Iacob Mathiesen

In Vivo Electroporation Enhances the Immunogenicity of Hepatitis C Virus Nonstructural 3/4A DNA by Increased Local DNA Uptake, Protein Expression, Inflammation, and Infiltration of CD3+ T Cells

The mechanisms by which in vivo electroporation (EP) improves the potency of i.m. DNA vaccination were characterized by using the hepatitis C virus nonstructural (NS) 3/4A gene. Following a standard i.m. injection of DNA with or without in vivo EP, plasmid levels peaked immediately at the site of injection and decreased by 4 logs the first week. In vivo EP did not promote plasmid persistence and, depending on the dose, the plasmid was cleared or almost cleared after 60 days. In vivo imaging and immunohistochemistry revealed that protein expression was restricted to the injection site despite the detection of significant levels of plasmid in adjacent muscle groups. In vivo EP increased and prolonged NS3/4A protein expression levels as well as an increased infiltration of CD3+ T cells at the injection site. These factors most likely additively contributed to the enhanced and broadened priming of NS3/4A-specific Abs, CD4+ T cells, CD8+ T cells, and γ-IFN production. The primed CD8+ responses were functional in vivo, resulting in elimination of hepatitis C virus NS3/4A-expressing liver cells in transiently transgenic mice. Collectively, the enhanced protein expression and inflammation at the injection site following in vivo EP contributed to the priming of in vivo functional immune responses. These localized effects most likely help to insure that the strength and duration of the responses are maintained when the vaccine is tested in larger animals, including rabbits and humans. Thus, the combined effects mediated by in vivo EP serves as a potent adjuvant for the NS3/4A-based DNA vaccine.

Electroporation as a “Prime/Boost” Strategy for Naked DNA Vaccination against a Tumor Antigen

We have developed novel DNA fusion vaccines encoding tumor Ags fused to pathogen-derived sequences. This strategy activates linked T cell help and, using fragment C of tetnus toxin, amplification of anti-tumor Ab, CD4+, and CD8+ T cell responses is achievable in mice. However, there is concern that simple DNA vaccine injection may produce inadequate responses in larger humans. To overcome this, we tested electroporation as a method to increase the transfection efficiency and immune responses by these tumor vaccines in vivo in mice. Using a DNA vaccine expressing the CTL epitope AH1 from colon carcinoma CT26, we confirmed that effective priming and tumor protection in mice are highly dependent on vaccine dose and volume. However, suboptimal vaccination was rendered effective by electroporation, priming higher levels of AH1-specific CD8+ T cells able to protect mice from tumor growth. Electroporation during priming with our optimal vaccination protocol did not improve CD8+ T cell responses. In contrast, electroporation during boosting strikingly improved vaccine performance. The prime/boost strategy was also effective if electroporation was used at both priming and boosting. For Ab induction, DNA vaccination is generally less effective than protein. However, prime/boost with naked DNA followed by electroporation dramatically increased Ab levels. Thus, the priming qualities of DNA fusion vaccines, integrated with the improved Ag expression offered by electroporation, can be combined in a novel homologous prime/boost approach, to generate superior antitumor immune responses. Therefore, boosting may not require viral vectors, but simply a physical change in delivery, facilitating application to the cancer clinic.

Recruitment of Antigen-Presenting Cells to the Site of Inoculation and Augmentation of Human Immunodeficiency Virus Type 1 DNA Vaccine Immunogenicity by In Vivo Electroporation

ABSTRACT In vivo electroporation (EP) has been shown to augment the immunogenicity of plasmid DNA vaccines, but its mechanism of action has not been fully characterized. In this study, we show that in vivo EP augmented cellular and humoral immune responses to a human immunodeficiency virus type 1 Env DNA vaccine in mice and allowed a 10-fold reduction in vaccine dose. This enhancement was durable for over 6 months, and re-exposure to antigen resulted in anamnestic effector and central memory CD8+ T-lymphocyte responses. Interestingly, in vivo EP also recruited large mixed cellular inflammatory infiltrates to the site of inoculation. These infiltrates contained 45-fold-increased numbers of macrophages and 77-fold-increased numbers of dendritic cells as well as 2- to 6-fold-increased numbers of B and T lymphocytes compared to infiltrates following DNA vaccination alone. These data suggest that recruiting inflammatory cells, including antigen-presenting cells (APCs), to the site of antigen production substantially improves the immunogenicity of DNA vaccines. Combining in vivo EP with plasmid chemokine adjuvants that similarly recruited APCs to the injection site, however, did not result in synergy.

Improved cellular and humoral immune responses against Mycobacterium tuberculosis antigens after intramuscular DNA immunisation combined with muscle electroporation

New delivery methods are needed to improve the efficiency of existing DNA vaccines. We have measured the immune response to Mycobacterium tuberculosis antigens following intramuscular DNA injection in combination with or without electroporation. Three to 6-fold increase in the number of antigen specific CD4(+) and CD8(+) T cells, measured by IFN-gamma-producing cells in an ELISPOT assay, was found in mice DNA injected and electroporated compared with non-electroporated mice. Similarly, 5 to 10-fold increase in antigen specific IgG1, IgG2a and IgG2b antibodies were found in an immunoglobulin subclass specific ELISA. A 100-fold reduction in DNA dose could be used without loss of efficiency when immunisation was combined with electroporation. A single injection of 1 microg of antigen 85b (ag85b) plasmid DNA was sufficient to elicit a higher and long lasting level of IgG2a antibodies against antigen 85B (Ag85B) compared to standard BCG vaccination. We conclude that DNA immunisation in combination with electroporation can significantly improve the immunogenicity of plasmid-based DNA vaccines.

Gene expression and immune response kinetics using electroporation-mediated DNA delivery to muscle

Injection of DNA encoding exogenic proteins into muscle tissue combined with electroporation often results in a transient increase of the encoded protein concentration in the muscle and the blood. The reduction is normally due to an immune response against the exogenic protein but other factors may also be involved. How various electroporation parameters affect the concentration kinetics of syngenic and exogenic proteins is studied in relation to immune response and muscle damage after electroporation‐mediated DNA transfer to muscle.

γ-AChR/ϵ-AChR Switch at Agrin-Induced Postsynaptic-like Apparatus in Skeletal Muscle

Abstract We transfected the extrajunctional region of denervated soleus muscles in adult rats with neural agrin cDNA to induce myofibers to form postsynaptic-like apparatus containing acetylcholine receptor (AChR) aggregates. By 1 week ≈30% of the AChR aggregates contained a mixture of ϵ-AChRs and γ-AChRs while ≈70% had only γ-AChRs. If the transfected muscles were reinnervated in the original junctional region, the postsynaptic-like apparatus, despite the absence of apposed axon terminals, gradually came to have only ϵ-AChRs. We conclude that at the postsynaptic apparatus of ectopic neuromuscular junctions formed by a foreign nerve implanted into the extrajunctional region of denervated muscles, agrin secreted by the axon terminal plays a direct role in the γ-AChR/ϵ-AChR switch that occurs as the apparatus reaches maturity. Our findings, together with results from other studies, indicate further that agrin and acetylcholine are the only nerve-derived factors required for this switch.

Therapeutic DNA Vaccination Using In Vivo Electroporation Followed by Standard of Care Therapy in Patients With Genotype 1 Chronic Hepatitis C

Clearance of infections caused by the hepatitis C virus (HCV) correlates with HCV-specific T cell function. We therefore evaluated therapeutic vaccination in 12 patients with chronic HCV infection. Eight patients also underwent a subsequent standard-of-care (SOC) therapy with pegylated interferon (IFN) and ribavirin. The phase I/IIa clinical trial was performed in treatment naive HCV genotype 1 patients, receiving four monthly vaccinations in the deltoid muscles with 167, 500, or 1,500 μg codon-optimized HCV nonstructural (NS) 3/4A-expressing DNA vaccine delivered by in vivo electroporation (EP). Enrollment was done with 2 weeks interval between patients for safety reasons. Treatment was safe and well tolerated. The vaccinations significantly improved IFN-γ–producing responses to HCV NS3 during the first 6 weeks of therapy. Five patients experienced 2–10 weeks 0.6–2.4 log10 reduction in serum HCV RNA. Six out of eight patients starting SOC therapy within 1–30 months after the last vaccine dose were cured. This first-in-man therapeutic HCV DNA vaccine study with the vaccine delivered by in vivo EP shows transient effects in patients with chronic HCV genotype 1 infection. The interesting result noted after SOC therapy suggests that therapeutic vaccination can be explored in a combination with SOC treatment.

Early events of electroporation-mediated intramuscular DNA vaccination potentiate Th1-directed immune responses.

Application of electrical pulses after DNA injection into muscle increases expression of the encoded genes, and is shown to improve antigen‐specific immune responses when used for DNA vaccination. In addition, electroporation causes tissue injury and inflammatory reactions. Together with immune stimulatory motifs in the injected DNA these factors may potentiate the immune response by acting as adjuvants for the antigen. Here, we have examined the role of these factors in promoting the efficiency of DNA vaccination.

DNA transfection of mononuclear cells in muscle tissue

Genes encoding non‐self proteins may be injected into skeletal muscles in vivo to obtain induction of cellular and humoral immune responses against the encoded antigens (DNA vaccination). Bone marrow derived professional antigen‐presenting cells (APCs) play a key role in the induction of immunity by DNA vaccination. In the present work we have investigated whether the APCs are transfected by DNA injection into muscle.

Taking Electroporation-Based Delivery of DNA Vaccination into Humans: A Generic Clinical Protocol

We are presently aware of two early-phase DNA vaccine clinical trials in humans using electroporation-enhanced vaccine delivery. Moreover, two phase I immunogenetherapy studies are in progress and several tolerability studies have been performed on healthy volunteers. We have used knowledge from these studies to compose a template for clinical protocols involving electroporation-mediated gene delivery. In this template the emphasis will be on aspects related to electroporation. In addition, we will discuss general topics concerning electroporation-augmented DNA vaccination in human subjects.