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Fragment analysis is a genetic analysis method comprising a series of techniques in which DNA fragments are fluorescently labeled, separated by capillary electrophoresis (CE), and sized by comparison to an internal standard.
CE-based genetic analyzers are capable of performing both Sanger sequencing and fragment analysis. In contrast to Sanger sequencing, fragment analysis can provide sizing, relative quantitation, and genotyping information using fluorescently labeled DNA fragments produced by PCR using primers designed for a specific DNA target. This information enables researchers to detect differences in alleles, homo- and heterozygosity, chimerism, sample mixtures, and inheritance. Fragment analysis enables a wide variety of applications, including cell line authentication, determination of CRISPR-Cas9 genome editing efficiency, microsatellite marker analysis, SNP genotyping, and more. Fragment analysis has a fast turnaround time, high sensitivity and resolution, and is cost-effective.
Additional advantages of fragment analysis include:
For more information on fragment analysis and its applications, download our comprehensive guide.
The DNA fragment analysis workflow consists of four general steps: DNA extraction, PCR amplification, capillary electrophoresis, and data analysis (Figure 1).
DNA extraction is a critical first step in the experimental workflow of DNA fragment analysis. The overall efficiency, quality, and size of the PCR product can be significantly affected by characteristics of the sample itself and the method chosen for nucleic acid extraction and purification. Ideal methods will vary depending on the source or tissue type, how the sample was obtained from its source, and how the sample was handled or stored prior to extraction.
To perform fragment analysis on a CE system, primers must be designed that flank the region of interest. Fluorescent dyes are attached to the primers, and the fragments are amplified by PCR before electrophoresis.
To prepare for capillary electrophoresis, a spectral calibration with the corresponding matrix standard for the selected group of dyes must be performed on the genetic analyzer in order to accurately detect the dye-labeled primers. Each unknown sample is mixed with the size standard and formamide before proceeding with electrophoresis. Size standards allow sizing of sample peaks and correct for injection variations.
During capillary electrophoresis, the products of the PCR are injected electrokinetically into capillaries filled with polymer. High voltage is applied so that the fluorescent DNA fragments are separated by size and are detected by a laser/camera system.
Data analysis software provides a profile of the separation, precisely calculates the sizes of the fragments, and determines the microsatellite alleles present in the sample (Figure 2).
Learn more about the steps of the fragment analysis workflow ›
Fragment analysis enables many applications and methods, including:
Fragment analysis is a powerful research tool that provides relative quantitation, sizing, and genotyping information and enables a wide array of genetic analysis applications.
To find out more about the applications enabled by CE, see the article What applications does capillary electrophoresis enable?
For Research Use Only. Not for use in diagnostic procedures.