@article{kononchik_vancini_brown_2011, title={Alphavirus adsorption to mosquito cells as viewed by freeze fracture immunolabeling}, volume={415}, ISSN={["0042-6822"]}, DOI={10.1016/j.virol.2011.04.011}, abstractNote={Sindbis Virus (SV), the prototype alphavirus in the family togaviridae, infects both mammalian and insect cells. The ability of SV to infect cells possessing significantly different biochemical environments suggests that there may be a common mode of entry into each cell type. Previous studies show that up to 4h post infection cells are permeable to small ions and alpha sarcin suggesting that the plasma membrane is compromised as infection takes place. Thin-section electron microscopy has also shown SV to bind to the plasma membrane and lose its electron dense core through a pore like structure developed upon interaction of the virus with the cell surface. Using freeze-fracture replicas, thin-sections and antibody labeling the data presented herein show virus associated with intramembrane particles on mosquito cells. These data suggest that the intramembrane particles associated with SV may be part of the pore structure consisting of virus proteins and cell receptor.}, number={2}, journal={VIROLOGY}, author={Kononchik, Joseph P. and Vancini, Ricardo and Brown, Dennis T.}, year={2011}, month={Jul}, pages={132–140} }
 @article{kononchik_nelson_hernandez_brown_2009, title={Helical virus particles formed from morphological subunits of a membrane containing icosahedral virus}, volume={385}, ISSN={["0042-6822"]}, DOI={10.1016/j.virol.2008.12.015}, abstractNote={The classic publication by Caspar and Klug in 1962 [Physical principles in the construction of regular viruses. Cold Spring Harbor Symp. Quant. Biol. 27:1–24.] has formed the basis of much research on virus assembly. Caspar and Klug predicted that a single virus morphological unit could form a two dimensional lattice composed of 6-fold arrays (primitive plane), a family of icosahedra of increasing triangulation numbers (T) and helical arrays of varying length. We have shown that icosahedral viruses of varying T numbers can be produced using Sindbis virus [Ferreira, D. F. et al. 2003. Morphological variants of Sindbis virus produced by a mutation in the capsid protein. Virology 307:54–66]. Other studies have shown that Sindbis glycoproteins can also form a 2-dimensional lattice confirming Caspar and Klug's prediction of the primitive plane as a biologically relevant structure [VonBonsdorff, C. H., and S. C. Harrison. 1978. Sindbis virus glycoproteins form a regular icosahedral surface lattice. J. Virol. 28:578]. In this study we have used mutations in the glycoproteins of membrane containing Sindbis virus to create helical-virus-like particles from the morphological subunits of a virus of icosahedral geometry. The resulting virus particles were examined for subunit organization and were determined to be constructed of only 6-fold rotational arrays of the virus glycoproteins. A model of the tubular virus particles created from the 6-fold rotational arrays of Sindbis virus confirmed the observed structure. These experiments show that a common morphological unit (the Sindbis E1–E2 heterodimer) can produce three different morphological entities of varying dimensions in a membrane-containing virus system.}, number={2}, journal={VIROLOGY}, author={Kononchik, Joseph R., Jr. and Nelson, Steevenson and Hernandez, Raquel and Brown, Dennis I.}, year={2009}, month={Mar}, pages={285–293} }