Karl-Heinz Wiesmüller

TLR1- and TLR6-independent recognition of bacterial lipopeptides.

Bacterial cell walls contain lipoproteins/peptides, which are strong modulators of the innate immune system. Triacylated lipopeptides are assumed to be recognized by TLR2/TLR1-, whereas diacylated lipopeptides use TLR2/TLR6 heteromers for signaling. Following our initial discovery of TLR6-independent diacylated lipopeptides, we could now characterize di- and triacylated lipopeptides (e.g. Pam2C-SK4, Pam3C-GNNDESNISFKEK), which have stimulatory activity in TLR1- and in TLR6-deficient mice. Furthermore, for the first time, we present triacylated lipopeptides with short length ester-bound fatty acids (like PamOct2C-SSNASK4), which induce no response in TLR1-deficient cells. No differences in the phosphorylation of MAP kinases by lipopeptide analogs having different TLR2-coreceptor usage were observed. Blocking experiments indicated that different TLR2 heteromers recognize their specific lipopeptide ligands independently from each other. In summary, a triacylation pattern is necessary but not sufficient to render a lipopeptide TLR1-dependent, and a diacylation pattern is necessary but not sufficient to render a lipopeptide TLR6-dependent. Contrary to the current model, distinct lipopeptides are recognized by TLR2 in a TLR1- and TLR6-independent manner.

Heterodimerization of TLR2 with TLR1 or TLR6 expands the ligand spectrum but does not lead to differential signaling.

TLR are primary triggers of the innate immune system by recognizing various microorganisms through conserved pathogen‐associated molecular patterns. TLR2 is the receptor for a functional recognition of bacterial lipopeptides (LP) and is up‐regulated during various disorders such as chronic obstructive pulmonary disease and sepsis. This receptor is unique in its ability to form heteromers with TLR1 or TLR6 to mediate intracellular signaling. According to the fatty acid pattern as well as the assembling of the polypeptide tail, LP can signal through TLR2 in a TLR1‐ or TLR6‐dependent manner. There are also di‐ and triacylated LP, which stimulate TLR1‐deficient cells and TLR6‐deficient cells. In this study, we investigated whether heterodimerization evolutionarily developed to broaden the ligand spectrum or to induce different immune responses. We analyzed the signal transduction pathways activated through the different TLR2 dimers using the three LP, palmitic acid (Pam)octanoic acid (Oct)2C‐(VPGVG)4VPGKG, fibroblast‐stimulating LP‐1, and Pam2C‐SK4. Dominant‐negative forms of signaling molecules, immunoblotting of MAPK, as well as microarray analysis indicate that all dimers use the same signaling cascade, leading to an identical pattern of gene activation. We conclude that heterodimerization of TLR2 with TLR1 or TLR6 evolutionarily developed to expand the ligand spectrum to enable the innate immune system to recognize the numerous, different structures of LP present in various pathogens. Thus, although mycoplasma and Gram‐positive and Gram‐negative bacteria may activate different TLR2 dimers, the development of different signal pathways in response to different LP does not seem to be of vital significance for the innate defense system.

Toll-like receptor 6-independent signaling by diacylated lipopeptides.

Bacterial lipopeptides are strong immune modulators that activate early host responses after infection as well as initiating adjuvant effects on the adaptive immune system. These lipopeptides induce signaling in cells of the immune system through Toll‐like receptor 2 (TLR2)–TLR1 or TLR2–TLR6 heteromers. So far it has been thought that triacylated lipopeptides, such as the synthetic N‐palmitoyl‐S‐[2,3‐bis(palmitoyloxy)‐(2RS)‐propyl]‐(R)‐cysteine (Pam3)‐CSK4, signal through TLR2–TLR1 heteromers, whereas diacylated lipopeptides, like the macrophage‐activating lipopeptide from Mycoplasma fermentans (MALP2) or S‐[2,3‐bis(palmitoyloxy)‐(2RS)‐propyl]‐(R)‐cysteine (Pam2)‐CGNNDESNISFKEK, induce signaling through TLR2–TLR6 heteromers. Using new synthetic lipopeptide derivatives we addressed the contribution of the lipid and, in particular, the peptide moieties with respect to TLR2 heteromer usage. In contrast to the current model of receptor usage, not only triacylated lipopeptides, but also diacylated lipopeptides like Pam2CSK4 and the elongated MALP2 analog Pam2CGNNDESNISFKEK‐SK4 (MALP2‐SK4) induced B lymphocyte proliferation and TNF‐α secretion in macrophages in a TLR6‐independent manner as determined with cells from TLR6‐deficient mice. Our results indicate that both the lipid and the N‐terminal peptides of lipoproteins contribute to the specificity of recognition by TLR2 heteromers and are responsible for the ligand–receptor interaction on host cells.

Binding of lipopeptide to CD14 induces physical proximity of CD14, TLR2 and TLR1

Lipoproteins or lipopeptides (LP) are bacterial cell wall components detected by the innate immune system. For LP, it has been shown that TLR2 is the essential receptor in cellular activation. However, molecular mechanisms of LP recognition are not yet clear. We used a FLAG‐labeled derivative of the synthetic lipopeptide N‐palmitoyl‐S‐[2,3‐bis(palmitoyloxy)‐(2R,S)‐propyl]‐(R)‐cysteinyl‐seryl‐(lysyl)3‐lysine (Pam3CSK4) to study the roles of CD14, TLR2 and TLR1 in binding and signaling of LP and their molecular interactions in human cells. The activity of Pam3CSK4‐FLAG was TLR2 dependent, whereas the binding was enabled by CD14, as evaluated by flow cytometry and confocal microscopy. Using FRET and FRAP imaging techniques to study molecular associations, we could show that after Pam3CSK4‐FLAG binding, CD14 and Pam3CSK4‐FLAG associate with TLR2 and TLR1, and TLR2 is targeted to a low‐mobility complex. Thus, LP binding to CD14 is the first step in the LP recognition, inducing physical proximity of CD14 and LP with TLR2/TLR1 and formation of the TLR2 signaling complex.

Novel low-molecular-weight synthetic vaccine against foot-and-mouth disease containing a potent B-cell and macrophage activator

Most synthetic peptide vaccines described to date are effective only in combination with proteins and Freunds adjuvant. The work describes a novel completely synthetic virus peptide vaccine, which consists of a synthetic activator of B cells and macrophages, covalently linked to an amphiphilic alpha-helical T-cell epitope. The low-molecular-weight vaccine of 3.4 kDa developed against foot-and-mouth disease virus (FMDV) is composed of a synthetic VP1 (135-154) with a sequence homologous to an FMDV protein and the adjuvant tripalmitoyl-S-glyceryl-cysteinylserylserine (P3CSS). P3CSS is the synthetic analogue of the N-terminal part of the lipoprotein from Gram-negative bacteria. The antigenic determinant VP1 (135-154) is an alpha-helix as shown by circular dichroism. The resulting novel type of vaccine tripalmitoyl-S-glyceryl-cysteinylserylseryl-FMDV-VP1 (135-154) induces a long-lasting high protection against foot-and-mouth disease and serotype-specific virus-neutralizing antibodies in guinea-pigs after a single administration without any additional adjuvant or carrier. In contrast to other simple fatty acid conjugates this new type of vaccine contains a built-in adjuvant with high affinity to both B and T lymphocytes.

Lipopeptide structure determines TLR2 dependent cell activation level

Bacterial lipoproteins/peptides are composed of di‐O‐acylated‐S‐(2,3‐dihydroxypropyl)‐cysteinyl residues N‐terminally coupled to distinct polypeptides, which can be N‐acylated with a third fatty acid. Using a synthetic lipopeptide library we characterized the contribution of the lipid portion to the TLR2 dependent pattern recognition. We found that the two ester bound fatty acid length threshold is beyond eight C atoms because almost no response was elicited by cellular challenge with analogues carrying shorter acyl chains in HEK293 cells expressing recombinant human TLR2. In contrast, the amide bound fatty acid is of lesser importance. While two ester‐bound palmitic acids mediate a high stimulatory activity of the respective analogue, a lipopeptide carrying one amide‐bound and another ester‐bound palmitic acid molecule was inactive. In addition, species specific LP recognition through murine and human TLR2 depended on the length of the two ester bound fatty acid chains. In conclusion, our results indicate the responsibility of both ester bound acyl chains but not of the amide bound fatty acid molecule for the TLR dependent cellular recognition of canonical triacylated LP, as well as a requirement for a minimal acyl chain length. Thus they might support the explanation of specific immuno‐stimulatory potentials of different microorganisms and provide a basis for rational design of TLR2 specific adjuvants mediating immune activation to distinct levels.

Identification of T-cell epitopes in the structural and non-structural proteins of classical swine fever virus.

To identify new T-cell epitopes of classical swine fever virus (CSFV), 573 overlapping, synthetic pentadecapeptides spanning 82% of the CSFV (strain Glentorf) genome sequence were synthesized and screened. In proliferation assays, 26 peptides distributed throughout the CSFV viral protein sequences were able to induce specific T-cell responses in PBMCs from a CSFV-Glentorf-infected d/d haplotype pig. Of these 26 peptides, 18 were also recognized by PBMCs from a CSFV-Alfort/187-infected d/d haplotype pig. In further experiments, it could be shown that peptide 290 (KHKVRNEVMVHWFDD), which corresponds to amino acid residues 1446-1460 of the CSFV non-structural protein NS2-3 could induce interferon-gamma secretion after secondary in vitro restimulation. The major histocompatibility complex (MHC) restriction for stimulation of T-cells by this pentadecapeptide was identified as being mainly MHC class II and partially MHC class I. In cytolytic assays, CSFV-specific cytotoxic T-lymphocytes (CTLs) were able to lyse peptide 290-loaded target cells. These findings indicate the existence of a CSFV-specific helper T-cell epitope and a CTL epitope in this peptide.

Determination of T cell epitopes with random peptide libraries

A new approach to T cell epitope determination is presented. Critical amino acids for the induction of cytotoxic T cell responses were identified using synthetic peptide libraries with single defined sequence positions combined with randomized sequence positions. Sequences for potential T cell epitopes were deduced from scan profiles using combinations of the active amino acids. Highly potent epitopes for cytotoxic T lymphocytes were obtained. Epitopes defined by this approach are, as shown in this communication, not necessarily the natural epitopes and, therefore, were named synthetic epitopes. They can serve effectively for the development of vaccines or for the determination of T cell receptor antagonists.

Evaluation of an optically active crown ether for the chiral separation of di- and tripeptides

The direct optical resolution of a number of di- and tripeptides was achieved by capillary zone electrophoresis using an enantioselective crown ether as buffer additive. The protonated primary amines form inclusion complexes with the crown ether. Chiral resolution is based on different stability constants of the diastereomeric complexes thereby changing the electrophoretic mobilities of the enantiomers. Enantioselectivity is strongly affected by the distance between the amine functionality and the chiral carbon atom. This effect was studied using di- and tripeptides especially synthesized for this purpose. In general, baseline resolution was obtained for those peptides with the amine group located as far as four bonds from the stereogenic center. Additionally, tripeptides possessing two chiral centers were separated to investigate the potential of the chiral selector for the analysis of complex analytes with related structures. Experimental factors such as crown ether concentration, buffer pH and temperature also show a strong influence on the resolution. These factors can be successfully employed for method optimization.

Protection against measles virus encephalitis by monoclonal antibodies binding to a cystine loop domain of the H protein mimicked by peptides which are not recognized by maternal antibodies.

After immunization with measles virus (MV) several monoclonal antibodies (MAbs) were obtained, which reacted with peptides corresponding to the amino acids 361-410 of the haemagglutinin protein (MV-H). Three of these MAbs (BH6, BH21 and BH216) inhibited haemagglutination, neutralized MV in vitro and protected animals from a lethal challenge of rodent-adapted neurotropic MV. These MAbs reacted with the 15-mer peptides H381 and H386 defining their overlapping region 386-395 as a sequential neutralizing and protective epitope, which can be imitated by a short peptide. H381 and H386 share two Cys residues (C(386)KGKIQALC(394)ENPEWA) and for optimal MAb binding of peptide (or MV) disulphide bonds were required in addition to a linear C-terminal extension. Other MAbs bound to peptides C- (BH147, BH195) and N-terminally (BH 168, BH 171) adjacent to the loop but did not neutralize or protect. When sera from measles patients or from women of child-bearing age were tested with the peptides corresponding to this haemagglutinating and neutralizing epitope (HNE), none of the sera recognized the 15-mer peptides of this region, while some reactivity was found to 30-mers homologous to different wild-type mutants. Its lack of recognition by maternal antibodies and its high degree of conservation would make the HNE loop an attractive candidate to include into a subunit vaccine, which could be administered during early childhood, independent of immune status.