Research Overview

Our work in non-invasive diagnostics uses next-generation sequencers as molecular counters to explore a phenomenon called circulating cell free DNA (cfDNA). When cells die, their genome gets digested into small nucleosome-sized pieces of DNA that circulate in the blood. Nearly all organs of the body contribute such DNA, as well as RNA. In particular, the blood of pregnant women contains DNA from their fetus. We used this phenomenon to develop the first non-invasive diagnostic for Down syndrome and other aneuploidies, and versions of this test are now offered worldwide. In 2014, approximately one million women were able to avoid dangerous invasive tests, such as amniocentesis, by using a simple blood test based on our approach – thereby saving thousands of lives. Our research in this area has enabled us to measure many other aspects of the fetus non-invasively – including sequencing its genome and monitoring its developmental gene expression program.

Another area in which we have combined cfDNA and high throughput sequencing is in the care of organ transplant recipients. Heart transplant patients are constantly monitored for rejection, in which their immune system recognizes the transplanted heart as a foreign object and attacks it. These patients must take strong immunosuppressant drugs and are monitored for rejection by invasive biopsies. We realized that the heart transplant should be thought of as a genome transplant, since each cell in the donor heart has a different genome than the recipient. Monitoring the quantity of this distinct DNA in the blood provides a direct window into the health of the transplanted organ, since when more cells die more DNA is contributed to the blood. Finally, not all of the DNA in one’s blood is human – a small fraction of it derives from the microbiome of the individual. We have been exploring this phenomenon as a tool to monitor the microbiome and as a diagnostic for infectious disease.