Mei-Fong Ho

Intranasal Administration Is an Effective Mucosal Vaccine Delivery Route for Self-Adjuvanting Lipid Core Peptides Targeting the Group A Streptococcal M Protein

BACKGROUND We investigated the lipid core peptide (LCP) system for mucosal vaccine delivery against infection with group A streptococcus (GAS)--the causative pathogen of rheumatic fever and rheumatic heart disease. METHODS An LCP vaccine formulation containing 2 different peptide epitopes of the antiphagocytic M protein of GAS--a conformational epitope from the carboxyterminal conserved C-repeat region and an aminoterminal serotypic epitope--was intranasally administered to mice with cholera toxin B subunit or without additional adjuvant. RESULTS Our data demonstrate that the LCP vaccine formulation induced the elicitation of antigen-specific systemic immunoglobulin G responses when administered with or without cholera toxin B subunit, whereas cholera toxin B subunit was required for the induction of antigen-specific mucosal immunoglobulin A responses. Immune serum samples from vaccinated mice were capable of opsonization of a homologous GAS strain, as well as opsonization of a heterologous GAS strain. Furthermore, mice were protected from GAS challenge following immunization with the LCP vaccine formulation, even in the absence of additional adjuvant. CONCLUSIONS These data support the potential of the LCP system in the development of a self-adjuvanting, synthetic, peptide-based mucosal GAS vaccine for the prevention of diseases caused by GAS.

Immunization with a Tetraepitopic Lipid Core Peptide Vaccine Construct Induces Broadly Protective Immune Responses against Group A Streptococcus

BACKGROUND The development of a vaccine to prevent infection with group A streptococcus (GAS) is hampered by the widespread diversity of circulating GAS strains and M protein types, and it is widely believed that a multivalent vaccine would provide better protective immunity. METHODS We investigated the efficacy of incorporating 3 M protein serotypic amino-terminal epitopes from GAS isolates that are common in Australian Aboriginal communities and a conformational epitope from the conserved carboxy-terminal C-repeat region into a single synthetic lipid core peptide (LCP) vaccine construct in inducing broadly protective immune responses against GAS after parenteral delivery to mice. RESULTS Immunization with the tetraepitopic LCP vaccine construct led to high titers of systemic, antigen-specific IgG responses and the induction of broadly protective immune responses, as was demonstrated by the ability of immune serum to opsonize multiple GAS strains. Systemic challenge of mice with a lethal dose of GAS given 60 or 300 days after primary immunization showed that, compared with the control mice, the vaccinated mice were significantly protected against GAS infection, demonstrating that the vaccination stimulated long-lasting protective immunity. CONCLUSIONS These data support the efficacy of the LCP vaccine delivery system in the development of a synthetic, multiepitopic vaccine for the prevention of GAS infection.

Streptococcal immunity is constrained by lack of immunological memory following a single episode of pyoderma

The immunobiology underlying the slow acquisition of skin immunity to group A streptococci (GAS), is not understood, but attributed to specific virulence factors impeding innate immunity and significant antigenic diversity of the type-specific M-protein, hindering acquired immunity. We used a number of epidemiologically distinct GAS strains to model the development of acquired immunity. We show that infection leads to antibody responses to the serotype-specific determinants on the M-protein and profound protective immunity; however, memory B cells do not develop and immunity is rapidly lost. Furthermore, antibodies do not develop to a conserved M-protein epitope that is able to induce immunity following vaccination. However, if re-infected with the same strain within three weeks, enduring immunity and memory B-cells (MBCs) to type-specific epitopes do develop. Such MBCs can adoptively transfer protection to naïve recipients. Thus, highly protective M-protein-specific MBCs may never develop following a single episode of pyoderma, contributing to the slow acquisition of immunity and to streptococcal endemicity in at-risk populations.

Synthesis and Immunological Evaluation of M Protein Targeted Tetra-Valent and Tri-Valent Group A Streptococcal Vaccine Candidates Based on the Lipid-Core Peptide System

Group A streptococcus (GAS) is responsible for causing many clinical complications including the relatively benign streptococcal pharyngitis and impetigo. However, if left untreated, these conditions may lead to more severe diseases such as rheumatic fever (RF) and rheumatic heart disease (RHD). These diseases exhibit high morbidity and mortality, particularly in developing countries and in indigenous populations of affluent countries. As RF and RHD only ever occur following GAS infection, a vaccine offers promise for their prevention. As such, we have investigated the use of the lipid-core peptide (LCP) system for the development of multi-valent prophylactic GAS vaccines. The current study has investigated the capacity of this system to adjuvant up to four different GAS peptide epitopes. Presented are the synthesis and immunological assessment of tetra-valent and tri-valent GAS LCP systems. We demonstrated their capacity to elicit systemic IgG antibody responses in B10.BR mice to all GAS peptide epitopes. The data also showed that the LCP systems were self-adjuvanting. These findings are particularly encouraging for the development of multi-valent LCP-based GAS vaccines.

Vaccination with chemically attenuated Plasmodium falciparum asexual blood-stage parasites induces parasite-specific cellular immune responses in malaria-naïve volunteers: a pilot study

BackgroundThe continuing morbidity and mortality associated with infection with malaria parasites highlights the urgent need for a vaccine. The efficacy of sub-unit vaccines tested in clinical trials in malaria-endemic areas has thus far been disappointing, sparking renewed interest in the whole parasite vaccine approach. We previously showed that a chemically attenuated whole parasite asexual blood-stage vaccine induced CD4+ T cell-dependent protection against challenge with homologous and heterologous parasites in rodent models of malaria.MethodsIn this current study, we evaluated the immunogenicity and safety of chemically attenuated asexual blood-stage Plasmodium falciparum (Pf) parasites in eight malaria-naïve human volunteers. Study participants received a single dose of 3 × 107 Pf pRBC that had been treated in vitro with the cyclopropylpyrolloindole analogue, tafuramycin-A.ResultsWe demonstrate that Pf asexual blood-stage parasites that are completely attenuated are immunogenic, safe and well tolerated in malaria-naïve volunteers. Following vaccination with a single dose, species and strain transcending Plasmodium-specific T cell responses were induced in recipients. This included induction of Plasmodium-specific lymphoproliferative responses, T cells secreting the parasiticidal cytokines, IFN-γ and TNF, and CD3+CD45RO+ memory T cells. Pf-specific IgG was not detected.ConclusionsThis is the first clinical study evaluating a whole parasite blood-stage malaria vaccine. Following administration of a single dose of completely attenuated Pf asexual blood-stage parasites, Plasmodium-specific T cell responses were induced while Pf-specific antibodies were not detected. These results support further evaluation of this chemically attenuated vaccine in humans.Trial registrationTrial registration: ACTRN12614000228684. Registered 4 March 2014.