Jonathan is Co-founder and CSO of EnPlusOne Bio. He performed his graduate work in organic synthesis at Indiana University in Bloomington, Indiana. During his time there, he secured a Briscoe Fellowship and worked in the laboratory of Professor Michael Vannieuwenhze. Much of this work was toward synthesizing 1) novel fluorescent probes to spy on bacteria and 2) macrocyclic natural products to kill them. He joined George Church’s Research Group at Harvard Medical School where he helped develop an enzymatic RNA synthesis platform that formed the technical basis of EnPlusOne Bio. Jonathan earned his BS in Chemistry from Indiana Wesleyan University and a PhD in Organic Chemistry from Indiana University.
Jon grew up in Halifax, Canada, and received his BSc in 2001 from Dalhousie University, winning the University Medal in Chemistry and conducting work in carbohydrate synthesis with Professor Bruce Grindley. After a year in the non-profit sector in Cote d’Ivoire, Jon returned to science and to Canada and received his PhD in 2008, working with Professor Masad Damha at McGill University. His doctoral work included the development of two new oligonucleotide analogues, an exploration of why 2′-fluorinated oligonucleotides show such high binding affinity, and studies on the chemical modification of ASOs and siRNAs. He then moved to Professor David Corey’s lab at UT Southwestern for postdoctoral studies, where his work included the chemical modification of promoter-targeted duplex RNAs and the use of oligonucleotide-oligospermine conjugates as antisense and antigene oligonucleotides. In 2012 Jon started his independent group at the University of Southampton, UK, where he received the 2013 Young Investigator Award from the Oligonucleotide Therapeutics Society and the 2015 Vice Chancellor’s Award for teaching. In summer 2015 he was recruited to the RNA Therapeutics Institute at UMass Medical School, where he is a professor.
George is Co-founder and Scientific Advisor of EnPlusOne Bio. He leads Synthetic Biology at the Wyss Institute, where he oversees the directed evolution of molecules, polymers and whole genomes to create new tools with applications in regenerative medicine and bioproduction of chemicals. Among his recent work at the Wyss, is development of a technology for synthesizing whole genes and engineering whole genomes, far faster, more accurate, and less costly than current methods. George is widely recognized for his innovative contributions to genomic science and his many pioneering contributions to chemistry and biomedicine. In 1984, he developed the first direct genomic sequencing method, which resulted in the first genome sequence (the human pathogen, H. pylori). He helped initiate the Human Genome Project in 1984 and the Personal Genome Project in 2005. George invented the broadly applied concepts of molecular multiplexing and tags, homologous recombination methods, and array DNA synthesizers.
His many innovations have been the basis for a number of companies including Editas (Gene therapy), Gen9bio (Synthetic DNA), Veritas & Nebula (full human genome). George is Professor of Genetics at Harvard Medical School and Professor of Health Sciences and Technology at Harvard and the Massachusetts Institute of Technology (MIT). He has been Director of the U.S. Department of Energy Technology Center and Director of the National Institutes of Health Center of Excellence in Genomic Science. He has received numerous awards including the 2011 Bower Award and Prize for Achievement in Science from the Franklin Institute and election to the National Academy of Sciences and Engineering.
