15.3 : DNA Agarose Gel Electrophoresis

Agarose gel electrophoresis is a technique commonly used to separate DNA molecules by their size.

Agarose — a polysaccharide derived from red algae — is added to a buffer such as Tris-acetate EDTA (TAE) or Tris-borate EDTA (TBE) and dissolved by heating.

Commonly, 1 gram of agarose is dissolved in 100 milliliters of buffer to form a 1% agarose solution, though different amounts of agarose can be added depending on the application.

To stain the gel, a fluorescent dye, such as ethidium bromide, is often added to the agarose solution. The dye intercalates between the DNA bases and fluoresces under UV light.

The solution can then be poured into horizontal molds. A comb is inserted into the gel cast to create wells into which DNA samples can be loaded.

The agarose solution is left undisturbed to solidify into a gel.

The gel consists of hydrogen-bonded agarose molecules forming a porous matrix through which the DNA molecules move.

DNA samples are mixed with a loading buffer and loaded on the gel. The loading buffer contains glycerol, which increases the density of the DNA samples and helps them settle at the bottom of the wells.

The buffer also contains dyes, such as xylene cyanol and bromophenol blue, which help monitor the progress of the migrating bands of DNA.

When an electric potential is applied along the length of the gel, the negatively charged DNA migrates towards the positive electrode, traveling through the layers of agarose pores.

Larger DNA molecules move more slowly through the pores than smaller molecules, allowing the molecules to be separated according to their size.

The size of the pores depends on the concentration of agarose in the solution. The higher the agarose concentration, the smaller the pore size, which helps separate shorter DNA fragments.

Under UV light, the stained DNA molecules appear as fluorescent bands. The position of the bands can be compared with DNA fragments of known sizes, called a DNA ladder.

The bands of a ladder serve as a reference to determine the size of the DNA molecules of interest.

Agarose gel electrophoresis is a laboratory technique commonly used to separate DNA fragments by size. However, it can also be used to isolate and purify DNA fragments using a gel extraction protocol.

Gel extraction follows five major steps: running gel electrophoresis to separate fragments, isolating the individual bands, extracting DNA from those bands, and removing the dye and salts from the extracted mixture to obtain pure DNA.

In cloning experiments, both the insert and vector DNA fragments are obtained after digestion with restriction endonucleases. These DNA fragments of varying sizes are mixed with contaminants, such as enzymes, salts, etc., that can inhibit the ligation reaction that follows. Gel extraction is therefore used to obtain pure DNA fragments before ligation.

To set up a gel for extraction, a lower percent (0.7-0.8%) agarose solution is used to ensure efficient migration of the DNA bands. In addition, a wide-combed gel cast is used to obtain thick DNA bands that are easy to isolate. Then, gel electrophoresis is performed at a lower voltage to prevent heating of the gel and damage to the DNA.

Once gel electrophoresis is complete, the ethidium bromide-stained DNA is identified by exposing the gel to long-wavelength UV for a short time. Short exposure to UV radiation prevents damage to DNA. This is followed by cutting out the desired band using a clean razor blade.

The isolated gel slice containing the DNA fragment of interest is then processed through one of the commercially available gel extraction kits. All of these kits follow the same basic principle. First, the agarose gel is dissolved by a buffer solution containing salts, such as sodium iodide. Next, DNA is bound to a column containing an anionic resin and washed a few times with a dilute alcoholic solution to remove impurities. The column is then dried by spinning in a centrifuge. The pure DNA can now be eluted with buffer or deionized water.

Tags

DNA Agarose Gel Electrophoresis Gel Extraction DNA Fragments Size Separation Purification Cloning Experiments Vector DNA Insert DNA Restriction Endonucleases Contaminants Ligation Reaction Agarose Solution Migration Of DNA Bands Wide combed Gel Cast Lower Voltage Electrophoresis Ethidium Bromide Staining UV Exposure Gel Slice Isolation

From Chapter 15:

Now Playing

15.3 : DNA Agarose Gel Electrophoresis

Studying DNA and RNA

97.0K Views

15.1 : Recombinant DNA

Studying DNA and RNA

16.8K Views

15.2 : DNA Isolation

Studying DNA and RNA

39.3K Views

15.4 : Labeling DNA Probes

Studying DNA and RNA

8.2K Views

15.5 : Southern Blot

Studying DNA and RNA

19.5K Views

15.6 : DNA Microarrays

Studying DNA and RNA

17.5K Views

15.7 : Complementary DNA

Studying DNA and RNA

5.6K Views

15.8 : FISH - Fluorescent In-situ Hybridization

Studying DNA and RNA

20.8K Views

15.9 : PCR - Polymerase Chain Reaction

Studying DNA and RNA

86.3K Views

15.10 : Real Time RT-PCR

Studying DNA and RNA

57.3K Views

15.11 : RACE - Rapid Amplification of cDNA Ends

Studying DNA and RNA

6.4K Views

15.12 : Sanger Sequencing

Studying DNA and RNA

754.6K Views

15.13 : Next-generation Sequencing

Studying DNA and RNA

89.0K Views

15.14 : RNA-seq

Studying DNA and RNA

10.0K Views

15.15 : Genome Annotation and Assembly

Studying DNA and RNA

18.9K Views

See More