Novel Technology To Investigate Gene Activities And Mutations In Cancer Cells
Knowing how mutations in cancer cells work will help researchers better understand how they evolve to become resistant to drugs
It is well known that not every cancer cell in a tumour is alike, and that mutations develop in the cells during the course of tumour growth. Some of these mutations can cause the tumour to develop resistance against therapy. To understand the complexity of the tumour, it is often necessary to sequence the entire tumour.
However, there are limitations to existing technologies in understanding the different components of a tumour and how such mutations change its characteristics. In particular, it is technically challenging to simultaneously sequence a single cell's DNA and analyse the activities of genes.
To address this problem, the team headed by Dr Axel Hillmer, senior author and Group Leader at GIS, developed a novel technology termed COncurrent single cell RNA and TArgeted DNA sequencing (CORTAD-seq)
Dr Kong Say Li, the lead author and Research Associate at GIS said, "CORTAD-seq is an enabling tool which can be implemented easily by other researchers that could lead to more impactful discoveries. The applications of this method include gaining insights into the cancer evolution and clonal heterogeneity, studying the mechanisms of drug resistance towards targeted therapy as well as discriminate between gene activities of cancer and normal cells by the identification of cancer mutations."
Dr Mark Lynch, Director of Single-Cell Genomics at Fluidigm, said, "Fluidigm is privileged to be partnered with GIS to develop CORTAD-seq, using microfluidics on the C1 system. This novel single-cell, multi-omic technology will help the characterisation of the tumour microenvironment at single-cell resolution and will thus help studies in cancer and immuno-oncology."
Professor Ng Huck Hui, Executive Director at GIS, said, "We are delighted to be working with NCCS and Fluidigm Corporation to develop this novel technology. Such cross-boundary collaborations allow us to further our capabilities and break new frontiers in genomic science. Doing so will also help us better understand how cancer works, and will help bring about better healthcare outcomes for Singaporeans."
The study was published in Clinical Chemistry (http://clinchem.aaccjnls.org/