Major Milestones in PCR Technology

The concept of DNA amplification was a groundbreaking idea in the early 1980s. The challenge was to develop a method that could replicate specific DNA sequences. In 1983, Kary Mullis, a biochemist at Cetus Corporation, invented PCR. His vision was to use a cyclical process of heating and cooling to denature DNA, anneal primers, and extend new DNA strands, thus amplifying the target sequence. This proof of concept formed the basis of PCR, for which Kary Mullis was awarded the Nobel Prize in Chemistry, 1993.

In 1985, Mullis and his colleagues published the first paper describing PCR. This publication, along with the filing of a patent, marked the formal introduction of PCR to the scientific community and sparked interest in its potential applications.

The drawback of Mullis’ experiment was the denaturation of DNA polymerases from high temperature cycles during thermal cycling. A watershed moment for PCR was the introduction of Taq polymerase, an enzyme derived from the thermophilic bacterium Thermus aquaticus. Taq polymerase is heat-stable, allowing it to withstand the high temperatures.

Read more on the development of DNA polymerases

Automated thermal cyclers that allowed precise control of temperature cycles were developed in the 1990s. The invention of thermal cyclers coupled with heat stable Taq polymerases greatly improved the efficiency and reliability of PCR, driving further adoption.

Find out more about the history of thermal cyclers
Learn more about the advancements in temperature optimization in thermal cyclers

Real-Time PCR (qPCR) combines PCR amplification of DNA fragments and real-time monitoring of PCR products. By using fluorescent dyes or probes, scientists could quantify the amount of DNA produced during each cycle. RT-qPCR is widely used in diagnostics and research, where precise quantification is necessary.

Learn more on the essentials of qPCR

Reverse Transcription PCR (RT-PCR) combines the principles of reverse transcription and PCR for RNA analysis. The reverse transcription step converts RNA into complementary DNA (cDNA), which is amplified by PCR. RT-PCR has been vital for gene expression studies and RNA virus detection, such as HIV and SARS-CoV-2.

Discover one-step and two-step RT-PCR

Digital PCR is a more recent innovation that allows for the absolute quantification of DNA molecules by partitioning the sample into numerous individual reactions. This method offers higher precision and sensitivity, making it valuable for applications requiring accurate DNA quantification.

Learn more about digital PCR
Find out more about the Common PCR methods and their core benefits

PCR has become indispensable in genetic research, enabling the amplification and sequencing of specific DNA regions. In medical diagnostics, PCR is used to detect infectious agents, identify genetic mutations, and monitor disease progression. Forensic science has also benefited from PCR, allowing analysis of minute DNA samples from crime scenes.

The COVID-19 pandemic put PCR technology at the forefront of global healthcare. PCR tests for SARS-CoV-2 became widely used for diagnosing COVID-19, enabling rapid and accurate detection of the virus. The pandemic spurred innovations in nucleic acid amplification technologies, including faster and more scalable isothermal amplification methods, which were essential for managing the public health crisis.

Learn more about isothermal amplification
Discover the wide-ranging applications of PCR

Since its invention, PCR has been an engine transforming science and medicine. Ongoing advancements such as innovations in high fidelity enzymes and sophisticated instrumentation are improving the speed, accuracy, and versatility of PCR. As we look to the future, PCR will continue to be a chief cornerstone in advancing molecular biology. 

Landmark publications that propelled PCR technology are listed below.