Increasing the immunogenicity of a trivalent influenza virus vaccine with adjuvant-active nonionic block copolymers for potential use in the elderly

What can imaging tell us about influenza virus transmission and protection?

The emergence of zoonotic influenza infections is a constant threat to public health. One of the major determinants of pandemic potential is the ability to transmit from animal to human and/or human to human via respiratory droplets. Understanding viral tropism and spread is crucial for predicting which viruses represent the most threatening to human health. Recently, a replication-competent influenza reporter virus was described that permitted in vivo imaging and visualization of infection in ferrets for the first time. This review will focus on the applications of luminescent reporter viruses toward understanding transmission of influenza viruses and development of therapeutic interventions.

Physical characterization and in vivo evaluation of poloxamer-based DNA vaccine formulations

BACKGROUND

Plasmid DNA (pDNA) vaccines have generated significant interest for the prevention or treatment of infectious diseases. Broader applications may benefit from the identification of safe and potent vaccine adjuvants. This report describes the development of a novel polymer-based formulation to enhance the immunogenicity of pDNA-based vaccines.

METHODS

Plasmid DNA was formulated with a nonionic block copolymer, poloxamer CRL1005, and the cationic surfactant benzalkonium chloride (BAK) to produce a thermodynamically stable, self-assembling system. The influence of parameters such as polymer concentration and BAK composition on the immune responses was evaluated in mice vaccinated with pDNA encoding influenza nucleoprotein.

RESULTS

At concentrations of 7.5 mg/ml CRL1005, 0.3 mM BAK and 5 mg/ml pDNA, CRL1005/BAK/pDNA particles had a mean diameter of 261 +/- 0.2 nm and a surface charge of - 11.6 +/- 0.9 mV. The negative surface charge and atomic force microscopy images suggested that pDNA binds to BAK adsorbed to the surface of poloxamer particles. The CRL1005/BAK/pDNA formulation significantly enhanced antigen-specific cellular and humoral immune responses, and increased transgene levels in muscle and serum. The complexity of the formulation was reduced by replacing the commercial BAK, which is a mixture of four alkyl chains, with a C14 BAK homolog. The substitution yielded an analytically preferable formulation with equivalent physical characteristics and immunogenicity.

CONCLUSIONS

The results suggest that the CRL1005/BAK/pDNA formulation may enhance immunogenicity by improving the delivery of pDNA-based vaccines. This formulation is currently being evaluated for the prevention of CMV-associated disease in a phase 2 clinical trial.

Evaluation of cholera vaccines formulated with toxin-coregulated pilin peptide plus polymer adjuvant in mice

Cholera is an acute diarrheal disease that is caused by the gram-negative bacterium Vibrio cholerae. The low efficacy of currently available killed-whole-cell vaccines and the reactinogenicity coupled with potential reversion of live vaccines have thus far precluded widespread vaccination for the control of cholera. Recent studies on the molecular nature of the virulence components that contribute to V. cholerae pathogenesis have provided insights into possible approaches for the development of a defined subunit cholera vaccine. Genetic analysis has demonstrated that the toxin-coregulated pilus (TCP) is the major factor that contributes to colonization of the human intestine by V. cholerae. In addition, polyclonal and several monoclonal antibodies directed against TCP have been shown to provide passive immunity to disease in the infant mouse cholera model. In the present study, synthetic peptides corresponding to portions of the C-terminal disulfide region of TcpA pilin were formulated with polymer adjuvants currently in clinical trials and used to actively immunize adult female CD-1 mice. The experimental vaccine formulations elicited high levels of antigen-specific immunoglobulin G (IgG), including a broad spectrum of subclasses (IgG1, IgG2a, IgG2b, and IgG3), and lower levels of IgA. Infant mice born to the immunized mothers showed 100% protection against a 50% lethal dose (1 LD(50)) challenge and 50% protection against a 10-LD(50) challenge with virulent strain O395. These results indicate that specific regions of TcpA, including those delineated by the peptides used in this study, have the potential to be incorporated into an effective defined subunit vaccine for cholera.

Structure and design of polymeric surfactant-based drug delivery systems

The review concentrates on the use of polymeric micelles as pharmaceutical carriers. Micellization of biologically active substances is a general phenomenon that increases the bioavailability of lipophilic drugs and nutrients. Currently used low-molecular-weight pharmaceutical surfactants have low toxicity and high solubilization power towards poorly soluble pharmaceuticals. However, micelles made of such surfactants usually have relatively high critical micelle concentration (CMC) and are unstable upon strong dilution (for example, with the blood volume upon intravenous administration). On the other hand, amphiphilic block co-polymers are also known to form spherical micelles in solution. These micelles have very high solubilization capacity and rather low CMC value that makes them very stable in vivo. Amphiphilic block co-polymers suitable for micelle preparation are described and various types of polymeric micelles are considered as well as mechanisms of their formation, factors influencing their stability and disintegration, their loading capacity towards various poorly soluble pharmaceuticals, and their therapeutic potential. The basic mechanisms underlying micelle longevity and steric protection in vivo are considered with a special emphasis on long circulating drug delivery systems. Advantages and disadvantages of micelles when compared with other drug delivery systems are considered. New polymer-lipid amphiphilic compounds such as diacyillipid-polyethylene glycol, are described and discussed. These compounds are very attractive from a practical point of view, since they easily micellize yielding extremely stable micelles with very high loading capacity. Micelle passive accumulation in the areas with leaky vasculature (tumors, infarct zones) is discussed as an important physiology-based mechanism of drug delivery into certain target zones. Targeted polymeric micelles prepared by using thermo- or pH-sensitive components or by attaching specific targeted moieties (such as antibodies) to their outer surface are described as well as their preparation and some in vivo properties. The fast growing field of diagnostic micelles is analyzed. Polymeric micelles are considered loaded with various agents for gamma, magnetic resonance, and computed tomography imaging. Their in vitro and in vivo properties are discussed and the results of the initial animal experiments are presented.

Improving vaccine performance with adjuvants

New vaccines are presently under development and in testing for the control of infectious diseases, including human immunodeficiency virus (HIV) and tuberculosis. Several of these vaccines are composed of synthetic, recombinant, or highly purified subunit antigens. Subunit vaccines are designed to include only the antigens required for protective immunization and to be safer than whole-inactivated or live-attenuated vaccines. However, the purity of the subunit antigens and the absence of the self-adjuvanting immunomodulatory components associated with attenuated or killed vaccines often result in weaker immunogenicity. Immunologic adjuvants are agents that enhance specific immune responses to vaccines. Formulation of vaccines with potent adjuvants is an attractive approach for improving the performance of vaccines composed of subunit antigens. Adjuvants have diverse mechanisms of action and should be selected for use on the basis of the route of administration and the type of immune response (antibody, cell-mediated, or mucosal immunity) that is desired for a particular vaccine.

A nonionic block co-polymer adjuvant (CRL1005) enhances the immunogenicity and protective efficacy of inactivated influenza vaccine in young and aged mice

The use of adjuvants is one approach to improve influenza vaccine immunogenicity and efficacy, particularly in aged populations. The response of BALB/c mice to subcutaneously administered formalin-inactivated whole influenza virus vaccine in the presence or absence of a nonionic block copolymer adjuvant CRL1005 was evaluated. In young adult naïve mice, the copolymer adjuvant significantly enhanced virus-specific IgG and hemagglutination-inhibition (HI) antibody responses and augmented the production of IL-2 following vaccination. Influenza vaccine formulated with 2.5 mg CRL1005 significantly enhanced the protective efficacy of the inactivated vaccine in the upper and lower respiratory tract. In mice previously infected with influenza virus or naïve aged mice, inactivated vaccine administered with the copolymer adjuvant substantially enhanced the serum HI antibody response to inactivated influenza vaccine and significantly reduced lung virus titers following subsequent challenge with live virus compared with mice administered vaccine alone. These results suggest that the copolymer adjuvant warrants further investigation as a potential adjuvant for use in human vaccination against influenza.

Design and development of adjuvant-active nonionic block copolymers

Nonionic block copolymers are surfactants synthesized using propylene oxide and ethylene oxide, and they can be designed so that individual copolymers have unique vaccine adjuvant properties. We have designed and produced nonionic block copolymers based on high molecular weight (MW), 9-15 kDA, cores of poly(oxypropylene) (POP) coupled with smaller poly(oxyethylene) (POE) end blocks. Copolymers synthesized with less than 10% (w/w) POE will spontaneously assemble into 300 nm-3 microm micelles or microparticles in aqueous solutions at physiological pH, and when formulated with protein, complex microparticles consisting of both the protein and copolymers are formed. The adjuvant activity of nonionic block copolymers is influenced by both size and POE content; maximal activity is associated with low POE content, 5-10%, and a molecular size of 11-12 kDa. The type of immune response produced is also influenced by the POE content. Copolymers with 10% POE significantly augmented Type 2 helper T-lymphocyte responses whereas copolymers with lower POE contents augmented both Type 1 and Type 2 helper T-lymphocyte responses. This property allows for vaccines to be "customized" by using adjuvant-active nonionic block copolymers that will augment the most appropriate types of immune responses.

Enhancement of HIV type 1 vaccine immunogenicity by block copolymer adjuvants. I. Induction of high-titer, long-lasting, cross-reactive antibodies of broad isotype

Improvements in HIV-1 vaccines are urgently needed since many of the available vaccines are weak immunogens. We examined the ability of CRL1005, a novel nonionic block copolymer adjuvant, to improve the immunogenicity of multiple HIV-1 envelope vaccines: six gp120s and single and multiple V3 peptides (MAPs). Formulation of vaccine with adjuvant, as compared with alum or saline, enhanced antibody titer in mice up to 200-fold, with antibody half-lives of >200 days. For most vaccinations, an oil-in-water formulation induced the highest antibody titers; for some antigens, however, particularly single peptides, water-in-oil (w/o) was better. Antigen cross-reactivity was optimized by formulation in w/o, while addition of detoxified lipopolysaccharide enhanced levels of IgG2a and IgG2b. After more than 1 year of observation, no vaccine-related toxicity was observed and emulsified antigen in encapsulated depots was found at immunization sites of w/o-immunized animals. No other adjuvant has been reported to induce such long-lasting antibodies, and the ability of CRL1005 to greatly amplify and qualitatively modify antibody responses suggests that it may be useful in developing improved HIV vaccines for humans.