The differential immunogenicity of plant viral protein and nucleoproteins

Multifunctional plant virus nanoparticles in the next generation of cancer immunotherapies

Plant virus nanoparticles (PVNPs) have inherent immune stimulatory ability, and have been investigated as immune adjuvants to stimulate an anti-tumor immune response. The combination of immune stimulation, nanoparticle structure and the ability to deliver other therapeutic molecules provides a flexible platform for cancer immunotherapy. Researching multifunctional PVNPs and their modification will generate novel reagents for cancer immunotherapy. Here we review the properties of PVNPs, and their potential for clinical utilization to activate anti-tumor innate and lymphoid immune responses. PVNPs have potential utility for cancer immunotherapy as vaccine adjuvant, and delivery systems for other reagents as mono immunotherapy or combined with other immunotherapies. This review outlines the potential and challenges in developing PVNPs as cancer immunotherapy reagents.

Injectable Hydrogel Containing Cowpea Mosaic Virus Nanoparticles Prevents Colon Cancer Growth

Despite advances in laparoscopic surgery combined with neoadjuvant and adjuvant therapy, colon cancer management remains challenging in oncology. Recurrence of cancerous tissue locally or in distant organs (metastasis) is the major problem in colon cancer management. Vaccines and immunotherapies hold promise in preventing cancer recurrence through stimulation of the immune system. We and others have shown that nanoparticles from plant viruses, such as cowpea mosaic virus (CPMV) nanoparticles, are potent immune adjuvants for cancer vaccines and serve as immunostimulatory agents in the treatment or prevention of tumors. While being noninfectious toward mammals, CPMV activates the innate immune system through recognition by pattern recognition receptors (PRRs). While the particulate structure of CPMV is essential for prominent immune activation, the proteinaceous architecture makes CPMV subject to degradation in vivo; thus, CPMV immunotherapy requires repeated injections for optimal outcome. Frequent intraperitoneal (IP) injections however are not optimal from a clinical point of view and can worsen the patient's quality of life due to the hospitalization required for IP administration. To overcome the need for repeated IP injections, we loaded CPMV nanoparticles in injectable chitosan/glycerophosphate (GP) hydrogel formulations, characterized their slow-release potential, and assessed the antitumor preventative efficacy of CPMV-in-hydrogel single dose versus soluble CPMV (single and prime-boost administration). Using fluorescently labeled CPMV-in-hydrogel formulations, in vivo release data indicated that single IP injection of the hydrogel formulation yielded a gel depot that supplied intact CPMV over the study period of 3 weeks, while soluble CPMV lasted only for one week. IP administration of the CPMV-in-hydrogel formulation boosted with soluble CPMV for combined immediate and sustained immune activation significantly inhibited colon cancer growth after CT26 IP challenge in BALB/c mice. The observed antitumor efficacy suggests that CPMV can be formulated in a chitosan/GP hydrogel to achieve prolonged immunostimulatory effects as single-dose immunotherapy against colon cancer recurrence. The present findings illustrate the potential of injectable hydrogel technology to accommodate plant virus nanoparticles to boost the translational development of effective antitumor immunotherapies.

The pharmacology of plant virus nanoparticles

The application of nanoparticles for medical purposes has made enormous strides in providing new solutions to health problems. The observation that plant virus-based nanoparticles (VNPs) can be repurposed and engineered as smart bio-vehicles for targeted drug delivery and imaging has launched extensive research for improving the therapeutic and diagnostic management of various diseases. There is evidence that VNPs are promising high value nanocarriers with potential for translational development. This is mainly due to their unique features, encompassing structural uniformity, ease of manufacture and functionalization by means of expression, chemical biology and self-assembly. While the development pipeline is moving rapidly, with many reports focusing on engineering and manufacturing aspects to tailor the properties and efficacy of VNPs, fewer studies have focused on gaining insights into the nanotoxicity of this novel platform nanotechnology. Herein, we discuss the pharmacology of VNPs as a function of formulation and route of administration. VNPs are reviewed in the context of their application as therapeutic adjuvants or nanocarrier excipients to initiate, enhance, attenuate or impede the formulation's toxicity. The summary of the data however also underlines the need for meticulous VNP structure-nanotoxicity studies to improve our understanding of their in vivo fates and pharmacological profiles to pave the way for translation of VNP-based formulations into the clinical setting.

Plant virus particles with various shapes as potential adjuvants

Plant viruses are biologically safe for mammals and can be successfully used as a carrier/platform to present foreign epitopes in the course of creating novel putative vaccines. However, there is mounting evidence that plant viruses, their virus-like and structurally modified particles may also have an immunopotentiating effect on antigens not bound with their surface covalently. Here, we present data on the adjuvant properties of plant viruses with various shapes (Tobacco mosaic virus, TMV; Potato virus X, PVX; Cauliflower mosaic virus, CaMV; Bean mild mosaic virus, BMMV) and structurally modified TMV spherical particles (SPs). We have analysed the effectiveness of immune response to individual model antigens (ovalbumin, OVA/hen egg lysozyme, HEL) and to OVA/HEL in compositions with plant viruses/SPs, and have shown that CaMV, TMV and SPs can effectively induce total IgG titers to model antigen. Some intriguing data were obtained when analysing the immune response to the plant viruses/SPs themselves. Strong immunity was induced to CaMV, BMMV and PVX, whereas TMV and SPs stimulated considerably lower self-IgG titers. Our results provide new insights into the immunopotentiating properties of plant viruses and can be useful in devising adjuvants based on plant viruses.

Display of peptides on the surface of tobacco mosaic virus particles

In this review, we focus on the potential that tobacco mosaic virus (TMV) has as a carrier for immunogenic epitopes, and the factors that must be considered in order to bring products based on this platform to the market. Large Scale Biology Corporation developed facile and scaleable methods for manufacture of candidate peptide display vaccines based on TMV. We describe how rational design of peptide vaccines can improve the manufacturability of particular TMV products. We also discuss downstream processing and purification of the vaccine products, with particular attention to the metrics that a product must attain in order to meet criteria for regulatory approval as injectable biologics.

Visualization by electron microscopy of the location of tobacco mosaic virus epitopes reacting with monoclonal antibodies in enzyme immunoassay

The binding of monoclonal antibodies obtained after immunization with tobacco mosaic protein was analyzed by electron microscopy. A method was developed for visualizing the viral antigen reacting in different ELISA procedures. It was found that the use of a pH 9.6 buffer during the coating of ELISA plates led to the dissociation of virions into subunits which bound preferentially to the solid phase. MAbs that reacted with both virions and subunits in ELISA were found to bind to one of the two extremities of viral rods. These MAbs also reacted with viral protein aggregated in the form of disks. In contrast, MAbs reacting only with virions in ELISA were found to bind over the entire surface of the virus.