Immortalised cell line

Immortalised cell line

Scanning electron micrograph of an apoptotic HeLa cell. Zeiss Merlin HR-SEM.

HeLa cells, an example of an immortalised cell line. DIC image, DNA stained with Hoechst 33258.

Anatomical terminology

An immortalized cell line is a population of cells from a multicellular organism which would normally not proliferate indefinitely but, due to mutation, have evaded normal cellular senescence and instead can keep undergoing division. The cells can therefore be grown for prolonged periods in vitro. The mutations required for immortality can occur naturally or be intentionally induced for experimental purposes. Immortal cell lines are a very important tool for research into the biochemistry and cell biology of multicellular organisms. Immortalised cell lines have also found uses in biotechnology.

An immortalised cell line should not be confused with stem cells, which can also divide indefinitely, but form a normal part of the development of a multicellular organism.

Relation to natural biology and pathology

There are various immortal cell lines. Some of them are normal cell lines (e.g. derived from stem cells). Other immortalised cell lines are the in vitro equivalent of cancerous cells. Cancer occurs when a somatic cell which normally cannot divide undergoes mutations which cause de-regulation of the normal cell cycle controls leading to uncontrolled proliferation. Immortalised cell lines have undergone similar mutations allowing a cell type which would normally not be able to divide to be proliferated in vitro. The origins of some immortal cell lines, for example HeLa human cells, are from naturally occurring cancers.

Role and uses

Immortalised cell lines are widely used as a simple model for more complex biological systems, for example for the analysis of the biochemistry and cell biology of mammalian (including human) cells. The main advantage of using an immortal cell line for research is its immortality; the cells can be grown indefinitely in culture. This simplifies analysis of the biology of cells which may otherwise have a limited lifetime.

Immortalised cell lines can also be cloned giving rise to a clonal population which can, in turn, be propagated indefinitely. This allows an analysis to be repeated many times on genetically identical cells which is desirable for repeatable scientific experiments. The alternative, performing an analysis on primary cells from multiple tissue donors, does not have this advantage.

Immortalised cell lines find use in biotechnology where they are a cost-effective way of growing cells similar to those found in a multicellular organism in vitro. The cells are used for a wide variety of purposes, from testing toxicity of compounds or drugs to production of eukaryotic proteins.

Limitations

Changes from nonimmortal origins

While immortalised cell lines often originate from a well-known tissue type they have undergone significant mutations to become immortal. This can alter the biology of the cell and must be taken into consideration in any analysis. Further, cell lines can change genetically over multiple passages, leading to phenotypic differences among isolates and potentially different experimental results depending on when and with what strain isolate an experiment is conducted.[1]

Contamination with other cells

Many cell lines that are widely used for biomedical research have been contaminated and overgrown by other, more aggressive cells. For example, supposed thyroid lines were actually melanoma cells, supposed prostate tissue was actually bladder cancer, and supposed normal uterine cultures were actually breast cancer.[2]

Methods of generation

There are several methods for generating immortalised cell lines:[3]

  1. Isolation from a naturally occurring cancer. This is the original method for generating an immortalised cell line. Major examples include human HeLa cells that were obtained from a cervical cancer, mouse Raw 264.7 cells that were subjected to mutagenesis and then selected for cells which are able to undergo division.
  2. Introduction of a viral gene that partially deregulates the cell cycle (e.g., the adenovirus type 5 E1 gene was used to immortalize the HEK 293 cell line).
  3. Artificial expression of key proteins required for immortality, for example telomerase which prevents degradation of chromosome ends during DNA replication in eukaryotes
  4. Hybridoma technology, specifically used for the generation of immortalised antibody-producing B cell lines, where an antibody-producing B cell is fused with a myeloma (B cell cancer) cell.

Examples

There are several examples of immortalised cell lines, each with different properties. Most immortalised cell lines are classified by the cell type they originated from or are most similar to biologically.

See also

References

  1. Marx, Vivien (29 April 2014). "Cell-line authentication demystified". Technology Feature. Nature Methods (Paper "Nature Reprint Collection, Technology Features" (Nov 2014)). 11 (5): 483. doi:10.1038/nmeth.2932. (Registration required (help)).
  2. Jill Neimark (27 February 2015). "Line of attack". Science. 347 (6225): 938–940. doi:10.1126/science.347.6225.938.
  3. Irfan Maqsood, M.; Matin, M. M.; Bahrami, A. R.; Ghasroldasht, M. M. (2013). "Immortality of cell lines: Challenges and advantages of establishment". Cell Biology International. 37 (10): 103845. PMID 23723166. doi:10.1002/cbin.10137. (Subscription required (help)).
  4. Mugnai, G; Lewandowska, K; Culp, LA (Jun 1988). "Multiple and alternative adhesive responses on defined substrata of an immortalized dorsal root neuron hybrid cell line.". European Journal of Cell Biology (not available online). 46 (2): 35261. PMID 3169039.
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