Cell Culture Techniques

Question 1

Name some characteristics of Primary Cell Cultures

Answer 1

Characteristics of primary cell cultures include: Cells derived directly from tissues (unmodified) Finite lifespan (~6-7 divisions) They can be grown in 2D or 3D Cells divide and/or differentiate Cells carry out normal functions Good for personalised medicine

Question 2

What are examples of methods of isolation of cells?

Answer 2

1. Cells allowed to migrate out of an explant 2. Mechanical (mincing, sieving, pipetting) or/and enzymatic dissociation (trypsin, collagenase, hyaluronidase, protease, DNAase) Exception – Haemopoietic cells – Do not need to be disaggregated – They already are In which case, we can use eg density centrifugation and we can use eg Immuno-purification (uses antibodies) or Fluorescence activated cell sorter (FACS) (uses fluorescent markers) to isolate specific cells

Question 3

What are some examples of non-haematopoietic and haematopoietic primary cells?

Answer 3

Non-haematopoietic: Liver Endothelial cells Muscle Skin Nerves Fibroblasts Haematopoietic: Stem, progenitor cells T and B cells Monocytes, macrophages Osteoblasts Dendritic cells Neutrophils Dendritic cells Erythrocytes Platelets

Question 4

What are some disadvantages of primary cells?

Answer 4

Inter-patient variation Limited Finite lifespan (ie dont survive for longer than a week) Difficult molecular manipulation Phenotypic instability Aberrant expression of some genes Variable contamination

Question 5

What are some characteristics of Cell line cultures?

Answer 5

Immortalised cells Less limited number of cell divisions (~30) or unlimited (whereas much more limited with primary cells) They can be grown in 2D or 3D Phenotypically stable, defined population Limitless availability Easy to grow Good reproducibility Good model for basic science

Question 6

What are some methods of production for cell line cultures?

Answer 6

. Isolated from cancerous tissues (e.g. HeLa cells) 2. Immortalisation of primary cultures: a) Spontaneously from prolonged culture: multiple ill-defined mutations transformed phenotype b) Through genetic manipulation: artificial transformation of healthy primary cells Production through genetic manipulation To generate cell lines we target processes that regulate cellular growth and ageing - As cells divide over time, telomeres shorten, and eventually cell division stops → Apoptosis (p53, pRb)

Question 7

How can we inhibit the function of tumour suppressor proteins, or introduce telomerase in order to alter a cell’s capability for its finite number of divisions?

Answer 7

taking advantage of viral ‘oncoproteins Oncoproteins are proteins encoded by oncogenes which are involved in the regulation or synthesis of proteins linked to cancer tumour cell growth. Current oncoprotein research focuses on antibodies that can directly target the oncoproteins inside cancer cells and suppress aggressive cancer growth. eg virus: Human Papilloma Virus (HPV) viral oncoprotein: E6 E7 cellular targets: p53 pRb HPV’s E6 targets p53 for degradation, and E7 binds to pRb inactivating it Cell lines made using E6/ E7 oncoproteins are believed to maintain a differentiated phenotype - The telomerase gene can also be introduced into a target primary cell. - Some cells need both introduction of the telomerase gene and inactivation of the pRb/p53 for “immortalisation”

basically nicola’s voicenote made sense but the above doesnt:

so looking at the second part of ‘finite’ so in a primary cell, there is a finite number that the cell can divide and if it divides more than that number, it will die-apoptosis and that number is 50(hayflicks constant!?) but that is what we want to prevent! we want to turn primary cells into cell lines so we can use as a culture add drugs etc becuase we can’t directly do that to primary cells as they will die (ie adding stuff to see how they respond etc),

we therefore need to do 2 things:

1. remove tumour supressors from primary cells
2. induce telomerase (you want to integrate telomerase into your primary cells) (which affects telomeres by adding a specific sequence to the end of the ) chromosome) but essentilaly telomerase is causing the cancer eg to be prominent- it allows the cancer to have that infinite number of divisions, and causes the tumour supressors to not supress the tumour.

the break and the accelerator analogy:

the break is the tumour suppressor- so you get rid of that (foot now on pedal) but you want the telomerase but essentially theres no stop to it- uncontrolled division

Question 8

What conditions and requirements are required for growth in cultures?

Answer 8

-Handled under aseptic conditions - Grown on tissue culture treated plastic flasks/dishes -Maintained in a warm (37°C) humidified atmosphere (5% CO2) -ideal supplemented medium that needs replacing every 2/3 days! if medium is yellow=acidic, if medium is tomato red= neutral, if medium is red to purple in colour= basic

Question 9

What are types of cell culture contamination that are a potential hazard?

Answer 9

• 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 10

What can cause cell line cross contamination?

Answer 10

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

Question 11

What are some differences between organoid and spheroid 3D cultures?

Answer 11

cells are grown in suspension, which bunch together and form a bigger blob of cells (known as organoids or spheroids) organoids and spheroids are helpful for modelling specific organs in the body Organoid: derived from stem cells multiple cell lineages long term culture eg so you can take a biopsy/sample of the tumour and grow organoid samples so you can test different drugs etc before giving it to the patient! Spheroid: derived from cell line monoculture represent single/partial tissue components difficult to maintain long term

Question 12

What are some advantages of organoids?

Answer 12

Advantages: - 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 13

What are some limitations of organoids?

Answer 13

Limitations: - 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 14

What is transfection?

Answer 14

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

Question 15

What does lipofection involve? (as a method of transfection)

Answer 15

Using cationic lipid transfection systems Lipofection- introduces DNA into cells through liposomes(vesicles which can easily merge with the cell membrane of the eukaryotic cell because liposomes are made with phospholipid bilayers) liposomes have a net positive charge 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 so cell expresses gene/material we have introduced better used for when material is small so liposomes are used as potential drug delivery carriers

Question 16

What does electroporation involve? (as a method of transfection)

Answer 16

where an electric field is applied to cells to increase their permeability to allow chemicals/drugs etc to be introduced into cells etc

Question 17

What is nucleofection? (as a method of transfection)

Answer 17

(so you can deliver material straight to the nucleus) - Combination of electroporation and lipofection - Increased efficiency particularly of non-dividing cells - Technology is protected under patent - Different solution and protocols are used for each cell type

Question 18

What does viral infection/transduction involve? *not a method of transfection

Answer 18

• Exploits the mechanism of viral infection. - High transfection efficiency. - Retrovirus, Adenovirus, but most commonly Lentivirus are used. - Target cells need to express the viral receptor to work. - There are safety aspects to Consider.

You start with putting universal saline eg HEK293T into contact with vectors containing the gene of interest.

Collect supernatant (whch is produced as hek293t cells translate gene of interest etc?) then inject cells of interest with that supernatant.

Question 19

Summary of the lecture

Answer 19

To overcome the short comings of primary cultures, cell lines have been produced Cell lines can be spontaneously induced or produced by transfection with viral oncogenes that inhibit tumour suppressor genes or by introducing/over-expressing telomerase. Cell transfection can be carry out using chemical, physical or viral methods. Rapidly dividing cells can lose differentiated functions → need for different models- Organoids

Question 20

Comparison summary table of primary cells and cell lines

Answer 20