperature
(ii) Physical changes during freezing
(iii) Cryo‐injuries
(iv) Procedure to freeze and thaw cells
(i) Storage at low temperature
‐196 oC Liquid nitrogen
‐120‐130 oC Liquid nitrogen vapor
‐70 oC Dry‐ice, deep freezer (Unstable)

How to achieve ‐196 oC and recover to 37oC?
(Freezing and thawing)

Moderate cooling 1‐2 oC/min
Rapid warming

Critical temperature range in cooling ‐5 oC to ‐40oC
(ii) Physical changes during freezing
< ‐10 oC

Dehydration
Slow

Rapid
‐2 oC Formation of
‐5 oC intracellular
ice crystal
 (iii) Cryoprotectants
‐ Small molecules are permeable to cells
‐ Glycerol and DMSO
‐ Delay intracellular freezing
‐ Increase extracellular fluid volume during extracellular ice formation

(iv) Cryo‐injuries due to low thawing rate
(a) Slow warming – recrystallization of intracellular ice
(b) Some cryoprotectants are toxic to cells at warm temperature
(iv) Procedure to freeze and thaw cells
Resuspend cells
Freezing: in freezing medium
(e.g.medium with DMSO)....... 400 x g,
5‐10 min
Aliquot into
freezing vials

Lid

‐70 oC freezer or
Liquid Nitrogen overnight
Tank (~ ‐1 oC/min)
Freezing container
containing isopropanol
 (iv) Procedure to freeze and thaw cells

Thawing:

on i
gat
ifu
ntr
Prewarm Prewarmed....

Ce
medium to 37oC medium..........

Discard medium
containing DMSO
and resuspend cells
in fresh medium
Pick a frozen Thaw the vial at
vial from liquid 37 oC water bath........
N2 Tank
Seed cells
in culture dish