The refined structure of Nudaurelia capensis omega virus reveals control elements for a T = 4 capsid maturation.

Large-scale reorganization of protein interactions characterizes many biological processes, yet few systems are accessible to biophysical studies that display this property. The capsid protein of Nudaurelia capensis omega Virus (NomegaV) has previously been characterized in two dramatically different T = 4 quasi-equivalent assembly states when expressed as virus-like particles (VLPs) in a baculovirus system. The procapsid (pH 7), is round, porous, and approximately 450 A in diameter. It converts, in vitro, to the capsid form at pH 5 and the capsid is sealed shut, shaped like an icosahedron, has a maximum diameter of 410 A and undergoes an autocatalytic cleavage at residue 570. Residues 571-644, the gamma peptide, remain associated with the particle and are partially ordered. The interconversion of these states has been previously studied by solution X-ray scattering, electron cryo microscopy (CryoEM), and site-directed mutagenesis. The particle structures appear equivalent in authentic virions and the low pH form of the expressed and assembled protein. Previously, and before the discovery of the multiple morphological forms of the VLPs, we reported the X-ray structure of authentic NomegaV at 2.8 A resolution. These coordinates defined the fold of the protein but were not refined at the time because of technical issues associated with the approximately 2.5 million reflection data set. We now report the refined, authentic virus structure that has added 29 residues to the original model and allows the description of the chemistry of molecular switching for T = 4 capsid formation and the multiple morphological forms. The amino and carboxy termini are internal, predominantly helical, and disordered to different degrees in the four structurally independent subunits; however, the refined structure shows significantly more ordered residues in this region, particularly at the amino end of the B subunit that is now seen to invade space occupied by the A subunits. These additional residues revealed a previously unnoticed strong interaction between the pentameric, gamma peptide helices of the A and B subunits that are largely proximal to the quasi-6-fold axes. One C-terminal helix is ordered in the C and D subunits and stabilizes a flat interaction in two interfaces between the protein monomers while the other, quasi-equivalent, interactions are bent. As this helix is arginine rich, the comparable, disordered region in the A and B subunits probably interacts with RNA. One of the subunit-subunit interfaces has an unusual arrangement of carboxylate side chains. Based on this observation, we propose a mechanism for the control of the pH-dependent transitions of the virus particle.

[1]  G J Kleywegt,et al.  Phi/psi-chology: Ramachandran revisited. , 1996, Structure.

[2]  John E. Johnson,et al.  The refined three-dimensional structure of an insect virus at 2.8 A resolution. , 1994, Journal of molecular biology.

[3]  John E. Johnson,et al.  Large-Scale, pH-Dependent, Quaternary Structure Changes in an RNA Virus Capsid Are Reversible in the Absence of Subunit Autoproteolysis , 2002, Journal of Virology.

[4]  J. Thornton,et al.  PROCHECK: a program to check the stereochemical quality of protein structures , 1993 .

[5]  T. Gallagher,et al.  Assembly-dependent maturation cleavage in provirions of a small icosahedral insect ribovirus , 1988, Journal of virology.

[6]  J. Johnson,et al.  A highly membrane-active peptide in Flock House virus: implications for the mechanism of nodavirus infection. , 1999, Chemistry & biology.

[7]  John E. Johnson,et al.  Structure of an insect virus at 3.0 Å resolution , 1987, Proteins.

[8]  R J Read,et al.  Crystallography & NMR system: A new software suite for macromolecular structure determination. , 1998, Acta crystallographica. Section D, Biological crystallography.

[9]  S. Munshi,et al.  The 2.8 A structure of a T = 4 animal virus and its implications for membrane translocation of RNA. , 1996, Journal of molecular biology.

[10]  P. Kraulis A program to produce both detailed and schematic plots of protein structures , 1991 .

[11]  P. Fitzgerald,et al.  Molecular replacement , 1992 .

[12]  John E. Johnson,et al.  Ordered duplex RNA controls capsid architecture in an icosahedral animal virus , 1993, Nature.

[13]  John E. Johnson,et al.  Structure Determination of Nudaurelia capensis ω Virus , 1998 .

[14]  M. Ghadiri,et al.  An animal virus-derived peptide switches membrane morphology: possible relevance to nodaviral transfection processes. , 1999, Biochemistry.

[15]  John E. Johnson,et al.  Functional implications of quasi-equivalence in a T = 3 icosahedral animal virus established by cryo-electron microscopy and X-ray crystallography. , 1994, Structure.

[16]  Liang Tang,et al.  The structure of Pariacoto virus reveals a dodecahedral cage of duplex RNA , 2000, Nature Structural Biology.

[17]  H. Tsuruta,et al.  Analysis of rapid, large-scale protein quaternary structural changes: time-resolved X-ray solution scattering of Nudaurelia capensis omega virus (NomegaV) maturation. , 2001, Journal of molecular biology.

[18]  G. Kleywegt,et al.  Halloween ... Masks and Bones , 1994 .

[19]  John E. Johnson,et al.  Large conformational changes in the maturation of a simple RNA virus, Nudaurelia capensis ω virus (NωV). , 2000 .

[20]  J. Zou,et al.  Improved methods for building protein models in electron density maps and the location of errors in these models. , 1991, Acta crystallographica. Section A, Foundations of crystallography.

[21]  A. Leslie,et al.  The crystal structure of the human hepatitis B virus capsid. , 1999, Molecular cell.

[22]  S. Clarke,et al.  Succinimide formation from aspartyl and asparaginyl peptides as a model for the spontaneous degradation of proteins. , 1989, The Journal of biological chemistry.