Structures of kobuviral and siciniviral polymerases reveal conserved mechanism of picornaviral polymerase activation.

RNA-dependent RNA polymerase 3Dpol is a key enzyme for the replication of picornaviruses. The viral genome is translated into a single polyprotein that is subsequently proteolytically processed into matured products. The 3Dpol enzyme arises from a stable 3CD precursor that has high proteolytic activity but no polymerase activity. Upon cleavage of the precursor the newly established N-terminus of 3Dpol is liberated and inserts itself into a pocket on the surface of the 3Dpol enzyme. The essential residue for this mechanism is the very first glycine that is conserved among almost all picornaviruses. However, kobuviruses and siciniviruses have a serine residue instead. Intrigued by this anomaly we sought to solve the crystal structure of these 3Dpol enzymes. The structures revealed a unique fold of the 3Dpol N-termini but the very first serine residues were inserted into a charged pocket in a similar manner as the glycine residue in other picornaviruses. These structures revealed a common underlying mechanism of 3Dpol activation that lies in activation of the α10 helix containing a key catalytical residue Asp238 that forms a hydrogen bond with the 2' hydroxyl group of the incoming NTP nucleotide.

Negative charge and membrane-tethered viral 3B cooperate to recruit viral RNA dependent RNA polymerase 3D pol.

Most single stranded plus RNA viruses hijack phosphatidylinositol 4-kinases (PI4Ks) to generate membranes highly enriched in phosphatidylinositol 4-phosphate (PI4P). These membranous compartments known as webs, replication factories or replication organelles are essential for viral replication because they provide protection from the innate intracellular immune response while serving as platforms for viral replication. Using purified recombinant proteins and biomimetic model membranes we show that the nonstructural viral 3A protein is sufficient to promote membrane hyper-phosphorylation given the proper intracellular cofactors (PI4KB and ACBD3). However, our bio-mimetic in vitro reconstitution assay revealed that rather than the presence of PI4P specifically, negative charge alone is sufficient for the recruitment of 3Dpol enzymes to the surface of the lipid bilayer. Additionally, we show that membrane tethered viral 3B protein (also known as Vpg) works in combination with the negative charge to increase the efficiency of membrane recruitment of 3Dpol.

Detection and genetic characterization of feline kobuviruses.

In order to survey for feline kobuviruses infection, fecal samples (n = 39) of cats with diarrhea were collected during 2011-2012. Six (14.5%) of the fecal samples tested were positive for feline kobuviruses. The partial nucleotide sequences of feline kobuviruses based on the RNA-dependent RNA polymerase gene were compared to those of other species. Feline kobuviruses were most closely related to canine kobuvirus in terms of their amino acid and nucleotide levels. In a phylogenetic tree, feline kobuviruses were also closely clustered with canine kobuvirus, Aichi virus (human), and mouse kobuvirus. This is the first report of the detection and genetic characterization of feline kobuviruses.