Epitope structure and binding affinity of single chain llama anti-ß-amyloid antibodies revealed by proteolytic excision affinity-mass spectrometry.

ß-Amyloid (Aß) immunotherapy has become a promising strategy for reducing the level of Aß in brain. New immunological approaches have been recently proposed for rapid, early diagnosis, and molecular treatment of neurodegenerative diseases related to Alzheimer's Disease (AD). The combination of proteolytic epitope excision and extraction and mass spectrometry using digestion with various proteases has been shown to be an efficient tool for the identification and molecular characterization of antigenic determinants. Here, we report the identification of the Aß epitope recognized by the variable domain of single chain llama anti-Aß-antibodies, termed Aß-nanobodies, that have been discovered in the blood of camelids and found to be promising candidates for immunotherapy of AD. The epitope recognized by two Aß-specific nanobodies was identified by proteolytic epitope extraction- and excision-mass spectrometry using a series of proteases (trypsin, chymotrypsin, GluC-protease, and LysC-protease). Matrix-assisted laser desorption ionization--mass spectrometric analysis of the affinity--elution fraction provided the epitope, Aß(17-28), in the mid- to carboxy-terminal domain of Aß, which has been shown to exert an Aß-fibril inhibiting effect. Affinity studies of the synthetic epitope confirmed that the Aß(17-28) peptide is the minimal fragment that binds to the nanobodies. The interactions between the nanobodies and full length Aß(1-40) or Aß-peptides containing or lacking the epitope sequence were further characterized by enzyme linked immunosorbent assay and bioaffinity analysis. Determinations of binding affinities between the Aß-nanobodies and Aß(1-40) and the Aß(17-28) epitope provided K(D) values of approximately 150 and 700 nmol, respectively. Thus, the knowledge of the epitope may be highly useful for future studies of Aß-aggregation (oligomerization and fibril formation) and for designing new aggregation inhibitors.

Identification of the epitope for anti-cystatin C antibody.

Human cystatin C (hCC), like many other amyloidogenic proteins, has been shown to form dimers by exchange of subdomains of the monomeric protein. Considering the model of hCC fibrillogenesis by propagated domain swapping, it seems possible that inhibition of this process should also suppress the entire process of dimerization and fibrillogenesis which leads to specific amyloidosis (hereditary cystatin C amyloid angiopathy (HCCAA)). It was reported that exogenous agents like monoclonal antibody against cystatin C are able to suppress formation of cystatin C dimers. In the effort to find a way of controlling the cystatin fibrillization process, the interactions between monoclonal antibody Cyst-13 and cystatin C were studied in detail. The present work describes the determination of the epitope of hCC to a monoclonal antibody raised against cystatin C, Cyst-13, by MALDI mass spectrometry, using proteolytic excision of the immune complex. The shortest epitope sequence was determined as hCC(107-114). Affinity studies of synthetic peptides revealed that the octapeptide with epitope sequence does not have binding ability to Cyst-13, whereas its longer counterpart, hCC(105-114), binds the studied antibody. The secondary structure of the peptides with epitope sequence was studied using circular dichroism and NMR spectroscopy.

Polystyrene beads as an alternative support material for epitope identification of a prion-antibody interaction using proteolytic excision-mass spectrometry.

The binding epitope structure of a protein specifically recognized by an antibody provides key information to prevent and treat diseases with therapeutic antibodies and to develop antibody-based diagnostics. Epitope structures of antigens can be effectively identified by the proteolytic epitope excision-mass spectrometry (MS) method, which involves (1) immobilization of monoclonal or polyclonal antibodies, e.g., on N-hydroxysuccinimide-activated sepharose, (2) affinity binding of the antigen followed by limited proteolytic digestion of the immobilized immune complex, and (3) elution and mass spectrometric analysis of the remaining affinity-bound peptide(s). In the epitope analysis of recombinant cellular bovine prion protein (bPrP(C)) to a monoclonal antibody (mAb3E7), we found that epitope excision experiments resulted in extensive nonspecific binding of bPrP to a standard sepharose matrix employed. Here, we show that the use of amino-modified polystyrene beads with aldehyde functionality is an efficient alternative support for antibody immobilization, suitable for epitope excision-MS, with complete suppression of nonspecific bPrP binding.

Binding epitopes and interaction structure of the neuroprotective protease inhibitor cystatin C with beta-amyloid revealed by proteolytic excision mass spectrometry and molecular docking simulation.

Human cystatin C (HCC) is a protease inhibitor with a propensity to form beta-amyloid (Abeta)-like fibrils and to coassociate with amyloidogenic proteins. Recently, a specific interaction between HCC and Abeta has been found. Here, we report the identification of the Abeta and HCC binding epitopes in the Abeta-HCC complex, using a combination of selective proteolytic excision and high resolution mass spectrometry. Proteolytic excision of Abeta(1-40) on sepharose-immobilized HCC and MALDI-MS identified the epitope Abeta(17-28). On immobilized Abeta(1-40), affinity MS of HCC fragments identified a specific C-terminal epitope, HCC(101-117). Binding specificities of both epitopes were ascertained by ELISA and surface plasmon resonance and by direct electrospray MS of the HCC-Abeta epitope peptide complexes. A structure model of the HCC-Abeta complex by molecular docking simulation showed full agreement with the identified Abeta and HCC epitopes. Inhibition studies in vitro revealed Abeta-fibril inhibiting activity of the HCC(101-117)-epitope. The Abeta-HCC interacting epitopes provide lead structures of neuroprotective inhibitors for AD and HCC amyloidosis therapy.

Mass spectrometric approaches for elucidation of antigenantibody recognition structures in molecular immunology.

Mass spectrometric approaches have recently gained increasing access to molecular immunology and several methods have been developed that enable detailed chemical structure identification of antigen-antibody interactions. Selective proteolytic digestion and MS-peptide mapping (epitope excision) has been successfully employed for epitope identification of protein antigens. In addition, "affinity proteomics" using partial epitope excision has been developed as an approach with unprecedented selectivity for direct protein identification from biological material. The potential of these methods is illustrated by the elucidation of a beta-amyloid plaque-specific epitope recognized by therapeutic antibodies from transgenic mouse models of Alzheimer's disease. Using an immobilized antigen and antibody-proteolytic digestion and analysis by high resolution Fourier transform ion cyclotron resonance mass spectrometry has lead to a new approach for the identification of antibody paratope structures (paratope-excision; "parex-prot"). In this method, high resolution MS-peptide data at the low ppm level are required for direct identification of paratopes using protein databases. Mass spectrometric epitope mapping and determination of "molecular antibody-recognition signatures" offer high potential, especially for the development of new molecular diagnostics and the evaluation of new vaccine lead structures.