Using flexible loop mimetics to extend phi-value analysis to secondary structure interactions.

Chemical synthesis allows the incorporation of nonnatural amino acids into proteins that may provide previously untried probes of their folding pathway and thermodynamic stability. We have used a flexible thioether linker as a loop mimetic in the human yes kinase-associated protein (YAP 65) WW domain, a three-stranded, 44-residue, beta-sheet protein. This linkage avoids problems of incorporating sequences that constrain loops to the extent that they significantly change the nature of the denatured state with concomitant effects on the folding kinetics. An NMR solution structure shows that the thioether linker had little effect on the global fold of the domain, although the loop is apparently more dynamic. The thioether variants are destabilized by up to 1.4 kcal/mol (1 cal = 4.18 J). Preliminary Phi-value analysis showed that the first loop is highly structured in the folding transition state, and the second loop is essentially unstructured. These data are consistent with results from simulated unfolding and detailed protein-engineering studies of structurally homologous WW domains. Previously, Phi-value analysis was limited to studying side-chain interactions. The linkers used here extend the protein engineering method directly to secondary-structure interactions.

Applications of peptide arrays prepared by the SPOT-technology.

The growing range of applications for peptide arrays synthesized on coherent membranes by the SPOT-synthesis method proves they have emerged as a powerful proteomics technique to study molecular recognition events and identify biologically active peptides. Several developments, such as the introduction of novel polymeric surfaces, linkers, synthesis/cleavage strategies and detection methods, are facilitating an increasing spectrum of accessible compounds and applications in biological or pharmaceutical research.

Coherent membrane supports for parallel microsynthesis and screening of bioactive peptides.

Since its invention the SPOT-synthesis methodology has become one of the most efficient strategies for the miniaturized assembly of large numbers of peptides. The combination of a facile synthetic method with high throughput solid- and solution-phase screening assays qualifies the SPOT-technique as a valuable tool in biomedical research. Recent developments such as the introduction of novel polymeric surfaces, new linker and cleavage strategies as well as automated robot systems extended the scope of practical chemical reactions that can be accommodated as well as the numbers of compounds obtainable by this technique. Thus, highly complex spatially addressed compound arrays have become accessible. Together with the introduction of novel screening assays, the method is excellently suited to elucidate recognition events on the molecular level.

Dual epitope recognition by the VASP EVH1 domain modulates polyproline ligand specificity and binding affinity.

The Ena-VASP family of proteins act as molecular adaptors linking the cytoskeletal system to signal transduction pathways. Their N-terminal EVH1 domains use groups of exposed aromatic residues to specifically recognize 'FPPPP' motifs found in the mammalian zyxin and vinculin proteins, and ActA protein of the intracellular bacterium Listeria monocytogenes. Here, evidence is provided that the affinities of these EVH1-peptide interactions are strongly dependent on the recognition of residues flanking the core FPPPP motifs. Determination of the VASP EVH1 domain solution structure, together with peptide library screening, measurement of individual K(d)s by fluorescence titration, and NMR chemical shift mapping, revealed a second affinity-determining epitope present in all four ActA EVH1-binding motifs. The epitope was shown to interact with a complementary hydrophobic site on the EVH1 surface and to increase strongly the affinity of ActA for EVH1 domains. We propose that this epitope, which is absent in the sequences of the native EVH1-interaction partners zyxin and vinculin, may provide the pathogen with an advantage when competing for the recruitment of the host VASP and Mena proteins in the infected cell.

Biosynthesis of the cyanobacterial reserve polymer multi-L-arginyl-poly-L-aspartic acid (cyanophycin): mechanism of the cyanophycin synthetase reaction studied with synthetic primers.

Biosynthesis of the cyanobacterial nitrogen reserve cyanophycin (multi-L-arginyl-poly-L-aspartic acid) is catalysed by cyanophycin synthetase, an enzyme that consists of a single kind of polypeptide. Efficient synthesis of the polymer requires ATP, the constituent amino acids aspartic acid and arginine, and a primer like cyanophycin. Using synthetic peptide primers, the course of the biosynthetic reaction was studied. The following results were obtained: (a) sequence analysis suggests that cyanophycin synthetase has two ATP-binding sites and hence probably two active sites; (b) the enzyme catalyses the formation of cyanophycin-like polymers of 25-30 kDa apparent molecular mass in vitro; (c) primers are elongated at their C-terminus; (d) the constituent amino acids are incorporated stepwise, in the order aspartic acid followed by arginine, into the growing polymer. A mechanism for the cyanophycin synthetase reaction is proposed; (e) the specificity of the enzyme for its amino-acid substrates was also studied. Glutamic acid cannot replace aspartic acid as the acidic amino acid, whereas lysine can replace arginine but is incorporated into cyanophycin at a much lower rate.

Analysis of CD8 T cell reactivity to cytomegalovirus using protein-spanning pools of overlapping pentadecapeptides.

The frequencies of human cytomegalovirus (HCMV) protein-specific CD8 T cells, identified by the presence of intracellular IFN-gamma, were measured by flow cytometry following stimulation of freshly isolated peripheral blood mononuclear cells (PBMC) with comprehensive peptide pools. These pools spanned the entire amino acid sequences of the HCMV pp65 and major immediate early (IE-1) proteins and consisted of 15-amino acid peptides with at least nine overlaps between neighboring peptides. As a result all potential CD8 T cell epitopes contained in these proteins were provided by the complete pools and, therefore, unlike with single epitopes, testing was independent of donor HLA type. Individual stimulating peptides from the same pools were identified in parallel experiments. Thus we found that our results with the complete pools using PBMC from 26 healthy HCMV-seropositive donors were 100% sensitive and specific with respect to predicting the presence of recognized epitopes in the respective proteins. In addition, cells from 15 renal transplant patients were tested with complete pools alone. While our results confirmed our previous contention that HCMV IE-1 is an important CD8 T cell target, the technical improvement we made in order to address this question has clearly wider implications. Similar pools may be applied to examine the role of proteins from other pathogens, in autoimmune disease or following vaccination.

Spot synthesis: observations and optimizations.

Positionally addressable syntheses of peptides on continuous cellulose membranes (spot synthesis) have often been reported in detail, but important questions dealing with synthesis quality, reproducibility and subsequent binding assays have largely been under-emphasized. In this report we have investigated some of these problems. The most important results were: (i) the signal intensity of ligate binding to cellulose-bound peptides and the affinity of the corresponding soluble peptides show good correlation, illustrated by three different ligate binding assays; (ii) reducing peptide density on the cellulose avoids the 'ring spot' effect, i.e. where less binding is observed in the spot-center compared to the rim. We recommend a peptide density of 10 nmol/cm2 as a reasonable starting point for further optimization; (iii) statistical analysis of binding assay reproducibility with more than 15000 peptides resulted in a mean standard signal deviation of 0.18; and (iv) optimization of side-chain deprotection revealed that a 30-min pretreatment of the cellulose with 90% trifluoroacetic acid followed by the standard deprotection protocol resulted in higher purity of the synthesized products.

The antigen binding domain of non-idiotypic human anti-F(ab')2 autoantibodies: study of their interaction with IgG hinge region epitopes.

In previous studies we described a natural human IgG-anti-F(ab')2 autoantibody family with immunoregulatory properties. Genes coding for the variable regions of the heavy and light chains of the Abs were isolated from a natural Ig gene library and scFv Abs were expressed in E. coli. The scFv Abs bound to F(ab')2 but not to Fab fragments. This points to an epitope located in the hinge region since Fab fragments are lacking most of the hinge. In order to verify our hypothesis, double chain peptides comprising the lower-, middle-, and part of the upper hinge subregion of IgG1-IgG4 were synthesized on cellulose membranes and tested for binding to the Abs. The results show binding of Abs to IgG1 and IgG4 hinge region peptides. In order to identify the key residues of the discontinuous epitopes we carried out complete substitutional analyses in which each amino acid of the wt peptides was substituted by all other amino acids except cysteine. The exchange of proline in the IgG1 or IgG4 middle hinge region abrogated the binding, revealing the importance of this subregion for epitope expression. No binding to the IgG2 or IgG3 hinge was detected. These results indicate that scFv anti-F(ab')2 Abs recognize the hinge region of IgG1 and IgG4 and that the expression of the epitope depends on an intact middle hinge subregion.

Charcoal surface-assisted catalysis of intramolecular disulfide bond formation in peptides.

A mild and highly efficient method for intramolecular disulfide bond formation in peptides mediated by charcoal has been developed. Completion of the charcoal-assisted catalysis of disulfide bond formation took less than 6 h, testing a series of peptides with ring sizes varying from 2 to 17 amino acids. Kinetic studies revealed that the formation of small and large intramolecular disulfide cycles especially was accelerated significantly by the aid of charcoal as compared with dimethyl sulfoxide- and air-mediated cyclization. Oxygen adsorbed onto the charcoal surface is a prerequisite for disulfide bond formation. Thermodynamic studies showed that cyclization is accelerated by reduction of entropy of the peptides, most likely because of transient adsorption to the charcoal surface, thus resulting in a lower activation energy.

Simultaneous synthesis of peptide libraries on single resin and continuous cellulose membrane supports: examples for the identification of protein, metal and DNA binding peptide mixtures.

Peptide libraries were simultaneously synthesized on single supports by double coupling 0.8 equivalents of an equimolar acylating amino acid mixture consisting of 19 amino acids (cysteine omitted) at randomized sites, thus compensating for the different coupling rates of the amino acids. Peptide epitope mixtures, as well as very complex mixtures such as a completely randomized hexapeptide, were prepared and analyzed by HPLC and amino acid analysis. The results obtained indicate that this method can be applied to the synthesis of peptide libraries. Parts of a simultaneously synthesized solution phase combinatorial library XXB1B2XX were successfully used for the detection of the linear epitope HFND of transforming growth factor-alpha (TGF alpha) recognized by the monoclonal antibody Tab2. Furthermore, novel combinatorial peptide libraries XXB1B2XX were prepared on continuous cellulose membrane supports, also allowing the identification of TGF alpha epitope sequences. In addition, peptide mixtures that bound to a double-stranded DNA (15mer) and silver were identified. These preliminary results indicate that cellulose-bound combinatorial peptide libraries can be used for the rapid and inexpensive screening of millions of peptides to identify single molecules that bind any given ligand such as proteins, nucleic acids and metals.