Real-Time PCR
A Brief History of PCR
Category: History | Technology
A Brief History of PCR
from Carl T. Wittwer and Jared S. Farrar writing in PCR Troubleshooting and Optimization: The Essential Guide:
The polymerase chain reaction (PCR) has become a fundamental tool in molecular research and clinical testing. A recent review by Wittwer and Farrar discusses the origins of PCR, its early evolution including adaptation to RNA, thermostable polymerases, automation, improvements in specificity and rapid temperature cycling. Perhaps the most significant advance is real-time PCR, combining both amplification and detection into one instrument as a superior solution for nucleic acid quantification. Real-time PCR is enabled by monitoring the reaction with double stranded DNA dyes or specific probes, including hydrolysis, hybridization, and conformation-sensitive probes. PCR product and probe melting analysis continues to improve in resolution, allowing greater sequence detail for genotyping and variant scanning. Microfluidic platforms and digital PCR are destined to find more applications in the future.
Read more: PCR Troubleshooting and Optimization: The Essential Guide
from Carl T. Wittwer and Jared S. Farrar writing in PCR Troubleshooting and Optimization: The Essential Guide:
The polymerase chain reaction (PCR) has become a fundamental tool in molecular research and clinical testing. A recent review by Wittwer and Farrar discusses the origins of PCR, its early evolution including adaptation to RNA, thermostable polymerases, automation, improvements in specificity and rapid temperature cycling. Perhaps the most significant advance is real-time PCR, combining both amplification and detection into one instrument as a superior solution for nucleic acid quantification. Real-time PCR is enabled by monitoring the reaction with double stranded DNA dyes or specific probes, including hydrolysis, hybridization, and conformation-sensitive probes. PCR product and probe melting analysis continues to improve in resolution, allowing greater sequence detail for genotyping and variant scanning. Microfluidic platforms and digital PCR are destined to find more applications in the future.
Read more: PCR Troubleshooting and Optimization: The Essential Guide
Detection of Microbes in Water
Molecular techniques based on genomics, proteomics and transcriptomics are rapidly growing as complete microbial genome sequences are becoming available and advances are made in sequencing technology, analytical biochemistry, microfluidics and data analysis. While the clinical and food industries are increasingly adapting these techniques, there appear to be major challenges in detecting health-related microbes in source and treated drinking waters. This is due in part to the low density of pathogens in water, necessitating significant processing of large volume samples. Quantitative PCR is a state-of-the-art technique available for pathogen detection and characterization from water.
Although quantitative PCR is almost 15 years old, only recently has it become a tool for diagnostic purposes in water microbiology. Conventional PCR and its variations largely give qualitative results (MPN-PCR being an exception) and are most useful when presence-absence of the target is to be noted. Since the product is measured at the end of the PCR, where the amount of amplicon (product) in a given reaction tube is likely to have been affected by saturation effects of excess amplicons or poorly optimized reactions, the yield of amplicon does not relate to the original starting concentration. Furthermore, a second step is always required for verification of the product. Because there is a quantitative relationship between amount of starting target and amount of PCR product during the exponential phase of the PCR process, if the yield of amplicons are made in the exponential or initial linear phases of amplification, which is the case in qPCR, then the data obtained can provide a quantitative relationship to the starting concentration.
In qPCR, fluorescent dyes and probes are generally used in addition to regular PCR primers, thus allowing for in situ assay of the targeted amplicon. With increasing cycles of PCR, the increase in target is directly quantified by an increase in fluorescence that is emitted by increased intercalation of fluorescent dye or hybridization of fluorescent oligonucleotide probe(s) to the target. These techniques are not "quantitative" in the strictest sense, as they measure a kinetic reaction. Often called "real time" or kinetic PCR, they do not measure the reaction as it occurs, but measure the results of the reaction in a pause between cycles. Perhaps the most correct descriptor is Kinetic PCR, but that term has not been adopted in molecular microbiology.
Further reading: Environmental Microbiology: Current Technology and Water Applications
Although quantitative PCR is almost 15 years old, only recently has it become a tool for diagnostic purposes in water microbiology. Conventional PCR and its variations largely give qualitative results (MPN-PCR being an exception) and are most useful when presence-absence of the target is to be noted. Since the product is measured at the end of the PCR, where the amount of amplicon (product) in a given reaction tube is likely to have been affected by saturation effects of excess amplicons or poorly optimized reactions, the yield of amplicon does not relate to the original starting concentration. Furthermore, a second step is always required for verification of the product. Because there is a quantitative relationship between amount of starting target and amount of PCR product during the exponential phase of the PCR process, if the yield of amplicons are made in the exponential or initial linear phases of amplification, which is the case in qPCR, then the data obtained can provide a quantitative relationship to the starting concentration.
In qPCR, fluorescent dyes and probes are generally used in addition to regular PCR primers, thus allowing for in situ assay of the targeted amplicon. With increasing cycles of PCR, the increase in target is directly quantified by an increase in fluorescence that is emitted by increased intercalation of fluorescent dye or hybridization of fluorescent oligonucleotide probe(s) to the target. These techniques are not "quantitative" in the strictest sense, as they measure a kinetic reaction. Often called "real time" or kinetic PCR, they do not measure the reaction as it occurs, but measure the results of the reaction in a pause between cycles. Perhaps the most correct descriptor is Kinetic PCR, but that term has not been adopted in molecular microbiology.
Further reading: Environmental Microbiology: Current Technology and Water Applications