qPCR Quality Control
The qPCR is an instrumental technique, and thus can produce false negative and false positive results. Contamination remains an issue especially for diagnostic laboratories. The main causes of production of false positive results are the accidental contamination of the samples or the reagents with positive samples (cross-contamination) or with amplification products and plasmid clones (carry over contamination). Quality Control in any qPCR procedure is essential to prevent problems.
To minimize the risks, several practices should be applied. It is recommended to establish space and time separation of pre- and post-amplification activities, in particular, separation of pre-PCR activities from recombinant DNA activities, as well as to define two different pre-PCR areas: for the preparation of the master mix and for the addition the nucleic acid template to the reaction mixture. Each working area must have its own separate set of equipment, including pipettes, reagents, pipette tips, racks, centrifuges, vortex, lab coats, etc., and lab coats and gloves should be worn at all times, and gloves should be changed frequently.
In addition, all reagents should be prepared in large volumes and aliquoted into single-use volumes for storage and free from contaminating nucleic acids and/or nucleases.
Other actions to prevent or reduce the risk of PCR contaminations are the use of UV light before carrying out the experiments in the sample preparation lab and in the cabinet where the amplification mixture is prepared, and samples should be manipulated with specialized barrier or positive-displacement pipettes, which prevent the carryover of aerosols created during pipetting.
The use of Uracil-DNA-glycosylase (UDG; also called uracil-N-glycosylase or UNG) is recommended, as it can eliminate the contamination arising from PCR products. During amplification, dTTP is substituted with dUTP, so the DNA product will contain dU instead of dT. Subsequent PCR runs are programmed to include a 50 °C incubation step with UDG, which will mediate cleavage of any contaminating DNA strands containing dU.
In addition of the prevention measures for avoiding contamination, a suite of controls must be included in order to correctly interpret the results of a qPCR.
Rodríguez-Lázaro, D. and Hernández, M. (2013). Introduction to the Real-time PCR In Real-Time PCR in Food Science: Current Technology and Applications.
D. Rodriguez-Lazaro, ed. (Norfolk, UK: Caister Academic Press). ISBN: 978-1-908230-15-7.
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Provides both the novice and experienced user with an invaluable reference to a wide-range of real-time PCR technologies and applications and supplies detailed technical insights into the underlying principles, methods and practice of real-time PCR.
Edited by: David Rodríguez-Lázaro read more ...
An indispensable manual on real-time PCR for scientists in the food industry and for anyone involved in the detection of foodborne pathogens.
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Aimed specifically at microbiologists, this volume describes and explains the most important aspects of current real-time quantitative PCR (qPCR) strategies, instrumentation and software.
Edited by: Suzanne Kennedy and Nick Oswald"an essential book ... a valuable tool to all those interested in PCR" (Doodys); "an essential guide" Aus. J. Med. Sci. read more ...
Control, optimize and troubleshoot PCR, reverse transcriptase PCR, real-time PCR and quantitative PCR. An essential book.
Edited by: Keith E. Herold and Avraham Rasooly "a comprehensive and felicitous compendium" (Drug Research) read more ...
Applications in the biomedical and life sciences: biomolecule separation, electrophoresis, chromatography, protein and cell separation, genetic and transcriptome analysis, PCR, cell viability analysis and microorganism capturing.