Paul Chaplin

Mouse CD8α+ DCs and human BDCA3+ DCs are major producers of IFN-λ in response to poly IC

In humans and mice, CD8α+ conventional dendritic cells are the primary source of interferon-λ released in response to the adjuvant and Toll-like receptor 3 agonist poly IC.

Modified Vaccinia Virus Ankara Protects Macaques against Respiratory Challenge with Monkeypox Virus

ABSTRACT The use of classical smallpox vaccines based on vaccinia virus (VV) is associated with severe complications in both naïve and immune individuals. Modified vaccinia virus Ankara (MVA), a highly attenuated replication-deficient strain of VV, has been proven to be safe in humans and immunocompromised animals, and its efficacy against smallpox is currently being addressed. Here we directly compare the efficacies of MVA alone and in combination with classical VV-based vaccines in a cynomolgus macaque monkeypox model. The MVA-based smallpox vaccine protected macaques against a lethal respiratory challenge with monkeypox virus and is therefore an important candidate for the protection of humans against smallpox.

Survival of lethal poxvirus infection in mice depends on TLR9, and therapeutic vaccination provides protection

Poxviruses such as the causative agent of smallpox have developed multiple strategies to suppress immune responses, including the suppression of DC activation. Since poxviruses are large DNA viruses, we hypothesized that their detection by DCs may involve the endosomal DNA recognition receptor TLR9. Indeed, we have shown here that DC recognition of ectromelia virus (ECTV), the causative agent of mousepox, completely depended on TLR9. The importance of TLR9 was highlighted by the fact that mice lacking TLR9 showed drastically increased susceptibility to infection with ECTV. In contrast, we found that the strongly attenuated poxvirus modified vaccinia virus Ankara (MVA) activated DCs by both TLR9-dependent and -independent pathways. We therefore tested whether we could use the broader induction of immune responses by MVA to protect mice from a lethal infection with ECTV. Indeed, MVA given at the same time as a lethal dose of ECTV protected mice from death. Importantly, MVA also rescued TLR9-deficient mice if administered 2 full days after an otherwise lethal infection with ECTV. Therefore, these data suggest an essential role for TLR9 in the defense against poxviruses. In addition, postexposure application of MVA may protect against lethal poxvirus infection.

Boosting T Cell-Mediated Immunity to Tyrosinase by Vaccinia Virus-Transduced, CD34+-Derived Dendritic Cell Vaccination: A Phase I Trial in Metastatic Melanoma

Purpose: Six American Joint Committee on Cancer stage IV melanoma patients were enrolled into a Phase I study of vaccination with autologous CD34+-derived dendritic cells transduced with a modified vaccinia Ankara virus encoding human tyrosinase gene (MVA-hTyr). Experimental Design: Patients received a first intravenous injection of 1 × 108 MVA-hTyr–transduced dendritic cells, followed by three s.c. injections at a 14-day interval. Results: Treatment was well tolerated, except for low-grade fever (three of six patients), mild erythema at injection site (five of six), and vitiligo (two of six). A partial response, involving shrinkage of an s.c. nodule, later surgically removed, was observed in 1 patient, who then remained disease-free (>850 days). By human lymphocyte antigen tetramer analysis, significant and often long-lasting increases in frequency of T cells directed to tyrosinase368–376 but not to gp100209–217 were documented in periphery of 4 of 5 HLA-A*0201+ patients, a few days after vaccine administration. In addition, maturation phenotype of tyrosinase-specific T cell shifted toward the T effector memory/T terminally differentiate stages (CCR7−CD45RA−/+) in synchrony with the T-cell frequency peaks. By enzyme-linked immunospot in peripheral blood of five HLA-A*0201+ patients, we found that the vaccine could induce interferon γ-releasing effector cells directed to HLA-A*0201/tyrosinase368–376 and to vaccinia virus HLA-A*0201/H3L184–192 epitopes. Moreover, an interferon γ response after vaccination was elicited even against the HLA-DRB1–1501/tyrosinase386–406 epitope in one out of two HLA-A* DRB1–01501+ patients. Conclusions: These results indicate that vaccination with MVA-hTyr–transduced dendritic cells is well tolerated, can possibly produce clinical responses, and activates tyrosinase- and vaccinia virus-specific T cells in vivo. These data suggest a broad utility of the MVA vector for targeting tumor-associated antigens to dendritic cells for tumor immunotherapy.

A randomized, double-blind, dose-finding Phase II study to evaluate immunogenicity and safety of the third generation smallpox vaccine candidate IMVAMUNE®

IMVAMUNE is a Modified Vaccinia Ankara (MVA)-based virus that is being developed as a safer 3rd generation smallpox vaccine. In order to determine the optimal dose for further development, a double-blind, randomized Phase II trial was performed testing three different doses of IMVAMUNE in 164 healthy volunteers. All three IMVAMUNE doses displayed a favourable safety profile, with local reactions as the most frequent observation. The 1 x 10(8)TCID(50) IMVAMUNE dose induced a total antibody response in 94% of the subjects following the first vaccination and the highest peak seroconversion rates by ELISA (100%) and PRNT (71%). This IMVAMUNE dose was considered to be optimal for the further clinical development of this highly attenuated poxvirus as a safer smallpox vaccine.

A phase I vaccination study with tyrosinase in patients with stage II melanoma using recombinant modified vaccinia virus Ankara (MVA-hTyr)

A significant percentage of patients with stage II melanomas suffer a relapse after surgery and therefore need the development of adjuvant therapies. In the study reported here, safety and immunological response were analyzed after vaccination in an adjuvant setting with recombinant modified vaccinia virus Ankara carrying the cDNA for human tyrosinase (MVA-hTyr). A total of 20 patients were included and vaccinated three times at 4-week intervals with 5×108 IU of MVA-hTyr each time. The responses to the viral vector, to known HLA class I–restricted tyrosinase peptides, and to dendritic cells transfected with tyrosinase mRNA, were investigated by ELISpot assay on both ex vivo T cells and on T cells stimulated in vitro prior to testing. The delivery of MVA-hTyr was safe and did not cause any side effects above grade 2. A strong response to the viral vector was achieved, indicated by an increase in the frequency of MVA-specific CD4+ and CD8+ T cells and an increase in virus-specific antibody titers. However, no tyrosinase-specific T-cell or antibody response was observed with MVA-hTyr in any of the vaccinated patients. Although MVA-hTyr provides a safe and effective antigen-delivery system, it does not elicit a measurable immune response to its transgene product in patients with stage II melanoma after repeated combined intradermal and subcutaneous vaccination. We presume that modification of the antigen and/or prime-boost vaccination applying different approaches to antigen delivery may be required to induce an effective tyrosinase-specific immune response.

Coexpression of Interleukin-12 Chains by a Self-Splicing Vector Increases the Protective Cellular Immune Response of DNA and Mycobacterium bovis BCG Vaccines against Mycobacterium tuberculosis

ABSTRACT More effective vaccines against Mycobacterium tuberculosis may contribute to the control of this major human pathogen. DNA vaccines encoding single mycobacterial proteins stimulate antimycobacterial T-cell responses and induce partial protection against M. tuberculosis in animal models. The protective efficacy of these vaccines encoding a single antigen, however, has been less than that afforded by the current vaccine, Mycobacterium bovis bacillus Calmette-Guérin (BCG). The heterodimeric cytokine interleukin-12 (IL-12) potentiates the induction and maintenance of the type 1 helper T-cell response. We have developed a novel self-splicing vector based on the 2A protein of foot-and-mouth disease virus that permits the coordinate expression of both chains of IL-12 (p2AIL12). Coimmunization with this vector and DNA expressing M. tuberculosis antigen 85B or MPT64 enhanced the specific lymphocyte proliferative response and increased the frequency of specific gamma interferon-secreting T cells against the whole protein and a defined CD8+ T-cell epitope on MPT64. Further, coimmunizing with p2AIL12 significantly increased the protective efficacy of DNA-85 in the lung against an aerosol challenge with M. tuberculosis to the level achieved with BCG. Therefore, codelivery of an IL-12-secreting plasmid may be a potent strategy for enhancing the protective efficacy of vaccines against M. tuberculosis.

A Multicenter, Open-Label, Controlled Phase II Study to Evaluate Safety and Immunogenicity of MVA Smallpox Vaccine (IMVAMUNE) in 18-40 Year Old Subjects with Diagnosed Atopic Dermatitis

Background Replicating smallpox vaccines can cause severe complications in individuals with atopic dermatitis (AD). Prior studies evaluating Modified Vaccinia Ankara virus (MVA), a non-replicating vaccine in humans, showed a favorable safety and immunogenicity profile in healthy volunteers. Objective This Phase II study compared the safety and immunogenicity of MVA enrolling groups of 350 subjects with AD (SCORAD ≤ 30) and 282 healthy subjects. Methods Subjects were vaccinated twice with MVA, each dose given subcutaneously 4 weeks apart. Adverse events, cardiac parameters, and the development of vaccinia virus humoral immune responses were monitored. Results The overall safety of the vaccine was similar in both groups. Adverse events affecting skin were experienced significantly more often in subjects with AD, but the majority of these events were mild to moderate in intensity. Seroconversion rates and geometric mean titers for total and neutralizing vaccinia-specific antibodies in the AD group were non-inferior compared to the healthy subjects. Limitations The size of the study population limited the detection of serious adverse events occurring at a frequency less than 1%. Conclusion MVA has a favorable safety profile and the ability to elicit vaccinia-specific immune responses in subjects with AD. Trial Registration ClinicalTrials.gov NCT00316602

Production of interleukin-12 as a self-processing 2A polypeptide.

Interleukin-12 (IL-12) is a heterodimeric cytokine composed of two disulfide-linked subunits (p40 and p35) encoded by separate genes. We used the apparent autocleavage property of a 2A peptide from the foot-and-mouth disease virus (FMDV) to express bovine (Bo) IL-12 as a self-processing polypeptide (p402Ap35). We demonstrate that 2A will mediate the cleavage of p402Ap35 into two separate subunits in a manner similar to that observed during the processing of the FMDV polypeptide. Furthermore, this 2A polypeptide encoded a functional heterodimer, which elicited activities associated with IL-12 in other species. We propose that this strategy of self-processing polypeptides may be used in many applications where the coordinated and stoichiometric expression of complex proteins is required.

Induction of lymphocyte recruitment in the absence of a detectable immune response.

Lymphocyte recruitment from blood into the lymph node is thought to be initiated by the presence of antigen. In this study, we have used lymphatic cannulation in sheep to demonstrate that the adjuvant ISCOMATRIX can induce dramatic lymph node activation in the absence of antigen. Consistent patterns of node shutdown (decreased output) and cell recruitment (increased output) with minimal blast cell responses were observed indicating that an antigen-specific immune response is not required. Production of IL-6, IL-8 and IFN-gamma, and the transient presence of red blood cells and neutrophils in the efferent lymph were associated with changes in efferent lymph cell trafficking. These early events may facilitate the screening of low frequency antigen-specific cells for binding to antigen and the subsequent amplification of the immune response.