Mehfuz Zaman

Polyacrylate Dendrimer Nanoparticles: A Self‐Adjuvanting Vaccine Delivery System

(Figure Presented) Special delivery: An effective group A streptococci vaccine is formed from a delivery device consisting of well-defined dendritic structures with nanoscale dimensions (see picture). The structures are designed to display multiple copies of the minimal B-cell epitopes, which were in the optimal conformation on the surface of the nanoparticles. The nanoparticles can be administered without the aid of an adjuvant.

Nanovaccines and their mode of action.

Nanosized particles including nanovaccines are a novel approach to the development of vaccines to combat diseases. Nanovaccines have the promise to utilize the immune system to cure infections and to prevent infections and diseases from spreading. Rational vaccine development requires an understanding of vaccine mediated stimulation of the immune system. We review here immunostimulatory properties of nanovaccines including their immunogenicity, adjuvant properties, inflammatory responses and the mechanisms of uptake and stimulation of immune cells. Examples of various nanoparticles currently being developed as vaccines are also provided.

Self-adjuvanting polyacrylic nanoparticulate delivery system for group A streptococcus (GAS) vaccine

UNLABELLED Infection with Streptococcus pyogenes, commonly known as group A Streptococcus (GAS), is responsible for acute and postinfectious complications, including rheumatic fever and rheumatic heart disease (RHD). RHD is a global health burden, and Australias indigenous population has one of the highest incidences of RHD worldwide. A potential peptide (J14) vaccine candidate has been previously identified from the C-terminal region of the M protein. However, such peptide-based vaccine development is hampered by a lack of carriers and adjuvants suitable for humans use. We have developed a fully synthetic peptide subunit vaccine candidate based on polyacrylate dendritic polymer. Intranasal administration of this nanoparticulate construct without additional adjuvant induced J14-specific IgG, which was also capable of in vitro opsonization of GAS, highlighting the potential of self-adjuvanting polyacrylate nanoparticle-based construct as a peptide vaccine delivery platform that may afford promising opportunities for treating systemic GAS infection. FROM THE CLINICAL EDITOR Polyacrylate dendrimers offer a unique approach to a nasally administered vaccine for addressing rheumatic heart disease. This paper describes the delivery of the J14 peptide, a C-terminal derivative of M-protein in group A Streptococcus.

Liposome-based delivery system for vaccine candidates: constructing an effective formulation

The discovery of liposomes in 1965 by Bangham and coworkers changed the prospects of drug delivery systems. Since then, the application of liposomes as vaccine delivery systems has been studied extensively. Liposomal vaccine delivery systems are made up of nano- or micro-sized vesicles consisting of phospholipid bilayers, in which the bioactive molecule is encapsulated/entrapped, adsorbed or surface coupled. In general, liposomes are not immunogenic on their own; thus, liposomes combined with immunostimulating ligands (adjuvants) or various other formulations have been used as vaccine delivery systems. A thorough understanding of formulation parameters allows the design of effective liposomal vaccine delivery systems. This article provides an overview of various factors that influence liposomal immunogenicity. In particular, the effects of vesicle size, surface charge, bilayer composition, lamellarity, pegylation and targeting of liposomes are described.

Strategies for intranasal delivery of vaccines

The vast majority of human pathogens colonize and invade at the mucosal surfaces. Preventing infection at these sites via mucosally active vaccines is a promising and rational approach for vaccine development. However, it is only recently that the stimulation of local immunity at the mucosal surfaces has become a primary objective in addition to inducing systemic immunity. This review describes vaccine formulations designed for mucosal delivery to the nasal-associated lymphoid tissue, via intranasal administration. The association of antigens with mucosal adjuvants and delivery systems is emphasised.

Immunological Evaluation of Lipopeptide Group A Streptococcus (GAS) Vaccine: Structure-Activity Relationship

Streptococcus pyogenes (group A streptococcus, GAS) is a Gram-positive bacterial pathogen responsible for a wide variety of diseases. To date, GAS vaccine development has focused primarily on the M-protein. The M-protein is highly variable at the amino (N)-terminus (determining serotype) but is conserved at the carboxyl (C)-terminus. Previously a 29 amino acid peptide (named J14) from the conserved region of the M-protein was identified as a potential vaccine candidate. J14 was capable of eliciting protective antibodies that recognized many GAS serotypes when co-administered with immuno-stimulants. This minimal epitope however showed no immunogenicity when administered alone. In an attempt overcome this immunological non-responsiveness, we developed a self-adjuvanting vaccine candidate composed of three components: the B-cell epitope (J14), a universal helper T-cell epitope (P25) and a lipid moiety consisting of lipoamino acids (Laas) which target Toll-like receptor 2 (TLR2). Immunological evaluation in B10.BR (H-2k) mice demonstrated that the epitope attachment to the point of lipid moiety, and the length of the Laa alkyl chain have a profound effect on vaccine immunogenicity after intranasal administration. It was demonstrated that a vaccine featuring C-terminal lipid moiety containing alkyl chains of 16 carbons, with P25 located at the N-terminus, and J14 attached to the side chain of a central lysine residue was capable of inducing optimal antibody response. These findings have considerable relevance to the development of a broad spectrum J14-based GAS vaccine and in particular provided a rational basis for peptide vaccine design based on this self-adjuvanting lipopeptide technology.

Liposomes as Nanovaccine Delivery Systems

Since the discovery of liposomes by Alec Bangham in mid-1960s, these phospholipid vesicles have been widely used as pharmaceutical carriers. Liposomes have been extensively studied in the vaccine delivery field as a carrier and an immune stimulating agent. Liposomes are usually formulated as nanoparticles, mimicking the properties of pathogens, and have the ability to induce humoral and cell-mediated immune responses. In this review, we focused on modern nanotechnology-based approaches for the improvement of liposomal vaccine delivery systems. Topics such as size-dependent uptake, processing and activation of antigen presenting cells, targeting liposomes and route of administration are discussed.

Structure-activity relationship of lipopeptide Group A streptococcus (GAS) vaccine candidates on toll-like receptor 2

Incorporation of lipoamino acids (LAAs) into peptide structures effectively imparts self-adjuvanting activity onto otherwise ineffective immunogens. Our fully synthetic lipopeptide vaccine candidates against group A streptococcus (GAS) were composed of J14 as a target GAS B-cell epitope alongside a universal helper T-cell epitope (P25) and a LAA-based lipid moiety. In the current study, we investigated the ability of our lipopeptides to activate nuclear factor-kappaB (NF-kappaB) in a toll-like receptor-2 (TLR2)-dependent manner as the possible mode of action and reported the structure-function requirements for novel TLR2 targeting lipopeptides based on LAAs. The NF-kappaB activation was dependent on the dose and the length of the alkyl chains of the incorporated lipid moieties with the hierarchy LAA 3 (16 carbons)>LAA 2 (14 carbons)>LAA 1 (12 carbons). The position of the lipid moiety (C-terminus vs. N(epsilon)-terminus of the central lysine residue) does not significantly affect NF-kappaB activation. Lipopeptides containing different copies of LAA 3 were synthesized and the di-lipidated analogue was the most effective in NFkappaB activation.

Structure–Activity Relationship for the Development of a Self-Adjuvanting Mucosally Active Lipopeptide Vaccine against Streptococcus pyogenes

Infection with group A streptococcus (GAS) can result in a number of diseases, some of which are potentially life-threatening. The oral-nasal mucosa is a primary site of GAS infection, and a mucosally active vaccine candidate could form the basis of an antidisease and transmission-blocking GAS vaccine. In the present study, a peptide from the GAS M protein (J14) representing a B cell epitope was incorporated alongside a universal T cell helper epitope and a Toll-like receptor 2 targeting lipid moiety to form lipopeptide constructs. Through structure activity studies, we identified a vaccine candidate that induces J14-specific mucosal and systemic antibody responses when administered intranasally without additional adjuvants. The systemic antibodies elicited were capable of inhibiting the growth of GAS. In addition, J14-specific mucosal antibodies corresponded with reduced throat colonization after respiratory GAS challenge. These preclinical experiments show that this lipopeptide could form the basis of an optimal needle-free mucosal GAS vaccine.

Immunostimulation by Synthetic Lipopeptide-Based Vaccine Candidates: Structure-Activity Relationships

Peptide-based vaccines offer several advantages over conventional whole organism or protein approaches by offering improved purity and specificity in inducing immune response. However, peptides alone are generally non-immunogenic. Concerns remain about the toxicity of adjuvants which are critical for immunogenicity of synthetic peptides. The use of lipopeptides in peptide vaccines is currently under intensive investigation because potent immune responses can be generated without the use of adjuvant (thus are self-adjuvanting). Several lipopeptides derived from microbial origin, and their synthetic versions or simpler fatty acid moieties impart this self-adjuvanting activity by signaling via Toll-like receptor 2 (TLR2). Engagement of this innate immune receptor on antigen-presenting cell leads to the initiation and development of potent immune responses. Therefore optimization of lipopeptides to enhance TLR2-mediated activation is a promising strategy for vaccine development. Considerable structure-activity relationships that determine TLR2 binding and consequent stimulation of innate immune responses have been investigated for a range of lipopeptides. In this mini review we address the development of lipopeptide vaccines, mechanism of TLR2 recognition, and immune activation. An overview is provided of the best studied lipopeptide vaccine systems.