Abstract
In the spherical virion of the parvovirus minute virus of mice, several amino acid side chains of the capsid were previously found to be involved in interactions with the viral single-stranded DNA molecule. We have individually truncated by mutation to alanine many (ten) of these side chains and analyzed the effects on capsid assembly, stability and conformation, viral DNA encapsidation, and virion infectivity. Mutation of residues Tyr-270, Asp-273, or Asp-474 led to a drastic reduction in infectivity. Mutant Y270A was defective in capsid assembly; mutant D273A formed stable capsids, but it was essentially unable to encapsidate the viral DNA or to externalize the N terminus of the capsid protein VP2, a connected conformational event. Mutation of residues Asp-58, Trp-60, Asn-183, Thr-267, or Lys-471 led to a moderate reduction in infectivity. None of these mutations had an effect on capsid assembly or stability, or on the DNA encapsidation process. However, those five mutant virions were substantially less stable than the parental virion in thermal inactivation assays. The results with this model spherical virus indicate that several capsid residues that are found to be involved in polar interactions or multiple hydrophobic contacts with the viral DNA molecule contribute to preserving the active conformation of the infectious viral particle. Their effect appears to be mediated by the non-covalent interactions they establish with the viral DNA. In addition, at least one acidic residue at each DNA-binding region is needed for DNA packaging.
Highlights
Many fundamental biological processes involve protein-nucleic acid recognition
None of these mutations had an effect on capsid assembly or stability, or on the DNA encapsidation process. Those five mutant virions were substantially less stable than the parental virion in thermal inactivation assays. The results with this model spherical virus indicate that several capsid residues that are found to be involved in polar interactions or multiple hydrophobic contacts with the viral DNA molecule contribute to preserving the active conformation of the infectious viral particle
Contact analysis was carried out using the program Whatif [64] and the PDB files 1mvm [29, 30] and 4dpv [26, 27], including symmetry-related subunits for completeness
Summary
Many fundamental biological processes involve protein-nucleic acid recognition. Double-stranded DNA-protein interactions have been extensively studied, but single-stranded (ss) DNA- or RNA-protein interactions are much less characterized. Specific and nonspecific capsid protein- oligonucleotide interactions were analyzed in detail in artificial complexes formed by a recombinant capsid of the bacteriophage MS2 and identical copies of a unique viral ssRNA fragment (OR) involved in translational repression and initiation of capsid assembly [31, 32] This allowed a structural interpretation of mutational analyses on the formation of a biologically relevant complex between OR and an MS2 capsid protein dimer [32,33,34,35,36,37]. No singleresidue scanning of capsid side chains involved in major interactions at the viral nucleic acid-capsid interface had, to our knowledge, been described
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