Structure-Function Relationships in Microviridae External Scaffolding Proteins

Uchiyama, Asako

January 2007

Microviruses (canonical members: øX174, G4, and alpha3) are T=1 icosahedral virions with a two scaffolding protein-mediated assembly pathway. The external scaffolding protein D mainly mediates the assembly of coat protein pentamers into procapsids. The results of previous genetic studies suggest that helix 1 of D protein may act as a substrate specificity domain, mediating the initial coat-scaffolding protein recognition in a species-specific manner. In an effort to elucidate a more mechanistic model, chimeric external scaffolding proteins were initially constructed in a plasmid, which over-expresses the protein, between the closely related phages G4 and øX174. The results of biochemical and genetic analyses identify coat-scaffolding domains needed to initiate procapsid formation and provide more evidence, albeit indirect, that the pores are the site of DNA entry during the packaging reaction.However, protein concentrations higher than those found in typical infections could drive reactions that may not occur under physiological conditions. In order to elucidate a more detailed mechanistic model, the same chimeric external scaffolding gene was placed directly in the øX174 genome, and the chimeric virus was characterized. The results of the genetic and biochemical analyses indicate that helix 1 most likely mediates the nucleation reaction for the formation of the first assembly intermediate containing the external scaffolding protein. Mutants that can more efficiently use the chimeric scaffolding protein were isolated. These second-site mutations appear to act on a kinetic level, shortening the lag phase before virion production.Finally, by using improved protocols, two novel early assembly intermediates, the 9S* and 12S* particles, have been isolated and characterized. The 9S* particle consists of a coat protein pentamer associated with the internal scaffolding protein. The 12S* intermediate is a complex of a 9S* particle with the major spike protein, and the DNA pilot protein. The existence of internal scaffolding and DNA pilot proteins that were absent in previously characterized intermediates suggest that 9S* and 12S* particles are biologically active intermediates. Moreover, preliminary in vitro assembly experiments performed with the 12S* particle and exogenous external scaffolding protein yield empty capsids-like particle, strongly suggesting that these are the physiologically relevant intermediates.

phix174

bacteriophage

virus assembly

scaffolding protein

SCRIBBLE: A POTENTIAL DUAL KINASE INHIBITOR

Christofakis, Steven

05 May 2010

Extracellular signal-regulated kinases (ERKs) modulate cellular activities in response to extracellular stimuli and play important biological roles. Thus, perturbed kinase pathways induce pathological conditions, such as tumor development. Rit, a novel member of the Ras family GTPases, activase ERK6, and its over-expression confers tumorigenicity. We hypothesized the presence of scaffolding molecules specific to ERK6, similar to other known MAP kinases. We performed yeast two-hybrid assays using ERK6 as bait, and Scribble was identified as a binding partner. Scribble contains 16 LRR domains and four PDZ domains. We performed immunoprecipitation (IP) assays and discovered ERK2 as another binding partner. Surprisingly, no interaction was observed with the highly homologous MAP kinase, ERK1. No other representative kinases showed binding capabilities with Scribble. IP data confirmed that both ERK2 and ERK6 bind to Scribble through its LRR and PDZ domains. Deletion of ten aminoi acids from the C-terminus of ERK2 and ERK6 abolished these interactions. In vitro kinase assays indicated the kinase suppressing ability of Scribble. Focus formation assays were performed with RitQ79L and H-RasV12 as constitutive activators of ERK6 and ERK2, respectively, in the presence of Scribble. Results confirmed the role of Scribble as a tumor suppressor.

ERK6

p38-gamma

ERK2

Scribble

scaffolding protein

cell polarity

Life Sciences

Physiology

Characterization of Tankyrase Structure & Function; Evidence for a Role as a Master Scaffolding Protein

De Rycker, Manu

23 May 2005

No description available.

tankyrase

poly-(ADP-ribosyl)ation

PARP

SAM

sterile alpha motif

polymerization

master scaffolding protein