ABSTRACT
The reovirus core particle is a molecular machine that mediates synthesis, capping, and export of the viral plus strand RNA transcripts. Its assembly and structure-function relationships remain to be well understood. Following the lead of previous studies with other Reoviridae family members, most notably orbiviruses and rotaviruses, we used recombinant baculoviruses to coexpress reovirus core proteins λ1, λ2, and σ2 in insect cells. The resulting core-like particles (CLPs) were purified and characterized. They were found to be similar to cores with regard to their sizes, morphologies, and protein compositions. Like cores, they could also be coated in vitro with the two major outer-capsid proteins, μ1 and σ3, to produce virion-like particles. Coexpression of core shell protein λ1 and core nodule protein σ2 was sufficient to yield CLPs that could withstand purification, whereas expression of λ1 alone was not, indicating a required role for σ2 as a previous study also suggested. In addition, CLPs that lacked λ2 (formed from λ1 and σ2 only) could not be coated with μ1 and σ3, indicating a required role for λ2 in the assembly of these outer-capsid proteins into particles. To extend the use of this system for understanding the core and its assembly, we addressed the hypothesis that the hydrophilic amino-terminal region of λ1, which adopts an extended arm-like conformation around each threefold axis in the reovirus core crystal structure, plays an important role in assembling the core shell. Using a series of λ1 deletion mutants, we showed that the amino-terminal 230 residues of λ1, including its zinc finger, are dispensable for CLP assembly. Residues in the 231-to-259 region of λ1, however, were required. The core crystal structure suggests that residues in the 231-to-259 region are necessary because they affect the interaction of λ1 with the threefold and/or fivefold copies of σ2. An effective system for studies of reovirus core structure, assembly, and functions is hereby established.
Crystal structure of the EutL shell protein of the ethanolamine ammonia lyase microcompartment
