HRA2pl peptide: a fusion inhibitor for human metapneumovirus produced in tobacco plants by transient transformation
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Main conclusion: The HRA2pl peptide expressed by transient transformation inN. tabacumplants is capable of inhibiting the binding of the human metapneumovirus to HEp-2 cells at the fusion stage. Human metapneumovirus (hMPV) is an agent responsible for acute respiratory infections that mainly affects children under 3 years, the elderly and immunocompromised patients. In children younger than 5 years, respiratory tract infections account for 20 %25 of deaths worldwide. However, there is currently no treatment or vaccine available against hMPV. The production of a safe, efficient and low cost treatment against this virus is a current challenge. Plants provide a system for recombinant protein production that is cost effective and is easier to scale up to an industrial level than other platforms; in addition, the plant tissue may be used as raw food, dried or, alternatively, proteins may be partially or fully purified and administered in aerosol or capsules as dry powder. In this study, we designed a gene expressing an antiviral peptide against hMPV based on the heptad repeat A domain of the F protein of the virus. We produced the recombinant peptide by a viral transient expression system (Magnifection®) in Nicotiana tabacum plants. The efficacy of this antiviral peptide was confirmed by in vitro assays in HEp-2 cell line. This is a promising result that can offer a prophylactic approach against hMPV. © 2015, Springer-Verlag Berlin Heidelberg.
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Antiviral peptide; hMPV; HRA domain; Transient transformation Human metapneumovirus; Nicotiana obtusifolia; Nicotiana tabacum; antivirus agent; HRA2pl peptide; peptide; amino acid sequence; bioassay; cell death; chemistry; drug design; drug effects; genetic transformation; genetics; human; Metapneumovirus; molecular genetics; paramyxovirus infection; pathology; physiology; tobacco; transgenic plant; tumor cell line; virology; virus entry; Amino Acid Sequence; Antiviral Agents; Biological Assay; Cell Death; Cell Line, Tumor; Drug Design; Humans; Metapneumovirus; Molecular Sequence Data; Paramyxoviridae Infections; Peptides; Plants, Genetically Modified; Tobacco; Transformation, Genetic; Virus Internalization
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