A pentavalent single-domain antibody approach to tumor antigen discovery and the development of novel proteomics reagents.

Proteomics research has delivered many novel tumor targets. However, due to key limitations, it does not specifically identify targets that are most accessible for drug delivery, such as cell-surface antigens. A novel tumor antigen discovery platform based on screening a single domain antibody (sdAb) library against tumor cells and subsequently identifying the corresponding antigens of the isolated antibodies is described. An sdAb, AFAI, specific for non-small cell lung carcinoma (A549 cell line) was isolated from a phage library derived from the heavy chain antibody repertoire of a llama. The homopentamerization property of a non-toxic verotoxin B-subunit was exploited to make the ES1 pentabody, a pentameric form of AFAI. Pentamerization improved the binding of the AFAI to A549 cells dramatically and greatly facilitated antigen identification by a Western blotting/mass spectrometry approach. The antigen of ES1, which is present only in the hydrophobic, not in the hydrophilic, fraction of A549 cellular proteins, was identified as carcinoembryonic antigen-related cell adhesion molecule 6 (CEA6). CEA6 was observed to be acidic and highly glycosylated, and to exist in multiple glycoforms. The results show that the platform described here should find wide application in antigen discovery, and demonstrated that the pentabodies are very useful immunological reagents for proteomics.

Characterization of protein-glycolipid recognition at the membrane bilayer.

A growing number of important molecular recognition events are being shown to involve the interactions between proteins and glycolipids. Glycolipids are molecules in which one or more monosaccharides are glycosidically linked to a lipid moiety. The lipid moiety is generally buried in the cell membrane or other bilayer, leaving the oligosaccharide moiety exposed but in close proximity to the bilayer surface. This presents a unique environment for protein-carbohydrate interactions, and studies to determine the influence of the bilayer on these phenomena are in their infancy. One important property of the bilayer is the ability to orient and cluster glycolipid species, as strong interactions in biological systems are often achieved through multivalency arising from the simultaneous association of two or more proteins and receptors. This is especially true of protein-carbohydrate binding because of the unusually low affinities that characterize the monovalent interactions. More recent studies have also shown that the composition of the lipid bilayer is a critical parameter in protein-glycolipid recognition. The fluidity of the bilayer allows for correct geometric positioning of the oligosaccharide head group relative to the binding sites on the protein. In addition, there are activity-based and structural data demonstrating the impact of the bilayer microenvironment on the modulation of oligosaccharide presentation. The use of model membranes in biosensor-based methods has supplied decisive evidence of the importance of the membrane in receptor presentation. These data can be correlated with three-dimensional structural information from X-ray crystallography, NMR, and molecular mechanics to provide insight into specific protein-carbohydrate inter--actions at the bilayer.