Your search keyword '"Jörg Reimann"' showing total 4 results

1. A Stress Protein-Facilitated Antigen Expression System for Plasmid DNA Vaccines

Author

Jörg Reimann, Nicolas Fissolo, Petra Riedl, and Reinhold Schirmbeck

Subjects

chemistry.chemical_compound, Expression vector, Immune system, chemistry, Antigen, Immunogenicity, Protein domain, Fusion protein, Molecular biology, DNA, DNA vaccination

Abstract

In DNA vaccination, an exciting new immunization technique with potential applications in clinical medicine, expression plasmid DNA containing antigen-encoding sequences cloned under heterologous promoter control are delivered by techniques that lead in vivo to antigen expression in transfected cells. DNA vaccination efficiently primes both humoral and cellular immune responses. We developed a novel expression system for DNA vaccines in which a fusion protein with a small, N-terminal, viral DnaJ-like sequence (J domain) is translated in frame with C-terminal antigen-encoding sequences. The J domain stable bind to constitutively expressed, cytosolic stress protein hsp73 and triggers intracellular accumulation of antigen/hsp73 complexes. The system supports enhanced expression of chimeric antigens of >800 residues in length in immunogenic form. A unique advantage of the system is that even unstable or toxic proteins (or protein domains) can be expressed. We describe the design of DNA vaccines expressing antigens with a stress protein-capturing domain and characterize the immunogenicity of the antigens produced by this expression system.

Published

2006

2. Complexes of DNA Vaccines With Cationic, Antigenic Peptides Are Potent, Polyvalent CD8+ T-Cell-Stimulating Immunogens

Author

Petra Riedl, Reinhold Schirmbeck, and Jörg Reimann

Subjects

chemistry.chemical_classification, Antigen, Biochemistry, chemistry, Oligonucleotide, Immunogenicity, Nucleic acid, Cytotoxic T cell, Peptide, Epitope, DNA vaccination

Abstract

A priority in current vaccine research is the development of multivalent vaccines that support the efficient priming of long-lasting CD8(+) T-cell immunity. We developed a novel vaccination strategy that used synthetic, cationic (positively charged), and antigenic peptides complexed to negatively charged nucleic acids: antigenic, major histocompatibility complex-class I-binding epitopes fused with a cationic sequence derived from the HIV tat protein (tat50-57: KKRRQRRR) were mixed with nucleic acids (e.g., CpG-containing oligonucleotides) to quantitatively form peptide/nucleic acid complexes. The injection of these complexes efficiently primed long-lasting, specific CD8(+) T-cell immunity of high magnitude. This chapter describes a novel strategy to codeliver complexes of cationic/antigenic peptides bound to antigen-encoding plasmid DNA vaccines in a way that enhances the immunogenicity of both components for T cells.

Published

2006

3. DNA-Based Vaccination Primes Tumor-Rejecting T-Cell Responses

Author

Martin Schleef, Jörg Reimann, Waltraud Böhm, Reinhold Schirmbeck, and Stefan Thoma

Subjects

Subdominant, CTL, medicine.anatomical_structure, Antigen, T cell, Immunology, medicine, Cytotoxic T cell, chemical and pharmacologic phenomena, Transfection, Biology, CD8, Epitope

Abstract

DNA-based vaccination efficiently primes MHC-restricted T-cell responses. This technique specifically stimulates MHC-II-restricted CD4(+) T-cell responses and MHC-I-restricted CD8(+) T-cell responses against "strong" (immunodominant) or "weak" (subdominant or cryptic) epitopes of intracellular, secreted or membrane-associated protein antigens. In many experimental systems, T-cell-mediated effector functions have the potential to control tumor growth. In particular MHC-I-restricted cytotoxic T lymphocytes (CTL) can reject tumors. This has been shown using either defined tumor-associated antigens (TAA), or viral antigens containing well-defined, MHC-binding and CTL-stimulating epitopes that are expressed by transfected tumor cells.

Published

2003

4. DNA-Based Vaccination with Polycistronic Expression Plasmids

Author

Jörg Reimann, Martin Schleef, Beate Grüner, Jan von Kampen, Hansjörg Hauser, Karin Metzger, Reinhold Schirmbeck, Andrea Kröger, and Jens Wild

Subjects

Messenger RNA, chemistry.chemical_compound, Plasmid, Expression vector, Antigen, chemistry, Priming (immunology), Transfection, Biology, Virology, DNA, DNA vaccination

Abstract

DNA-based vaccination is a potent technique to prime cellular (T-cell mediated) immune responses (reviewed in 1). Many details of the priming of T-cell precursors by antigen translated from injected expression plasmid DNA are unknown. The relevant cell that is transfected in situ after DNA vaccination and that can process and present the protein in an immunogenic form has not yet been identified. Alternatively, the transfected cell may initiate 'cross-priming' in vivo by transferring processed antigen to a professional antigen-presenting cell (APC).

Published

2003