Cell Culture Techniques

Question 1

What are the methods of cell isolation from blood?

Answer 1

Density centrifugation
- entire cell populations

Immunopurification / FACS
- specific cell types

Question 2

How does density centrifugation work?

Answer 2

Density centrifugation takes advantage of the varying densities of the blood cell populations and the density gradient medium (DGM) that we use

Depending on the medium we use, we can isolate different types of cells

Question 3

Name an example of a density gradient medium used in density centrifugation

Answer 3

We can mix our blood sample with Ficoll (DGM) that has a density of 1.077 g/mL
After centrifugation we can observe different layers

Question 4

Which blood cell type sediments as the bottom layer?

Answer 4

Granulocytes and erythrocytes are denser than the other cell layers and so sediment through the DGM to the bottom

Question 5

Which cells are found towards the top of the blood centrifugation?

Answer 5

Less dense mononuclear cells usually remain towards the top in the plasma interface - can isolate and centrifuge to separate the mononuclear cells

Question 6

What is the buffy coat?

Answer 6

Can also isolate the buffy coat white layer (lymphocytes) containing copies of the germline info

Question 7

What techniques can be used to isolate more specific cell types?

Answer 7

In order to isolate more specific type of cells we can use other techniques e.g.

• Immuno-purification
• Fluorescence Activated Cell Sorter

Question 8

Outline the process of immunopurification

Answer 8

1. Magnetic beads coated with antibodies - bind to
   specific antigen on cell of interest surface
2. Coated beads mixed with blood sample and only bind
   to cell type of interest
3. By application of magnetic fields, we can instruct beads
   bound to cells of interest

Question 9

How does FACS isolate specific cell types?

Answer 9

uses cell size and antibodies to separate cells of interest

Question 10

How are cell types differentiated in FACS?

Answer 10

Uses cell surface markers and size to differentiate between cell types

Question 11

Give an example where cells are isolated from tissues

Answer 11

E.g. Isolation of hematopoietic placental stem cells that can differentiate into any cell lineage

Or placental endothelial cells

Question 12

What is the difference between cell isolaton from blood and from tissue?

Answer 12

In tissues cells require isolation from solid tissue so need to carry out a mechanical enzymatic disruption

Question 13

How do we carry out a mechanical enzymatic disruption of cells?

Answer 13

• Scalpels used to disrupt tissue

- Pass tissue through needles to extract individual cells

Question 14

What other technique is used to disrupt cells alongside mechanical disruption?

Answer 14

Mechanical disruption is usually combined with digestive enzymatic disruption
e.g.
Dispase, trypsin, collagenase

Question 15

How are specific cell types extracted from tissue after disruption?

Answer 15

We can now apply magnetic immunopurification techniques to extract the cell type of interest

Question 16

Outline how mechanical enzymatic disruption is used in explant cultures

Answer 16

Easily carried out in chondrocytes as they migrate away from a cartilage explant - doesn’t require any additional techniques, can occur spontaneously

Question 17

What are the advantages of using primary cell cultures?

Answer 17

Unmodified; carry all genetic info belonging to patients tumour / tissue they’re isolated from

Makes them good for personalised medicine e.g. therapeutic drug assays: assess response of patient to certain drugs based on their genetic profile

Question 18

Why are primary cell cultures not good for basic science?

Answer 18

However, for in vitro contours for basic science, primary cells aren’t ideal models as they carry other non-functional genes - contribute in contamination (e.g. bacteria from organism extracted form)

Question 19

What are some disadvantages of primary cell cultures?

Answer 19

Short life span - can’t be handled after a certain no. of times

Can’t carry out reproducible in vitro analysis using other cell lines - primary cell population will have different characteristics to others

Question 20

Where are cell lines isolated from?

Answer 20

Can be isolated from healthy or cancerous tissues (e.g., HeLa cells)

Question 21

Where are cell lines derived from?

Answer 21

Spontaneously
from prolonged culture, multiple ill-defined mutations transformed phenotype

Through genetic manipulation
Transformation of healthy primary cells

Question 22

How are cell lines generated?

Answer 22

To generate cell lines we target processes that regulate cellular growth and ageing

Question 23

What 3 genes are manipulated to form immortal cells?

Answer 23

P53
pRB
Telomerase enzyme

Question 24

What are the roles of p53 and pRB?

Answer 24

P53 and pRB are encoded by tumour suppressor genes and maintain cell cycle checkpoints and regulate genomic instability

Question 25

What are telomeres?

Answer 25

Telomeres are short tandem nucleotide repetitions found at the ends of each chromosome.

Question 26

What is the function of telomeres?

Answer 26

To maintain stability of chromosomes and prevent fusion with other chromosomes

Question 27

What is telomerase?

Answer 27

Telomerase is an enzyme that elongates chromosomes

Question 28

Why does telomerase elongate chromosomes?

Answer 28

Every time DNA is replicated in a cell, DNA pol. is unable to elongate telomere sequences completely ∴ in each cell division there is telomere shortening

Question 29

How does certain no. of cell divisions lead to apoptosis?

Answer 29

When cell division no. reaches its limit, telomeres are very short in length causing chromosomal damage ⇒ activates p53 and pRB; lead cell to apoptosis due to damage signal

Question 30

Which cells contain active telomerase?

Answer 30

Other types of cells also contain active telomerase e.g. - Gametes - Stem cells - Cancer cells

Question 31

What is the advantage of activated telomerase?

Answer 31

By activating TERT (telomerase enzyme) we can create immortal cells

Question 32

How can we produce immortal cells?

Answer 32

We can inhibit the function of tumour suppressor proteins, or introduce telomerase in order to alter a cell’s capability for its finite number of divisions by taking advantage of viral ‘oncoproteins

Question 33

Which viruses do we use to produce immortal cells?

Answer 33

can use SV40 and HPV to manipulate telomerase enzymes in their viral oncoproteins.

Question 34

How is SV40 used to produce immortal cells?

Answer 34

SV40’s large T-antigen DNA binding domains interact with p53 and pRb preventing them from binding to E6 and E7 domains. This can cause increased growth without loss of function of these proteins

Question 35

How are HPV manipulated to produce immortal cells?

Answer 35

E6 in HPV targets p53 for degradation, and E7 binds to pRb inactivating it

Question 36

Describe the phenotype of viral oncoprotein manipulated cell lines

Answer 36

E6/ E7 and telomerase transformations are believed to result in cell lines with a differentiated phenotype

Question 37

Outline how the telomerase gene is introduced to immortalise primary cells

Answer 37

1. Plasmid vector designed carrying gene for selection marker e.g. antibiotic resistance marker 2. Insert into plasmid, the telomerase gene sequence we want to transfect into cells 3. Completed plasmid vector transfected 4. Positively transfected cells identified via antibiotic resistance marker 5. Only positively transfected cells show antibiotic resistance as they have antibiotic resistance gene

Question 38

Why are cell lines a good model for basic science?

Answer 38

Cell lines show good reproducibility as different labs using the same cell line can obtain the same results from an assay > makes cell lines a very good model for basic science

Question 39

Why are cell lines an unreliable source?

Answer 39

Cell lines usually lose differentiated function and revert to become stem cell like without a differentiated phenotype

Question 40

What are the disadvantages of cell line use?

Answer 40

Show bias to cell substrates in their actions; acquire polarity due to attachments to cell surfaces Phenotype needs to be validated by an external source - identify cross contaminations, acquired mutations etc.

Question 41

Outline the conditions and requirements of growth in culture

Answer 41

a) Handled under aseptic conditions b) Grown on tissue culture treated plastic flasks/dishes c) Maintained in warm (37°C) humidified atmosphere (5% CO2) - mimics internal human conditions d) In ideal supplemented medium that is replaced by fresh one every 2/3 days*

Question 42

What conditions need to be maintained for cell culture growth?

Answer 42

Need to ensure cells are grown at optimum pH (7.0) and temperature (37.0c) Ensure there is enough space to grow in the dish We need to add the corresponding growth factors and supplements to the medium

Question 43

What is the consequence of a lack of any of the conditions required for cell culture growth?

Answer 43

If the cells lack any of the aforementioned requirements they will arrest in the cell cycle ⇒ quiescent cells

Question 44

What are quiescent cells?

Answer 44

Quiescent cells - still alive, but won’t divide and proliferate

Question 45

Give examples of 2 common growth culture mediums

Answer 45

Growth medium RPMI 1640 | Growth Medium DMCM

Question 46

Why does the growth medium need to be replaced so often?

Answer 46

Medium needs to be replaced every 2-3 days to replenish nutrients and metabolite excretion

Question 47

What is phenol red?

Answer 47

Phenol red is a medium pH indicator

Question 48

What causes a colour change in phenol red?

Answer 48

Colour change based on medium pH dependent on metabolite presence Ideal colour - red (neutral)

Question 49

What are the two ways culture cells can grow?

Answer 49

Cells can either grow in suspension or attached to a surface

Question 50

Outline the features of adherent cells

Answer 50

- Grow attached to solid surface - Anchorage-dependent - Trypsinization required - Tissue culture treated vessels - Low yield - Growth limited by SA - Most cell lines and cultures

Question 51

Outline features of suspension cells

Answer 51

- Grow suspended in a liquid medium - Anchorage-independent - Continuous agitation needed - High yield - Growth limited by [cells] in medium - Some non-adhesive cell lines

Question 52

What are some of the microbial contaminations found in cell cultures?

Answer 52

Bacteria (pH change, cloudiness/turbidity, precipitation, stink) Yeast (cloudiness, pH change) Fungus (spores furry growths, pH change) Mycoplasma (often covert, poor cell adherent, reduced cell growth) Virus (sometimes cytopathic)

Question 53

What are the types of cross contaminations that can occur in cell cultures?

Answer 53

- Poor tissue culture technique - Culture of multiple cell lines at one time - Accidental mixing of cell lines

Question 54

What is the purpose of new in vitro models?

Answer 54

Used to overcome cell line disadvantages

Question 55

What are the 2 types of 3D cell culture models?

Answer 55

- Organoid | - Spheroid

Question 56

How are spheroid cells made?

Answer 56

Spheroids are made from established immortalised cell lines that normally grow in 2D but are grown in 3D

Question 57

What are organoid cells?

Answer 57

Organoids are 3D cultures derived from stem cells normally present in normal tissues

Question 58

Why are organoids and spheroids better than 2D models?

Answer 58

Organoids and spheroids are better models than the 2D cell cultures, as they replicate 3D growth as in humans - no bias to cell attachments

Question 59

What areas in cell culturing are spheroids and organoids respectively used for?

Answer 59

Spheroids good for in vitro model = reproducible Organoids good for drug resistance studies

Question 60

Outline the features of organoid cells

Answer 60

- Derived from stem cells - Multiple cell lineages - Recapitulate organ physiological parameters - long term culture

Question 61

Outline the features of spheroid cells

Answer 61

- Derived from cell line monoculture - Represent single / partial tissue components - transiently resemble cell organisation - Difficult to maintain long term

Question 62

Explain how patient derived organoids are used to study cancer drug resistance

Answer 62

1. Extraction of primary cells from a tumour 2. Grown in 3D in the lab - Allows tumour to maintain its 3D structure and cell-cell contacts - can test different drugs and their efficacy and response - simulates body well

Question 63

What are the advantages of organoid use?

Answer 63

- Gene expression as in vivo (87% phenotype and genotype similarity) - Cells-cell communication re-established - Cells are orientated in same ways as tissue - Ideal platform for individualized therapeutic screening

Question 64

What are the limitations of organoid use?

Answer 64

- Limited amount of tissue in some cases (e.g. prostate) - Organoids in the same culture are heterogeneous - Absence of immune cells in culture system - Unable to mimic in vivo growth factor/signalling gradients

Question 65

What is transfection?

Answer 65

Process by which foreign DNA is deliberately introduced into a eukaryotic cell through non-viral methods (chemical and physical methods in the lab) e.g. a plasmid, a CRISPR/Cas9 complex

Question 66

Give examples of chemical methods of transfection

Answer 66

``` Lipofection Calcium phosphate Cationic polymer DEAE-Dextran Magnet-mediated transfection Dendrimers ```

Question 67

Outline the physical transfection methods

Answer 67

``` Electroporation Nucleofection Microinjection Biolistic Particle Delivery Laserfection/ opto injection ```

Question 68

Explain how lipofection occurs

Answer 68

Lipofection takes advantage of the cationic nature of liposomes DNA by nature is -ve charged - can introduce DNA into those liposomes allowing it to fuse

Question 69

What are liposomes?

Answer 69

small vesicles surrounded with phospholipid bilayer with positive heads

Question 70

Outline the mechanism of lipofection

Answer 70

Lipoplexes positively charged Membrane is negatively charged 1. Interaction with the cell membrane 2. Taken up by endocytosis 3. Release from the endosome 4. Transport to the nucleus 5. Entry to the nucleus inefficient and may need mitosis

Question 71

When is lipofection commonly used?

Answer 71

Lipofection significantly used in transfection of drugs

Question 72

How can we make liposomes tissue specific?

Answer 72

Can make liposomes tissue specific by attaching antigens to their surface

Question 73

What is the disadvantage of lipofection?

Answer 73

Lipofection however can be quite toxic for the cells

Question 74

What is the process of electroporation?

Answer 74

Application of electric fields enables us to open pores in the cell membranes making them permeable to the plasmids Once the plasmid is in the cell, the membrane pores reseal

Question 75

What needs to occur in electroporation for transcription to occur?

Answer 75

In order to activate the transcription machinery, the cell needs to incorporate the plasmid in its nuclear DNA

Question 76

What is nucleofection?

Answer 76

Combination of electroporation and lipofection

Question 77

Outline the features of nucleofection?

Answer 77

Increased efficiency particularly of non-dividing cells Technology is protected under patent Different solution and protocols are used for each cell type

Question 78

How effective is viral infection as a transfection method?

Answer 78

High transfection efficiency

Question 79

How is viral infection manipulated for transfection?

Answer 79

Package viral components into plasmid and infect other cells Material release containing both viral components in the supernatant

Question 80

Name examples of viruses used to transfect cells

Answer 80

Retrovirus, Adenovirus, but most commonly Lentivirus are used

Question 81

What are the limitations of viral infection as a transfection method?

Answer 81

Target cells need to express the viral receptor to work There are safety aspects to consider