Next-generation epigenetic analysis: direct reading of DNA methylation. This project aims to develop a new molecular tool to directly and dynamically read chemical modifications on genomic DNA (epigenetics) by utilizing advanced nanomaterials with the unique features of Raman spectroscopy. Epigenetics affects cellular processes and controls genetic programs by turning them “on” and “off" but there is currently no direct method to measure modifications on DNA. A new technology will be designed to ....Next-generation epigenetic analysis: direct reading of DNA methylation. This project aims to develop a new molecular tool to directly and dynamically read chemical modifications on genomic DNA (epigenetics) by utilizing advanced nanomaterials with the unique features of Raman spectroscopy. Epigenetics affects cellular processes and controls genetic programs by turning them “on” and “off" but there is currently no direct method to measure modifications on DNA. A new technology will be designed to avoid complicated procedures/chemistry for DNA epigenetic analysis providing a specific molecular fingerprint. The anticipated outcomes include a new technique and advanced knowledge in nanomaterials and DNA functions, thus strengthening the economic viability of Australian manufacturing and biotechnology sectors.Read moreRead less
DNA exhibits new self-assembled structures due to clustered DNA methylation. This project aims to develop a technology to investigate detailed epigenetic patterns in DNA by directly interrogating the physical properties of DNA polymers in their native state. Epigenetics controls whether genes and genetic programs are turned on or off in living systems. The project will build on a recent discovery that key physical properties of native DNA polymers are strongly influenced by epigenetic patterns c ....DNA exhibits new self-assembled structures due to clustered DNA methylation. This project aims to develop a technology to investigate detailed epigenetic patterns in DNA by directly interrogating the physical properties of DNA polymers in their native state. Epigenetics controls whether genes and genetic programs are turned on or off in living systems. The project will build on a recent discovery that key physical properties of native DNA polymers are strongly influenced by epigenetic patterns created by living organisms. By fully understanding this phenomenon, this project aims to provide new tools for the study of epigenetics with broad potential applications in the life sciences, biotechnology and nanotechnology.Read moreRead less