In the video DNA Sequencing: Sanger Method and Beyond Explained, I explain the Sanger method and look at some of the new approaches and methods that can speed up the DNA sequencing process.
DNA sequencing allows scientists to decode the genetic information that dictates everything from the colour of our eyes to how our cells function. One of the most widely used laboratory methods for DNA sequencing is the Sanger method, also known as the chain-terminating dideoxynucleotide method.
The Basics of Sanger Sequencing
The Sanger sequencing process begins like a PCR (Polymerase Chain Reaction), with a template DNA that you want to sequence, a single primer (and not two primers as in PCR), DNA polymerase, and nucleotides (dNTPs). However, the method also includes special nucleotides called dideoxynucleotides (ddNTPs), which play a key role in the sequencing process.
In the sequencing method, the reaction goes through 25-30 cycles of denaturing, annealing and extension, just as you would in PCR. The DNA polymerase builds new DNA strands during the reaction and adds nucleotides to the growing chain. The twist comes with the ddNTPs; when one of these is incorporated, the chain is terminated, and no further nucleotides can be added. Each ddNTP is tagged with a different fluorescent marker corresponding to one of the four DNA bases (A, T, C, or G). This allows the sequence to be read by analysing the fluorescent tags after the reaction.
Once the reaction is completed, the next step is separation. The DNA fragments are separated using gel electrophoresis. As the fragments move through the gel, a laser scans the gel for the fluorescent tags, and the sequence of the DNA is determined by the fluorescence colour at each position.
While the Sanger method has been incredibly valuable, it has limitations. It can only read between 500 to 1000 bases per reaction, making it labour-intensive and unsuitable for large-scale projects.
Moving Beyond Sanger: Advanced Sequencing Methods
As the need for faster and more efficient sequencing has grown, new methods have been developed. One such method is shotgun sequencing, where the genome is broken into random segments. Each segment is sequenced individually using the Sanger method, and then the fragments are pieced together like a puzzle to reconstruct the full genome.
Another significant advancement was Next-Generation Sequencing (NGS), also known as massively parallel sequencing. NGS technologies have revolutionised genomics by allowing the simultaneous sequencing of many DNA molecules. This high-throughput approach can detect the sequence using either fluorescent nucleotides or pH changes.
Finally, we have Third-Generation Sequencing methods, which include techniques like nanopore sequencing. In nanopore sequencing, DNA is passed through a nanopore, and the sequence can be determined by detecting changes in electrical current.
