Specific glycosidase activity isolated from a random phage display antibody library.

Carbohydrates serve as key receptor sites in various cellular events such as viral attachment, tumor formation, and tissue inflammation. A potential route to control these events is to manipulate targeted carbohydrate structures in vivo using specifically designed glycohydrolases. Here we show that a stereospecific catalytic activity designed toward a particular sugar and linkage can be readily isolated from a phage display antibody library derived from a nonimmunized host. The activity was isolated using a transition-state analogue mimicking an alpha-glucosidasic linkage as antigen and showed a 20-fold specificity for that sugar and linkage. The DNA sequence, however, contains a large deletion in the antibody gene, which also changes the downstream reading frame, resulting in a translated sequence containing only 57 amino acids that has a predominantly hydrophobic amino terminal and a strongly hydrophilic carboxy terminal. The isolated catalytic activity has a strong pH dependence, attributable to one or more of the numerous potentially charged groups in the carboxyl terminal. While the protein readily forms more stable multimers, the 7.3-kD monomer represents by far the smallest glycosidase enzyme reported to date and can provide substantial new information toward understanding and modifying glycosidase activity.

Artificial antibodies for affinity chromatography of homologous proteins: application to blood clotting proteins.

A method to readily isolate antibodies that bind to only one member of a family of homologous proteins is described. A library of different single chain antibody fragments can be displayed on the surface of a bacteriophage vector. Individual antibodies from this library recognizing a particular protein from a family of homologous proteins can be readily isolated by a two-step affinity screening process. In the first step antibodies which bind specifically to the undesired proteins or to homologous regions of the proteins are removed. In the second step, those antibodies specifically recognizing the desired protein are then isolated. Using this procedure and starting with a naive antibody library, a single chain antibody fragment specific to the blood clotting protein, Protein C, which did not recognize either of the homologous proteins, Factor IX or Factor X, was isolated. Similarly an antibody specific to Factor IX, but not Factor X or Protein C, was also isolated. The isolated antibodies can be readily produced, purified, and affixed to sepharose beads for affinity chromatography of the blood clotting factors. One of the key advantages to this procedure over conventional monoclonal antibody isolation is that the antibodies are isolated and produced in vitro so a broad range of related proteins, toxins, viruses, or other products can be targeted.

Selection of optimum affinity tags from a phage-displayed peptide library. Application to immobilized copper(II) affinity chromatography.

Immobilized metal affinity chromatography (IMAC) is a versatile tool for the purification of proteins with affinity for immobilized metals. Moreover, this technique has also been used for the separation of proteins that do not exhibit significant metal affinity in the native form, by their fusion to a short metal-binding peptide (a tail), most commonly, a sequence consisting of six adjacent histidine residues (His6). A phage-displayed random hexamer library is used to select for peptides with affinity for immobilized copper. The study follows our previous investigation in which a stringent selection protocol led to the selection of only one copper-binding peptide containing two histidines. The less stringent conditions employed in this work resulted in the selection of a more diverse population of peptides, but again, dominated by peptides containing two histidines (13 out of 19). The prevalence of peptides with two histidines, in contrast to peptides with a higher number of histidines (e.g. His6 or HHHMVH), is explained based on the differences in the pH dependence of their affinity for copper. As discussed, the selected peptides with two histidines will be superior affinity tails than peptides with a higher histidine content (e.g. His6). Moreover, a peptide with a single histidine but with a very high copper affinity, is also identified. Its high copper affinity is related to the presence of several hydrophobic residues in the neighborhood of histidine. Chromatography of human interleukin-1 beta (hIL-1 beta) and several other proteins containing a single surface-exposed histidine surrounded by several hydrophobic residues confirmed that such a sequence could also serve as a very effective metal binding domain for protein purification using immobilized copper(II) columns.