Immunostimulatory DNA sequences function as T helper-1-promoting adjuvants

HIV-Specific CD4(+) and CD8(+) immune responses are generated with a gp120-depleted, whole-killed HIV-1 immunogen with CpG immunostimulatory sequences of DNA

We examined the adjuvant effects of a synthetic CpG oligodeoxynucleotide immunostimulatory sequence (ISS) using a whole-killed, gp120-depleted HIV antigen (HIV-1 antigen) in a Lewis rat model. We hypothesized that HIV-1-specific CD4(+) T helper (Th) immune responses could be enhanced when an ISS was combined with an HIV-1 antigen in incomplete Freund's adjuvant (IFA). We also reasoned that if such Th responses were sufficient, such a combination might also induce HIV-specific CD8(+) T cell immune responses. Here we demonstrate that the HIV-1 antigen in IFA combined with ISS stimulates both CD4(+) and CD8(+) HIV-specific immune responses as measured by interferon-gamma (IFN-gamma) in the ELISPOT assay. A strong correlation between these CD4(+) and CD8(+) responses was demonstrated. Furthermore, we found that the HIV-1 antigen in IFA with ISS as an adjuvant stimulated strong antibody responses to core antigen (p24). These studies suggest that the combination of the whole-killed, gp120-depleted HIV-1 antigen in IFA with ISS may be an ideal candidate to test in nonhuman primates and in human studies as a preventive HIV-1 vaccine.

Myelin oligodendrocyte glycoprotein-DNA vaccination induces antibody-mediated autoaggression in experimental autoimmune encephalomyelitis

One strategy to reestablish self tolerance in autoimmune diseases is based on the use of DNA vaccination to induce ectopic expression of the target autoantigen. We assessed the potential of vaccination with a DNA construct encoding the myelin oligodendrocyte glycoprotein (MOG), an important candidate autoantigen in multiple sclerosis, to induce tolerance and protect against experimental autoimmune encephalomyelitis (EAE). Unexpectedly, mice vaccinated with MOG-DNA developed an exacerbated form of EAE when challenged with either MOG or an unrelated encephalitogen, myelin proteolipid protein. We demonstrate that this is due to the inability of DNA vaccination to tolerize the MOG-specific T cell response and to the concomitant induction of a cytopathic MOG-specific autoantibody response, which is pathogenic, enhancing demyelination, inflammation and disease severity. Our data suggest that tolerogenic strategies for autoimmune diseases based on DNA vaccination should be approached with caution, as the outcome is unpredictable.

APC stimulated by CpG oligodeoxynucleotide enhance activation of MHC class I-restricted T cells

Oligonucleotides containing unmethylated CpG motifs (cytosine-phosphorothioate-guanine oligodeoxynucleotide (CpG ODN)) are potent immunostimulatory agents capable of enhancing the Ag-specific Th1 response when used as immune adjuvants. We evaluated the cellular mechanisms responsible for this effect. Development of a CTL response was enhanced when mice were immunized with peptide-pulsed dendritic cells (DCs) treated with CpG ODN. However, in vitro, CpG ODN had no direct effect on highly purified T cells. In vitro, CpG ODN treatment of peptide- or protein-pulsed DCs enhanced the ability of the DCs to activate class I-restricted T cells. The presence of helper T cells enhanced this effect, indicating that treatment with CpG ODN does not obviate the role of T cell help. The enhanced ability of CpG ODN-treated DCs to activate T cells was present but blunted when DCs derived from IL-12 knockout mice were used. Fixation of Ag-pulsed, CpG ODN-treated DCs limited their ability to activate T cells. In contrast, fixation had little effect on DC activation of T cells when DCs were not exposed to CpG ODN. This indicates that production of soluble factors by DCs stimulated with CpG ODN plays a particularly important role in their ability to activate class I-restricted T cells. We conclude that CpG ODN enhances the development of a cellular immune response by stimulating APCs such as DCs, to produce IL-12 and other soluble factors.

CpG DNA is an effective oral adjuvant to protein antigens in mice

We have previously reported that synthetic oligodeoxynucleotides containing immunostimulatory CpG motifs (CpG ODN) are potent adjuvants to protein administered by intramuscular (IM) injection or intranasal (IN) inhalation to BALB/c mice. Herein, we have evaluated oral delivery of CpG ODN with purified hepatitis B surface antigen (HBsAg) or tetanus toxoid (TT) to determine its potential as an adjuvant to oral vaccines. CpG ODN augmented systemic (IgG in plasma, CTL, T-cell proliferation) and mucosal (IgA in lung, vaginal or gut washes, feces and saliva) immune responses against both antigens. CpG stimulated both T-helper type 1 (Th1) (CTL, IgG2a) and Th2 (IgG1, IgA) responses when delivered orally. Results from this study indicate that stimulatory CpG ODN may be effective as an adjuvant with oral vaccines.

Immune effects and mechanisms of action of CpG motifs

Bacterial DNA differs from vertebrate DNA in having a much higher content of unmethylated CpG dinucleotides, in particular, base contexts that are termed 'CpG motifs'. The vertebrate immune system appears to have evolved pattern recognition molecules that recognize 'CpG motifs' as foreign, and trigger protective immune responses which are strongly Th1-biased. These responses can be mimicked using synthetic oligodeoxyribonucleotides, which have demonstrated remarkable utility as vaccine adjuvants and as immunotherapeutics for treatment of cancer and allergic diseases.

Naked DNA vaccination differentially modulates autoimmune responses in experimental autoimmune encephalomyelitis

Vaccination with naked DNA represents a therapeutic strategy currently under consideration in multiple sclerosis (MS). In this study, we tested the potential therapeutic effect of vaccination with a naked DNA construct encoding proteolipid protein (pRc/CMV-PLP) upon the outcome of subsequent sensitization for experimental autoimmune encephalomyelitis (EAE) actively-induced in SJL mice with PLP139-151 peptide in adjuvant. Intramuscular vaccination with the naked DNA pRc/CMV-PLP construct led to PLP expression in local muscle tissue that persisted for about 8 weeks. Early sensitization for EAE (4 weeks after DNA vaccination) caused recipient mice to develop a severe, exacerbated form of disease (in comparison to control mice), while late sensitization (>10 weeks) resulted in a milder, ameliorated form. In the groups sensitized <10 weeks post-DNA vaccination with pRc/CMV-PLP induction of a Th1-type cytokine response was noted. In contrast, sensitization >10 weeks post-DNA vaccination led to peripheral tolerance as evidenced by a decrease in T cell proliferation and cytotoxic T cell response, no Th2 response, and no increase in apoptosis. These data are novel in that they demonstrate a differential effect of DNA vaccination and have important implications for its use as a mechanism to enhance or modulate immune reactivity.

Nonviral skin gene therapy

Nonviral skin gene therapy is an effective method to directly deliver and transiently express genes in the skin. Several different nonviral delivery methods have been successfully used and are analyzed here for their efficiency and efficacy in achieving specific therapeutic applications. For one important and frequently used application of nonviral skin gene therapy, genetic immunization, the types of resulting immune responses (Th1 versus Th2) will depend on which delivery method is used. In addition, we discuss the contributions of DNA as an immunostimulatory adjuvant in genetic immunization and how activation of skin dendritic cells and induction of IL-12 expression are mechanistically important in this process. Nonviral skin gene therapy has also been successfully used to enhance tumor regression in animal models, frequently by inducing a specific immune response against the tumor. In the future, nonviral skin gene therapy may be successfully used for the treatment of additional skin diseases if genes can be selectively delivered and expressed in specific skin cells, and if increased level and duration of gene expression can be achieved.

Phosphorothioate backbone modification modulates macrophage activation by CpG DNA

Macrophages respond to unmethylated CpG motifs present in nonmammalian DNA. Stabilized phosphorothioate-modified oligodeoxynucleotides (PS-ODN) containing CpG motifs form the basis of immunotherapeutic agents. In this study, we show that PS-ODN do not perfectly mimic native DNA in activation of macrophages. CpG-containing PS-ODN were active at 10- to 100-fold lower concentrations than corresponding phosphodiester ODN in maintenance of cell viability in the absence of CSF-1, in induction of NO production, and in activation of the IL-12 promoter. These enhancing effects are attributable to both increased stability and rate of uptake of the PS-ODN. By contrast, PS-ODN were almost inactive in down-modulation of the CSF-1R from primary macrophages and activation of the HIV-1 LTR. Delayed or poor activation of signaling components may contribute to this, as PS-ODN were slower and less effective at inducing phosphorylation of the extracellular signal-related kinases 1 and 2. In addition, at high concentrations, non-CpG PS-ODN specifically inhibited responses to CpG DNA, whereas nonstimulatory phosphodiester ODN had no such effect. Although nonstimulatory PS-ODN caused some inhibition of ODN uptake, this did not adequately explain the levels of inhibition of activity. The results demonstrate that the phosphorothioate backbone has both enhancing and inhibitory effects on macrophage responses to CpG DNA.

Bacterial DNA methylation and gene transfer efficiency

The necessary amplification step in bacteria of any plasmid currently used in DNA immunization or gene therapy introduces modification in the nucleotide sequence of plasmid DNA used in gene transfer. These changes affect the adenine and the internal cytosine in respectively all of the GATC and CC(A/T)GG sequences. These modifications which introduce 6-methyladenine and 5-methylcytosine in plasmidic DNA are the consequence of the existence of the bacterial modification systems Dam and Dcm. In eucaryotes, the presence of 5-methylcytosine at dinucleotides -CG- is involved in silencing gene expression, but the possible consequences of the presence of the bacterial G(m)ATC and C(m)C(A/T)GG sequences in the plasmids used in gene transfer experiments are presently unknown. Since the possibility exists to obtain plasmid DNA lacking this specific bacterial pattern of methylation by using (dam(-), dcm(-)) bacteria we performed experiments to compare in vitro and in vivo gene transfer efficiency of a pCMV-luc reporter plasmid amplified either in the JM109 (dam(+), dcm(+)) or JM110 (dam(-), dcm(-)) bacteria. Data obtained demonstrated that the presence of 6-methyladenine in GATC sequences and 5-methylcytosine in the second C of CC(A/T)GG motifs does not reduce the levels of luciferase activity detected following in vitro or in vivo gene transfer. On the contrary, gene transfer with a pCMV-luc amplified in JM109 (dam(+), dcm(+)) bacteria gives greater amounts of luciferase than the same transfection performed with a plasmid amplified in the mutated JM110 (dam(-), dcm(-)) counterpart. Therefore, these data do not suggest that the use of (dam(-), dcm(-)) bacteria to amplify plasmid DNA may increase gene transfer efficiency. However, the persistence of the use of (dam(+), dcm(+)) bacteria in order to amplify plasmid DNA raises the question of the possible biological consequences of the introduction of the bacterial G(m)ATC and C(m)C(A/T)GG sequences in eukaryotic cells or organisms.

Characterization of T cell receptor (TCR) of organ-specific autoimmune disease-inducing T cells and TCR-based immunotherapy with DNA vaccines

Organ-specific autoimmune diseases and their animal models are characterized by the finding that the development of the diseases is closely associated with, or induced by, T cells reactive to organ-specific antigens. Therefore, the identification of T cell receptors (TCR) used by disease-inducing T cells within a short period of time is a key factor for designing TCR-based immunotherapy. The findings introduced in this article show that TCR associated with the development of multiple sclerosis and experimental autoimmune diseases including encephalomyelitis (EAE), neuritis (EAN) and carditis (EAC) are identifiable by complementarity-determining region 3 (CDR3) spectratyping analysis and subsequent sequencing of the CDR3 region of spectratype-derived TCR clones. It is also demonstrated that immunotherapy targeting disease-associated TCR using monoclonal antibodies and DNA vaccines significantly reduced the histological severity, and completely suppressed the inflammation in some animals. Since depletion or suppression of one of several types of effector cells does not significantly improve the severity of the disease, combined TCR-based immunotherapy should be considered as a primary therapy for T cell-mediated autoimmune diseases. TCR-based immunotherapy after rapid identification of autoimmune disease-associated TCR by CDR3 spectratyping can be applicable, not only to animal, but also to human autoimmune diseases whose pathomechanism is poorly understood.

Response of human monocyte-derived dendritic cells to immunostimulatory DNA

Activated dendritic cells (DC) are of key importance for the initiation of primary immune responses and represent promising tools for immunotherapies in humans. Since DNA containing CpG motifs have been described as potent immunostimulatory (IS) adjuvants for murine DC, we here studied maturation and stimulation of functional activity in human monocyte-derived DC (MODC) in response to several immunostimulatory oligodeoxynucleotides (IS-ODN) and plasmid DNA (IS-PL). We show that exposure of MODC to IS-PL, but not IS-ODN, induced a dose-dependent strong up-regulation of HLA class II and co-stimulatory molecules (CD80, CD86), similar to that observed after treatment with TNF-alpha. Functional activity was assessed by the detection of increased secretions of IL-6 and IL-12(p75) following treatment with IS-PL. In addition, IS-PL-stimulated MODC acquired a high T cell-stimulatory capacity. T cells stimulated by tetanus toxoid-pulsed, IS-PL-matured MODC were significantly more frequently IFN-gamma positive (25.2+/-2.7%) as compared to TNF-alpha-treated MODC (15.4+/-1.4%), indicating a strong activation of Th1 lymphocytes. In conclusion, we demonstrate that human MODC are activated by IS-PL but not IS-ODN previously used as adjuvants in animal models. The Th1-like immune response observed after stimulation with IS-PL-treated DC suggests that preincubation of human MODC with IS-PL or coimmunization with IS-PL may represent an useful approach to generate strongly activated human MODC for several therapeutic applications such as DC-based tumor immunotherapy.

CpG DNA as a Th1-promoting adjuvant in immunization against Trypanosoma cruzi

Th1-type immune response plays a critical role in resistance to Trypanosoma cruzi infection. We asked whether a synthetic oligodeoxynucleotide that contains immunostimulatory CpG motifs (CpG ODN), known to promote a Th1 response, could act as an adjuvant in immunization with parasite antigens. Mice immunized with a whole homogenate (WH) of T. cruzi antigens co-administered with CpG ODN presented high titers of T. cruzi antibodies (IgG2a isotype), strong delayed type hypersensitivity and a Th1-dominated (IFN-gamma and IL-12) cytokine profile. Furthermore, WH plus CpG ODN protected mice from challenge with an otherwise lethal dose of bloodstream trypomastigotes. As reported for leishmaniasis and malaria, CpG ODN holds considerable promise as an adjuvant for future vaccines against T. cruzi.

The combination of apoptotic U937 cells and lupus IgG is a potent IFN-alpha inducer

Patients with active systemic lupus erythematosus (SLE) have signs of an ongoing IFN-alpha production, that may be of pathogenic significance in the disease. We previously showed that SLE patients have an IFN-alpha-inducing factor in blood, probably consisting of complexes containing anti-DNA Abs and immunostimulatory DNA. The DNA component could be derived from apoptotic cells, because SLE patients have been reported to have both increased apoptosis and reduced clearance of apoptotic cell material. In the present study, we therefore investigated whether apoptotic cells, together with IgG from SLE patients, could act as an IFN-alpha inducer in normal PBMC in vitro. We found that apoptotic cells of the myeloid leukemia cell line U937 as well as four other cell lines (MonoMac6, H9, Jurkat, U266) could induce IFN-alpha production in PBMC when combined with IgG from SLE patients. The IFN-alpha production by PBMC was much enhanced when PBMC were costimulated by IFN-alpha2b. The ability of IgG from different SLE patients to promote IFN-alpha induction by apoptotic U937 cells was associated with the presence of anti-ribonucleoprotein Abs, but not clearly with occurrence of anti-DNA Abs. These results suggest that apoptotic cells in the presence of autoantibodies can cause production of a clearly immunostimulatory cytokine, which is IFN-alpha. This mechanism for induction of IFN-alpha production could well be operative also in vivo, explain the IFN-alpha production seen in SLE patients, and be important in the pathogenesis of SLE.

Distribution of DNA vaccines determines their immunogenicity after intramuscular injection in mice

Intramuscular injection of DNA vaccines elicits potent humoral and cellular immune responses in mice. However, DNA vaccines are less efficient in larger animal models and humans. To gain a better understanding of the factors limiting the efficacy of DNA vaccines, we used fluorescence-labeled plasmid DNA in mice to 1) define the macroscopic and microscopic distribution of DNA after injection into the tibialis anterior muscle, 2) characterize cellular uptake and expression of DNA in muscle and draining lymph nodes, and 3) determine the effect of modifying DNA distribution and cellular uptake by volume changes or electroporation on the magnitude of the immune response. Injection of a standard 50-microl dose resulted in the rapid dispersion of labeled DNA throughout the muscle. DNA was internalized within 5 min by muscle cells near the injection site and over several hours by cells that were located along muscle fibers and in the draining lymph nodes. Histochemical staining and analysis of mRNA expression in isolated cells by RT-PCR showed that the transgene was detectably expressed only by muscle cells, despite substantial DNA uptake by non-muscle cells. Reduction of the injection volume to 5 microl resulted in substantially less uptake and expression of DNA by muscle cells, and correspondingly lower immune responses against the transgene product. However, expression and immunogenicity were restored when the 5-microl injection was followed by electroporation in vivo. These findings indicate that distribution and cellular uptake significantly affect the immunogenicity of DNA vaccines.

Antipeptide antibody responses following intranasal immunization: effectiveness of mucosal adjuvants

Toxicity is a major factor limiting the development and use of potent adjuvants for human mucosally delivered vaccines. Novel adjuvant formulations have recently become available, and in the present study two have been used for intranasal immunization with a synthetic peptide immunogen (MAP-M2). This peptide represents a multiple antigenic peptide containing multiple copies of a mimotope M2, a peptide mimic of a conformational epitope of the fusion protein of measles virus. MAP-M2 was administered intranasally to experimental animals together with synthetic oligodeoxynucleotides containing unmethylated CpG motifs with or without a mutant of wild-type enterotoxin of Escherichia coli (LTR72). The combination of the mutant toxin LTR72 and the CpG repeats, codelivered with a peptide immunogen, induced both local and systemic peptide- and pathogen-specific humoral and cellular immune responses comparable to those obtained after intranasal immunization with the wild-type toxin LT. In addition, this combination of adjuvants induced a predominantly immunoglobulin G2a antibody response. If both the LTR72 and CpG adjuvants are shown to be safe for use in humans, this particular combination would appear to have potential as an adjuvant for mucosally delivered vaccines in humans.

Preventive and therapeutic vaccines for human papillomavirus-associated cervical cancers

'High risk' genotypes of the human papillomavirus (HPV), particularly HPV type 16, are the primary etiologic agent of cervical cancer. Thus, HPV-associated cervical malignancies might be prevented or treated by induction of the appropriate virus-specific immune responses in patients. Sexual transmission of HPV may be prevented by the generation of neutralizing antibodies that are specific for the virus capsid. In ongoing clinical trials, HPV virus-like particles (VLPs) show great promise as prophylactic HPV vaccines. Since the capsid proteins are not expressed at detectable levels by basal keratinocytes, therapeutic vaccines generally target other nonstructural viral antigens. Two HPV oncogenic proteins, E6 and E7, are important in the induction and maintenance of cellular transformation and are coexpressed in the majority of HPV-containing carcinomas. Therefore, therapeutic vaccines targeting these proteins may provide an opportunity to control HPV-associated malignancies. Various candidate therapeutic HPV vaccines are currently being tested whereby E6 and/or E7 are administered in live vectors, in peptides or protein, in nucleic acid form, as components of chimeric VLPs, or in cell-based vaccines. Encouraging results from experimental vaccination systems in animal models have led to several prophylactic and therapeutic vaccine clinical trials. Should they fulfill their promise, these vaccines may prevent HPV infection or control its potentially life-threatening consequences in humans.

Theory and in vivo application of electroporative gene delivery

Efficient and safe methods for delivering exogenous genetic material into tissues must be developed before the clinical potential of gene therapy will be realized. Recently, in vivo electroporation has emerged as a leading technology for developing nonviral gene therapies and nucleic acid vaccines (NAV). Electroporation (EP) involves the application of pulsed electric fields to cells to enhance cell permeability, resulting in exogenous polynucleotide transit across the cytoplasmic membrane. Similar pulsed electrical field treatments are employed in a wide range of biotechnological processes including in vitro EP, hybridoma production, development of transgenic animals, and clinical electrochemotherapy. Electroporative gene delivery studies benefit from well-developed literature that may be used to guide experimental design and interpretation. Both theory and experimental analysis predict that the critical parameters governing EP efficacy include cell size and field strength, duration, frequency, and total number of applied pulses. These parameters must be optimized for each tissue in order to maximize gene delivery while minimizing irreversible cell damage. By providing an overview of the theory and practice of electroporative gene transfer, this review intends to aid researchers that wish to employ the method for preclinical and translational gene therapy, NAV, and functional genomic research.

Anti-tumor immunity against CT26 colon tumor in mice immunized with plasmid DNA encoding beta-galactosidase fused to an envelope protein of endogenous retrovirus

Endogenous retroviral gene products have been recognized as being expressed in human cancerous tissues. However, these products have not been shown to be antigenic targets for T-cells, possibly due to immune tolerance. Since carcinogen-induced colon tumor CT26 expresses an envelope protein, gp70, of an endogenous ecotropic murine leukemia virus that is comparable to human tumor-associated antigens, we examined whether a DNA vaccine containing the gp70 gene induces protective immunity against CT26 cells. Injection of mice with plasmid DNA (pDNA) encoding gp70 alone failed to induce anti-gp70 antibody (Ab) or anti-CT26 cytotoxic T lymphocyte (CTL) responses. However, immunization with pDNA encoding the beta-galactosidase (beta-gal)/gp70 fusion protein induced anti-gp70 Ab and anti-CT26 CTL responses and conferred protective immunity against CT26 cells. These results indicate that beta-gal acts as an immunogenic carrier protein that helps in the induction of immune responses against the poorly immunogenic gp70. Considering these results, it is possible that potential tolerance to the endogenous retroviral gene products expressed by human tumors may be overcome by DNA vaccines that contain an endogenous retroviral gene fused to genes encoding immunogenic carrier proteins.

Adjuvant activities of immune response modifier R-848: comparison with CpG ODN

R-848 and imiquimod belong to a class of immune response modifiers that are potent inducers of cytokines, including IFN-alpha, TNF-alpha, IL-12, and IFN-gamma. Many of these cytokines can affect the acquired immune response. This study examines the effects of R-848 on aspects of acquired immunity, including immunoglobulin secretion, in vivo cytokine production, and Ag-specific T cell cytokine production. Results are compared with those of Th1 CpG ODN. R-848 and CpG ODN are effective at skewing immunity in the presence of Alum toward a Th1 Ab response (IgG2a) and away from a Th2 Ab response (IgE). R-848 and CpG ODN are also capable of initiating an immune response in the absence of additional adjuvant by specifically enhancing IgG2a levels. Both R-848 and imiquimod showed activity when given subcutaneously or orally, indicating that the compound mechanism was not through generation of a depot effect. Although CpG ODN behaves similarly to R-848, CpG ODN has a distinct cytokine profile, is more effective than R-848 when given with Alum in the priming dose, and is active only when given by the same route as the Ag. The mechanism of R-848's adjuvant activity is linked to cytokine production, where increases in IgG2a levels are associated with IFN-alpha, TNF-alpha, IL-12, and IFN-gamma induction, and decreases in IgE levels are associated with IFN-alpha and TNF-alpha. Imiquimod also enhances IgG2a production when given with Ag. The above results suggest that the imidazoquinolines R-848 and imiquimod may be attractive compounds for use as vaccine adjuvants and in inhibiting pathological responses mediated by Th2 cytokines.

CpG-DNA-mediated transient lymphadenopathy is associated with a state of Th1 predisposition to antigen-driven responses

Infections can influence concurrent and subsequent Th1 vs Th2 immune responses to Ags. Through pattern recognition of foreign unmethylated CpG dinucleotides, the vertebrate innate immune system can sense infectious danger and typically replies with a Th1-polarized adaptive immune response. We examined whether CpG-DNA exposure would influence subsequent responses to infection and soluble Ags. CpG-DNA injection led to local lymphadenopathy characterized by maintenance of cellular composition with some biasing toward elevated dendritic cell composition. Sustained local production of IL-12 and IFN-gamma from dendritic cells and T cells was shown. Prior injection by up to 2 wk with CpG-DNA protected BALB/c mice from Th2 driven lethal leishmaniasis. CpG-DNA injection by up to 5 wk before soluble Ag challenge resulted in the generation of Ag-specific CTL, Th1 recall responses to Ag, and Th1-polarized Ag-specific Abs. Thus, CpG-DNA instigated a local predisposition for intense CTL responses and Th1-polarized immune responses to subsequent infections or Ag challenge. The induction by the innate immune system of a locally contained hypersensitivity could represent a capacitating immune reaction yielding rapid conditioned responses to secondary infections.

A plasmid construct encoding murine interferon beta antagonizes the replication of herpes simplex virus type I in vitro and in vivo

In the present study, we employed a plasmid DNA encoding murine interferon (IFN)-beta to assess its antiviral efficacy in an in vitro transfection-infection assay and in an ocular HSV-1 infection model of mice. In the in vitro assay, transfection of mouse fibroblasts with the IFN-beta transgene resulted in a 17-fold or greater reduction in the viral load of HSV-1 at a multiplicity of infection (MOI) of 1 compared to that of those mice treated with the plasmid control. RT-PCR analysis of representative immediate early (ICP27), early (thymidine kinase, TK) and late (VP16) viral genes found no changes in the level of expression comparing the IFN-beta transgene- to the vector-treated control group, suggesting that the IFN-beta transgene may act at the post-transcriptional level of viral replication. In the ocular HSV-1 infection model, topical application of the plasmid DNA encoding murine IFN-beta onto mouse cornea enhanced cumulative survival and significantly reduced the viral load of HSV-1 in the eyes and trigeminal ganglia of mice at both day 3 and 6 post-infection compared with mice treated with the plasmid vector control or normal saline. Neutralizing antibody to IFN-beta blocked the protective effect elicited by the IFN-beta transgene. Unlike the in vitro experiment, viral gene expression was reduced in the trigeminal ganglion of mice pre-treated 24 h with the IFN-beta transgene day 3 (ICP27 and VP16) and day 6 (ICP27, TK, DNA polymerase, and VP16) post-infection in comparison to mice treated with the plasmid vector control as determined by semi-quantitative RT-PCR.

Potential applications of gene therapy in the patient with cancer

The elderly population has much to gain from the advances of molecular medicine, although at present genetic pharmacology remains mostly at the conceptual level. Cancer, in particular, is an increasing health burden and the majority (over 70%) of gene therapy trials are aimed at tackling this problem. Available strategies employ both viral and synthetic vectors with the selective delivery and expression of therapeutic genes a pivotal requirement. Clinical trials are now in progress with a view to modulating disease at many different levels, including the direct replacement of abnormal genes. suicide-gene formulations, and the delivery of 'gain of function' genes, which seek to alter the malignant phenotype by indirect means, such as, immunopotentiation and stromal reorganisation. Early data from these studies is tantalising and we must remain optimistic that gene therapy will benefit the patient with cancer by both reducing morbidity and extending life.

The function of type I interferons in antimicrobial immunity

Type I interferons (IFN-alpha and IFN-beta) were originally described as potent antiviral substances, which are produced upon infection of animal cells with viruses. Despite a large body of literature that has accumulated during the past 25 years, their regulatory function in the immune system is still much less appreciated. Recent studies have highlighted the production of type I IFNs, their function in the immune response to infectious agents and the target cells of these interferons. Type I IFNs clearly affect the release of proinflammatory cytokines or nitric oxide by dendritic cells and macrophages, the capacity of type II interferon (IFN-gamma) to activate phagocytes, the differentiation of T helper cells and the innate control of non-viral pathogens.

Intranasal vaccines: forthcoming challenges

The mucosal epithelium of the upper respiratory tract constitutes an effective physical barrier to many pathogens. Its mucosal-associated lymphoid tissue is of particular importance for the protection and integrity of mucosal surfaces and the body's interior. Understanding the factors that influence the induction and regulation of mucosal immune responses will facilitate the design of vaccines capable of eliciting the appropriate type of protective immune response.

DNA-based vaccination reduces the risk of lethal anaphylactic hypersensitivity in mice

BACKGROUND

Anaphylactic hypersensitivity is the most serious clinical concern facing allergists. However, for the majority of anaphylactic hypersensitivities, avoidance is the only therapeutic option presently available.

OBJECTIVE

This study evaluated the effectiveness of primary gene and protein-immunostimulatory DNA vaccination in the prevention of anaphylactic hypersensitivity in a murine model.

METHODS

Female C3H/HeJ mice were immunized with a plasmid encoding beta-galactosidase (beta-gal) or beta-gal protein plus an immunostimulatory sequence oligodeoxynucleotide. The mice were then T(H2) sensitized to beta-gal by coinjection with alum and pertussis and then intravenously challenged with this model allergen.

RESULTS

Primary gene and protein-immunostimulatory DNA vaccination of subsequently T(H2)-sensitized mice reduced the risk of death after anaphylactic challenge from 100% to 67% and 58%, respectively (P<.018 vs control mice). In addition, gene and protein-immunostimulatory DNA vaccination reduced postchallenge plasma histamine levels by greater than 4-fold (P <.05 vs control mice). Consistent with previous studies, these DNA-based vaccination strategies were further shown to blunt the development of T(H2)-biased immune responses after allergen sensitization. Vaccination with protein alone, the experimental equivalent of a traditional immunotherapy reagent, provided no protection from anaphylaxis nor did it prevent the development of a T(H2)-biased immune profile after allergen sensitization.

CONCLUSION

The present series of experiments demonstrate that both gene vaccination and coimmunization with protein and immunostimulatory DNA are effective in attenuating the development of anaphylactic hypersensitivity in subsequently T(H2) sensitized mice.

DNA vaccines: immunology, application, and optimization*

The development and widespread use of vaccines against infectious agents have been a great triumph of medical science. One reason for the success of currently available vaccines is that they are capable of inducing long-lived antibody responses, which are the principal agents of immune protection against most viruses and bacteria. Despite these successes, vaccination against intracellular organisms that require cell-mediated immunity, such as the agents of tuberculosis, malaria, leishmaniasis, and human immunodeficiency virus infection, are either not available or not uniformly effective. Owing to the substantial morbidity and mortality associated with these diseases worldwide, an understanding of the mechanisms involved in generating long-lived cellular immune responses has tremendous practical importance. For these reasons, a new form of vaccination, using DNA that contains the gene for the antigen of interest, is under intensive investigation, because it can engender both humoral and cellular immune responses. This review focuses on the mechanisms by which DNA vaccines elicit immune responses. In addition, a list of potential applications in a variety of preclinical models is provided.

Synthetic oligodeoxynucleotides inhibit IgE induction in human lymphocytes

Synthetic oligodeoxynucleotides (ODNs) containing unmethylated CpG motifs have the capacity to stimulate T-helper (Th)1-type responses in mice. Th1 cytokines are known to act as downregulators of IgE production. In this study we investigated whether synthetic ODNs inhibited IgE production in human peripheral blood mononuclear cells (PBMC) from normal donors stimulated with interleukin (IL)-4 plus anti-CD40 monoclonal antibody (mAb) in vitro. Thirty-mer single-stranded ODNs were randomly selected from the complementary DNA encoding the MPB-70 of Mycobacterium bovis Bacillus Calmette-Guerin. Two ODNs, containing CGTACG or AACGTT inhibited IgE production by human PBMC. When other oligonucleotides were substituted in a portion of the sequence of the core or flanking oligonucleotides in the ODN containing CGTACG, ODNs containing NACGTTCG or A/CTCGTTCG sequences specifically inhibited IgE production by human PBMC in vitro. The inhibition of IgE production by certain ODNs was mediated by both interferon (IFN)-gamma and IL-12, since the ODN-induced suppression was blocked by the addition of anti-IFN-gamma or anti-IL-12 mAb. Also, the ODNs inhibited induction of epsilon germline transcripts by IL-4. Our findings indicate that synthetic ODNs appear to be candidates for the treatment of IgE-dependent allergic disease in humans.

Conjugation of immunostimulatory DNA to the short ragweed allergen amb a 1 enhances its immunogenicity and reduces its allergenicity

BACKGROUND

Allergen immunotherapy is inconvenient and associated with the risk of anaphylaxis. Efforts to improve the safety of immunotherapy by means of chemical modification of allergens have not been successful because it greatly reduced their antigenicity. Recently, immunostimulatory DNA sequences (ISS or CpG motifs) have been shown to act as strong T(H)1 response-inducing adjuvants.

OBJECTIVE

We sought to determine whether conjugation of ISS to the major short ragweed allergen Amb a 1 results in enhanced immunotherapeutic potential in mice and decreased allergenicity in human subjects.

METHODS

A 22-mer ISS oligodeoxynucleotide (ISS-ODN) was coupled to Amb a 1 and used for immunization of mice, rabbits, and monkeys.

RESULTS

In mice the Amb a 1-ISS conjugate induced a T(H)1 response (IFN-gamma secretion), whereas Amb a 1 induced a T(H)2 response (IL-5 secretion). The T(H)1 response was not observed with an Amb a 1-non-ISS conjugate. Coinjection of Amb a 1 with ISS-ODN was much less effective in inducing a T(H)1 response. In mice primed for a T(H)2 response, injection with Amb a 1-ISS conjugate induced a de novo T(H)1 response and suppressed IgE antibody formation after challenge with Amb a 1. Amb a 1-ISS conjugate induced high-titer anti-Amb a 1 IgG antibodies in rabbits and cynomolgus monkeys, whereas Amb a 1 alone or Amb a 1 coinjected with ISS-ODN did not induce a detectable response. Amb a 1-ISS conjugate was less allergenic than Amb a 1 alone, as shown by a 30-fold lower histamine release from human basophils of patients with ragweed allergy, whereas mixing ISS-ODN with Amb a 1 did not reduce histamine release.

CONCLUSION

Amb a 1-ISS conjugate has an enhanced T(H)1-biased immunogenicity and reduced allergenicity. It may offer a more effective and safer approach for allergen immunotherapy than currently available methods.

Genetic immunotherapy for cancer

Genetic immunization refers to treatment strategies where gene transfer methods are used to generate immune responses against cancer. Our growing knowledge of the mechanisms regulating the initiation and maintenance of cytotoxic immune responses has provided the rationale for the design of several genetic immunization strategies. Tumor cells have been gene-modified to express immune stimulatory genes and are then administered as tumor vaccines, in an attempt to overcome tumor cell ignorance by the immune system. With the description of well-characterized tumor antigens, multiple strategies have been proposed mainly aimed at optimal tumor antigen presentation by antigen-presenting cells (APC). Among APC, the dendritic cells have been recognized as the most powerful cells in this class, and have become the target for introducing tumor antigen genes to initiate antitumor immune responses. The detailed knowledge of how the immune system can be activated to specifically recognize tumor antigens, and the mechanisms involved in the control of this immune response, provide the basis for modern genetic immunization strategies for cancer treatment.

DNA vaccine delivery by attenuated intracellular bacteria

Vaccination by intramuscular or intradermal injection of antigen-encoding DNA is a promising new approach leading to strong cellular and humoral immune responses. Since bone-marrow derived antigen presenting cells (APC) seem to induce these immune responses after migration to the spleen, it is desirable to deliver DNA vaccines directly to splenic APC. Recently, attenuated intracellular bacteria have been exploited for the introduction of DNA vaccine vectors into different cell types in vitro as well as in vivo and offer an attractive alternative to the direct inoculation of naked plasmid DNA.

An overview of cancer immunotherapy

The survival of patients with cancer has improved steadily but incrementally over the last century, with the advent of effective anticancer treatments such as chemotherapy and radiotherapy. However, the majority of patients with metastatic disease will not be cured by these measures and will eventually die of their disease. New and more effective methods of treating these patients are required urgently. The immune system is a potent force for rejecting transplanted organs or microbial pathogens, but effective spontaneous immunologically induced cancer remissions are very rare. In recent years, much has been discovered about the mechanisms by which the immune system recognizes and responds to cancers. The specific antigens involved have now been defined in many cases. Improved adjuvants are available. Means by which cancer cells overcome immunological attack can be exploited and overcome. Most importantly, the immunological control mechanisms responsible for initiating and maintaining an effective immune response are now much better understood. It is now possible to manipulate immunological effector cells or antigen-presenting cells ex vivo in order to induce an effective antitumour response. At the same time, it is possible to recruit other aspects of the immune system, both specific (e.g. antibody responses) and innate (natural killer cells and granulocytes).

CpG motifs induce Langerhans cell migration in vivo

Cytosine-guanosine (CpG) oligonucleotide (CpG-oligo) sequences are immunostimulatory motifs that are present in bacterial DNA and their presence in plasmids might contribute to the immune response generated by DNA vaccination. The cell targets of CpG motifs in vivo have not been characterized yet. In this report we assessed the in vivo effects of CpG motifs on Langerhans cells (LC) migration. We showed that intradermal injection of 10 microg of CpG-containing oligonucleotides in mouse ear induced the local depletion of LC within 2 h of exposure as shown by CD11c and Ia immunohistological staining. To demonstrate that LC depletion was due to LC migration, CpG oligonucleotides were injected into the explants ex vivo, and the CD11c(+) cells emigrating from the cultured isolated skin within medium were evaluated by immunostaining and FACS analysis. Our findings demonstrate that CpG motifs induce LC/dendritic cell (DC) migration out of the skin. To assess whether CpG motifs may act directly on LC/DC to induce their emigration we next analyzed the effects of CpG motifs in vitro on the expression of adhesion molecules involved in LC/DC migration. The results of these experiments show that alpha(6) integrins, E-Cadherin, ICAM-1, CD11b and CD11c were differentially regulated upon CpG-oligo treatment of immortalized DC. CpG treatment (10 microg/ml for 8 h) resulted in a 100% increase in ICAM-1 staining intensity, a 50% decrease in E-Cadherin staining and a 25% decrease in alpha(6) integrins staining, while no changes in the levels of CD11b and CD11c expression were recorded. Changes in adhesion molecule expression were mirrored by concomitant changes in the cell morphology that included cell depolarization, the appearance of filopods and loss of adherence. This study provides the first in vivo evidence that CpG motifs signal the migration of LC from the epidermis.

CpG oligodeoxynucleotides enhance monoclonal antibody therapy of a murine lymphoma

Bacterial DNA and synthetic oligodeoxynucleotides containing unmethylated cytosine-guanine dinucleotides known as cytosine phosphorothioate guanine oligodeoxynucleotides (CpG ODN) can activate various immune-cell subsets, including cells that participate in antibody-dependent cell-mediated cytotoxicity (ADCC). Studies have shown that CpG ODN enhance the efficacy of antitumor monoclonal antibody (MoAb) therapy in the 38C13 murine B-cell lymphoma. We performed a series of in vivo experiments using this tumor model to better characterize combination therapy with MoAb and CpG ODN. CpG ODN enhanced the efficacy of MoAb therapy of lymphoma in a dose-dependent manner. This effect was seen whether the CpG ODN was given before or after the MoAb therapy, but was decreased when CpG ODN was given more than 2 days after MoAb therapy. Three doses of CpG ODN and MoAb were more effective than single doses. There was no obvious toxicity with multiple dosing. These studies confirm that immunostimulatory CpG ODN enhance the efficacy of MoAb therapy, and that multiple courses of combination therapy with CpG ODN can serve as an effective therapy for lymphoma. Further exploration of this potentially potent combination of treatments, including clinical evaluation, is indicated.

CpG oligonucleotides are potent adjuvants for the activation of autoreactive encephalitogenic T cells in vivo

The mechanism of action of microbial adjuvants in promoting the differentiation of autoimmune effector cells remains to be elucidated. We demonstrate that CpG-containing oligodeoxynucleotides (ODN) can completely substitute for heat-killed mycobacteria in the priming of encephalitogenic myelin-reactive T cells in vivo. The adjuvanticity of the CpG ODN was secondary to their direct ability to induce IL-12 or to act synergistically with endogenous IL-12 to promote Th1 differentiation and encephalitogenicity. T cells primed in the absence of CpG with Ag and IFA alone appeared to be in a transitional state and had not undergone differentiation along a conventional Th pathway. Unlike Th2 cells, they expressed low levels of the IL-12R beta 2 subunit and retained the ability to differentiate into encephalitogenic effectors when reactivated in vitro under Th1-polarizing conditions. These results support the use of CpG ODN as adjuvants but also suggest that they could potentially trigger autoimmune disease in a susceptible individual.

Modular retro-vectors for transgenic and therapeutic use

Retroviruses have been used for many years as vectors for human gene therapy as well as for making transgenic animals. However, the efficient insertion of genes by retroviruses is often complicated by transcriptional inactivation of the retroviral long terminal repeats (LTRs) and by the production of replication-competent retroviruses (RCR). Solutions to these and other difficulties are being found in modular vectors, in which the desirable features of different vector systems are combined. Examples of synergistic vectors include virosomes (liposome/virus delivery), adeno-retro vectors, and MLV/VL30 chimeras. As gene delivery systems become increasingly complex, methodology is also needed for precise assembly of modular vectors. Gene self-assembly (GENSA) technology permits seamless vector construction and simultaneous, multifragment assembly.

Immunostimulatory DNA-based vaccines induce cytotoxic lymphocyte activity by a T-helper cell-independent mechanism

Immunostimulatory DNA sequences (ISS) contain unmethylated CpG dinucleotides within a defined motif. Immunization with ISS-based vaccines has been shown to induce high antigen-specific cytotoxic lymphocyte (CTL) activity and a Th1-biased immune response. We have developed a novel ISS-based vaccine composed of ovalbumin (OVA) chemically conjugated to ISS-oligodeoxynucleotide (ODN). Protein-ISS conjugate (PIC) is more potent in priming CTL activity and Th1-biased immunity than other ISS-based vaccines. Cytotoxic lymphocyte activation by ISS-ODN-based vaccines is preserved in both CD4-/- and MHC class II-/- gene-deficient animals. Furthermore, PIC provides protection against a lethal burden of OVA-expressing tumor cells in a CD8+ cell-dependent manner. These results demonstrate that PIC acts through two unique mechanisms: T-helper-independent activation of CTL and facilitation of exogenous antigen presentation on MHC class I. This technology may have clinical applications in cancer therapy and in stimulating host defense in AIDS and chronic immunosuppression.

DNA immunization with Onchocerca volvulus genes, Ov-tmy-1 and OvB20: serological and parasitological outcomes following intramuscular or GeneGun delivery in a mouse model of onchocerciasis

The objective of this study was to evaluate whether the distinct immune responses invoked by epidermal and intramuscular DNA immunization could be harnessed to improve upon the levels of protection to Onchocerca volvulus infective larvae achieved previously by recombinant protein immunization. Intramuscular (IM) and epidermal (GeneGun) routes of DNA immunization generally drive T helper1 and Th2 dominant responses, respectively. This dichotomy was used in an attempt to further define the nature of host-protective immunity in a mouse model of onchocerciasis. Mice were immunized with DNA plasmids expressing the O. volvulus antigens, Ov-TMY-1 (tropomyosin) and OvB20 (a nematode specific gene product). While, IM and GeneGun immunization of mice with Ov-tmy-1 induced expected Th1/Th2-associated IgG isotype profiles, mice responded to OvB20 immunization with a Th2 dominant response, irrespective of the delivery route. Despite inducing potent serological responses, neither DNA construct promoted statistically significant levels of protection to L3 challenge infection. We conclude that DNA immunization has good potential for induction of humoral responses against nematode infections and that serological responses alone do not predict vaccination efficacy under the conditions used here to measure host resistance to parasite challenge.

Macrophage activation by immunostimulatory DNA

Macrophage/dendritic cells and B cells remain the only cell types where direct responses to CpG DNA are well established. The role of macrophages in vivo in DNA clearance and the potent cytokine induction in macrophages and dendritic cells places them in the central role in the in vivo response to foreign DNA. Although responses to DNA are unlikely to evolve and be retained if they are not significant in the immune response to infection, the relative contributions of DNA and other stimulators of the innate immune recognition of foreign organisms is difficult to assess. Although CpG DNA and LPS have similar actions, significant differences are emerging that make the use of DNA as a therapeutic immunostimulatory molecule feasible. The macrophage response to DNA generates cytokines favouring the development of Th1-type immunity, and active oligonucleotides now show promise as Th1-promoting adjuvants and as allergy treatments.