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[[Image:PhOH-CHCl3 extraction.svg|thumb|250px]]
[[Image:PhOH-CHCl3 extraction.svg|thumb|250px]]
'''Phenol–chloroform extraction''' (abbreviated PC or PCIA, see reagents below) is a [[liquid–liquid extraction]] technique in [[biochemistry]]. It is widely used in [[molecular biology]] for isolating [[DNA]], [[RNA]] and [[protein]]. Equal volumes of a phenol:chloroform mixture and an aqueous sample are mixed, forming a [[Emulsion|biphasic mixture]]. This method may take longer than a [[Column-based nucleic acid purification|column-based system]] such as the silica-based purification, but has higher purity {{Citation needed|date=September 2008}} and the advantage of high recovery of RNA: an RNA column is typically unsuitable for purification of short (<200 [[nucleotides]]) RNA species, such as [[siRNA]], [[miRNA]], [[gRNA]] and [[tRNA]]. Column methods also shear large DNA fragments, which may or may not be a problem depending on downstream applications.
'''Acid guanidinium thiocyanate-phenol-chloroform extraction''' (abbreviated '''AGPC''') is a [[liquid–liquid extraction]] technique in [[biochemistry]]. It is widely used in [[molecular biology]] for isolating [[RNA]] (as well as [[DNA]] and [[protein]] in some cases). This method may take longer than a [[Column-based nucleic acid purification|column-based system]] such as the silica-based purification, but has higher purity and the advantage of high recovery of RNA:{{cn|date=September 2022}} an RNA column is typically unsuitable for purification of short (<200 [[nucleotides]]) RNA species, such as [[siRNA]], [[miRNA]], [[gRNA]] and [[tRNA]].


It was originally devised by Piotr Chomczynski and Nicoletta Sacchi and published in 1987 (referred to as ''guanidinium thiocyanate-phenol-chloroform extraction'').<ref>{{cite journal | author = Chomczynski, P. & Sacchi, N. | title = Single-step method of RNA isolation by acid guanidinium thiocyanate-phenol-chloroform extraction | journal = [[Anal. Biochem.]] | volume = 162 | pages = 156–159 | year = 1987 | doi = 10.1016/0003-2697(87)90021-2 | pmid=2440339}}</ref><ref>{{cite journal | author = Chomczynski, P. & Sacchi, N. | title = Single-step method of RNA isolation by acid guanidinium thiocyanate-phenol-chloroform extraction: Twenty-something years on | doi = 10.1038/nprot.2006.83 | journal = [[Nature Prot.]] | volume =1 | pages = 581–585 | year = 2006 | pmid = 17406285 | issue = 2}}</ref> The reagent used specifically for RNA extraction is sold by [[Sigma-Aldrich]] by the name TRI Reagent, by [[Invitrogen]] under the name [[Trizol|TRIzol]], by [[Bioline]] as Trisure and by Tel-Test as STAT-60.
It was originally devised by Piotr Chomczynski and [[Nicoletta Sacchi]], who published their protocol in 1987.<ref>{{cite journal |author1=Chomczynski, P. |author2=Sacchi, N. | title = Single-step method of RNA isolation by acid guanidinium thiocyanate-phenol-chloroform extraction | journal = [[Anal. Biochem.]] | volume = 162 | pages = 156–159 | year = 1987 |issue=1 | doi = 10.1016/0003-2697(87)90021-2 | pmid=2440339}}</ref><ref>{{cite journal |author1=Chomczynski, P. |author2=Sacchi, N. | title = Single-step method of RNA isolation by acid guanidinium thiocyanate-phenol-chloroform extraction: Twenty-something years on | doi = 10.1038/nprot.2006.83 | journal = [[Nature Protocols]] | volume =1 | pages = 581–585 | year = 2006 | pmid = 17406285 | issue = 2|s2cid=28653075 }}</ref> The reagent is sold by [[Sigma-Aldrich]] by the name TRI Reagent; by [[Invitrogen]] under the name [[Trizol|TRIzol]]; by [[Bioline Reagents|Bioline]] as Trisure; and by Tel-Test as STAT-60.


==How it works==
==How it works==
This method relies on phase separation by centrifugation of a mix of the aqueous sample and a solution containing water-saturated [[phenol]], [[chloroform]] and a chaotropic denaturing solution ([[guanidinium thiocyanate]]) resulting in an upper aqueous phase and a lower organic phase (mainly chloroform). Nucleic acid (RNA, DNA) partitions in the aqueous phase, while protein partitions in organic phase. In a last step, RNA is recovered from the aqueous phase by precipitation with [[2-propanol]] or [[ethanol]]. DNA will be located in the aqueous phase in the absence of guanidinium thiocyanate and thus the technique can be used for DNA purification alone.
This method relies on phase separation by centrifugation of a mixture of the aqueous sample and a solution containing water-saturated [[phenol]] and [[chloroform]], resulting in an upper aqueous phase and a lower organic phase (mainly phenol). [[Guanidinium thiocyanate]], a [[chaotropic agent]], is added to the organic phase to aid in the denaturation of proteins (such as those that strongly bind nucleic acids or those that degrade RNA). The nucleic acids (RNA and/or DNA) partition into the aqueous phase, while protein partitions into the organic phase. The pH of the mixture determines which nucleic acids get purified.<ref>Perry RP, La Torre J, Kelley DE, Greenberg JR. (1972) On the lability of poly(A) sequences during extraction of messenger RNA from polyribosomes. Biochim. Biophys. Acta 262: 220–226; Brawerman G, Mendecki J, Lee SY. (1972) A procedure for the isolation of mammalian messenger ribonucleic acid. Biochemistry 11: 637–641.</ref> Under acidic conditions (pH 4-6), DNA partitions into the organic phase while RNA remains in the aqueous phase. Under neutral conditions (pH 7-8), both [[DNA partition|DNA]] and [[RNA replication|RNA partition]] into the aqueous phase. In a last step, the nucleic acids are recovered from the aqueous phase by precipitation with [[2-propanol]]. The 2-propanol is then washed with [[ethanol]] and the pellet briefly air-dried and dissolved in TE buffer or RNAse free water.


[[Guanidinium thiocyanate]] denatures proteins, including RNases, and separates rRNA from ribosomes, while [[phenol]], [[isopropanol]] and water are solvents with poor solubility. In the presence of [[chloroform]] or BCP ([[bromochloropropane]]), these solvents separate entirely into two phases that are recognized by their color: a clear, upper aqueous phase (containing the nucleic acids) and a bright pink lower phase (containing the proteins dissolved in phenol and the lipids dissolved in chloroform).
[[Guanidinium thiocyanate]] denatures proteins, including RNases, and separates rRNA from ribosomal proteins, while [[phenol]], [[isopropanol]] and water are solvents with poor solubility. In the presence of [[chloroform]] or BCP ([[bromochloropropane]]), these solvents separate entirely into two phases that are recognized by their color: a clear, upper aqueous phase (containing the nucleic acids) and a lower phase (containing the proteins dissolved in phenol and the lipids dissolved in chloroform).
Other denaturing chemicals such as [[2-mercaptoethanol]] and [[sarcosine]] may also be used.
Other denaturing chemicals such as [[2-mercaptoethanol]] and [[sarcosine]] may also be used.
The major downside is that [[phenol]] and [[chloroform]] are both hazardous and inconvenient materials, and the extraction is often laborious, so in recent years many companies now offer alternative ways to isolate DNA.
The major downside is that [[phenol]] and [[chloroform]] are both hazardous and inconvenient materials, and the extraction is often laborious, so in recent years many companies now offer alternative ways to isolate RNA.


===Reagents===
===Reagents===
* ''Phenol'': The phenol used for [[biochemistry]] comes as a water-saturated solution with [[Tris buffer]], as a Tris-buffered 50% phenol, 50% chloroform solution, or as a Tris-buffered 50% phenol, 48% chloroform, 2% [[isoamyl alcohol]] solution (sometimes called "25:24:1"). Phenol is naturally somewhat water-soluble, and gives a fuzzy interface, which is sharpened by the presence of chloroform, and the isoamyl alcohol reduces foaming. Most solutions also have an antioxidant, as oxidized phenol damages the nucleic acids. For RNA purification, the pH is kept around pH 4, which retains RNA in the aqueous phase preferentially. For DNA purification, the pH is usually near 7, at which point all nucleic acids are found in the aqueous phase.
* ''Phenol'': The phenol used for [[biochemistry]] comes as a water-saturated solution with [[Tris buffer]], as a Tris-buffered 50% phenol, 50% chloroform solution, or as a Tris-buffered 50% phenol, 48% chloroform, 2% [[isoamyl alcohol]] solution (sometimes called "25:24:1"). Phenol is naturally somewhat water-soluble, and gives a fuzzy interface, which is sharpened by the presence of chloroform, and the isoamyl alcohol reduces foaming. Most solutions also have an antioxidant, as oxidized phenol damages the nucleic acids. For RNA purification, the pH is kept at around 4, which retains RNA in the aqueous phase preferentially. For DNA purification, the pH is usually near 7, at which point all nucleic acids are found in the aqueous phase.
* ''Chloroform'': Chloroform is stabilized with small quantities of [[amylene]] or [[ethanol]], because exposure of pure chloroform to oxygen and ultraviolet light produces [[phosgene]] gas. Some chloroform solutions come as pre-made a 96% chloroform, 4% isoamyl alcohol mixture that can be mixed with an equal volume of phenol to obtain the 25:24:1 solution.
* ''Isoamyl alcohol'': Isoamyl alcohol may reduce foaming and ensure deactivation of RNases.
* ''Chloroform'': Chloroform is stabilized with small quantities of [[amylene]] or [[ethanol]], because exposure of pure chloroform to oxygen and ultraviolet light produces [[phosgene]] gas. Some chloroform solutions come as pre-made a 96% chloroform, 4% isoamyl alcohol mixtures that can be mixed with an equal volume of phenol to obtain the 25:24:1 solution.

* ''Isoamyl alcohol'': Isoamyl alcohol may reduce foaming and ensure deactivation of RNase.


==See also==
==See also==
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==External links==
==External links==
* [http://www.mrcgene.com/tri.htm Manual for TRI reagent]
* [https://web.archive.org/web/20080509131137/http://www.mrcgene.com/tri.htm Manual for TRI reagent]
* [http://openwetware.org/wiki/Phenol/chloroform_extraction Protocol on OpenWetWare]
* [http://openwetware.org/wiki/Phenol/chloroform_extraction Protocol on OpenWetWare]
* [http://www.invitrogen.com/site/us/en/home/References/protocols/nucleic-acid-purification-and-analysis/dna-extraction-protocols/phenol-chloroform-extraction.html Invitrogen]
* [http://tools.invitrogen.com/content/sfs/manuals/15596018%20pps%20Trizol%20Reagent%20061207.pdf invitrogen]
* [http://www.ambion.com/techlib/prot/bp_9738.pdf Ambion]


{{Molecular Biology}}
{{Molecular Biology}}


{{DEFAULTSORT:Acid guanidinium thiocyanate-phenol-chloroform extraction}}
[[Category:Biochemistry methods]]
[[Category:Extraction (chemistry)]]
[[Category:Molecular biology]]
[[Category:Molecular biology]]
[[Category:Biochemistry methods]]

[[de:Phenol-Chloroform-Extraktion]]

Latest revision as of 20:53, 29 September 2022

Acid guanidinium thiocyanate-phenol-chloroform extraction (abbreviated AGPC) is a liquid–liquid extraction technique in biochemistry. It is widely used in molecular biology for isolating RNA (as well as DNA and protein in some cases). This method may take longer than a column-based system such as the silica-based purification, but has higher purity and the advantage of high recovery of RNA:[citation needed] an RNA column is typically unsuitable for purification of short (<200 nucleotides) RNA species, such as siRNA, miRNA, gRNA and tRNA.

It was originally devised by Piotr Chomczynski and Nicoletta Sacchi, who published their protocol in 1987.[1][2] The reagent is sold by Sigma-Aldrich by the name TRI Reagent; by Invitrogen under the name TRIzol; by Bioline as Trisure; and by Tel-Test as STAT-60.

How it works[edit]

This method relies on phase separation by centrifugation of a mixture of the aqueous sample and a solution containing water-saturated phenol and chloroform, resulting in an upper aqueous phase and a lower organic phase (mainly phenol). Guanidinium thiocyanate, a chaotropic agent, is added to the organic phase to aid in the denaturation of proteins (such as those that strongly bind nucleic acids or those that degrade RNA). The nucleic acids (RNA and/or DNA) partition into the aqueous phase, while protein partitions into the organic phase. The pH of the mixture determines which nucleic acids get purified.[3] Under acidic conditions (pH 4-6), DNA partitions into the organic phase while RNA remains in the aqueous phase. Under neutral conditions (pH 7-8), both DNA and RNA partition into the aqueous phase. In a last step, the nucleic acids are recovered from the aqueous phase by precipitation with 2-propanol. The 2-propanol is then washed with ethanol and the pellet briefly air-dried and dissolved in TE buffer or RNAse free water.

Guanidinium thiocyanate denatures proteins, including RNases, and separates rRNA from ribosomal proteins, while phenol, isopropanol and water are solvents with poor solubility. In the presence of chloroform or BCP (bromochloropropane), these solvents separate entirely into two phases that are recognized by their color: a clear, upper aqueous phase (containing the nucleic acids) and a lower phase (containing the proteins dissolved in phenol and the lipids dissolved in chloroform). Other denaturing chemicals such as 2-mercaptoethanol and sarcosine may also be used. The major downside is that phenol and chloroform are both hazardous and inconvenient materials, and the extraction is often laborious, so in recent years many companies now offer alternative ways to isolate RNA.

Reagents[edit]

  • Phenol: The phenol used for biochemistry comes as a water-saturated solution with Tris buffer, as a Tris-buffered 50% phenol, 50% chloroform solution, or as a Tris-buffered 50% phenol, 48% chloroform, 2% isoamyl alcohol solution (sometimes called "25:24:1"). Phenol is naturally somewhat water-soluble, and gives a fuzzy interface, which is sharpened by the presence of chloroform, and the isoamyl alcohol reduces foaming. Most solutions also have an antioxidant, as oxidized phenol damages the nucleic acids. For RNA purification, the pH is kept at around 4, which retains RNA in the aqueous phase preferentially. For DNA purification, the pH is usually near 7, at which point all nucleic acids are found in the aqueous phase.
  • Chloroform: Chloroform is stabilized with small quantities of amylene or ethanol, because exposure of pure chloroform to oxygen and ultraviolet light produces phosgene gas. Some chloroform solutions come as pre-made a 96% chloroform, 4% isoamyl alcohol mixture that can be mixed with an equal volume of phenol to obtain the 25:24:1 solution.
  • Isoamyl alcohol: Isoamyl alcohol may reduce foaming and ensure deactivation of RNases.

See also[edit]

References[edit]

  1. ^ Chomczynski, P.; Sacchi, N. (1987). "Single-step method of RNA isolation by acid guanidinium thiocyanate-phenol-chloroform extraction". Anal. Biochem. 162 (1): 156–159. doi:10.1016/0003-2697(87)90021-2. PMID 2440339.
  2. ^ Chomczynski, P.; Sacchi, N. (2006). "Single-step method of RNA isolation by acid guanidinium thiocyanate-phenol-chloroform extraction: Twenty-something years on". Nature Protocols. 1 (2): 581–585. doi:10.1038/nprot.2006.83. PMID 17406285. S2CID 28653075.
  3. ^ Perry RP, La Torre J, Kelley DE, Greenberg JR. (1972) On the lability of poly(A) sequences during extraction of messenger RNA from polyribosomes. Biochim. Biophys. Acta 262: 220–226; Brawerman G, Mendecki J, Lee SY. (1972) A procedure for the isolation of mammalian messenger ribonucleic acid. Biochemistry 11: 637–641.

External links[edit]

Retrieved from "https://en.wikipedia.org/w/index.php?title=Acid_guanidinium_thiocyanate-phenol-chloroform_extraction&oldid=1113115913"