Search Thermo Fisher Scientific
Choosing the right electrophoresis products for your nucleic acid analysis workflow is critical to the success of your experiment. This article is a quick guide on how to improve gel electrophoresis results.
Ladder selection for sizing PCR products or high-throughput gels is an important step in molecular biology experiments. The Thermo Fisher Scientific FastRuler DNA ladders are designed for fast separation and short migration distances and can be a great option for these applications. Here are some guidelines for choosing the right ladder:
The right ladder can greatly impact the accuracy and efficiency of your experiment (Figure 1).
Figure 1. High-throughput agarose gel electrophoresis using the FastRuler High Range DNA Ladder. DNA samples run alongside the appropriate DNA ladder, which shows clean separation of ladder markers.
Agarose concentration can have a big impact on the quality of separation of sample or ladder on a gel. Lower agarose gel concentration is suitable for analyzing longer DNA fragments, and vice versa (Figure 2).
Figure 2. Effect of agarose concentration on DNA resolution. (A) Poor band resolution resulting from incorrect agarose concentration. (B) Improved band resolution with correct agarose concentration.
The two common running buffers used in DNA electrophoresis are TAE and TBE buffer solutions (Figure 3). Linear double-stranded DNA fragments migrate approximately 10% slower in TBE buffer when compared to TAE buffers.
Figure 3. TAE versus TBE running buffers in DNA electrophoresis. Linear double-stranded nucleic acid fragments migrate approximately 10% slower in TBE buffer, so TAE is best used to differentiate smaller DNA fragments while TBS is best used to differentiate heavier or longer DNA fragments.
The guidelines for choice of TAE and TBE buffers are:
The sample loading buffer serves two purposes in DNA gel electrophoresis:
When selecting a dye, care must be taken to avoid masking bands of interest with the tracking dyes that are present in loading buffers. For example, 6X Orange DNA loading buffer contains the dyes Orange G and xylene cyanol. Orange G migrates like a 50 bp DNA fragment, and xylene cyanol migrates like 4,000 bp DNA fragment (Figure 4). Although this loading buffer is generally suitable for electrophoresis of small fragments, bands of ~50 bp fragments may not be visible due to masking by the Orange G.
Ensure the amount of DNA loaded into each well is at least 20 ng per band if the gel is stained using ethidium bromide (EtBr) or SYBR Safe DNA Gel Stain. SYBR Gold Nucleic Acid Gel Stain is more sensitive than EtBr or SYBR Safe DNA Gel Stain. If using SYBR Gold Nucleic Acid Gel Stain, the DNA loaded into each well should be at least 1 ng per band.
Figure 5. Effect of DNA sample concentration on gel migration patterns. Increasing concentrations of DNA samples aliquoted into different wells on an agarose gel. Bands at 2,500 bp and 100 bp are shown.
When the DNA samples in the center lanes migrate faster than the peripheral lanes, the DNA bands form a crescent shape; this is called the “smiling” effect (Figure 6). The main causes of bands “smiling” on a gel are:
Figure 6. “Smiling” effect on a gel. DNA samples run via agarose gel electrophoresis may encounter the “smiling” effect where center samples run faster than outer-lane samples usually due to high voltage or loose contacts in the gel tank.
A gel must be fully submerged in running buffer with 3–5 mm of buffer covering the gel’s surface. Insufficient amounts of running buffer can cause poor resolution, band distortion, or even melting of the gel (Figure 7). However, excess running buffer can decrease DNA mobility and cause band distortion.
For Research Use Only. Not for use in diagnostic procedures.