出典(authority):フリー百科事典『ウィキペディア(Wikipedia)』「2012/12/20 12:03:41」(JST)
Ethanol precipitation is a method used to purify and/or concentrate RNA, DNA and polysaccharides such as pectin and xyloglucan from aqueous solutions.
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DNA is polar due to its highly charged phosphate backbone. This polarity, based on the principle of "like dissolves like", makes it soluble in water, which is also highly polar.
The high polarity of water, reflected by the high value of its dielectric constant 80.1 (at 20 °C), means that the electrical force between any two charges in aqueous solution is highly diminished compared to the force in a vacuum or air.
This relation is reflected in Coulomb's law, which can be used to calculate the force acting on two charges and separated by a distance by using the dielectric constant (also called relative static permittivity) of the medium in the denominator of the equation ( is an electric constant):
At an atomic level, the diminishment of force acting on charges results from water molecules forming hydration shells around them. It makes water a very good solvent for charged compounds like salts. Electric force which normally holds salt crystals together by way of ionic bonds is weakened in the presence of water allowing ions to separate from the crystal and spread through solution.
The same mechanism operates in the case of negatively charged phosphate groups on a DNA backbone: even if positive ions are present in solution, the relatively weak electric force prevents them from forming stable ionic bonds with phosphates and precipitating out of solution.
Ethanol is much less polar than water; its dielectric constant is 24.3 (at 25 °C). This means that adding ethanol to solution disrupts the screening of charges by water. If enough ethanol is added, the electrical attraction between phosphate groups and any positive ions present in solution becomes strong enough to form stable ionic bonds and DNA precipitation. This usually happens when ethanol composes over 64% of the solution. As the mechanism suggests, the solution has to contain positive ions for precipitation to occur; usually Na+, NH4+ or Li+ play this role .[1]
DNA is precipitated by first ensuring that the correct concentration of positive ions is present in solution (too much will result in a lot of salt co-precipitating with DNA, too little will result in incomplete DNA recovery) and then adding two to three volumes of at least 95% ethanol. Many protocols advise storing DNA at low temperature at this point but this has been shown to lower precipitation efficiency.[2][3] The best efficiency is achieved at room temperature but when possible degradation is taken into account it is probably best to incubate DNA on wet ice. Optimal incubation time depends on the length and concentration of DNA. Smaller fragments and lower concentrations will require longer times to achieve the same recovery. For very small lengths and low concentrations over-night incubation is recommended. In such cases use of carriers like tRNA, glycogen or linear polyacrylamide can greatly improve recovery.
During incubation DNA and some salts will precipitate from solution, in the next step this precipitate is collected by centrifugation in a microcentrifuge tube at high speeds (~12,000g). Time and speed of centrifugation has the biggest effect on DNA recovery rates. Again smaller fragments and higher dilutions require longer and faster centrifugation. Centrifugation can be done either at room temperature or in 4 °C or 0 °C. During centrifugation precipitated DNA has to move through ethanol solution to the bottom of the tube, lower temperatures increase viscosity of the solution and larger volumes make the distance longer, so both those factors lower efficiency of this process requiring longer centrifugation for the same effect.[2][3] After centrifugation the supernatant solution is removed, leaving a pellet of crude DNA. Whether the pellet is visible depends on the amount of DNA and on its purity (dirtier pellets are easier to see) or the use of co-precipitants.
In the next step, 70% ethanol is added to the pellet, and it is gently mixed to break the pellet loose and wash it. This removes some of the salts present in the leftover supernatant and bound to DNA pellet making the final DNA cleaner. This suspension is centrifuged again to once again pellet DNA and the supernatant solution is removed. This step is repeated once.
Finally, the pellet is air-dried and the DNA is resuspended in water or other desired buffer. It is important not to over-dry the pellet as it may lead to denaturation of DNA and make it harder to resuspend.
Isopropanol can also be used instead of ethanol; the precipitation efficiency of the isopropanol is higher making one volume enough for precipitation. However, isopropanol is less volatile than ethanol and needs more time to air-dry in the final step. The pellet might also adhere less tightly to the tube when using isopropanol.[1]
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リンク元 | 「エタノール沈殿」「エタ沈」「EtOH ppt」「precipitate with ethanol」「エタノール沈澱」 |
関連記事 | 「precipitation」 |
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