HEK cell

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Human Embryonic Kidney cells, also known as HEK cells, HEK 293 or just 293 cells, are a cell line originally derived, as their name indicates, from embryonic human kidney. HEK cells are not themselves particularly interesting, but are very easy to work with, and so are a widely-used cell line in cell biology research. It should be noted that cultures of the original (untransformed) HEK line have become contaminated with HeLa cells, which have displaced the cell line as originally established.

Origins of HEK Cells

HEK 293 cells were generated by transformation of cultures of normal human embryonic kidney cells with sheared adenovirus 5 DNA in the laboratory of Alex Van der Eb in Leiden, Holland in the early 70s. The human embryonic kidney cells were obtained from a healthy aborted fetus and originally cultured by Van der Eb himself, and the transformation by adenovirus was performed by Frank Graham who published his findings in the late 1970s after he left Leiden for McMaster University in Canada (Graham 1977[1]). They are called HEK for human embryonic kidney, while the number 293 comes from Graham's habit of numbering his experiments; the original HEK 293 cell clone was simply the product of his 293rd experiment.

Subsequent analysis has shown that the transformation was brought about by an insert consisting of ~4.5 kilobases from the left arm of the viral genome, which became incorporated into human chromosome 19 (Louis 1997[2]).

For many years it was assumed that HEK 293 cells were generated by transformation of either a fibroblastic, endothelial or epithelial cell all of which are abundant in kidney. However the fact that the cells originated from cultured kidney cells does not say much about the exact cellular origin of the HEK 293, as embryonic kidney cultures may contain small numbers of almost all cell types of the body. In fact Graham and coworkers more recently provided evidence that HEK 293 cells and several other human cell lines generated by adenovirus transformation of human embryonic kidney cells have many properties of immature neurons, suggesting that the adenovirus was taken up and transformed a neuronal lineage cell in the original kidney culture (Shaw et al. 2002[3]).

Uses of HEK 293 Cells

As an experimentally transformed cell line, HEK cells are not a particularly good model for normal cells, cancer cells, or any other kind of cell that is a fundamental object of research. However, they are extremely easy to work with, being straightforward to culture and to transfect, and so can be used in experiments in which the behaviour of the cell itself is not of interest. Typically, these experiments involve transfecting in a gene (or combination of genes) of interest, and then analysing the expressed protein; essentially, the cell is used simply as a test tube with a membrane. The widespread use of this cell line is due to its extreme transfectability by the calcium phosphate method, achieving efficiencies approaching 100% as determined by FACS using a 2XPBS buffer. A lower efficiency might be achievable with an HBS buffer.

An important variant of this cell line is the 293T cell line that contains, in addition, the SV40 large T antigen, that allows for episomal replication of transfected plasmids containing the SV40 origin of replication. This allows for amplification of transfected plasmids and extended temporal expression of the desired gene products. Note that any similarly domesticated cell line can be used for this sort of work; HeLa, COS and Chinese Hamster Ovary cell are common alternatives.

Examples of such experiments include:

• A study of the effects of a drug on sodium channels [4]
• Testing of an inducible RNA interference system [5]
• Testing of an isoform-selective protein kinase C agonist [6]
• Investigation of the interaction between two proteins [7]
• Analysis of a nuclear export signal in a protein [8]

A more specific use of HEK cells is in the propagation of adenoviral vectors. Viruses offer an extremely efficient means of delivering genes into cells, since this is what they have evolved to do, and are thus of great use as experimental tools. However, as pathogens, they also present a degree of danger to the experimenter. This danger can be avoided by the use of viruses which lack key genes, and which are thus unable to replicate after entering a cell. In order to propagate such viral vectors, a cell line that expresses the missing genes is required. Since HEK cells express a number of adenoviral genes, they can be used to propagate adenoviral vectors in which these genes (typically, E1 and E3) are deleted, such as AdEasy (He 1998).

293, and especially 293T, cells are commonly used for the production of lentiviral and retroviral vectors. Various retroviral and lentiviral packaging cell lines are based on these cells.

External links

• Maintaining HEK Cell Cultures
• Characterization of a human cell line transformed by DNA from human adenovirus type 5. Graham et al., J. Gen Virol 1977 Jul;36(1):59-74
• Cloning and sequencing of the cellular-viral junctions from the human adenovirus type 5 transformed 293 cell line - N. Louis, C. Evelegh, F. L. Graham, Virology 1997 Jul 7;233(2):423-9
• Preferential transformation of human neuronal cells by human adenoviruses and the origin of HEK 293 cells. Shaw et al. Faseb J Express 2002 Jun;16(8):869-71
• A simplified system for generating recombinant adenoviruses - T. C. He et al., Proc Natl Acad Sci USA 1998 Mar 3;95(5):2509-14
• HEK 293 Database
• 293 Cells in the ATCC database
• Transcript of FDA meeting, in which, starting page 77, Dr. Alex Van der Eb describes in detail the origin of HEK 293 cellde:HEK-Zellen

sv:HEK-celler

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Some of the initial content on this page may be incorporated in part from copyleft sources in the public domain including wikis such as Wikipedia and AskDrWiki. Drug information for patients came from the The National Library of Medicine. Infectious disease information may have come from the Centers for Disease Control (CDC). Differential Diagnoses are drawn from clinicians as well as an amalgamation of 3 sources: 1.The Disease Database; 2. Kahan, Scott, Smith, Ellen G. In A Page: Signs and Symptoms. Malden, Massachusetts: Blackwell Publishing, 2004:3; 3. Sailer, Christian, Wasner, Susanne. Differential Diagnosis Pocket. Hermosa Beach, CA: Borm Bruckmeir Publishing LLC, 2002:7 .