Bentley A Fane

PMID: 7836321;PMCID: PMC176665;Abstract:

The morphogenetic defects conferred by the cold-sensitive prohead accessory and scaffolding proteins of φX174 were determined in vivo. The results suggest that the cold-sensitive prohead accessory protein blocks the formation of the 12S assembly intermediate. The cold-sensitive scaffolding protein most likely affects the stability of the prohead.

The first alpha-helices of Microviridae external scaffolding proteins function as coat protein substrate specificity domains. Mutations in this helix can lengthen the lag phase before progeny production. 5' deletion genes, encoding N-terminal deletion proteins, were constructed on plasmids and in the øX174 genome. Proteins lacking the first seven amino acids were able to rescue a nullD mutant when expressed from a plasmid. However, the lag phase before progeny production was lengthened. The øX174 mutant with the corresponding genomic gene grew very poorly. The molecular basis of the defective phenotype was complex. External scaffolding protein levels were reduced compared to wild-type and most of the viral coat protein in mutant infected cells appears to be siphoned off the assembly pathway. Second-site suppressors of the growth defects were isolated and appear to act via two different mechanisms. One class of suppressors most likely acts by altering mutant external scaffolding protein expression while the second class of suppressors appears to act on the level of protein-protein interactions.

PMID: 19640994;PMCID: PMC2748053;Abstract:

The φX174 DNA pilot protein H contains four predicted C-terminal coiled-coil domains. The region of the gene encoding these structures was cloned, expressed in vivo, and found to strongly inhibit wild-type replication. DNA and protein synthesis was investigated in the absence of de novo H protein synthesis and in wild-type-infected cells expressing the inhibitory proteins (ΔH). The expression of the ΔH proteins interfered with early stages of DNA replication, which did not require de novo H protein synthesis, suggesting that the inhibitory proteins interfere with the wild-type H protein that enters the cell with the penetrating DNA. As transcription and protein synthesis are dependent on DNA replication in positive single-stranded DNA life cycles, viral protein synthesis was also reduced. However, unlike DNA synthesis, efficient viral protein synthesis required de novo H protein synthesis, a novel function for this protein. A single amino acid change in the C terminus of protein H was both necessary and sufficient to confer resistance to the inhibitory ΔH proteins, restoring both DNA and protein synthesis to wild-type levels. ΔH proteins derived from the resistant mutant did not inhibit wild-type or resistant mutant replication. The inhibitory effects of the ΔH proteins were lessened by the coexpression of the internal scaffolding protein, which may suppress H-H protein interactions. While coexpression relieved the block in DNA biosynthesis, viral protein synthesis remained suppressed. These data indicate that protein H's role in DNA replication and stimulating viral protein synthesis can be uncoupled. Copyright © 2009, American Society for Microbiology. All Rights Reserved.

PMID: 14659765;Abstract:

φX174 utilizes two scaffolding proteins during morphogenesis, an internal protein (B) and an external protein (D). The B protein induces a conformational change in coat protein pentamers, enabling them to interact with both spike and external scaffolding proteins. While functions of the carboxyl terminus of protein B have been defined, the functions of the amino terminus remain obscure. To investigate the morphogenetic functions of the amino terminus, several 5′ deleted genes were constructed and the proteins expressed in vivo. The ΔNH2 B proteins were assayed for the ability to complement an ochre B mutant and defects in the morphogenetic pathway were characterized. The results of the biochemical, genetic and second-site genetic analyses indicate that the amino terminus induces conformational changes in the viral coat protein and facilitates minor spike protein incorporation. Defects in conformational switching can be suppressed by substitutions in the external scaffolding protein, suggesting some redundancy of function between the two proteins. © 2003 Elsevier Ltd. All rights reserved.