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Of the myriad viruses, very few have been shown to be capable of self- assembly in vitro from purified components into infectious virus particles. One of these is Cowpea Chlorotic Mottle Virus (CCMV), an unenveloped spherical plant virus whose capsid self-assembles around its RNA genome without a packaging signal. While heterologous RNA, not just cognate viral RNA, can be packaged into individual CCMV virus-like particles (VLPs), the RNA needs to fall within a certain range of lengths. If it is too short, it is packaged into particles smaller than wild type, or with two or more RNAs per capsid. If the RNA is too long, multiple capsids assemble around one RNA, and the RNA associated with these multiplet structures is not as RNase resistant. Further, as shown in the present work, 4200 nt appears to be the limiting length of RNA that can be packaged into single RNase-resistant CCMV VLPs. We explore the extent to which “overlong” RNA can be packaged more efficiently upon the addition of spermine, a polyvalent cation whose increasing concentration has been shown to compactify RNA. Finally, we show that the capsid protein of Brome Mosaic Virus (BMV), a bromovirus closely related to CCMV, also gives rise to multiplets when it is self-assembled with the same “overlong” RNA constructs, but with different distributions of multiplets. 

We report here the spontaneous formation of lipid-bilayer-wrapped virus particles, following the injection of “naked” virus particles into the subphase of a Langmuir trough with a liquid monolayer of lipids at its air–water interface. The virus particles are those of the well-studied cowpea chlorotic mottle virus, CCMV, which are negatively charged at the pH 6 of the subphase; the lipids are a 9:1 mix of neutral DMPC and cationic CTAB molecules. Before adding CCMV particles to the subphase we establish the mixed lipid monolayer in its liquid-expanded state at a fixed pressure (17.5 mN/m) and average area-per- molecule of (41 ̊A2). Keeping the total area fixed, the surface pressure is observed to decrease at about 15 h after adding the virus particles in the subphase; by 37 h it has dropped to zero, corresponding to essentially all the lipid molecules having been removed from the air–water interface. By collecting particles from the subphase and measuring their sizes by atomic force microscopy, we show that the virus particles have been wrapped by lipid bilayers (or by two lipid bilayers). These results can be understood in terms of thermal fluctuations and electrostatic interactions driving the wrapping of the anionic virus particles by the cationic lipids. 

The vast majority of plant viruses are unenveloped, i . e ., they lack a lipid bilayer that is characteristic of most animal viruses. The interactions between plant viruses, and between viruses and surfaces, properties that are essential for understanding their infectivity and to their use as bionanomaterials, are largely controlled by their surface charge, which depends on pH and ionic strength. They may also depend on the charge of their contents, i.e., of their genes or–in the instance of virus-like particles–encapsidated cargo such as nucleic acid molecules, nanoparticles or drugs. In the case of enveloped viruses, the surface charge of the capsid is equally important for controlling its interaction with the lipid bilayer that it acquires and loses upon leaving and entering host cells. We have previously investigated the charge on the unenveloped plant virus Cowpea Chlorotic Mottle Virus (CCMV) by measurements of its electrophoretic mobility. Here we examine the electrophoretic properties of a structurally and genetically closely related bromovirus, Brome Mosaic Virus (BMV), of its capsid protein, and of its empty viral shells, as functions of pH and ionic strength, and compare them with those of CCMV. From measurements of both solution and gel electrophoretic mobilities (EMs) we find that the isoelectric point (pI) of BMV (5.2) is significantly higher than that of CCMV (3.7), that virion EMs are essentially the same as those of the corresponding empty capsids, and that the same is true for the pIs of the virions and of their cleaved protein subunits. We discuss these results in terms of current theories of charged colloidal particles and relate them to biological processes and the role of surface charge in the design of new classes of drug and gene delivery systems.