Identification of a protein encoded in the EB-viral open reading frame BMRF2

Using monospecific rabbit sera against a peptide derived from a potential antigenic region of the Epstein-Barr viral amino acid sequence encoded in the open reading frame BMRF2 we could identify a protein-complex of 53/55 kDa in chemically induced B95-8, P3HR1 and Raji cell lines. This protein could be shown to be membrane-associated, as predicted by previous computer analysis of the secondary structure and hydrophilicity pattern, and may be a member of EBV-induced membrane proteins in lytically infected cells

Proteasome inhibition and mechanism of resistance to a synthetic, library-based hexapeptide

Chemical Immunolog

Rapid Probing of Biological Surfaces with a Sparse-Matrix Peptide Library

Finding unique peptides to target specific biological surfaces is crucial to basic research and technology development, though methods based on biological arrays or large libraries limit the speed and ease with which these necessary compounds can be found. We reasoned that because biological surfaces, such as cell surfaces, mineralized tissues, and various extracellular matrices have unique molecular compositions, they present unique physicochemical signatures to the surrounding medium which could be probed by peptides with appropriately corresponding physicochemical properties. To test this hypothesis, a naïve pilot library of 36 peptides, varying in their hydrophobicity and charge, was arranged in a two-dimensional matrix and screened against various biological surfaces. While the number of peptides in the matrix library was very small, we obtained “hits” against all biological surfaces probed. Sequence refinement of the “hits” led to peptides with markedly higher specificity and binding activity against screened biological surfaces. Genetic studies revealed that peptide binding to bacteria was mediated, at least in some cases, by specific cell-surface molecules, while examination of human tooth sections showed that this method can be used to derive peptides with highly specific binding to human tissue

Epitope-mapping on the Epstein-Barr virus major capsid protein using systematic synthesis of overlapping oligopeptides

Systematic solid-phase synthesis of all possible overlapping nonapeptides of the 1381 amino acid sequence of the Epstein-Barr virus major capsid protein (EBV-MCP) was used to identify the position of linear antigen epitopes on this protein as recognised by human polyclonal antisera. Antisera were selected for reactivity with EBV-MCP on immunoblots. The results show that antibodies from different individual donors may recognise EBV-MCP through binding to a variety of different epitopes. These epitopes are localized at random over the protein backbone though some non-binding areas are also present. In addition, ten 'hot-spots' were identified containing closely-spaced reactive peptides (epitope-clusters) recognised by most (greater than or equal to 70%) individuals. No significant correlation was found between the actual location of these epitope-clusters and computer predictions using either hydrophilicity plots, secondary structure plots or a combination of (additional) parameters. Epitope-clusters generally were located in regions of indifferent or hydrophilic nature and mostly contained predicted beta-turn configurations. Only one epitope-cluster was located within a region of sequence homology with the MCPs of herpes simplex virus type 1 and varicella-zoster virus. The present study demonstrates the potential of using systematic peptide synthesis to define serologically relevant linear epitopes on large and relatively unexplored viral polypeptides

Specificity of chimpanzee antibodies binding a strain-specific HIV-1 neutralization epitope of the external envelope

Sera from three chimpanzees infected with a primary lymphadenopathy-associated virus (LAV-1) or human T-lymphotropic virus type III (HTLV-IIIB) passage, from two chimpanzees infected with blood from the primary infected chimpanzees, and from one chimpanzee infected with blood from a secondary passage animal all bound the peptides 3B and 3B/RF, sharing the sequence IQRGPGR, with equally high titers. Pepscan analysis confirmed the amino acids Q, R, G, P, and G as irreplaceable in order to retain antigenicit