High-content screening to distinguish between attachment and post-attachment steps of human cytomegalovirus entry into fibroblasts and epithelial cells.

Human cytomegalovirus (HCMV) enters cells through a complex pathway involving the interaction of multiple viral glycoproteins and cellular receptors. While HCMV clinical isolates enter a wide range of cell types, entry has historically been studied using a laboratory strain of virus that can only infect fibroblasts. Herein, we have constructed a HCMV reporter strain that contains GFP fused to the abundant tegument protein pp65 to allow for the direct visualization of virus attachment and entry. Furthermore, the UL131 gene of this strain was restored to clinical isolate sequence to expand our studies of entry into physiologically relevant epithelial cell types. Using the HCMV-GFP reporter virus, we developed an image-based assay and screened a library containing 65,000 compounds for the inhibition of virus entry into fibroblasts. In addition to assessing the effect on virus entry, automated image analysis provided information on compound toxicity and whether the compounds acted as attachment or post-attachment inhibitors. To identify therapeutically viable inhibitors capable of blocking entry in multiple cell types, the inhibitors were screened further for their ability to inhibit virus entry into epithelial cells. Compounds were identified that were able to inhibit virus entry into both cell types at either attachment or post-attachment steps.

Real-time analysis of antibody interactions with whole enveloped human cytomegalovirus using surface plasmon resonance.

Human cytomegalovirus (CMV) is a large enveloped virus that encodes multiple glycoproteins required for virus-cell binding and fusion. To assess the binding properties of antibodies with target glycoprotein in a natural context of infection, we investigated the feasibility of using the surface plasmon resonance (SPR) technique for studying the direct binding of antibodies with CMV virions. Direct immobilization of whole virions to sensor surface and a surface regeneration procedure allowed for quantitative and reproducible measurements of binding affinity and binding kinetics of antibody-whole virion interactions. The conformational and functional integrity of viral particles was not compromised by the regeneration condition as evaluated with antibodies recognizing conformational epitopes and by electron microscopy. Binding of an irrelevant antibody was not observed, indicating the high specificity of the method. A panel of anti-gB antibodies was measured and the binding affinities correlated fairly well with those determined by ELISA. These data demonstrated that the interaction of anti-gB antibody with whole virion of large enveloped CMV can be quantitatively studied using SPR. This method has been successfully applied for screening and selection of anti-CMV antibodies and can be potentially extended to study antibody-glycoprotein interactions of other related herpesviruses.

Genomic organization of infectious salmon anaemia virus.

The RNA genome segment order, nucleotide sequence and the putative encoded proteins were determined for infectious salmon anaemia virus (ISAV). Eight segments of genomic viral RNA between 1.0 and 2.4 kb in length were identified. RNA segments 1-6 each had a predicted single open reading frame encoding the P1, PB1, NP, P2, P3 and HA proteins, respectively. Segment 7 encoded the P4/P5 proteins and segment 8 encoded the P6/P7 proteins. Seven virion proteins with molecular masses between 25 and 72 kDa were found by SDS-PAGE analysis. The 72 and 42 kDa proteins were immunoreactive with ISAV antiserum from Atlantic salmon. The molecular mass of the 72 kDa virion protein suggested that it was the NP protein encoded by segment 3. The amino acid sequence was conserved, sharing 96.6% identity with the NP protein of a Scottish ISAV isolate. Comparison of the amino acid sequences obtained by N-terminal analyses and cDNA nucleotide translation revealed that the 42 and 47 kDa proteins were the HA and P3 proteins encoded by segments 6 and 5, respectively. In addition, analysis provided evidence for their protein synthesis initiation sites. Like the HA protein, the signal sequence and potential glycosylation sites of P3 suggested that it was a surface glycoprotein. The predicted amino acid sequence shared 83.1, 84.0 and 99.6% identity to the predicted P3 protein sequences for ISAV isolates from Norway, Scotland and Maine, respectively. These results establish the specificity, migration, number and nucleotide sequence of the eight RNA segments of the ISAV genome.