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Selectable markers have a remarkably relevant role in industrial applications. Because of their ability to distinguish cells from one another, selectable markers are an essential tool for artificial selection. While artificial selection of organisms is possible without the use of selectable markers, the process is significantly shorter with their use.
Selectable markers have a remarkably relevant role in industrial applications. Because of their ability to distinguish cells from one another, selectable markers are an essential tool for artificial selection. While artificial selection of organisms is possible without the use of selectable markers, the process is significantly shorter with their use.


Artificial selection is a special instance in which selectable markers are often the desired gene to be introduced into a cell. For instance, rice has been transfected with a plethora of resistances using selectable markers. Glycopeptide binding protein, dihydrofolate reductase, and hygromycin phosphotransferase have all been introduced into rice, conferring resistance to bleomycin and pheomycin, methotrexate, and hygromycin B respectively<cite>Twyman2002</cite>.
Artificial selection is a special instance in which selectable markers are often the desired gene to be introduced into a cell. For instance, rice has been transfected with a plethora of resistances using selectable markers. Glycopeptide binding protein, dihydrofolate reductase, and hygromycin phosphotransferase have all been introduced into rice, conferring resistance to bleomycin and pheomycin, methotrexate, and hygromycin B respectively. This allows farmers to use herbicides select for only rice with these markers, while eliminating the majority of invasive species<cite>Twyman2002</cite>.
==Issues==
==Issues==
===Genetically Modified Organisms===
===Genetically Modified Organisms===
Roundup Ready crops


==References==
==References==

Revision as of 18:01, 19 February 2012


Selectable Markers Overview

Example application of selectable genetic markers in nematodes. Only nematodes transfected with markers survive and proliferate[1].

Selectable genetic markers are exogenous genes that are introduced into a cell, conferring a previously absent resistance. These markers are primarily used to "mark" the successful transformation of DNA into a plasmid. Oftentimes, selectable markers are accompanied by other exogenous genes that is the primary gene of interest; the marker simply serves to distinguish between successful transformations, and unaltered cells. It is not atypical to witness transformation efficiencies as low as .05%, making it difficult to pick correct cellular colonies without additional techniques.

This is where the selectable genetic markers prove their usefulness. For instance, selectable genetic markers can be used to confer ampicillin resistance to E. coli. These newly resistant E. coli can then be grown on culture plates with ampicillin, allowing only E.coli with successfully transformed DNA to proliferate.

In addition to selectable genetic markers are screenable genetic markers. Screenable genetic markers function in a similar manner in that they are extraneous genes that are transformed into a cell; however, they do not confer any new sort of resistance to the cell. Instead, they cause the cell to respond differently to environmental conditions in such a way as to distinguish transformed cells from untransformed cells. This can be useful when determining the transformation efficiency of a cell, or when carefully monitoring the activity of proteins.

Types of Selectable Markers

Antibiotic

Types of Screening

Successful example of a blue/white screen test. Blue colonies are wild-type cells, while white colonies are successfully transformed cells

Blue/White Screening

Blue/White Screening is commonly used in E. coli transformations. In this screening, cells are grown on agar plates in the presence of X-gal and IPTG to test for the presence of β-galactosidase enzyme. In the M15 strain of E. coli, part of the lacZ gene is deleted, removing the cell's ability to produce β-galactosidase. However, when transfected with a plasmid containing a lacZα domain, such as pUC19, the gene becomes operable and the cell produces β-galactosidase. It is possible to create a successful transformation in which β-galactosidase is not produced by inserting DNA into the lacZα domain. This is particularly useful to check for successful ligations. Successful ligations will not produce β-galactosidase, while unsuccessful ligations will.

X-gal, while normally colorless (i.e. white), will readily hydrolyze in the presence of β-galactosidase into a compound with a sharp blue color. Therefore, colonies with successfully transformed cells with the desired DNA will grow white, while background colonies will grow blue.

Green Fluorescent Protein Screening

Mice transfected with GFP. One can easily distinguish the wild-type mouse (middle) from the two mice with GFP (left and right)[2].

Green Fluorescent Protein, or GFP, was first isolated from the crystal jellyfish Aequorea victoria in the 1960s. In 1994, GFP was successfully cloned[3], allowing researchers to use the protein as a screenable marker for the first time. Virtually harmless in live cells, GFP has the unique pheotype of glowing bright green under ultraviolet light. GFP functions entirely of its own accord, and requires no exogenous material besides ionizing radiation in order to fluoresce. This allows GFP to be used as a marker accompanying transfected DNA, and has been used extensively in academia.

In 2011, GFP was used to create an in vivo mammary model to investigate tumorigenesis in mice. Tumor cells were introduced into the mice, accompanied with GFP as a screenable marker. As the mice tumors proliferated, so did GFP. This allowed for easy differentiate between tumors and stroma cells, greatly aiding cancer researchers[2].

Artificial Selection

Selectable markers have a remarkably relevant role in industrial applications. Because of their ability to distinguish cells from one another, selectable markers are an essential tool for artificial selection. While artificial selection of organisms is possible without the use of selectable markers, the process is significantly shorter with their use.

Artificial selection is a special instance in which selectable markers are often the desired gene to be introduced into a cell. For instance, rice has been transfected with a plethora of resistances using selectable markers. Glycopeptide binding protein, dihydrofolate reductase, and hygromycin phosphotransferase have all been introduced into rice, conferring resistance to bleomycin and pheomycin, methotrexate, and hygromycin B respectively. This allows farmers to use herbicides select for only rice with these markers, while eliminating the majority of invasive species[4].

Issues

Genetically Modified Organisms

Roundup Ready crops

References

  1. Giordano-Santini R and Dupuy D. Selectable genetic markers for nematode transgenesis. Cell Mol Life Sci. 2011 Jun;68(11):1917-27. DOI:10.1007/s00018-011-0670-1 | PubMed ID:21431833 | HubMed [Giordano-Santini2011]

    Review article about selectable genetic markers as used in nematodes. Relatively new field for nematodes, possible due to the completion of the Caenorhabditis elegans genome.

  2. Moen I, Jevne C, Wang J, Kalland KH, Chekenya M, Akslen LA, Sleire L, Enger PØ, Reed RK, Øyan AM, and Stuhr LE. Gene expression in tumor cells and stroma in dsRed 4T1 tumors in eGFP-expressing mice with and without enhanced oxygenation. BMC Cancer. 2012 Jan 17;12:21. DOI:10.1186/1471-2407-12-21 | PubMed ID:22251838 | HubMed [Moen2011]

    Observes tumor growth in mice by introducing GFP into the mice.

  3. Chalfie M, Tu Y, Euskirchen G, Ward WW, and Prasher DC. Green fluorescent protein as a marker for gene expression. Science. 1994 Feb 11;263(5148):802-5. DOI:10.1126/science.8303295 | PubMed ID:8303295 | HubMed [Chalfie1994]

    The first instance of using GFP as a marker.

  4. Caplan A, Dekeyser R, and Van Montagu M. Selectable markers for rice transformation. Methods Enzymol. 1992;216:426-41. DOI:10.1016/0076-6879(92)16039-m | PubMed ID:1282647 | HubMed [Twyman2002]

All Medline abstracts: PubMed | HubMed