Abstract
Silica nanoparticles (SiNPs) have been shown to have significant potential for drug delivery and as adjuvants for vaccines. We have simulated the adsorption of GnRH-I (gonadotrophin releasing hormone I) and a cysteine-tagged modification (cys-GnRH-I) to model silica surfaces, as well as its conjugation to the widely-used carrier protein bovine serum albumin (BSA). Our subsequent immunological studies revealed no significant antibody production was caused by the peptide-SiNP systems, indicating that the treatment was not effective. However, the testosterone response with the native peptide-SiNPs indicated a drug effect not found with cys-GnRH-I-SiNPs; this behaviour is explained by the specific orientation of the peptides at the silica surface found in the simulations. With the BSA systems, we found significant testosterone reduction, particularly for the BSA-native conjugates, and an antibody response that was notably higher with the SiNPs acting as an adjuvant; this behaviour again correlates well with the epitope presentation predicted by the simulations. The range of immunological and hormone response can therefore be interpreted and understood by the simulation results and the presentation of the peptides to solution, paving the way for the future rational design of drug delivery and vaccine systems guided by biomolecular simulation.
Highlights
The use of nanoparticles, and silica nanoparticles (SiNPs) in particular, as effective drug delivery vehicles has been the topic of much recent research[1,2,3,4]
We hope to demonstrate the power of simulation to provide new understanding for the interpretation of experimental results, and its potential to guide the future formulation of effective drug delivery and adjuvant systems
The experimental work has been supported and enhanced by biomolecular simulations that provide molecular-scale understanding of the vaccine systems, allowing the results to be interpreted with a physical insight that is otherwise unattainable
Summary
The use of nanoparticles, and silica nanoparticles (SiNPs) in particular, as effective drug delivery vehicles has been the topic of much recent research[1,2,3,4]. We performed immunisation studies, and aim to interpret the results of these using the structural details provided by the simulation In this way, we hope to demonstrate the power of simulation to provide new understanding for the interpretation of experimental results, and its potential to guide the future formulation of effective drug delivery and adjuvant systems. GnRH-I effectively regulates fertility[9], and immunisation against GnRH-I can have a major effect on the fertility of both sexes in mammals[10,11,12,13,14,15] This is caused by antibodies, induced by the vaccine, neutralising any circulating GnRH-I, preventing it from stimulating FSH and LH secretion[8]. With peptide vaccines an adjuvant is very often crucial to stimulate the immune response to adequate levels
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