Abstract
Betanodavirus is a causative agent of viral nervous necrosis syndrome in many important aquaculture marine fish larvae, resulting in high global mortality. The coat protein of Betanodavirus is the sole structural protein, and it can assemble the virion particle by itself. In this study, we used a high-titer neutralizing mAB, RG-M18, to identify the linear B-cell epitope on the viral coat protein. By mapping a series of recombinant proteins generated using the E. coli PET expression system, we demonstrated that the linear epitope recognized by RG-M18 is located at the C-terminus of the coat protein, between amino acid residues 195 and 338. To define the minimal epitope region, a set of overlapping peptides were synthesized and evaluated for RG-M18 binding. Such analysis identified the 195VNVSVLCR202 motif as the minimal epitope. Comparative analysis of Alanine scanning mutagenesis with dot-blotting and ELISA revealed that Valine197, Valine199, and Cysteine201 are critical for antibody binding. Substitution of Leucine200 in the RGNNV, BFNNV, and TPNNV genotypes with Methionine200 (thereby simulating the SJNNV genotype) did not affect binding affinity, implying that RG-M18 can recognize all genotypes of Betanodaviruses. In competition experiments, synthetic multiple antigen peptides of this epitope dramatically suppressed giant grouper nervous necrosis virus (GGNNV) propagation in grouper brain cells. The data provide new insights into the protective mechanism of this neutralizing mAB, with broader implications for Betanodavirus vaccinology and antiviral peptide drug development.
Highlights
Viral nervous necrosis (VNN) [1], otherwise known as viral encephalopathy and retinopathy (VER) [2], is an infectious neuropathological disease that has spread to more than 40 species of marine and freshwater fish worldwide, and results in nearly 100% mortality in infected larvae and juvenile stage fish [3, 4]
Based on the similarity of the T4 variable region of RNA2 sequences encoding the C-terminal halves of the coat protein, four genotype strains have been phylogenetically classified: redspotted grouper nervous necrosis virus (RGNNV), striped jack nervous necrosis virus (SJNNV), barfin flounder nervous necrosis virus (BFNNV), and tiger puffer nervous necrosis virus (TPNNV) [7]
In a previous study [16], mAB RG-M18 was identified as a neutralizing antibody against yellow grouper nervous necrosis virus (YGNNV) of the redspotted grouper nervous necrosis virus (RGNNV) strain [22]
Summary
Viral nervous necrosis (VNN) [1], otherwise known as viral encephalopathy and retinopathy (VER) [2], is an infectious neuropathological disease that has spread to more than 40 species of marine and freshwater fish worldwide, and results in nearly 100% mortality in infected larvae and juvenile stage fish [3, 4]. Several factors influence host specificity for viral multiplication, including environmental adaptability (e.g. temperature), host defense systems (e.g. immune systems and posttranscriptional gene silencing), and host intracellular factors, as well as target cell receptors for viral entry. Binding between such receptors and Betanodavirus coat protein is important for host specificity determination. In vivo experiments showed that the host specificity of SGNNV (a member of the RGNNV type) and SJNNV to their original host fish larvae, sevenband grouper and striped jack, respectively, is controlled by the T4 variable region of viral RNA2 and/or encoded coat protein via reassortant chimeric viruses from SJNNV and SGNNV [14, 15]
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