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Tuesday, February 9, 2010

Cell culture

Cell culture

Cell culture is the process by which cells are grown under controlled conditions. In practice the term "cell culture" has come to refer to the culturing of cells derived from multicellular eukaryotes, especially animal cells. The historical development and methods of cell culture are closely interrelated to those of tissue culture and organ culture.
Animal cell culture became a common laboratory technique in the mid-1900s,[1] but the concept of maintaining live cell lines separated from their original tissue source was discovered in the 19th century.[2]

History

The 19th-century English physiologist Sydney Ringer developed salt solutions containing the chlorides of sodium, potassium, calcium and magnesium suitable for maintaining the beating of an isolated animal heart outside of the body.[1] In 1885 Wilhelm Roux removed a portion of the medullary plate of an embryonic chicken and maintained it in a warm saline solution for several days, establishing the principle of tissue culture.[3] Ross Granville Harrison, working at Johns Hopkins Medical School and then at Yale University, published results of his experiments from 1907–1910, establishing the methodology of tissue culture.[4]
Cell culture techniques were advanced significantly in the 1940s and 1950s to support research in virology. Growing viruses in cell cultures allowed preparation of purified viruses for the manufacture of vaccines. The Salk polio vaccine was one of the first products mass-produced using cell culture techniques. This vaccine was made possible by the cell culture research of John Franklin Enders, Thomas Huckle Weller, and Frederick Chapman Robbins, who were awarded a Nobel Prize for their discovery of a method of growing the virus in monkey kidney cell cultures.

[edit] Concepts in mammalian cell culture

[edit] Isolation of cells

Cells can be isolated from tissues for ex vivo culture in several ways. Cells can be easily purified from blood, however only the white cells are capable of growth in culture. Mononuclear cells can be released from soft tissues by enzymatic digestion with enzymes such as collagenase, trypsin, or pronase, which break down the extracellular matrix. Alternatively, pieces of tissue can be placed in growth media, and the cells that grow out are available for culture. This method is known as explant culture.
Cells that are cultured directly from a subject are known as primary cells. With the exception of some derived from tumors, most primary cell cultures have limited lifespan. After a certain number of population doublings cells undergo the process of senescence and stop dividing, while generally retaining viability.
An established or immortalised cell line has acquired the ability to proliferate indefinitely either through random mutation or deliberate modification, such as artificial expression of the telomerase gene. There are numerous well established cell lines representative of particular cell types.

[edit] Maintaining cells in culture

Cells are grown and maintained at an appropriate temperature and gas mixture (typically, 37°C, 5% CO2 for mammalian cells) in a cell incubator. Culture conditions vary widely for each cell type, and variation of conditions for a particular cell type can result in different phenotypes being expressed.
Aside from temperature and gas mixture, the most commonly varied factor in culture systems is the growth medium. Recipes for growth media can vary in pH, glucose concentration, growth factors, and the presence of other nutrients. The growth factors used to supplement media are often derived from animal blood, such as calf serum. One complication of these blood-derived ingredients is the potential for contamination of the culture with viruses or prions, particularly in biotechnology medical applications. Current practice is to minimize or eliminate the use of these ingredients wherever possible, but this cannot always be accomplished. Alternative strategies involve sourcing the animal blood from countries with minimum BSE/TSE risk such as Australia and New Zealand, and using purified nutrient concentrates derived from serum in place of whole animal serum for cell culture.[5]
Cells can be grown in suspension or adherent cultures. Some cells naturally live in suspension, without being attached to a surface, such as cells that exist in the bloodstream. There are also cell lines that have been modified to be able to survive in suspension cultures so that they can be grown to a higher density than adherent conditions would allow. Adherent cells require a surface, such as tissue culture plastic or microcarrier, which may be coated with extracellular matrix components to increase adhesion properties and provide other signals needed for growth and differentiation. Most cells derived from solid tissues are adherent. Another type of adherent culture is organotypic culture which involves growing cells in a three-dimensional environment as opposed to two-dimensional culture dishes. This 3D culture system is biochemically and physiologically more similar to in vivo tissue, but is technically challenging to maintain because of many factors (e.g. diffusion).

[edit] Cell line cross-contamination

Cell line cross-contamination can be a problem for scientists working with cultured cells. Studies suggest that anywhere from 15–20% of the time, cells used in experiments have been misidentified or contaminated with another cell line.[6][7][8] Problems with cell line cross contamination have even been detected in lines from the NCI-60 panel, which are used routinely for drug-screening studies.[9][10] Major cell line repositories including the American Type Culture Collection (ATCC) and the German Collection of Microorganisms and Cell Cultures (DSMZ) have received cell line submissions from researchers that were misidentified by the researcher.[9][11] Such contamination poses a problem for the quality of research produced using cell culture lines, and the major repositories are now authenticating all cell line submissions.[12] ATCC uses short tandem repeat (STR) DNA fingerprinting to authenticate its cell lines.[13]
To address this problem of cell line cross-contamination, researchers are encouraged to authenticate their cell lines at an early passage to establish the identity of the cell line. Authentication should be repeated before freezing cell line stocks, every two months during active culturing and before any publication of research data generated using the cell lines. There are many methods for identifying cell lines including isoenzyme analysis, human lymphocyte antigen (HLA) typing and STR analysis.[13]
One significant cell-line cross contaminant is the immortal HeLa cell line.

[edit] Manipulation of cultured cells

As cells generally continue to divide in culture, they generally grow to fill the available area or volume. This can generate several issues:
Among the common manipulations carried out on culture cells are media changes, passaging cells, and transfecting cells. These are generally performed using tissue culture methods that rely on sterile technique. Sterile technique aims to avoid contamination with bacteria, yeast, or other cell lines. Manipulations are typically carried out in a biosafety hood or laminar flow cabinet to exclude contaminating micro-organisms. Antibiotics (e.g. penicillin and streptomycin) and antifungals (e.g. Amphotericin B) can also be added to the growth media.
As cells undergo metabolic processes, acid is produced and the pH decreases. Often, a pH indicator is added to the medium in order to measure nutrient depletion.

[edit] Media changes

In the case of adherent cultures, the media can be removed directly by aspiration and replaced.

[edit] Passaging cells

Main article: Passaging
Passaging (also known as subculture or splitting cells) involves transferring a small number of cells into a new vessel. Cells can be cultured for a longer time if they are split regularly, as it avoids the senescence associated with prolonged high cell density. Suspension cultures are easily passaged with a small amount of culture containing a few cells diluted in a larger volume of fresh media. For adherent cultures, cells first need to be detached; this is commonly done with a mixture of trypsin-EDTA, however other enzyme mixes are now available for this purpose. A small number of detached cells can then be used to seed a new culture.

[edit] Transfection and transduction

Main article: transfection
Main article: transformation (genetics)
Another common method for manipulating cells involves the introduction of foreign DNA by transfection. This is often performed to cause cells to express a protein of interest. More recently, the transfection of RNAi constructs have been realized as a convenient mechanism for suppressing the expression of a particular gene/protein.
DNA can also be inserted into cells using viruses, in methods referred to as transduction, infection or transformation. Viruses, as parasitic agents, are well suited to introducing DNA into cells, as this is a part of their normal course of reproduction.

[edit] Established human cell lines

One of the earliest human cell lines, descended from Henrietta Lacks, who died of the cancer that those cells originated from, the cultured HeLa cells shown here have been stained with Hoechst turning their nuclei blue.
Cell lines that originate with humans have been somewhat controversial in bioethics, as they may outlive their parent organism and later be used in the discovery of lucrative medical treatments. In the pioneering decision in this area, the Supreme Court of California held in Moore v. Regents of the University of California that human patients have no property rights in cell lines derived from organs removed with their consent.[14]

[edit] Generation of hybridomas

For more details on this topic, see Hybridoma.
It is possible to fuse normal cells with an immortalised cell line. This method is used to produce monoclonal antibodies. In brief, lymphocytes isolated from the spleen (or possibly blood) of an immunised animal are combined with an immortal myeloma cell line (B cell lineage) to produce a hybridoma which has the antibody specificity of the primary lymphoctye and the immortality of the myeloma. Selective growth medium (HA or HAT) is used to select against unfused myeloma cells; primary lymphoctyes die quickly in culture and only the fused cells survive. These are screened for production of the required antibody, generally in pools to start with and then after single cloning.

[edit] Applications of cell culture

Mass culture of animal cell lines is fundamental to the manufacture of viral vaccines and many products of biotechnology. Biological products produced by recombinant DNA (rDNA) technology in animal cell cultures include enzymes, synthetic hormones, immunobiologicals (monoclonal antibodies, interleukins, lymphokines), and anticancer agents. Although many simpler proteins can be produced using rDNA in bacterial cultures, more complex proteins that are glycosylated (carbohydrate-modified) currently must be made in animal cells. An important example of such a complex protein is the hormone erythropoietin. The cost of growing mammalian cell cultures is high, so research is underway to produce such complex proteins in insect cells or in higher plants, use of single embryonic cell and somatic embryos as a source for direct gene transfer via practicle bombardment, transit gene expression and confocal microscopy observation is one of its applications. It also offers to confirm single cell origin of somatic embryos and the asymmetry of the first cell division, which starts the process.

[edit] Tissue culture and engineering

Cell culture is a fundamental component of tissue culture and tissue engineering, as it establishes the basics of growing and maintaining cells ex vivo. The major application of human cell culture is in stem cell industry where mesenchymal stem cells can be cultured and cryopreserved for future use.

[edit] Vaccines

Vaccines for polio, measles, mumps, rubella, and chickenpox are currently made in cell cultures. Due to the H5N1 pandemic threat, research into using cell culture for influenza vaccines is being funded by the United States government. Novel ideas in the field include recombinant DNA-based vaccines, such as one made using human adenovirus (a common cold virus) as a vector,[15][16] or the use of adjuvants.[17]

[edit] Culture of non-mammalian cells

[edit] Plant cell culture methods

See also: Tobacco BY-2 cells
Plant cell cultures are typically grown as cell suspension cultures in liquid medium or as callus cultures on solid medium. The culturing of undifferentiated plant cells and calli requires the proper balance of the plant growth hormones auxin and cytokinin.

[edit] Bacterial/Yeast culture methods

Main article: microbiological culture
For bacteria and yeast, small quantities of cells are usually grown on a solid support that contains nutrients embedded in it, usually a gel such as agar, while large-scale cultures are grown with the cells suspended in a nutrient broth.

[edit] Viral culture methods

Main article: Viral culture
The culture of viruses requires the culture of cells of mammalian, plant, fungal or bacterial origin as hosts for the growth and replication of the virus. Whole wild type viruses, recombinant viruses or viral products may be generated in cell types other than their natural hosts under the right conditions. Depending on the species of the virus, infection and viral replication may result in host cell lysis and formation of a viral plaque.

[edit] Common cell lines

Human cell lines
Primate cell lines
Rat tumor cell lines
Mouse cell lines
Plant cell lines
Other species cell lines

[edit] List of cell lines

Cell line  ↓ Meaning  ↓ Organism  ↓ Origin tissue  ↓ Morphology  ↓ Link  ↓
293-T
Human kidney (embryonic)
Derivative of HEK 293ECACC
3T3 cells "3-day transfer, inoculum 3 x 105 cells" Mouse embryonic fibroblast
Also known as NIH 3T3 ECACC
721
Human melanoma

9L
Rat glioblastoma

A2780
Human Ovary Ovarian Cancer ECACC
A2780ADR
Human Ovary Adriamycin-resistant derivative ECACC
A2780cis
Human Ovary Cisplatin-resistant derivative ECACC
A172
human glioblastoma malignant glioma ECACC
A20
murine B lymphoma B lymphocyte
A253
human head and neck carcinoma submandibular duct
A431
human skin epithelium squamous carcinoma ECACCCell Line Data Base
A-549
human lungcarcinoma epithelium DSMZECACC
ALC
murine bone marrow stroma PubMed
B16
murine Melanoma
ECCAC
B35
rat Neuroblastoma
ATCC
BCP-1 cells
Human PBMC HIV+ lymphoma ATCC
BEAS-2B bronchial epithelium + adenovirus 12-SV40 virus hybrid (Ad12SV40) Human lung epithelial ATCC
bEnd.3 brain endothelial mouse brain / cerebral cortex endothelium ATCC
BHK-21 "Baby Hamster Kidney Fibroblast cells" Hamster kidney fibroblast ECACCOlympus
BR 293
human breast breast cancer
BxPC3 Biopsy xenograph of pancreatic carcinoma line 3 human pancreatic adenocarcinoma epithelial ATCC
C3H-10T1/2
Mouse Embryonic mesenchymal cell line
ECACC
C6/36
Asian tiger mosquito larval tissue
ECACC
Cal-27
human tongue squamous cell carcinoma
CHO Chinese hamster ovary hamster Ovary epithelium ECACCICLC
COR-L23
Human Lung
ECACC
COR-L23/CPR
Human Lung
ECACC
COR-L23/5010
Human Lung
ECACC
COR-L23/R23
Human Lung Epithelial ECACC
COS-7 Cercopithecus aethiops, origin-defective SV-40 ape - Cercopithecus aethiops (Chlorocebus) kidney fibroblast ECACCATCC
CML T1 Chronic Myelod Leukaemia T-lymphocyte 1 human CML acute phase T cell leukaemia Blood
CMT canine mammary tumor dog mammary gland epithelium
CT26
murine Colorectal Carcinoma Colon
D17
canine osteosarcoma
ECACC
DH82
canine histiocytosis monocyte/macrophage ECACC J Vir Meth
DU145
human Androgen insensitive carcinoma Prostate
DuCaP Dura mater Cancer of the Prostate human Metastatic Prostate Cancer epithelial PubMed
EL4
mouse
T cell leukaemia ECACC
EM2
human CML blast crisis Ph+ CML line Cell Line Data Base
EM3
human CML blast crisis Ph+ CML line Cell Line Data Base
EMT6/AR1
mouse Breast Epithelial-like ECACC
EMT6/AR10.0
Mouse Breast Epithelial-like ECACC
FM3
human Metastatic lymph node melanoma
H1299
human lung lung cancer
H69
Human Lung
ECACC
HB54
hybridoma hybridoma secretes L243 mAb (against HLA-DR) Human Immunology
HB55
hybridoma hybridoma secretes MA2.1 mAb (against HLA-A2 and HLA-B17) Journal of Immunology
HCA2
human fibroblast
Journal of General Virology
HEK-293 human embryonic kidney human kidney (embryonic) epithelium ATCC
HeLa Henrietta Lacks human Cervical cancer epithelium DSMZECACC
Hepa1c1c7 clone 7 of clone 1 hepatoma line 1 mouse Hepatoma epithelial ECACC ATCC
HL-60 human leukemia human Myeloblast bloodcells ECACCDSMZ
HMEC human mammary epithelial cell human
epithelium ECACC
HT-29
human colon epithelium adenocarcinoma ECACC Cell Line Data Base
Jurkat
human T-Cell-Leukemia white blood cells ECACC DSMZ
JY cells
human lymphoblastoid EBV immortalised B cell
K562 cells
human lymphoblastoid CML blast crisis ECACC
Ku812
human lymphoblastoid erythroleukemia ECACC LGCstandards
KCL22
human lymphoblastoid CML
KG1
human lymphoblastoid AML
KYO1 Kyoto 1 human lymphoblastoid CML DSMZ
LNCap Lymph node Cancer of the Prostate human prostatic adenocarcinoma epithelial ECACCATCC
Ma-Mel 1, 2, 3....48
human
a range of melanoma cell lines
MC-38
mouse
adenocarcinoma
MCF-7 Michigan Cancer Foundation-7 human mammary gland invasive breast ductal carcinoma ER+, PR+
MCF-10A Michigan Cancer Foundation human mammary gland epithelium ATCC
MDA-MB-231 M.D. Anderson - Metastatic Breast human breast cancer ECACC
MDA-MB-468 M.D. Anderson - Metastatic Breast human breast cancer ECACC
MDA-MB-435 M.D. Anderson - Metastatic Breast human breast melanoma or carcinoma (disputed) Cambridge Pathology ECACC
MDCK II Madin Darby canine kidney dog kidney epithelium ECACC ATCC
MDCK II Madin Darby canine kidney dog kidney epithelium [2] ATCC
MOR/0.2R
Human Lung
ECACC
MONO-MAC 6
human WBC myeloid metaplasic AML Cell Line Data Base
MTD-1A
mouse
epithelium
MyEnd myocardial endothelial mouse
endothelium
NCI-H69/CPR
Human Lung
ECACC
NCI-H69/LX10
Human Lung
ECACC
NCI-H69/LX20
Human Lung
ECACC
NCI-H69/LX4
Human Lung
ECACC
NIH-3T3 NIH, 3-day transfer, inoculum 3 x 105 cells mouse embryo fibroblast ECACCATCC
NALM-1

peripheral blood blast-crisis CML Cancer Genetics and Cytogenetics
NW-145


melanoma ESTDAB
OPCN / OPCT cell lines Onyvax[3] Prostate Cancer....

Range of prostate tumour lines Asterand
Peer
human T cell leukemia
DSMZ
PNT-1A / PNT 2


Prostate tumour lines ECACC
RenCa Renal Carcinoma mouse
renal carcinoma
RIN-5F
mouse pancreas

RMA/RMAS
mouse
T cell tumour
Saos-2 cells
human
Osteosarcoma ECACC
Sf-9 Spodoptera frugiperda insect - Spodoptera frugiperda (moth) Ovary
DSMZECACC
SkBr3
human
breast carcinoma
T2
human
T cell leukemia/B cell line hybridoma DSMZ
T-47D
human mammary gland ductal carcinoma
T84
human colorectal Carcinoma / lungmetastasis epithelium ECACCATCC
THP1 cell line
human monocyte AML ECACC
U373
human glioblastoma-astrocytoma epithelium
U87
human glioblastoma-astrocytoma epithelial-like Abcam
U937
human leukaemic monocytic lymphoma
ECACC
VCaP Vertebra Prostate Cancer human metastatic prostate cancer epithelial ECACC ATCC
Vero cells 'Vera Reno' ('green kidney') / 'Vero' ('truth') African Green Monkey kidney epithelium
ECACC
WM39
human skin primary melanoma
WT-49
human lymphoblastoid

X63
mouse melanoma

YAC-1
mouse lymphoma
Cell Line Data Base ECACC
YAR
human B-cell EBV transofrmed [4] Human Immunology
Note: this list is a sample of available cell lines, and is not comprehensive

[edit] See also

[edit] References and notes

  1. ^ ""Cell Culture"". http://www.bioteach.ubc.ca/Bioengineering/CellCulture/index.htm. Retrieved 2006-04-19. 
  2. ^ ""Some landmarks in the development of tissue and cell culture."". http://www.ncbi.nlm.nih.gov/books/bv.fcgi?db=Books&rid=mboc4.table.1516. Retrieved 2006-04-19. 
  3. ^ ""Animals and alternatives in testing."". http://caat.jhsph.edu/pubs/animal_alts/appendix_c.htm. Retrieved 2006-04-19. 
  4. ^ Schiff, Judith Ann. ""An unsung hero of medical research."". http://www.yalealumnimagazine.com/issues/02_02/old_yale.html. Retrieved 2006-04-19.  Yale Alumni Magazine, February 2002.
  5. ^ "LipiMAX purified lipoprotein solution from bovine serum". Selborne Biological Services. 2006. http://www.selbornebiological.com/products/lipimax.htm. Retrieved 2010-02-02. 
  6. ^ Drexler, HG; Dirks; Macleod (Oct 1999). "False human hematopoietic cell lines: cross-contaminations and misinterpretations". Leukemia 13 (10): 1601–7. doi:10.1038/sj/leu/2401510. ISSN 0887-6924. PMID 10516762. 
  7. ^ Drexler, HG; Macleod; Dirks (Dec 2001). "Cross-contamination: HS-Sultan is not a myeloma but a Burkitt lymphoma cell line" (Free full text). Blood 98 (12): 3495–6. doi:10.1182/blood.V98.12.3495. ISSN 0006-4971. PMID 11732505. http://www.bloodjournal.org/cgi/pmidlookup?view=long&pmid=11732505. 
  8. ^ Cabrera, CM; Cobo, F; Nieto, A; Cortés, JL; Montes, RM; Catalina, P; Concha, A (Jun 2006). "Identity tests: determination of cell line cross-contamination". Cytotechnology 51 (2): 45–50. doi:10.1007/s10616-006-9013-8. ISSN 0920-9069. PMID 19002894. 
  9. ^ a b Chatterjee, R (Feb 2007). "Cell biology. Cases of mistaken identity.". Science (New York, N.Y.) 315 (5814): 928–31. doi:10.1126/science.315.5814.928. ISSN 0036-8075. PMID 17303729. 
  10. ^ Liscovitch, M; Ravid (Jan 2007). "A case study in misidentification of cancer cell lines: MCF-7/AdrR cells (re-designated NCI/ADR-RES) are derived from OVCAR-8 human ovarian carcinoma cells.". Cancer letters 245 (1-2): 350–2. doi:10.1016/j.canlet.2006.01.013. ISSN 0304-3835. PMID 16504380. 
  11. ^ Macleod, RA; Dirks; Matsuo; Kaufmann; Milch; Drexler (Nov 1999). "Widespread intraspecies cross-contamination of human tumor cell lines arising at source.". International journal of cancer. Journal international du cancer 83 (4): 555–63. ISSN 0020-7136. PMID 10508494. 
  12. ^ Masters, JR (Apr 2002). "HeLa cells 50 years on: the good, the bad and the ugly.". Nature reviews. Cancer 2 (4): 315–9. doi:10.1038/nrc775. ISSN 1474-175X. PMID 12001993. 
  13. ^ a b Dunham, J.H. and Guthmiller, P. (2008) Doing good science: Authenticating cell line identity. Cell Notes 22, 15–17.
  14. ^ Ceb.com
  15. ^ Reuters (2006-01-26). Wired.com "Quickie Bird Flu Vaccine Created". Wired. http://wired.com/news/wireservice/0,70102-0.html?tw=wn_index_7 Wired.com. Retrieved 2010-01-31. 
  16. ^ Gao W, Soloff AC, Lu X, Montecalvo A, Nguyen DC, Matsuoka Y, Robbins PD, Swayne DE, Donis RO, Katz JM, Barratt-Boyes SM, Gambotto A. (February 2006). "Protection of mice and poultry from lethal H5N1 avian influenza virus through adenovirus-based immunization". Journal of Virology (United States: American Society for Microbiology) 80 (4): 1959–1964. doi:10.1128/JVI.80.4.1959-1964.2006. ISSN 0022-538X. http://jvi.asm.org/cgi/content/abstract/80/4/1959. Retrieved 2010-01-31. 
  17. ^ "NIAID Taps Chiron to Develop Vaccine Against H9N2 Avian Influenza". National Institute of Allergy and Infectious Diseases (NIAID). 2004-08-17. http://www3.niaid.nih.gov/news/newsreleases/2004/h9n2.htm. Retrieved 2010-01-31. 

[edit] External links

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Tuesday, February 9, 2010

Cell culture

Cell culture

Cell culture is the process by which cells are grown under controlled conditions. In practice the term "cell culture" has come to refer to the culturing of cells derived from multicellular eukaryotes, especially animal cells. The historical development and methods of cell culture are closely interrelated to those of tissue culture and organ culture.
Animal cell culture became a common laboratory technique in the mid-1900s,[1] but the concept of maintaining live cell lines separated from their original tissue source was discovered in the 19th century.[2]

History

The 19th-century English physiologist Sydney Ringer developed salt solutions containing the chlorides of sodium, potassium, calcium and magnesium suitable for maintaining the beating of an isolated animal heart outside of the body.[1] In 1885 Wilhelm Roux removed a portion of the medullary plate of an embryonic chicken and maintained it in a warm saline solution for several days, establishing the principle of tissue culture.[3] Ross Granville Harrison, working at Johns Hopkins Medical School and then at Yale University, published results of his experiments from 1907–1910, establishing the methodology of tissue culture.[4]
Cell culture techniques were advanced significantly in the 1940s and 1950s to support research in virology. Growing viruses in cell cultures allowed preparation of purified viruses for the manufacture of vaccines. The Salk polio vaccine was one of the first products mass-produced using cell culture techniques. This vaccine was made possible by the cell culture research of John Franklin Enders, Thomas Huckle Weller, and Frederick Chapman Robbins, who were awarded a Nobel Prize for their discovery of a method of growing the virus in monkey kidney cell cultures.

[edit] Concepts in mammalian cell culture

[edit] Isolation of cells

Cells can be isolated from tissues for ex vivo culture in several ways. Cells can be easily purified from blood, however only the white cells are capable of growth in culture. Mononuclear cells can be released from soft tissues by enzymatic digestion with enzymes such as collagenase, trypsin, or pronase, which break down the extracellular matrix. Alternatively, pieces of tissue can be placed in growth media, and the cells that grow out are available for culture. This method is known as explant culture.
Cells that are cultured directly from a subject are known as primary cells. With the exception of some derived from tumors, most primary cell cultures have limited lifespan. After a certain number of population doublings cells undergo the process of senescence and stop dividing, while generally retaining viability.
An established or immortalised cell line has acquired the ability to proliferate indefinitely either through random mutation or deliberate modification, such as artificial expression of the telomerase gene. There are numerous well established cell lines representative of particular cell types.

[edit] Maintaining cells in culture

Cells are grown and maintained at an appropriate temperature and gas mixture (typically, 37°C, 5% CO2 for mammalian cells) in a cell incubator. Culture conditions vary widely for each cell type, and variation of conditions for a particular cell type can result in different phenotypes being expressed.
Aside from temperature and gas mixture, the most commonly varied factor in culture systems is the growth medium. Recipes for growth media can vary in pH, glucose concentration, growth factors, and the presence of other nutrients. The growth factors used to supplement media are often derived from animal blood, such as calf serum. One complication of these blood-derived ingredients is the potential for contamination of the culture with viruses or prions, particularly in biotechnology medical applications. Current practice is to minimize or eliminate the use of these ingredients wherever possible, but this cannot always be accomplished. Alternative strategies involve sourcing the animal blood from countries with minimum BSE/TSE risk such as Australia and New Zealand, and using purified nutrient concentrates derived from serum in place of whole animal serum for cell culture.[5]
Cells can be grown in suspension or adherent cultures. Some cells naturally live in suspension, without being attached to a surface, such as cells that exist in the bloodstream. There are also cell lines that have been modified to be able to survive in suspension cultures so that they can be grown to a higher density than adherent conditions would allow. Adherent cells require a surface, such as tissue culture plastic or microcarrier, which may be coated with extracellular matrix components to increase adhesion properties and provide other signals needed for growth and differentiation. Most cells derived from solid tissues are adherent. Another type of adherent culture is organotypic culture which involves growing cells in a three-dimensional environment as opposed to two-dimensional culture dishes. This 3D culture system is biochemically and physiologically more similar to in vivo tissue, but is technically challenging to maintain because of many factors (e.g. diffusion).

[edit] Cell line cross-contamination

Cell line cross-contamination can be a problem for scientists working with cultured cells. Studies suggest that anywhere from 15–20% of the time, cells used in experiments have been misidentified or contaminated with another cell line.[6][7][8] Problems with cell line cross contamination have even been detected in lines from the NCI-60 panel, which are used routinely for drug-screening studies.[9][10] Major cell line repositories including the American Type Culture Collection (ATCC) and the German Collection of Microorganisms and Cell Cultures (DSMZ) have received cell line submissions from researchers that were misidentified by the researcher.[9][11] Such contamination poses a problem for the quality of research produced using cell culture lines, and the major repositories are now authenticating all cell line submissions.[12] ATCC uses short tandem repeat (STR) DNA fingerprinting to authenticate its cell lines.[13]
To address this problem of cell line cross-contamination, researchers are encouraged to authenticate their cell lines at an early passage to establish the identity of the cell line. Authentication should be repeated before freezing cell line stocks, every two months during active culturing and before any publication of research data generated using the cell lines. There are many methods for identifying cell lines including isoenzyme analysis, human lymphocyte antigen (HLA) typing and STR analysis.[13]
One significant cell-line cross contaminant is the immortal HeLa cell line.

[edit] Manipulation of cultured cells

As cells generally continue to divide in culture, they generally grow to fill the available area or volume. This can generate several issues:
Among the common manipulations carried out on culture cells are media changes, passaging cells, and transfecting cells. These are generally performed using tissue culture methods that rely on sterile technique. Sterile technique aims to avoid contamination with bacteria, yeast, or other cell lines. Manipulations are typically carried out in a biosafety hood or laminar flow cabinet to exclude contaminating micro-organisms. Antibiotics (e.g. penicillin and streptomycin) and antifungals (e.g. Amphotericin B) can also be added to the growth media.
As cells undergo metabolic processes, acid is produced and the pH decreases. Often, a pH indicator is added to the medium in order to measure nutrient depletion.

[edit] Media changes

In the case of adherent cultures, the media can be removed directly by aspiration and replaced.

[edit] Passaging cells

Main article: Passaging
Passaging (also known as subculture or splitting cells) involves transferring a small number of cells into a new vessel. Cells can be cultured for a longer time if they are split regularly, as it avoids the senescence associated with prolonged high cell density. Suspension cultures are easily passaged with a small amount of culture containing a few cells diluted in a larger volume of fresh media. For adherent cultures, cells first need to be detached; this is commonly done with a mixture of trypsin-EDTA, however other enzyme mixes are now available for this purpose. A small number of detached cells can then be used to seed a new culture.

[edit] Transfection and transduction

Main article: transfection
Main article: transformation (genetics)
Another common method for manipulating cells involves the introduction of foreign DNA by transfection. This is often performed to cause cells to express a protein of interest. More recently, the transfection of RNAi constructs have been realized as a convenient mechanism for suppressing the expression of a particular gene/protein.
DNA can also be inserted into cells using viruses, in methods referred to as transduction, infection or transformation. Viruses, as parasitic agents, are well suited to introducing DNA into cells, as this is a part of their normal course of reproduction.

[edit] Established human cell lines

One of the earliest human cell lines, descended from Henrietta Lacks, who died of the cancer that those cells originated from, the cultured HeLa cells shown here have been stained with Hoechst turning their nuclei blue.
Cell lines that originate with humans have been somewhat controversial in bioethics, as they may outlive their parent organism and later be used in the discovery of lucrative medical treatments. In the pioneering decision in this area, the Supreme Court of California held in Moore v. Regents of the University of California that human patients have no property rights in cell lines derived from organs removed with their consent.[14]

[edit] Generation of hybridomas

For more details on this topic, see Hybridoma.
It is possible to fuse normal cells with an immortalised cell line. This method is used to produce monoclonal antibodies. In brief, lymphocytes isolated from the spleen (or possibly blood) of an immunised animal are combined with an immortal myeloma cell line (B cell lineage) to produce a hybridoma which has the antibody specificity of the primary lymphoctye and the immortality of the myeloma. Selective growth medium (HA or HAT) is used to select against unfused myeloma cells; primary lymphoctyes die quickly in culture and only the fused cells survive. These are screened for production of the required antibody, generally in pools to start with and then after single cloning.

[edit] Applications of cell culture

Mass culture of animal cell lines is fundamental to the manufacture of viral vaccines and many products of biotechnology. Biological products produced by recombinant DNA (rDNA) technology in animal cell cultures include enzymes, synthetic hormones, immunobiologicals (monoclonal antibodies, interleukins, lymphokines), and anticancer agents. Although many simpler proteins can be produced using rDNA in bacterial cultures, more complex proteins that are glycosylated (carbohydrate-modified) currently must be made in animal cells. An important example of such a complex protein is the hormone erythropoietin. The cost of growing mammalian cell cultures is high, so research is underway to produce such complex proteins in insect cells or in higher plants, use of single embryonic cell and somatic embryos as a source for direct gene transfer via practicle bombardment, transit gene expression and confocal microscopy observation is one of its applications. It also offers to confirm single cell origin of somatic embryos and the asymmetry of the first cell division, which starts the process.

[edit] Tissue culture and engineering

Cell culture is a fundamental component of tissue culture and tissue engineering, as it establishes the basics of growing and maintaining cells ex vivo. The major application of human cell culture is in stem cell industry where mesenchymal stem cells can be cultured and cryopreserved for future use.

[edit] Vaccines

Vaccines for polio, measles, mumps, rubella, and chickenpox are currently made in cell cultures. Due to the H5N1 pandemic threat, research into using cell culture for influenza vaccines is being funded by the United States government. Novel ideas in the field include recombinant DNA-based vaccines, such as one made using human adenovirus (a common cold virus) as a vector,[15][16] or the use of adjuvants.[17]

[edit] Culture of non-mammalian cells

[edit] Plant cell culture methods

See also: Tobacco BY-2 cells
Plant cell cultures are typically grown as cell suspension cultures in liquid medium or as callus cultures on solid medium. The culturing of undifferentiated plant cells and calli requires the proper balance of the plant growth hormones auxin and cytokinin.

[edit] Bacterial/Yeast culture methods

Main article: microbiological culture
For bacteria and yeast, small quantities of cells are usually grown on a solid support that contains nutrients embedded in it, usually a gel such as agar, while large-scale cultures are grown with the cells suspended in a nutrient broth.

[edit] Viral culture methods

Main article: Viral culture
The culture of viruses requires the culture of cells of mammalian, plant, fungal or bacterial origin as hosts for the growth and replication of the virus. Whole wild type viruses, recombinant viruses or viral products may be generated in cell types other than their natural hosts under the right conditions. Depending on the species of the virus, infection and viral replication may result in host cell lysis and formation of a viral plaque.

[edit] Common cell lines

Human cell lines
Primate cell lines
Rat tumor cell lines
Mouse cell lines
Plant cell lines
Other species cell lines

[edit] List of cell lines

Cell line  ↓ Meaning  ↓ Organism  ↓ Origin tissue  ↓ Morphology  ↓ Link  ↓
293-T
Human kidney (embryonic)
Derivative of HEK 293ECACC
3T3 cells "3-day transfer, inoculum 3 x 105 cells" Mouse embryonic fibroblast
Also known as NIH 3T3 ECACC
721
Human melanoma

9L
Rat glioblastoma

A2780
Human Ovary Ovarian Cancer ECACC
A2780ADR
Human Ovary Adriamycin-resistant derivative ECACC
A2780cis
Human Ovary Cisplatin-resistant derivative ECACC
A172
human glioblastoma malignant glioma ECACC
A20
murine B lymphoma B lymphocyte
A253
human head and neck carcinoma submandibular duct
A431
human skin epithelium squamous carcinoma ECACCCell Line Data Base
A-549
human lungcarcinoma epithelium DSMZECACC
ALC
murine bone marrow stroma PubMed
B16
murine Melanoma
ECCAC
B35
rat Neuroblastoma
ATCC
BCP-1 cells
Human PBMC HIV+ lymphoma ATCC
BEAS-2B bronchial epithelium + adenovirus 12-SV40 virus hybrid (Ad12SV40) Human lung epithelial ATCC
bEnd.3 brain endothelial mouse brain / cerebral cortex endothelium ATCC
BHK-21 "Baby Hamster Kidney Fibroblast cells" Hamster kidney fibroblast ECACCOlympus
BR 293
human breast breast cancer
BxPC3 Biopsy xenograph of pancreatic carcinoma line 3 human pancreatic adenocarcinoma epithelial ATCC
C3H-10T1/2
Mouse Embryonic mesenchymal cell line
ECACC
C6/36
Asian tiger mosquito larval tissue
ECACC
Cal-27
human tongue squamous cell carcinoma
CHO Chinese hamster ovary hamster Ovary epithelium ECACCICLC
COR-L23
Human Lung
ECACC
COR-L23/CPR
Human Lung
ECACC
COR-L23/5010
Human Lung
ECACC
COR-L23/R23
Human Lung Epithelial ECACC
COS-7 Cercopithecus aethiops, origin-defective SV-40 ape - Cercopithecus aethiops (Chlorocebus) kidney fibroblast ECACCATCC
CML T1 Chronic Myelod Leukaemia T-lymphocyte 1 human CML acute phase T cell leukaemia Blood
CMT canine mammary tumor dog mammary gland epithelium
CT26
murine Colorectal Carcinoma Colon
D17
canine osteosarcoma
ECACC
DH82
canine histiocytosis monocyte/macrophage ECACC J Vir Meth
DU145
human Androgen insensitive carcinoma Prostate
DuCaP Dura mater Cancer of the Prostate human Metastatic Prostate Cancer epithelial PubMed
EL4
mouse
T cell leukaemia ECACC
EM2
human CML blast crisis Ph+ CML line Cell Line Data Base
EM3
human CML blast crisis Ph+ CML line Cell Line Data Base
EMT6/AR1
mouse Breast Epithelial-like ECACC
EMT6/AR10.0
Mouse Breast Epithelial-like ECACC
FM3
human Metastatic lymph node melanoma
H1299
human lung lung cancer
H69
Human Lung
ECACC
HB54
hybridoma hybridoma secretes L243 mAb (against HLA-DR) Human Immunology
HB55
hybridoma hybridoma secretes MA2.1 mAb (against HLA-A2 and HLA-B17) Journal of Immunology
HCA2
human fibroblast
Journal of General Virology
HEK-293 human embryonic kidney human kidney (embryonic) epithelium ATCC
HeLa Henrietta Lacks human Cervical cancer epithelium DSMZECACC
Hepa1c1c7 clone 7 of clone 1 hepatoma line 1 mouse Hepatoma epithelial ECACC ATCC
HL-60 human leukemia human Myeloblast bloodcells ECACCDSMZ
HMEC human mammary epithelial cell human
epithelium ECACC
HT-29
human colon epithelium adenocarcinoma ECACC Cell Line Data Base
Jurkat
human T-Cell-Leukemia white blood cells ECACC DSMZ
JY cells
human lymphoblastoid EBV immortalised B cell
K562 cells
human lymphoblastoid CML blast crisis ECACC
Ku812
human lymphoblastoid erythroleukemia ECACC LGCstandards
KCL22
human lymphoblastoid CML
KG1
human lymphoblastoid AML
KYO1 Kyoto 1 human lymphoblastoid CML DSMZ
LNCap Lymph node Cancer of the Prostate human prostatic adenocarcinoma epithelial ECACCATCC
Ma-Mel 1, 2, 3....48
human
a range of melanoma cell lines
MC-38
mouse
adenocarcinoma
MCF-7 Michigan Cancer Foundation-7 human mammary gland invasive breast ductal carcinoma ER+, PR+
MCF-10A Michigan Cancer Foundation human mammary gland epithelium ATCC
MDA-MB-231 M.D. Anderson - Metastatic Breast human breast cancer ECACC
MDA-MB-468 M.D. Anderson - Metastatic Breast human breast cancer ECACC
MDA-MB-435 M.D. Anderson - Metastatic Breast human breast melanoma or carcinoma (disputed) Cambridge Pathology ECACC
MDCK II Madin Darby canine kidney dog kidney epithelium ECACC ATCC
MDCK II Madin Darby canine kidney dog kidney epithelium [2] ATCC
MOR/0.2R
Human Lung
ECACC
MONO-MAC 6
human WBC myeloid metaplasic AML Cell Line Data Base
MTD-1A
mouse
epithelium
MyEnd myocardial endothelial mouse
endothelium
NCI-H69/CPR
Human Lung
ECACC
NCI-H69/LX10
Human Lung
ECACC
NCI-H69/LX20
Human Lung
ECACC
NCI-H69/LX4
Human Lung
ECACC
NIH-3T3 NIH, 3-day transfer, inoculum 3 x 105 cells mouse embryo fibroblast ECACCATCC
NALM-1

peripheral blood blast-crisis CML Cancer Genetics and Cytogenetics
NW-145


melanoma ESTDAB
OPCN / OPCT cell lines Onyvax[3] Prostate Cancer....

Range of prostate tumour lines Asterand
Peer
human T cell leukemia
DSMZ
PNT-1A / PNT 2


Prostate tumour lines ECACC
RenCa Renal Carcinoma mouse
renal carcinoma
RIN-5F
mouse pancreas

RMA/RMAS
mouse
T cell tumour
Saos-2 cells
human
Osteosarcoma ECACC
Sf-9 Spodoptera frugiperda insect - Spodoptera frugiperda (moth) Ovary
DSMZECACC
SkBr3
human
breast carcinoma
T2
human
T cell leukemia/B cell line hybridoma DSMZ
T-47D
human mammary gland ductal carcinoma
T84
human colorectal Carcinoma / lungmetastasis epithelium ECACCATCC
THP1 cell line
human monocyte AML ECACC
U373
human glioblastoma-astrocytoma epithelium
U87
human glioblastoma-astrocytoma epithelial-like Abcam
U937
human leukaemic monocytic lymphoma
ECACC
VCaP Vertebra Prostate Cancer human metastatic prostate cancer epithelial ECACC ATCC
Vero cells 'Vera Reno' ('green kidney') / 'Vero' ('truth') African Green Monkey kidney epithelium
ECACC
WM39
human skin primary melanoma
WT-49
human lymphoblastoid

X63
mouse melanoma

YAC-1
mouse lymphoma
Cell Line Data Base ECACC
YAR
human B-cell EBV transofrmed [4] Human Immunology
Note: this list is a sample of available cell lines, and is not comprehensive

[edit] See also

[edit] References and notes

  1. ^ ""Cell Culture"". http://www.bioteach.ubc.ca/Bioengineering/CellCulture/index.htm. Retrieved 2006-04-19. 
  2. ^ ""Some landmarks in the development of tissue and cell culture."". http://www.ncbi.nlm.nih.gov/books/bv.fcgi?db=Books&rid=mboc4.table.1516. Retrieved 2006-04-19. 
  3. ^ ""Animals and alternatives in testing."". http://caat.jhsph.edu/pubs/animal_alts/appendix_c.htm. Retrieved 2006-04-19. 
  4. ^ Schiff, Judith Ann. ""An unsung hero of medical research."". http://www.yalealumnimagazine.com/issues/02_02/old_yale.html. Retrieved 2006-04-19.  Yale Alumni Magazine, February 2002.
  5. ^ "LipiMAX purified lipoprotein solution from bovine serum". Selborne Biological Services. 2006. http://www.selbornebiological.com/products/lipimax.htm. Retrieved 2010-02-02. 
  6. ^ Drexler, HG; Dirks; Macleod (Oct 1999). "False human hematopoietic cell lines: cross-contaminations and misinterpretations". Leukemia 13 (10): 1601–7. doi:10.1038/sj/leu/2401510. ISSN 0887-6924. PMID 10516762. 
  7. ^ Drexler, HG; Macleod; Dirks (Dec 2001). "Cross-contamination: HS-Sultan is not a myeloma but a Burkitt lymphoma cell line" (Free full text). Blood 98 (12): 3495–6. doi:10.1182/blood.V98.12.3495. ISSN 0006-4971. PMID 11732505. http://www.bloodjournal.org/cgi/pmidlookup?view=long&pmid=11732505. 
  8. ^ Cabrera, CM; Cobo, F; Nieto, A; Cortés, JL; Montes, RM; Catalina, P; Concha, A (Jun 2006). "Identity tests: determination of cell line cross-contamination". Cytotechnology 51 (2): 45–50. doi:10.1007/s10616-006-9013-8. ISSN 0920-9069. PMID 19002894. 
  9. ^ a b Chatterjee, R (Feb 2007). "Cell biology. Cases of mistaken identity.". Science (New York, N.Y.) 315 (5814): 928–31. doi:10.1126/science.315.5814.928. ISSN 0036-8075. PMID 17303729. 
  10. ^ Liscovitch, M; Ravid (Jan 2007). "A case study in misidentification of cancer cell lines: MCF-7/AdrR cells (re-designated NCI/ADR-RES) are derived from OVCAR-8 human ovarian carcinoma cells.". Cancer letters 245 (1-2): 350–2. doi:10.1016/j.canlet.2006.01.013. ISSN 0304-3835. PMID 16504380. 
  11. ^ Macleod, RA; Dirks; Matsuo; Kaufmann; Milch; Drexler (Nov 1999). "Widespread intraspecies cross-contamination of human tumor cell lines arising at source.". International journal of cancer. Journal international du cancer 83 (4): 555–63. ISSN 0020-7136. PMID 10508494. 
  12. ^ Masters, JR (Apr 2002). "HeLa cells 50 years on: the good, the bad and the ugly.". Nature reviews. Cancer 2 (4): 315–9. doi:10.1038/nrc775. ISSN 1474-175X. PMID 12001993. 
  13. ^ a b Dunham, J.H. and Guthmiller, P. (2008) Doing good science: Authenticating cell line identity. Cell Notes 22, 15–17.
  14. ^ Ceb.com
  15. ^ Reuters (2006-01-26). Wired.com "Quickie Bird Flu Vaccine Created". Wired. http://wired.com/news/wireservice/0,70102-0.html?tw=wn_index_7 Wired.com. Retrieved 2010-01-31. 
  16. ^ Gao W, Soloff AC, Lu X, Montecalvo A, Nguyen DC, Matsuoka Y, Robbins PD, Swayne DE, Donis RO, Katz JM, Barratt-Boyes SM, Gambotto A. (February 2006). "Protection of mice and poultry from lethal H5N1 avian influenza virus through adenovirus-based immunization". Journal of Virology (United States: American Society for Microbiology) 80 (4): 1959–1964. doi:10.1128/JVI.80.4.1959-1964.2006. ISSN 0022-538X. http://jvi.asm.org/cgi/content/abstract/80/4/1959. Retrieved 2010-01-31. 
  17. ^ "NIAID Taps Chiron to Develop Vaccine Against H9N2 Avian Influenza". National Institute of Allergy and Infectious Diseases (NIAID). 2004-08-17. http://www3.niaid.nih.gov/news/newsreleases/2004/h9n2.htm. Retrieved 2010-01-31. 

[edit] External links

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