Identification of the potential matrix protein of invertebrate iridescent virus 6 (IIV6).

Invertebrate iridescent virus 6 (IIV6) is a nucleocytoplasmic virus with a ∼212 kb linear dsDNA genome that encodes 215 putative open reading frames (ORFs). Proteomic analysis has revealed that the IIV6 virion consists of 54 virally encoded proteins. Interactions among the structural proteins were investigated using the yeast two-hybrid system, revealing that the protein of 415R ORF interacts reciprocally with the potential envelope protein 118L and the major capsid protein 274L. This result suggests that 415R might be a matrix protein that plays a role as a bridge between the capsid and the envelope proteins. To elucidate the function of 415R protein, we determined the localization of 415R in IIV6 structure and analyzed the properties of 415R-silenced IIV6. Specific antibodies produced against 415R protein were used to determine the location of the 415R protein in the virion structure. Both western blot hybridization and immunogold electron microscopy analyses showed that the 415R protein was found in virions treated with Triton X-100, which degrades the viral envelope. The 415R gene was silenced by the RNA interference (RNAi) technique. We used gene-specific dsRNA's to target 415R and showed that this treatment resulted in a significant drop in virus titer. Silencing 415R with dsRNA also reduced the transcription levels of other viral genes. These results provide important data on the role and location of IIV6 415R protein in the virion structure. Additionally, these results may also shed light on the identification of the homologs of 415R among the vertebrate iridoviruses.

Kveik Brewing Yeasts Demonstrate Wide Flexibility in Beer Fermentation Temperature Tolerance and Exhibit Enhanced Trehalose Accumulation.

Traditional Norwegian Farmhouse ale yeasts, also known as kveik, have captured the attention of the brewing community in recent years. Kveik were recently reported as fast fermenting thermo- and ethanol tolerant yeasts with the capacity to produce a variety of interesting flavor metabolites. They are a genetically distinct group of domesticated beer yeasts of admixed origin with one parent from the "Beer 1" clade and the other unknown. While kveik are known to ferment wort efficiently at warmer temperatures, their range of fermentation temperatures and corresponding fermentation efficiencies, remain uncharacterized. In addition, the characteristics responsible for their increased thermotolerance remain largely unknown. Here we demonstrate variation in kveik strains at a wide range of fermentation temperatures and show not all kveik strains are equal in fermentation performance and stress tolerance. Furthermore, we uncovered an increased capacity of kveik strains to accumulate intracellular trehalose, which likely contributes to their increased thermo- and ethanol tolerances. Taken together our results present a clearer picture of the future opportunities presented by Norwegian kveik yeasts and offer further insight into their applications in brewing.

Protein-protein interactions among the structural proteins of Chilo iridescent virus.

Chilo iridescent virus (CIV), officially named invertebrate iridescent virus 6 (IIV6), is a nucleocytoplasmic virus with a ~212-kb linear dsDNA genome that encodes 215 putative open reading frames (ORFs). Proteomic analysis has revealed that the CIV virion consists of 54 virally encoded proteins. In this study, we identified the interactions between the structural proteins using the yeast two-hybrid system. We cloned 47 structural genes into both bait and prey vectors, and then analysed the interactions in Saccharomyces cerevisiae strain AH109. A total of 159 protein-protein interactions were detected between the CIV structural proteins. Only ORF 179R showed a self-association. Four structural proteins that have homologues in iridoviruses (118L, 142R, 274L and 295L) showed indirect interactions with each other. Seven proteins (138R, 142R, 361L, 378R, 395R, 415R and 453R) interacted with the major capsid protein 274L. The putative membrane protein 118L, a homologue of the frog virus 3/Ranagrylio virus 53R protein, showed direct interactions with nine other proteins (117L, 229L, 307L, 355R, 366R, 374R, 378R, 415R and 422L). The interaction between 118L and 415R was confirmed by a GST pull-down assay. These data indicate that 415R is a potential matrix protein connecting the envelope protein 118L with the major capsid protein 274L.

Amsacta moorei entomopoxvirus encodes a functional esterase (amv133) with protease activity.

OBJECTIVES: Lipolytic genes have been investigated in several viral genomes, and some of them show enzyme activity which can be used for various functions including the production of DNA replication metabolites, rescue from endosomes, and membrane fusion. Amsacta moorei entomopoxvirus (AMEV) replicates in nearly the entire insect body, especially in the adipose tissue. One of the open reading frames (ORFs) in the AMEV genome, amv133, encodes a putative lipase enzyme. In this study, we therefore investigate the enzyme activity of amv133. METHODS: amv133 was aligned with known lipase genes and their homologs in entomopoxviruses. Expressed proteins were partially purified and assayed for lipase, esterase and protease. RESULTS: We found that amv133 contains all the domains required for a functional lipase enzyme and that it shows a significant similarity with homologs in other entomopoxviruses. Since there is a similarity of the catalytic triad between lipases and serine proteases, we also investigated the protease activity of amv133. Lipase, esterase and protease assays showed that amv133 encodes a functional esterase enzyme with protease activity. CONCLUSION: The current data show that amv133 is a conserved gene in all entomopoxvirus genomes sequenced so far and might contribute greatly to degrading the lipids or proteins and hence improve the virus infection.

Transcriptional analysis of ORF amv133 of Amsacta moorei entomopoxvirus.

The open reading frame (ORF) amv133 of Amsacta moorei entomopoxvirus, encodes a putative lipase gene. Its temporal expression pattern was characterized by RT-PCR and found to start at 6 h postinfection (h p.i.) and reach a maximum level at 48 h p.i. While the ORF has a late promoter motif, the inhibition of viral DNA synthesis by Ara-C failed to inhibit transcription, but a general inhibitor of protein synthesis prevented its transcription, indicating that amv133 is an intermediate gene. 5'-RACE analysis showed that transcription was initiated at position -77 relative to the translational start site. To determine the size of the promoter, several truncations were generated and cloned upstream of the firefly luciferase reporter gene. The resulting constructs were tested in a dual assay. A fragment that contained 115 bp relative to the transcription start site exhibited optimum promoter length.