A novel application of small-angle scattering techniques: Quality assurance testing of virus quantification technology.

Small-angle scattering (SAS) techniques, like small-angle X-ray scattering (SAXS) and small-angle neutron scattering (SANS), were used to measure and thus to validate the accuracy of a novel technology for virus sizing and concentration determination. These studies demonstrate the utility of SAS techniques for use in quality assurance measurements and as novel technology for the physical characterization of viruses.

Mass Spectrometry and Integrated Virus Detection System Characterization of MS2 Bacteriophage.

ABSTRACT In this study, we demonstrate the effect of sample matrix composition of MS2 virus on its characterization by ESI-MS and IVDS. MS2 samples grown and purified using various techniques showed different responses on ESI-MS than that on IVDS. The LC-MS of the specific biomarker of MS2 bacteriophage from an infected Escherichia coli sample was characterized by the presence of E. coli proteins. The significant impact of sample matrix was observed upon identification of MS2 using a database search. Infected E. coli with MS2 showed a matching score indifferent from uninfected ones. Only purified MS2, using CsCl and analyzed by LS-MS, showed a positive match using the database search. However, the variation in MS2 sample matrix had no effect on the deification of MS2.

The MS2 coat protein shell is likely assembled under tension: a novel role for the MS2 bacteriophage A protein as revealed by small-angle neutron scattering.

Recombinant forms of the bacteriophage MS2 and its RNA-free (empty) MS2 capsid were analyzed in solution to determine if RNA content and/or the A (or maturation) protein play a role in the global arrangement of the virus protein shell. Analysis of the (coat) protein shell of recombinant versions of MS2 that lack the A protein revealed dramatic differences compared to wild-type MS2 in solution. Specifically, A protein-deficient virus particles form a protein shell of between 31(+/-1) A and 37(+/-1) A. This is considerably thicker than the protein shell formed by either the wild-type MS2 or the RNA-free MS2 capsid, whose protein shells have a thickness of 21(+/-1) A and 25(+/-1) A, respectively. Since the A protein is known to separate from the intact MS2 protein shell after infection, the thin shell form of MS2 represents the pre-infection state, while the post-infection state is thick. Interestingly, these A protein-dependent differences in the virus protein shell are not seen using crystallography, as the crystallization process seems to artificially compact the wild-type MS2 virion. Furthermore, when the A protein is absent from the virus shell (post-infection), the process of crystallization exerts sufficient force to convert the protein shell from the post-infection (thick) state to the pre-infection (thin) conformation. In summary, the data are consistent with the idea that RNA content or amount does not affect the structure of the MS2 virus shell. Rather, the A protein influences the global arrangement of the virus coat dramatically, possibly by mediating the storage of energy or tension within the protein shell during virus assembly. This tension may later be used to eject the MS2 genomic RNA and A protein fragments into the host during infection.

Bacteriophage MS2: molecular weight and spatial distribution of the protein and RNA components by small-angle neutron scattering and virus counting.

Small-angle neutron scattering (SANS) has been used to extend the structural characterization of the MS2 phage by examining its physical characteristics in solution. Specifically, the contrast variation technique was employed to determine the molecular weight of the individual components of the MS2 virion (protein shell and genomic RNA) and the spatial relationship of the genomic RNA to its protein shell. A consequence of this work was to evaluate a novel particle counting instrument, the integrated virus detection system (IVDS) that, in combination with SANS, has the potential to provide rapid quantitative physical characterization of unidentified viruses and phage.