Binding kinetics of grouper nervous necrosis viruses with functionalized antimicrobial peptides by nanomechanical detection.

We report the binding kinetics of fish-infected grouper nervous necrosis viruses (NNV) and selected antimicrobial peptides (AMPs) by nanomechanical detection. AMPs, the vital member in an innate immunity, are promising candidates in the fight against pathogens due to their broad range of antimicrobial activity and low toxicity. Grouper NNV primarily cause mass mortality of many marine cultured fish species, and two selected AMPs in this study were found to inhibit viruses by agglutinating its virions to form aggregates. The binding activity of NNVs with functionalized AMPs onto a sensing microcantilever yielded induced surface stresses, indicating high binding strength of molecular interaction. The binding affinity and kinetic rate constants of molecular recognition events calculated for NNV-AMP(TH1-5) compared to NNV-AMP(cSALF) were found to be 2.1-fold and 4.43-fold, respectively, indicating TH1-5 effectively bind with NNV more than cSALF. Moreover, a microscopic X-ray photoelectron spectroscopy technique was employed for further validation of pre- and post-NNV binding onto peptides-functionalized sensing surface. An increase in the spectrum and intensity of the P 2p and N 1s elements for the post-NNV binding was clearly shown to ensure the existence of phosphate groups and nitrogen-containing ring structures of specific NNV-TH1-5 interaction. Therefore, the microcantilever biosensing technique provides a potential and useful screening of AMPs for affinity to NNVs.

Antimicrobial peptides (AMP) with antiviral activity against fish nodavirus.

Nervous necrosis virus (NNV) is classified as betanodavirus of Nodaviridae, and has caused mass mortality of numerous marine fish species at larval stage. Antimicrobial peptides (AMPs) play an important role of innate immunity either against bacterial pathogens or viruses. Up to date, little is known if any AMP could effectively inhibit fish nodaviruses and its mechanism. In this study, the antiviral activities of three antimicrobial peptides (AMPs) against grouper NNV (GNNV) were screened in the fish cell line. Two of the three AMPs, tilapia hepcidin 1-5 (TH 1-5) and cyclic shrimp anti-lipopolysaccharide factor (cSALF), were able to agglutinate purified NNV particles into clump, and the clumps were further confirmed to be viral proteins by TEM and Western blot. The NNV solution, separately pre-mixed with AMP (TH 1-5 or cSALF) or deionized-distilled water for 1 h, was used to infect GF-1 cells, and the levels of capsid protein in the GNNV-AMP-infected cells at 1 h post infection were much lower than that in the GNNV-H(2)O-infected cells, indicating that only a small portion of viral particles in the GNNV-AMP mixture could successfully infected the cells. Treatment of cBB cells with TH 1-5 and cSALF did not induce Mx gene expression; however, grouper epinecidin-1 (CP643-1) could induce the expression of Mx in the pre-treated cBB cells. This study revealed three AMPs with anti-NNV activity through two different mechanisms, and shed light on the future application in aquaculture.