Browsing by Author "McDonald, Sarah M."

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    Genetic determinants restricting the reassortment of heterologous NSP2 genes into the simian rotavirus SA11 genome
    Mingo, Rebecca; Zhang, Shu; Long, Courtney P.; LaConte, Leslie E. W.; McDonald, Sarah M. (Springer Nature, 2017-08-24)
    Rotaviruses (RVs) can evolve through the process of reassortment, whereby the 11 double-stranded RNA genome segments are exchanged among strains during co-infection. However, reassortment is limited in cases where the genes or encoded proteins of co-infecting strains are functionally incompatible. In this study, we employed a helper virus-based reverse genetics system to identify NSP2 gene regions that correlate with restricted reassortment into simian RV strain SA11. We show that SA11 reassortants with NSP2 genes from human RV strains Wa or DS-1 were efficiently rescued and exhibit no detectable replication defects. However, we could not rescue an SA11 reassortant with a human RV strain AU-1 NSP2 gene, which differs from that of SA11 by 186 nucleotides ( 36 amino acids). To map restriction determinants, we engineered viruses to contain chimeric NSP2 genes in which specific regions of AU-1 sequence were substituted with SA11 sequence. We show that a region spanning AU-1 NSP2 gene nucleotides 784-820 is critical for the observed restriction; yet additional determinants reside in other gene regions. In silico and in vitro analyses were used to predict how the 784-820 region may impact NSP2 gene/protein function, thereby informing an understanding of the reassortment restriction mechanism.
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    Molecular Surveillance of Viral Processes Using Silicon Nitride Membranes
    Gilmore, Brian L.; Tanner, Justin R.; McKell, Allison O.; Boudreaux, Crystal E.; Dukes, Madeline J.; McDonald, Sarah M.; Kelly, Deborah F. (MDPI, 2013-03)
    Here we present new applications for silicon nitride (SiN) membranes to evaluate biological processes. We determined that 50-nanometer thin films of SiN produced from silicon wafers were sufficiently durable to bind active rotavirus assemblies. A direct comparison of SiN microchips with conventional carbon support films indicated that SiN performs equivalent to the traditional substrate to prepare samples for Electron Microscopy (EM) imaging. Likewise, SiN films coated with Ni-NTA affinity layers concentrated rotavirus particles similarly to affinity-coated carbon films. However, affinity-coated SiN membranes outperformed glow-discharged conventional carbon films 5-fold as indicated by the number of viral particles quantified in EM images. In addition, we were able to recapitulate viral uncoating and transcription mechanisms directed onto the microchip surfaces. EM images of these processes revealed the production of RNA transcripts emerging from active rotavirus complexes. These results were confirmed by the functional incorporation of radiolabeled nucleotides into the nascent RNA transcripts. Collectively, we demonstrate new uses for SiN membranes to perform molecular surveillance on life processes in real-time.
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    Visualizing virus particle mobility in liquid at the nanoscale
    Varano, A. Cameron; Rahimi, Amina; Dukes, Madeline J.; Poelzing, Steven; McDonald, Sarah M.; Kelly, Deborah F. (The Royal Society of Chemistry, 2015-09-04)
    Currently, there remains a critical need to develop real-time imaging resources for life sciences. Here, we demonstrate the use of high resolution in situ imaging to observe biological complexes in liquid at the nanoscale. Using a model virus system, we produced the first time-resolved videos of individual biological complexes moving in solution within an electron microscope.