The potential of CpG oligodeoxynucleotides as mucosal adjuvants.

The development of mucosal vaccines for humans has been hindered by the lack of safe yet effective mucosal adjuvants. Bacterial toxins are commonly used as adjuvants in animal models, but they are too toxic for use in humans. A novel class of adjuvant is CpG DNA, which contains unmethylated CpG dinucleotides in particular base contexts (CpG motifs). CpG DNA is most often coadministered with antigen in the form of synthetic oligodeoxynucleotides (CpG ODN), which are made with a nuclease-resistant phosphorothioate backbone. The vast majority of studies using CpG DNA as adjuvant have been with parenteral delivery; recently, however, mucosal immunization with CpG DNA as adjuvant has also been shown to induce both systemic (humoral and cellular) and mucosal antigen-specific immune responses. This review will highlight the recent uses of CpG DNA as an adjuvant at mucosal surfaces.

Immune-mediated destruction of transfected myocytes following DNA vaccination occurs via multiple mechanisms.

The delivery of antigenic proteins in the context of a DNA vaccine leads to the intracellular synthesis of antigen and the induction of both humoral and cellular immune responses. Subsequent to immune activation, any transfected cell expressing the immunogenic protein should, by the rules of immunology, become a legitimate target for removal by immune-mediated mechanisms. Herein, we have used an indirect assay of myocyte integrity following intra-muscular (i.m.) delivery of a DNA vaccine, in mice with various immune deficiencies, to determine which immunological mechanisms may be involved in destruction of antigen-expressing cells. We demonstrate that destruction of antigen- expressing myocytes following i.m. injection of a DNA vaccine is dependent on major histocompatibility complex (MHC) class II restricted CD4+ T cell activation, but is not mediated solely by MHC I-restricted or perforin-mediated lysis and appears to have a component that is antibody-mediated. Although we studied myocytes, the results likely represent what happens to any transfected cell expressing a foreign antigen. This study underscores the ability of DNA vaccines at inducing antigen-specific immune responses that include a number of effector mechanisms. From the perspective of gene therapy, this study highlights the significance of immune activation when considering strategies where maintenance of therapeutic gene expression is desired.

The use of CpG DNA as a mucosal vaccine adjuvant.

CpG DNA has been shown to be a potent adjuvant in many disease models. Most studies using CpG DNA as adjuvant have used parenteral delivery, but more effective protection against mucosal pathogens could be achieved with effective mucosal immunization. Recently, mucosal immunization with CpG DNA as an adjuvant has been shown to induce both systemic (humoral and cellular) and mucosal antigen-specific immune responses. This review will concentrate on the use of CpG DNA as an adjuvant for the induction of mucosal immunity.

CpG oligodeoxynucleotides with hepatitis B surface antigen (HBsAg) for vaccination in HBsAg-transgenic mice.

DNA motifs containing unmethylated CpG dinucleotides within the context of certain flanking sequences enhance both innate and antigen-specific immune responses, due in part to the enhanced production of Th1-type cytokines. Here we explored the ability of CpG-containing oligodeoxynucleotides combined with recombinant hepatitis B surface antigen (HBsAg) to induce Th1 responses in mice that are transgenic for this antigen and that represent a model for asymptomatic hepatitis B virus chronic carriers. This was compared to hepatitis B virus-specific DNA-mediated immunization, which we have previously shown to induce the clearance of the transgene expression product and the down-regulation of hepatitis B virus mRNA in this transgenic mouse lineage. In control nontransgenic C57BL/6 mice, three immunizations with HBsAg and CpG triggered the production of anti-HBs antibodies and of HBs-specific T cells that secrete gamma interferon but do not display any HBsAg-specific cytotoxic activity. In the HBsAg-transgenic mice, immunization with HBsAg and CpG oligodeoxynucleotides, but not with CpG alone, induced the clearance of HBsAg circulating in the sera, with a concomitant appearance of specific antibodies, and was able to regulate the hepatitis B virus mRNA constitutively expressed in the liver. Finally, adoptive transfer experiments with CD8(+) T cells primed in C57BL/6 mice with HBsAg and CpG oligodeoxynucleotide-based immunization show that these cells were able to partially control transgene expression in the liver and to clear the HBsAg from the sera of recipient transgenic mice without an antibody requirement. CpG oligodeoxynucleotides motifs combined with HBsAg could therefore represent a potential therapeutic approach with which to treat chronically infected patients.

History of vaccines and positioning of current trends.

The history of vaccine development spans a relatively short period of time in comparison to the history of human civilization. However, monumental advances in the field of vaccines have been made in effort to combat infectious disease. These advances have led to a reduction, and in one case the complete eradication, of the burden of some infectious diseases of the world. Throughout the history of vaccine development, milestone discoveries can be identified that have shaped the field of vaccine development, as we know it. These milestones include the first official use of a vaccine by Edward Jenner, the attenuation principals observed by Pasteur, the development of cell culture for the propagation of viruses, and the production of first recombinant protein based vaccine for hepatitis B. As vaccine development progresses into the 21st century, it will be important to build on the experience and knowledge generated in the past, in an effort to surpass the limitations that currently hamper the development of new and more effective vaccine technologies. Presented here is an overview on the history of vaccine development and its influence on the positioning of current trends and future considerations.

Vaccination of chimpanzees with plasmid DNA encoding the hepatitis C virus (HCV) envelope E2 protein modified the infection after challenge with homologous monoclonal HCV.

Hepatitis C virus (HCV) is an important cause of chronic liver disease worldwide. Development of vaccines to prevent HCV infection, or at least prevent progression to chronicity, is a major goal. In mice and rhesus macaques, a DNA vaccine encoding cell-surface HCV-envelope 2 (E2) glycoprotein stimulated stronger immune responses than a vaccine encoding intracellular E2. Therefore, we used DNA encoding surface-expressed E2 to immunize chimpanzees 2768 and 3001. Chimpanzee 3001 developed anti-E2 after the second immunization and antibodies to hypervariable region 1 (HVR1) after the third immunization. Although chimpanzee 2768 had only low levels of anti-E2 after the third immunization, an anamnestic response occurred after HCV challenge. CTL responses to E2 were not detected before challenge, but a strong response was detected after HCV challenge in chimpanzee 2768. An E2-specific CD4+ response was detected in chimpanzee 2768 before challenge and in both chimpanzees postchallenge. Three weeks after the last immunization, animals were challenged with 100 50% chimpanzee-infectious doses (CID(50)) of homologous monoclonal HCV. As a control, a naive chimpanzee was inoculated with 3 CID(50) of the challenge virus. The vaccine did not generate sterilizing immunity because both vaccinated chimpanzees were infected. However, both vaccinated chimpanzees resolved the infection early whereas the control animal became chronically infected. Compared with the control animal, hepatitis appeared earlier in the course of the infection in both vaccinated chimpanzees. Therefore, DNA vaccine encoding cell surface-expressed E2 did not elicit sterilizing immunity in chimpanzees against challenge with a monoclonal homologous virus, but did appear to modify the infection and might have prevented progression to chronicity.

Development of an enzyme-linked immunosorbent assay for measurement of serum-associated ALX40-4C.

ALX40-4C is an antiretrovirus agent that has been found to have some inhibitory properties against human immunodeficiency virus (HIV) replication in vitro. The compound was designed as a competitor of the HIV Tat protein for TAR binding. In addition to its anti-HIV properties, it has demonstrated the ability to inhibit in vitro replication of herpes simplex virus types 1 and 2 as well as human cytomegalovirus. Subsequently, in vivo pharmacokinetic evaluation of ALX40-4C necessitated the establishment of a detection system for the measurement of ALX40-4C in subject serum. For this purpose, an indirect-competition enzyme-linked immunosorbent assay with generated rabbit anti-ALX40-4C antiserum was developed. The original assay took 12 h to complete and required many manipulations. Herein, we describe alterations to the system that resulted in the overall reduction in assay time and manipulation. We demonstrate that our alterations do not affect the specificity or sensitivity of the assay compared to that of the original system. ALX40-4C levels in spiked serum samples as well as drug levels from patient samples were used to validate the assay.