Abstract
BackgroundProtein shells assembled from viral coat proteins are an attractive platform for development of new vaccines and other tools such as targeted bioimaging and drug delivery agents. Virus-like particles (VLPs) derived from the single-stranded RNA (ssRNA) bacteriophage coat proteins (CPs) have been important and successful contenders in the area due to their simplicity and robustness. However, only a few different VLP types are available that put certain limitations on continued developments and expanded adaptation of ssRNA phage VLP technology. Metagenomic studies have been a rich source for discovering novel viral sequences, and in recent years have unraveled numerous ssRNA phage genomes significantly different from those known before. Here, we describe the use of ssRNA CP sequences found in metagenomic data to experimentally produce and characterize novel VLPs.ResultsApproximately 150 ssRNA phage CP sequences were sourced from metagenomic sequence data and grouped into 14 different clusters based on CP sequence similarity analysis. 110 CP-encoding sequences were obtained by gene synthesis and expressed in bacteria which in 80 cases resulted in VLP assembly. Production and purification of the VLPs was straightforward and compatible with established protocols, with the only exception that a considerable proportion of the CPs had to be produced at a lower temperature to ensure VLP assembly. The VLP morphology was similar to that of the previously studied phages, although a few deviations such as elongated or smaller particles were noted in certain cases. In addition, stabilizing inter-subunit disulfide bonds were detected in six VLPs and several possible candidate RNA structures in the phage genomes were identified that might bind to the coat protein and ensure specific RNA packaging.ConclusionsCompared to the few types of ssRNA phage VLPs that were used before, several dozens of new particles representing ten distinct similarity groups are now available with a notable potential for biotechnological applications. It is believed that the novel VLPs described in this paper will provide the groundwork for future development of new vaccines and other applications based on ssRNA bacteriophage VLPs.
Highlights
Protein shells assembled from viral coat proteins are an attractive platform for development of new vaccines and other tools such as targeted bioimaging and drug delivery agents
It is believed that the novel Virus-like particles (VLPs) described in this paper will provide the groundwork for future development of new vaccines and other applications based on single-stranded RNA (ssRNA) bacteriophage VLPs
The ssRNA phage VLP technology has been further extended for encapsulation of both macromolecular and small-molecule substances of interest inside the particles, which in combination with VLP surface modification allows for the development of targeted bioimaging and drug delivery agents. ssRNA phage coat proteins (CPs) and VLPs have found a number of applications as tools for molecular biology research, notably in generation of peptide display libraries [12], identification of protein–RNA interactions [13, 14] and real-time imaging of RNA molecules in living cells [15]
Summary
Protein shells assembled from viral coat proteins are an attractive platform for development of new vaccines and other tools such as targeted bioimaging and drug delivery agents. We describe the use of ssRNA CP sequences found in metagenomic data to experimentally produce and characterize novel VLPs. The single-stranded RNA (ssRNA) bacteriophages of the Levivirdae family are small viruses that infect a variety of Gram-negative bacteria. The ssRNA phage VLP technology has been further extended for encapsulation of both macromolecular and small-molecule substances of interest inside the particles, which in combination with VLP surface modification allows for the development of targeted bioimaging and drug delivery agents (see [10, 11] for comprehensive reviews). In vaccine development and related areas, the immune response against the carrier coat protein has to be taken into account, and a narrow range of available CPs adversely limits the number of potential vaccines that could be produced using the ssRNA phage platform. Discovery and characterization of novel ssRNA phage CPs and VLPs is of considerable interest for continued developments in the area
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