02 February, 2022
Since the first human genome was sequenced over 20 years ago, sequencing technologies and the sample preparation methods associated with them have evolved rapidly. Early sample prep methods required DNA and/or RNA to be extracted from large numbers of cells from a section of tissue or a cell culture. The sequencing data produced was therefore an average of what was happening in all of the cells in that sample and meant that we couldn鈥檛 understand how a single cell behaves.
However, over the last ten years, major developments in sample prep techniques have enabled us to extract and sequence the genetic material of a single cell. Now, single cell sequencing is increasingly becoming an essential part of the biologists鈥 toolkit. Used by researchers at the Babraham Institute and others worldwide, we will be able to further our understanding of embryo development, immunology and much, much more.
In this blog, we explore:
Sequencing is a technology that allows us to read the sequence of DNA or RNA. Studying DNA and RNA sequences allows us to understand which sections are needed for a stem cell to become a neuron or for the body to respond to viral infection, for example.
The first sequencing method was developed by in the late 1970s. The method was gel based and used DNA polymerase (an enzyme that catalyses the synthesis of DNA) with a mixture of and standard nucleotides (dNTPs). Using a mix of ddNTPs and dNTPs causes DNA synthesis to stop early at random during the sequencing reaction, producing DNA fragments of different lengths. Four reactions are run, one for each of the bases that make up DNA, and the DNA fragments produced can be visualised using . Fragments run on a gel are separated by length and this means we can read the DNA sequence base by base.
By the 1980s, Sanger鈥檚 original method had been optimised, automated and made commercially available. This allowed scientists to feed a prepared DNA sample into a machine and view the gel results. Sanger sequencing was at the core of the human genome project and is still used today for some experiments. During the 2000s, a lot of effort was made to reduce the cost of sequencing and develop high throughput sequencing methods that would allow scientists to perform large sequencing projects.
Today, there are several different approaches to sequencing and one of the most widely used methods is Illumina sequencing. ; library preparation, cluster generation, sequencing and data analysis:
Simply, sequencing helps increase our understanding of the world around us and develop things like new therapeutics that can benefit the global community. The next evolution of sequencing 鈥 single-cell sequencing 鈥 is already unlocking more knowledge that could lead to exciting developments.
The human body is made up over 200 different cell types that work together in complex biological systems. Almost all the cells in the body share the same DNA but the 鈥榤arks鈥 that regulate how the DNA is read by the cell and the RNA present will differ between cells in a sample.
鈥淏ulk鈥 sequencing methods (where we extract DNA/RNA from a large number of cells) were a major development in the early 00鈥檚. They are very useful for comparisons between different species, e.g., how similar are the brains of mice and humans, and useful for looking at the levels of RNA in cells from patients with different conditions versus healthy individuals. The data produced by bulk methods is an average of what is happening in all the cells in the sample. This means bulk data is not ideal for looking at systems made up of a lot of different specialised cells, like the brain, or complex systems such as developing embryos.
Single-cell sequencing is a relatively new technology that allows sequencing data to be linked back to an individual cell in a sample. This means we are now able to answer questions where cell specific differences are important. An example of this is research by the Reik group into early embryo development.
The key to sequencing DNA and RNA from single cells is library preparation methods that have been developed to work with the tiny amounts of DNA and RNA in a single cell 鈥 the actual sequencing stage is the same as for bulk samples.
A few strategies for single cell library prep have evolved but they share common features. For example, tissue samples like tumours must be broken up into a single cell suspension so cells can be more easily isolated from one another. The downside of this is we lose information about where the cell was located in the original sample. Another common feature is that the RNA, DNA or cDNA from each cell is barcoded in some way. These barcodes allow us to identify which cell the DNA/RNA/cDNA belongs to. Not at all alike the barcodes you鈥檙e used to seeing in a supermarket, these barcodes are short bits of DNA with a known sequence that can be used during data analysis to group all the sequences from one cell together. Frequently used methods include:
There are pros and cons of both approaches but having different techniques available allows researchers to pick the one most suited to answering their question.
Single cell sequencing is allowing scientists to answer questions where the differences between individual cells in a system are vitally important. It is helping scientists in the Reik group at the Institute to investigate how the cells of an embryo divide and become the 200 different cell types in the human body, and also scientists in the Liston and Turner labs to name a few. Single cell sequencing is also at the core of , an international effort to create a comprehensive map of all the cells in the human body. By understanding the location and function of all cells in the body, we will be able to unlock key insight into human health that will enable scientists to develop new preventatives and therapeutics.
At the Institute, we have eight cutting-edge facilities, including one dedicated to sequencing. Our Genomics facility offers single cell sequencing using 10x Genomics Chromium and SMART-seq v4 on Illumina sequencers. We also support Babraham Institute researchers with their custom sequencing projects. Our facility is also open for external users on a fee-for-service basis. Find out more about the expertise and capabilities of our Genomics facility in the video below:
02 February 2022
By Alumni Blogger