Small Particles with Big Impact : Structural Studies of Viruses and Toxicological Studies of Nanodiamonds

Sammanfattning: Nanoparticles (NPs) can be found everywhere and their existence has both beneficial and harmful consequences for the environment and living beings. The investigations on which this thesis is based upon have contributed to an increased understanding of some of these particles and to the development of a method that could be used to study their structure.Three different NPs have been studied by different means. In the first study, I describe how single-particle cryo-electron microscopy was used to determine the atomic structure of an algal virus; Chaetoceros tenuissimus RNA virus type II. This virus is taxonomically classified in the order Picornavirales, which includes viruses that infect a wide range of organisms, including humans, plants and insects. By comparing the algal virus structure to structures of related viruses in the order, we could identify a number of traits that were likely acquired or lost among these viruses during the course of evolution. In the second study, rice dwarf virus was utilised as a test sample to develop a new structural biology method, single-particle coherent diffractive imaging (CDI). The method aims to study macromolecules in a single-particle fashion at room temperature with the help of an X-ray free-electron laser, thus enabling studies of fast dynamics without the need to crystallize or freeze the sample. The study was the first of several within a large international collaboration and the first single-particle CDI experiment reported using femtosecond hard X-ray pulses. Despite several advances by the team, many challenges remain for the method to reach its full potential. In the third study, I describe in vitro and in vivo toxicological studies of detonation nanodiamonds (DNDs). I could demonstrate that some DNDs are toxic and that the toxicity is dependent both on the core and surface of the particles. DNDs are suggested for numerous different biomedical applications that alternately utilise their toxic properties or require biocompatibility. The results presented show that these contrasting properties can be exhibited by similar DNDs and that thorough characterisation and close control of the manufacturing process is essential for biomedical applications.This thesis explores how studies of some of nature’s nanoparticles - viruses - can lead to biological insight, how virus NPs can play a role in developing new technologies that may enable an even deeper understanding and explores issues that need to be considered for NPs to reach their potential in biomedical applications.