Bentley A Fane

Unlike most viral assembly systems, two scaffolding proteins, B and D, mediate bacteriophage øX174 morphogenesis. The external scaffolding protein D is highly ordered in the atomic structure and proper function is very sensitive to mutation. In contrast, the internal scaffolding protein B is relatively unordered and extensive alterations do not eliminate function. Despite this genetic laxity, protein B is absolutely required for virus assembly. Thus, this system, with its complex arrangements of overlapping reading frames, can be regarded as an example of "irreducible complexity." To address the biochemical functions of a dual scaffolding protein system and the evolution of complexity, progressive and targeted genetic selections were employed to lessen and finally eliminate B protein-dependence. The biochemical and genetic bases of adaptation were characterized throughout the analysis that led to the sextuple mutant with a B-independent phenotype, as evaluated by plaque formation in wild-type cells. The primary adaptation appears to be the over-expression of a mutant external scaffolding protein. Progeny production was followed in lysis-resistant cells. The ability to produce infectious virions does not require all six mutations. However, the lag phase before progeny production is shortened as mutations accumulate. The results suggest that the primary function of the internal scaffolding protein may be to lower the critical concentration of the external scaffolding protein needed to nucleate procapsid formation. Moreover, they demonstrate a novel mechanism by which a stringently required gene product can be bypassed, even in a system encoding only eight strictly essential proteins.

Conformational switching is an overarching paradigm in which to describe scaffolding protein-mediated virus assembly. However, rapid morphogenesis with small assembly subunits hinders the isolation of early morphogenetic intermediates in most model systems. Consequently, conformational switches are often defined by comparing the structures of virions, procapsids and aberrantly assembled particles. In contrast, X174 morphogenesis proceeds through at least three preprocapsid intermediates, which can be biochemically isolated. This affords a detailed analysis of early morphogenesis and internal scaffolding protein function. Amino acid substitutions were generated for the six C-terminal, aromatic amino acids that mediate most coat-internal scaffolding protein contacts. The biochemical characterization of mutant assembly pathways revealed two classes of molecular defects, protein binding and conformational switching, a novel phenotype. The conformational switch mutations kinetically trapped assembly intermediates before procapsid formation. Although mutations trapped different particles, they shared common second-site suppressors located in the viral coat protein. This suggests a fluid assembly pathway, one in which the scaffolding protein induces a single, coat protein conformational switch and not a series of sequential reactions. In this model, an incomplete or improper switch would kinetically trap intermediates.

PMID: 22297520;Abstract:

For a machine to function, it must first be assembled. The morphogenesis of the simplest icosahedral virus would require only 60 copies of a single capsid protein to coalesce. If the capsid protein's structure could be entirely dedicated to this endeavor, the morphogenetic mechanism would be relatively uncomplicated. However, capsid proteins have had to evolve other functions, such as receptor recognition, immune system evasion, and the incorporation of other structure proteins, which can detract from efficient assembly. Moreover, evolution has mandated that viruses obtain additional proteins that allow them to adapt to their hosts or to more effectively compete in their respective niches. Consequently, genomes have increased in size, which has required capsids to do likewise. This, in turn, has lead to more complex icosahedral geometries. These challenges have driven the evolution of scaffolding proteins, which mediate, catalyze, and promote proper virus assembly. The mechanisms by which these proteins perform their functions are discussed in this review. © 2012 Springer Science+Business Media, LLC.

PMID: 1825987;PMCID: PMC1204354;Abstract:

Within the amino acid sequences of polypeptide chains little is known of the distribution of sites and sequences critical for directing chain folding and assembly. Temperature-sensitive folding (tsf) mutations identifying such sites have been previously isolated and characterized in gene 9 of phage P22 encoding the tailspike endorhamnosidase. We report here the isolation of a set of second-site conformational suppressors which alleviate the defect in such folding mutants. The suppressors were selected for their ability to correct the defects of missense tailspike polypeptide chains, generated by growth of gene 9 amber mutants on Salmonella host strains inserting either tyrosine, serine, glutamine or leucine at the nonsense codons. Second-site suppressors were recovered for 13 of 22 starting sites. The suppressors of defects at six sites mapped within gene 9. (Suppressors for seven other sites were extragenic and distant from gene 9.) The missense polypeptide chains generated from all six suppressible sites displayed ts phenotypes. Temperature-sensitive alleles were isolated at these amber sites by pseudoreversion. The intragenic suppressors restored growth at the restrictive temperature of these presumptive tsf alleles. Characterization of protein maturation in cells infected with mutant phages carrying the intragenic suppressors indicates that the suppression is acting at the level of polypeptide chain folding and assembly.

PMID: 14972548;Abstract:

The øX174 DNA binding protein contains two DNA binding domains, containing a series of DNA binding basic amino acids, separated by a proline-rich linker region. Within each DNA binding domain, there is a conserved glycine residue. Glycine and proline residues were mutated and the effects on virion structure were examined. Substitutions for glycine residues yield particles with similar properties to previously characterized mutants with substitutions for DNA binding residues. Both sets of mutations share a common extragenic second-site suppressor, suggesting that the defects caused by the mutant proteins are mechanistically similar. Hence, glycine residues may optimize DNA-protein contacts. The defects conferred by substitutions for proline residues appear to be fundamentally different. The properties of the mutant particles along with the atomic structure of the virion suggest that the proline residues may act to guide the packaged DNA to the adjacent fivefold related asymmetric unit, thus preventing a chaotic packaging arrangement. © 2003 Elsevier Inc. All rights reserved.