Catherine J. Pachuk

DNA Vaccines Encoding Interleukin-8 and RANTES Enhance Antigen-Specific Th1-Type CD4+ T-Cell-Mediated Protective Immunity against Herpes Simplex Virus Type 2 In Vivo

ABSTRACT Chemokines are inflammatory molecules that act primarily as chemoattractants and as activators of leukocytes. Their role in antigen-specific immune responses is of importance, but their role in disease protection is unknown. Recently it has been suggested that chemokines modulate immunity along more classical Th1 and Th2 phenotypes. However, no data currently exist in an infectious challenge model system. We analyzed the modulatory effects of selected chemokines (interleukin-8 [IL-8], gamma interferon-inducible protein 10 [IP-10], RANTES, monocyte chemotactic protein 1 [MCP-1], and macrophage inflammatory protein 1α [MIP-1α]) on immune phenotype and protection against lethal challenge with herpes simplex virus type 2 (HSV-2). We observed that coinjection with IL-8 and RANTES plasmid DNAs dramatically enhanced antigen-specific Th1 type cellular immune responses and protection from lethal HSV-2 challenge. This enhanced protection appears to be mediated by CD4+ T cells, as determined by in vitro and in vivo T-cell subset deletion. Thus, IL-8 and RANTES cDNAs used as DNA vaccine adjuvants drive antigen-specific Th1 type CD4+ T-cell responses, which result in reduced HSV-2-derived morbidity, as well as reduced mortality. However, coinjection with DNAs expressing MCP-1, IP-10, and MIP-1α increased mortality in the challenged mice. Chemokine DNA coinjection also modulated its own production as well as the production of cytokines. These studies demonstrate that chemokines can dominate and drive immune responses with defined phenotypes, playing an important role in the generation of protective antigen-specific immunity.

Facilitated DNA inoculation induces anti-HIV-1 immunity in vivo

Vaccine design against HIV-1 is complicated both by the latent aspects of lentiviral infection and the diversity of the virus. The type of vaccine approach used is therefore likely to be critically important. In general, vaccination strategies have relied on the use of live attenuated material or inactivated/subunit preparations as specific immunogens. Each of these methodologies has advantages and disadvantages in terms of the elicitation of broad cellular and humoral immune responses. Although most success has been achieved with live attenuated vaccines, there is a conceptual safety concern associated with the use of these vaccines for the prevention of human infections. In contrast, subunit or killed vaccine preparations enjoy advantages in preparation and conceptual safety; however, their ability to elicit broad immunity is more limited. In theory, inoculation of a plasmid DNA that supports in vivo expression of proteins, and therefore presentation of the processed protein antigen to the immune system, could be used to combine the features of a subunit vaccine and a live attenuated vaccine. We have designed a strategy for intramuscular DNA inoculation to elicit humoral and cellular immune responses against expressed HIV antigens. Uptake and expression are significantly enhanced if DNA is administered in conjunction with the facilitating agent bupivacaine-HCl. Using this technique we have demonstrated functional cellular and humoral immune responses against the majority of HIV-1 encoded antigens in both rodents and non-human primates.

DNA Priming-Protein Boosting Enhances Both Antigen-Specific Antibody and Th1-Type Cellular Immune Responses in a Murine Herpes Simplex Virus-2 gD Vaccine Model

It has previously been reported that herpes simplex virus (HSV)-2 gD DNA vaccine preferentially induces T-helper (Th) 1-type cellular immune responses, whereas the literature supports the view that subunit vaccines tend to induce potent antibody responses, supporting a Th2 bias. Here, using an HSV gD vaccine model, we investigated whether priming and boosting with a DNA or protein vaccine could induce both potent antibody and Th1-type cellular immune responses. When animals were primed with DNA and boosted with protein, both antibody and Th-cell proliferative responses were significantly enhanced. Furthermore, production of Th1-type cytokines (interleukin-2, interferon-gamma) was enhanced by DNA priming-protein boosting. In contrast, protein priming-DNA boosting produced antibody levels similar to those following protein-protein vaccination but failed to further enhance Th-cell proliferative responses or cytokine production. DNA priming-protein boosting resulted in an increased IgG2a isotype (a Th1 indicator) profile, similar to that induced by DNA-DNA vaccination, whereas protein priming-DNA boosting caused an increased IgG1 isotype (a Th2 indicator) profile similar to that seen after protein-protein vaccination. This result indicates that preferential induction of IgG1 or IgG2a isotype is determined by the type of priming vaccine used. Thus, this study suggests that HSV DNA priming-protein boosting could elicit both potent Th1-type cellular immune responses and antibody responses, both of which likely are important for protection against HSV infection.

Chain reaction cloning: a one-step method for directional ligation of multiple DNA fragments

A novel DNA assembly method, chain reaction cloning (CRC), is described. CRC enables the ordered assembly of multiple DNA fragments in a single step. The power of the technique was demonstrated by the directed in vitro assembly of a plasmid comprised of six DNA fragments from a pool of 12 available fragments. The odds of obtaining the correct plasmid clone in a single step, using conventional techniques, is less than 1 in 191000000. Using CRC, the desired plasmid was recovered at a frequency of one in two. Ligation is no longer the rate limiting step in cloning, and limitless possibilities exist for the reconstruction of complex genomes.

Plasmid DNA-expressed secreted and nonsecreted forms of herpes simplex virus glycoprotein D2 induce different types of immune responses

Herpes simplex viruses (HSVs) are significant pathogens and major targets of vaccine development. Several attempts have been made to develop prophylactic and therapeutic vaccines for HSV types 1 and 2. Although these vaccines elicit strong humoral responses, the overall impact on pathology has been disappointing. An effective vaccine for HSV must induce both humoral and cellular immune responses. DNA vaccines are ideal candidates for HSV vaccines because they induce both types of immune responses. This study showed that the type of immune response generated by immunization with DNA vaccines is modulated by expression of various forms of an antigen, each with a different cellular localization. Expression of cell-associated forms of HSV-2 glycoprotein D (gD) induces primarily a Th1 response, whereas expression of secreted gD results in a Th2 response. Immunization with plasmids expressing different forms of the antigen may increase the efficacy of a vaccine.

Characterization of a new class of DNA delivery complexes formed by the local anesthetic bupivacaine

Bupivacaine, a local anesthetic and cationic amphiphile, forms stable liposomal-like structures upon direct mixing with plasmid DNA in aqueous solutions. These structures are on the order of 50-70 nm as determined by scanning electron microscopy, and are homogeneous populations as analyzed by density gradient centrifugation. The DNA within these structures is protected from nuclease degradation and UV-induced damage in vitro. Bupivacaine:DNA complexes have a negative zeta potential (surface charge), homogeneous nature, and an ability to rapidly assemble in aqueous solutions. Bupivacaine:DNA complexes, as well as similar complexes of DNA with other local anesthetics, have the potential to be a novel class of DNA delivery agents for gene therapy and DNA vaccines.

Herpes Simplex Virus DNA Vaccine Efficacy: Effect of Glycoprotein D Plasmid Constructs

The impact of vaccination with plasmid DNA encoding full-length glycoprotein D (gD) from herpes simplex virus (HSV) type 2 (gD2), secreted gD2, or cytosolic gD2 was evaluated in mice and guinea pigs. Immunization with plasmids encoding full-length gD2 or secreted gD2 produced high antibody levels, whereas immunization with DNA encoding cytosolic gD2 resulted in significantly lower antibody titers in both species (P<.001). Vaccination with DNA encoding full-length or secreted gD2 significantly reduced acute disease in mice and guinea pigs (both P<.001) and subsequent recurrent disease in guinea pigs (P<.05). In guinea pigs, immunization with DNA encoding cytosolic gD2 did not protect from acute or recurrent disease, whereas in mice it did protect, but not as well as DNA encoding full-length or secreted gD2. None of the vaccines resulted in improved virus clearance from the inoculation site, and none significantly reduced recurrent disease when used as a therapeutic vaccine in HSV-2-infected guinea pigs.

Interleukin 7 can enhance antigen-specific cytotoxic-T-lymphocyte and/or Th2-type immune responses in vivo.

ABSTRACT Interleukin 7 (IL-7) protein has been reported to be important in the development of cytotoxic-T-lymphocyte (CTL) responses. However, other studies also support a partial Th2 phenotype for this cytokine. In an effort to clarify this unusual conflict, we compared IL-7 along with IL-12 (Th1 control) and IL-10 (Th2 control) for its ability to induce antigen (Ag)-specific CTL and Th1- versus Th2-type immune responses using a well established DNA vaccine model. In particular, IL-7 codelivery showed a significant increase in immunoglobulin G1 (IgG1) levels compared to IgG2a levels. IL-7 coinjection also decreased production of Th1-type cytokine IL-2, gamma interferon, and the chemokine RANTES but increased production of the Th2-type cytokine IL-10 and the similarly biased chemokine MCP-1. In herpes simplex virus (HSV) challenge studies, IL-7 coinjection decreased the survival rate after lethal HSV type 2 (HSV-2) challenge compared with gD plasmid vaccine alone in a manner similar to IL-10 coinjection, whereas IL-12 coinjection enhanced the protection, further supporting that IL-7 drives immune responses to the Th2 type, resulting in reduced protection against HSV-2 challenge. Moreover, coinjection with human immunodeficiency virus type 1 env and gag/polgenes plus IL-12 or IL-7 cDNA enhanced Ag-specific CTLs, while coinjection with IL-10 cDNA failed to influence CTL induction. Thus, IL-7 could drive Ag-specific Th2-type cellular responses and/or CTL responses. These results support that CTLs could be induced by IL-7 in a Th2-type cytokine and chemokine environment in vivo. This property of IL-7 allows for an alternative pathway for CTL development which has important implications for host-pathogen responses.

Using RNA interference to modulate gene expression

Abstract RNA interference (RNAi) has emerged as one of the most promising technologies among those directed towards regulating gene expression in animals. The presence of a double-stranded RNA (dsRNA) in eukaryotic cells triggers this post-transcriptional gene-silencing mechanism, leading to a sequence-specific degradation of the target mRNA. RNAi offers unique advantage over other technologies due to its ability both to amplify catalytically the initial trigger signal to silence the target RNA sequence and to systemically spread the silencing signal to other cells. Various strategies currently being developed to employ RNAi technology for rapid functional genomic analyses and therapeutic applications will be reviewed in this paper.

Methods for DNA introduction into mammalian cells

Publisher Summary The development of methods for the introduction of DNA into cultured cells, especially mammalian cells, has proceeded in parallel with advances in molecular cloning techniques. The process of introducing DNA into vertebrate cells is generally referred to as “transfection,” although some authors have referred to the same process as “transformation,” by analogy with DNA transfer in prokaryotes. In this chapter, the term transfection is used to avoid confusion, as transformation can have a distinct meaning with regard to the growth and the morphologic state of mammalian cells. Ideally, a transfection efficiency of 100% (all target cells acquire and express the introduced DNA) associated with minimal toxicity (all cells survive the procedure) is desired. Although a number of transfection methods have been described, virtually all fall short of these ideals. Increased transfection efficiency often correlates with increased toxicity, necessitating a tradeoff. This chapter reviews the most commonly encountered methods, with consideration of their relative merits both in principle and in practice. The principal barriers to successful transfection are identified and discussed, as further research in this area will likely lead to improved methods in the future. Transfection methods can be grouped simplistically into three categories: physically mediated delivery, chemically mediated delivery and biological vector-mediated delivery of nucleic acid. Although mammalian cells have been transfected with nucleic acids from a variety of sources, including total genomic DNA and RNA, the vast majority of experiments involve DNA sequences that have been subcloned and propagated in Escherichia coli .