Carbohydrate-based templates for synthetic vaccines and drug delivery

Methyl tetra-O-allyl, and tetra-O-[2-(tetrahydro-2H-pyranyl)oxy.-3-oxapentyl glucosides, and tetra-O-(cyanoethyl)galactosyl azide were converted into derivatives containing linkers with terminal carboxylic acid functionalities at the anomeric position and bearing four arms with phthaloyl- or BOC-protected terminal amino groups. These molecules were suitable for use in solid-phase peptide synthesis and for the preparation of dendrimers, containing multiple copies of peptides. (C) 2001 Elsevier Science Ltd. All rights reserved.

Towards synthetic vaccines built on carbohydrate cores

Lipophilic polyfunctional carbohydrate core/templates have been designed and developed for drug/vaccine delivery. Three carbohydrate-based templates containing four protected N-terminal arms were synthesised from glucose and galactose. Methyl alpha-D-glucopyranoside was converted to two derivatives bearing a carboxylic acid handle for attachment to solid supports, spacer arms of differing hydrophilicity, and phthaloyl-protected amino groups suitable for peptide chain extension. beta-D-Galactopyranosyl azide was converted to a template bearing a carboxylic acid handle and four BOC-protected amines. All the templates were found to be suitable for attachment to solid supports and subsequent cleavage from resins, using either BOC- or FMOC-methodologies.

Long synthetic peptides for the production of vaccines and drugs: a technological platform coming of age.

Long synthetic peptides (LSPs) have a variety of important clinical uses as synthetic vaccines and drugs. Techniques for peptide synthesis were revolutionized in the 1960s and 1980s, after which efficient techniques for purification and characterization of the product were developed. These improved techniques allowed the stepwise synthesis of increasingly longer products at a faster rate, greater purity, and lower cost for clinical use. A synthetic peptide approach, coupled with bioinformatics analysis of genomes, can tremendously expand the search for clinically relevant products. In this Review, we discuss efforts to develop a malaria vaccine from LSPs, among other clinically directed work.

Molecularly defined vaccines for cancer immunotherapy, and protective T cell immunity.

Malignant cells are frequently recognized and destroyed by T cells, hence the development of T cell vaccines against established tumors. The challenge is to induce protective type 1 immune responses, with efficient Th1 and CTL activation, and long-term immunological memory. These goals are similar as in many infectious diseases, where successful immune protection is ideally induced with live vaccines. However, large-scale development of live vaccines is prevented by their very limited availability and vector immunogenicity. Synthetic vaccines have multiple advantages. Each of their components (antigens, adjuvants, delivery systems) contributes specifically to induction and maintenance of T cell responses. Here we summarize current experience with vaccines based on proteins and peptide antigens, and discuss approaches for the molecular characterization of clonotypic T cell responses. With carefully designed step-by-step modifications of innovative vaccine formulations, T cell vaccination can be optimized towards the goal of inducing therapeutic immune responses in humans.

Locally produced mucosal IgG in chickens immunized with conventional vaccines for Newcastle disease virus

Newcastle disease virus (NDV) is the causative agent of an economically important disease, which affects all species of birds worldwide. Current vaccination programs for NDV include the use of either low-virulent live-virus vaccines or inactivated vaccines to induce protective immunity while producing minimal adverse effects in birds. In order to further characterize the immune response elicited by live virus and inactivated NDV conventional vaccines in chickens, we evaluated the presence of specific antibodies in different secretions and in tissue culture supernatants of immunized birds. To this end, we analyzed all the samples by ELISA, using an indirect assay set up in the laboratory. Specific anti-NDV IgG antibodies were detected in tracheal and cloacal swabs and tracheal and intestinal washes of immunized animals. We also found specific anti-NDV IgG antibodies in tracheal and intestinal tissue culture supernatants, indicating that the IgG found in swabs and washes was not transudated from serum or, at least, was not all transudated from serum. Knowledge about the mechanisms involved in the immune response of chickens to different NDV vaccines should increase our understanding of the mucosal response against the virus and, eventually, provide new useful information for the development and evaluation of synthetic vaccines.

Rapid and strong human CD8+ T cell responses to vaccination with peptide, IFA, and CpG oligodeoxynucleotide 7909.

The induction of potent CD8+ T cell responses by vaccines to fight microbes or tumors remains a major challenge, as many candidates for human vaccines have proved to be poorly immunogenic. Deoxycytidyl-deoxyguanosin oligodeoxynucleotides (CpG ODNs) trigger Toll-like receptor 9, resulting in dendritic cell maturation that can enhance immunogenicity of peptide-based vaccines in mice. We tested whether a synthetic ODN, CpG 7909, could improve human tumor antigen-specific CD8+ T cell responses. Eight HLA-A2+ melanoma patients received 4 monthly vaccinations of low-dose CpG 7909 mixed with melanoma antigen A (Melan-A; identical to MART-1) analog peptide and incomplete Freund's adjuvant. All patients exhibited rapid and strong antigen-specific T cell responses: the frequency of Melan-A-specific T cells reached over 3% of circulating CD8+ T cells. This was one order of magnitude higher than the frequency seen in 8 control patients treated similarly but without CpG and 1-3 orders of magnitude higher than that seen in previous studies with synthetic vaccines. The enhanced T cell populations consisted primarily of effector memory cells, which in part secreted IFN- and expressed granzyme B and perforin ex vivo. In vitro, T cell clones recognized and killed melanoma cells in an antigen-specific manner. Thus, CpG 7909 is an efficient vaccine adjuvant that promotes strong antigen-specific CD8+ T cell responses in humans.

Virus-like particles induce robust human T-helper cell responses.

Among synthetic vaccines, virus-like particles (VLPs) are used for their ability to induce strong humoral responses. Very little is reported on VLP-based-vaccine-induced CD4(+) T-cell responses, despite the requirement of helper T cells for antibody isotype switching. Further knowledge on helper T cells is also needed for optimization of CD8(+) T-cell vaccination. Here, we analysed human CD4(+) T-cell responses to vaccination with MelQbG10, which is a Qβ-VLP covalently linked to a long peptide derived from the melanoma self-antigen Melan-A. In all analysed patients, we found strong antibody responses of mainly IgG1 and IgG3 isotypes, and concomitant Th1-biased CD4(+) T-cell responses specific for Qβ. Although less strong, comparable B- and CD4(+) T-cell responses were also found specific for the Melan-A cargo peptide. Further optimization is required to shift the response more towards the cargo peptide. Nevertheless, the data demonstrate the high potential of VLPs for inducing humoral and cellular immune responses by mounting powerful CD4(+) T-cell help.

Quantitative multiparameter assays to measure the effect of adjuvants on human antigen-specific CD8 T-cell responses.

Large numbers and functionally competent T cells are required to protect from diseases for which antibody-based vaccines have consistently failed (1), which is the case for many chronic viral infections and solid tumors. Therefore, therapeutic vaccines aim at the induction of strong antigen-specific T-cell responses. Novel adjuvants have considerably improved the capacity of synthetic vaccines to activate T cells, but more research is necessary to identify optimal compositions of potent vaccine formulations. Consequently, there is a great need to develop accurate methods for the efficient identification of antigen-specific T cells and the assessment of their functional characteristics directly ex vivo. In this regard, hundreds of clinical vaccination trials have been implemented during the last 15 years, and monitoring techniques become more and more standardized.

Development of designed site-directed pseudopeptide-peptido-mimetic immunogens as novel minimal subunit-vaccine candidates for malaria

Synthetic vaccines constitute the most promising tools for controlling and preventing infectious diseases. When synthetic immunogens are designed from the pathogen native sequences, these are normally poorly immunogenic and do not induce protection, as demonstrated in our research. After attempting many synthetic strategies for improving the immunogenicity properties of these sequences, the approach consisting of identifying high binding motifs present in those, and then performing specific changes on amino-acids belonging to such motifs, has proven to be a workable strategy. In addition, other strategies consisting of chemically introducing non-natural constraints to the backbone topology of the molecule and modifying the a-carbon asymmetry are becoming valuable tools to be considered in this pursuit. Non-natural structural constraints to the peptide backbone can be achieved by introducing peptide bond isosters such as reduced amides, partially retro or retro-inverso modifications or even including urea motifs. The second can be obtained by strategically replacing L-amino-acids with their enantiomeric forms for obtaining both structurally site-directed designed immunogens as potential vaccine candidates and their Ig structural molecular images, both having immunotherapeutic effects for preventing and controlling malaria.

3D Analysis of the TCR/pMHCII Complex Formation in Monkeys Vaccinated with the First Peptide Inducing Sterilizing Immunity against Human Malaria

T-cell receptor gene rearrangements were studied in Aotus monkeys developing high antibody titers and sterilizing immunity against the Plasmodium falciparum malaria parasite upon vaccination with the modified synthetic peptide 24112, which was identified in the Merozoite Surface Protein 2 (MSP-2) and is known to bind to HLA-DR beta 1*0403 molecules with high capacity. Spectratyping analysis showed a preferential usage of V beta 12 and V beta 6 TCR gene families in 67% of HLA-DR beta 1*0403-like genotyped monkeys. Docking of peptide 24112 into the HLA-DR beta 1*0401-HA peptide-HA1.7TCR complex containing the VDJ rearrangements identified in fully protected monkeys showed a different structural signature compared to nonprotected monkeys. These striking results show the exquisite specificity of the TCR/pMHCII complex formation needed for inducing sterilizing immunity and provide important hints for a logical and rational methodology to develop multiepitopic, minimal subunit-based synthetic vaccines against infectious diseases, among them malaria.

Synthese tumorassoziierter Glycopeptidkonjugate basierend auf den epithelialen Mucinen MUC1 und MUC4 als potentielle Antitumorvakzine

Die Immuntherapie stellt eine hoffnungsvolle Alternative zu etablierten Behandlungsmethoden für Krebserkrankungen dar. Durch die Aktivierung des Immunsystems erhofft man sich eine selektive Abtötung von Tumorzellen. Eine solche Aktivierung kann durch Vakzinierung mit Glycopeptiden, welche Partialstrukturen tumorassoziierter Oberflächenglycoproteine darstellen, erfolgen. Um eine effektive Immunantwort zu erreichen, ist allerdings eine Konjugation dieser Glycopeptide mit immunogenen Trägern nötig. Zur Darstellung solcher Konjugate wurden im Rahmen dieser Arbeit zunächst mehrere, mit tumorassoziierten Kohlenhydraten glycosylierte Aminosäurebausteine dargestellt. Diese Bausteine wurden anschließend zur Festphasensynthese von Glycopeptiden eingesetzt. Durch ein neuartiges, chemoselektives Kupplungsverfahren konnten diese tumorassoziierten Glycopeptide an ein immunogenes Trägerprotein angebunden werden. Weiterhin wurde durch Festphasenpeptidsynthese ausgehend von einem tetrafunktionellen Lysin-Baustein ein dendrimeres Glycopeptid (MAP) erzeugt. Die Darstellung von vollsynthetischen Vakzinen gelang in Form von Konjugaten bestehend aus einem universellen T-Zell-Epitop und einem tumorassoziierten Glycopeptid. Diese Synthesen wurden ausgehend von einem festphasengebundenen, orthogonal geschützten Lysin durchgeführt. Abschließend wurde die Synthese von Konjugaten bestehend aus einem tumorassoziierten Glycopeptid und dem Mitogen Pam3Cys untersucht.

Synthese und immunologische Evaluierung von Antitumor-Impfstoffen aus dem epithelialen tumorassoziierten Mucin MUC1

Eine Immuntherapie von Tumorerkrankungen, die mit Hilfe von Antitumorimpfstoffen prophylaktisch und therapeutisch erfolgen könnte, wäre eine attraktive Alternative zu den bisher angewendeten Krebsbehandlungen. Aufgrund charakteristisch veränderter Aktivitäten von Glycosyltransferasen in der Glycoprotein-Biosynthese werden auf malignen Zellen stark verkürzte, frühzeitig sialylierte mucinartige Glycoproteine exprimiert. Diese verkürzten Kohlenhydrate repräsentieren tumorassoziierte Antigene. Sie haben zur Folge, dass Peptidepitope der Mucin-Glycoproteine, die auf gesundem Gewebe durch den hohen Glycosylierungsgrad maskiert sind, für das Immunsystem freiliegen. Diese Strukturunterschiede sollten einen selektiven Angriff auf das Tumorgewebe erlauben, ohne dass gesundes Gewebe beeinträchtigt wird, wenn es gelänge, das Immunsystem auf diese veränderten Strukturelemente zu fokussieren. Dabei ist es wichtig, dass die Immunantwort mit synthetisch definierten Glycopeptidepitopen ausgelöst wird, um Autoimmunreaktionen zu vermeiden. Somit ist die Synthese von exakt definierten tumorassoziierten Glycopeptiden von zentraler Bedeutung für die Entwicklung eines Antitumor-Impfstoffes. rnDa die tumorassoziierten Kohlenhydratstrukturen Antigene darstellen, die vom Immunsystem weitgehend toleriert werden, ist es notwendig, ihre Immunogenität mit Hilfe immunstimulierender Epitope so zu erhöhen, dass eine effiziente Immunreaktion erfolgt. Nach diesem Konzept wurden in der vorliegenden Arbeit Methoden und Strategien entwickelt, synthetische Impfstoff-Konjugate zu synthetisieren und immunologisch in Mausexperimenten zu evaluieren. So konnte gezeigt werden, das mit vollsynthetischen Analoga aus tumorassoziierten Glycopeptid-Oberflächenmolekülen in Kombination mit immunstimulierenden Substanzen, wie Trägerproteinen oder Mitogenen, hochselektive humorale Immunantworten ausgelöst werden können.rn