Nanoimaging the cellular architecture of the malaria parasite, Plasmodium falciparum. The immediate benefit of this work will be in the understanding and treatment of malaria - a disease that kills approximately 1 million children annually. The ability to image the three-dimensional structure of cells at high resolution will allow us to ask fundamental questions about the cellular architecture of the malaria parasite and to design novel antimalarial strategies. By developing new methods for cor ....Nanoimaging the cellular architecture of the malaria parasite, Plasmodium falciparum. The immediate benefit of this work will be in the understanding and treatment of malaria - a disease that kills approximately 1 million children annually. The ability to image the three-dimensional structure of cells at high resolution will allow us to ask fundamental questions about the cellular architecture of the malaria parasite and to design novel antimalarial strategies. By developing new methods for correlating structure and elemental location, the work in this proposal will offer a new paradigm for the study of cellular function and disease. This represents an important advance in the suite of investigative tools available to the biotechology sector and will see a corresponding improvement in our understanding of a wide range of disease states.Read moreRead less
Extending X-ray Crystallography to Allow Structure Retrieval from Highly Disordered Crystals and Nanocrystals. X-ray crystallography is one of the most important tools in structural biology, responsible for over 80 per cent of the protein structures solved today. Obtaining X-ray diffraction data however is critically dependent on having large, high quality crystals. Many proteins, particularly membrane proteins, only form nanocrystals or crystals of poor quality which prevents their structure be ....Extending X-ray Crystallography to Allow Structure Retrieval from Highly Disordered Crystals and Nanocrystals. X-ray crystallography is one of the most important tools in structural biology, responsible for over 80 per cent of the protein structures solved today. Obtaining X-ray diffraction data however is critically dependent on having large, high quality crystals. Many proteins, particularly membrane proteins, only form nanocrystals or crystals of poor quality which prevents their structure being solved. This project aims to combine ideas from X-ray coherent diffraction imaging and X-ray crystallography to develop a method that can be used for structure retrieval from nanocrystals or crystals which are highly disordered. A particular emphasis will be placed on solving the structure of membrane proteins which are of special importance in drug development.Read moreRead less