Phospho-specific antibodies as a tool to study in vivo regulation of BRCA1 after DNA damage.

Phospho-specific antibodies have become very useful reagents for study of signal transduction pathways. This chapter describes the production of phospho-specific antibodies and their use to assess individual phosphorylation events in vivo in cells. The first step involves the synthesis of peptides (12-15 residues), where the phosphorylation site is centrally located, and a cysteine residue is incorporated at either the N- or C-terminus of the peptide to facilitate coupling it to an immunogenic carrier protein. No special immunization protocols are required to generate phospho-specific antibodies. Typically, animals of choice are immunized twice, several weeks apart, and enzyme-linked immunosorbent assay is used to determine the relative titer of sera against phosphorylated and nonphosphorylated peptides. Where the titer against phosphorylated peptides is much greater than nonphosphorylated peptides, the sera can be used at appropriate dilutions without further processing. In case a significant level of antibodies specific to the nonphosphorylated peptide is present in the antisera, an enhancement step is used to obtain a useful phospho-specific antibody. Although these enhanced antisera are suitable for many applications, there may be circumstances where affinity-purified antibodies are required. These antibodies can be used to detect a particular phosphorylation event in vivo using Western blotting, immunoprecipitation, and immunofluorescence.

Crystal structure of a glycosylated Fab from an IgM cryoglobulin with properties of a natural proteolytic antibody.

The 2.6 A (1 A=0.1 nm) resolution structure has been determined for the glycosylated Fab (fragment antigen binding) of an IgM (Yvo) obtained from a subject with Waldenström's macroglobulinaemia. Dynamic light scattering was used to estimate the gel point and monitor the formation of an ordered hydroscopic gel of Yvo IgM upon cooling. If a cryoglobulin forms gels in peripheral tissues and organs, the associated swelling and damage to microvasculature can result in considerable morbidity and mortality. The three-dimensional structure of the branched N-linked oligosaccharide associated with the CH1 domain (first constant domain of heavy chain) is reported. The carbohydrate may act to shield part of the lateral surface of the CH1 domain and crowd the junction between the CH1 and CH2 domains, thereby limiting the segmental flexibility of the Fab arms in intact Yvo IgM, especially at low temperatures. Recently, Yvo IgM was shown to have the properties of a naturally occurring proteolytic antibody [Paul, Karle, Planque, Taguchi, Salas, Nishiyama, Handy, Hunter, Edmundson and Hanson (2004) J. Biol. Chem. 279, 39611-39619; Planque, Bangale, Song, Karle, Taguchi, Poindexter, Bick, Edmundson, Nishiyama and Paul (2004) J. Biol Chem. 279, 14024-14032]. The Yvo protein displayed the ability to cleave, by a nucleophilic mechanism, the amide bonds of a variety of serine protease substrates and the gp120 coat protein of HIV. An atypical serine, arginine and glutamate motif is located in the middle of the Yvo antigen-binding site and displays an overall geometry that mimics the classical serine, histidine and aspartate catalytic triad of serine proteases. Our present findings indicate that pre-existing or natural antibodies can utilize at least one novel strategy for the cleavage of peptide bonds.

Characterisation of epitopes of pan-IgG/anti-G3m(u) and anti-Fc monoclonal antibodies.

The characterisation of monoclonal antibodies (MAbs) and their epitopes is important prior to their application as molecular probes. In this study, Western blotting using IgG1 Fc and pFc' fragments was employed to screen seven MAbs before pepscan analysis to determine their reactivity to potentially linear epitopes. MAbs PNF69C, PNF110A, X1A11 and MAbs WC2, G7C, JD312, 1A1 detected epitopes within the C(H)3 and C(H)2 domains, respectively. However, only four MAbs showed pepscan profiles that highlighted likely target residues. In particular, MAbs PNF69C and PNF110A that have previously been characterised with pan-IgG and anti-G3m(u) specificity, detected the peptide motif 338-KAKGQPR-344 which was located within the N-terminal region of the C(H)3 domain. Furthermore the majority of residues were present in all four IgG subclasses. Consequently the peptide identified was consistent with the pan-IgG nature of these antibodies. By using PCImdad, a molecular display programme, this sequence was visualised as surface accessible, located in the C(H)2/C(H)3 inter-domain region and proximal to the residue arginine(435). It is speculated that this residue may be important for phenotypic expression of G3m(u) and specificity of these reagents. Pepscan analysis of MAbs G7C and JD312 (both pan-IgG) highlighted the core peptide sequence 290-KPREE-294, which was present in the C(H)2 domain and was common to all four IgG subclasses. PCImdad also showed this region to be highly accessible and was consistent with previous bioinformatic and autoimmune analysis of IgG. Overall these MAbs may serve as useful anti-IgG or anti-G3m(u) reagents and probes of immunoglobulin structure.

Combinatorial methods for discovery of peptide ligands which bind to antibody-like molecules.

In the 1980s, new methods of parallel peptide synthesis were used to make large libraries of peptides, which were then screened for binding to Bence-Jones dimers. Subsequent X-ray crystallography of the Bence-Jones proteins, which had been infiltrated with peptide ligand, was used to determine the structural correlate of the binding data. The mode of binding was found to be not predictable and insight was gained into the forces determining how the so-called mimotopes interacted with binding sites.

Multipin peptide libraries for antibody and receptor epitope screening and characterization.

It has been nearly 15 years since the papers describing the fully systematic epitope mapping approach both for the so-called "continuous" epitopes [Proc. Natl. Acad. Sci. U. S. A. 81 (1984) 3998] and "discontinuous" epitopes [Mol. Immunol. 23 (1986) 709] were published. These seminal papers laid the conceptual foundation for all subsequent developments where a combinatorial approach is applied. Dr. Mario Geysen, the 2000 Kilby Laureate, can certainly lay claim to be the "father of combinatorial chemistry" (http://www.kilby.org/laureates.htm). In this review, I will focus on the aspects of the Multipin technology as they apply to antibody and receptor epitope mapping. Much of what will be presented applies equally well to other applications where peptide libraries (PepSets) and combinatorial approaches are used [Rodda, S.J., 1996. T-cell epitope mapping with synthetic peptides and peripheral blood mononuclear cells. In: Morris, G.E. (Eds.), Methods in Molecular Biology, Vol. 66: Epitope Mapping Protocols. Humana Press, Totowa, NJ, Chap. 30, p. 363; Int. J. Pept. Protein Res. 42 (1993) 384; J. Biol. Chem. 271 (1996) 5603]. Factors and techniques that influence the use of the Multipin method for successful epitope mapping will be presented.