Heterobinary Adhesins Based on the Escherichia coli FimH Fimbrial Protein

The FimH adhesin of Escherichia coli type 1 fimbriae confers the ability to bind to d-mannosides by virtue of a receptor-binding domain located in its N-terminal region. This protein was engineered into a heterobifunctional adhesin by introducing a secondary binding site in the C-terminal region. The insertion of histidine clusters into this site resulted in coordination of various metal ions by recombinant cells expressing chimeric FimH proteins. In addition, libraries consisting of random peptide sequences inserted into the FimH display system and screened by a “panning” technique were used to identify specific sequences conferring the ability to adhere to Ni²⁺ and Cu²⁺. Recombinant cells expressing heterobifunctional FimH adhesins could adhere simultaneously to both metals and saccharides. Finally, combining the metal-binding modifications with alterations in the natural receptor-binding region demonstrated the ability to independently modulate the binding of FimH to two ligands simultaneously.

Expression systems for the display of heterologous protein segments facilitate the presentation of both defined and random peptide sequences at exposed regions of surface proteins of filamentous bacteriophage virions, bacteria, and yeasts (2, 4). We are particularly interested in the display of heterologous peptides in type 1 fimbriae. Such surface organelles are found on the majority of Escherichia coli strains and confer the ability to bind to specific surfaces. A single type 1 fimbria is a heteropolymer that is 7 nm wide and approximately 1 μm long. It consists of approximately 1,000 subunits of the major element, FimA, that are polymerized in a right-handed helical structure that also contains low levels of the minor components FimF, FimG, and FimH (9). The FimH protein has been shown to be the actual receptor-binding molecule which recognizes α-d-mannose-containing structures (10). Because of this, type 1 fimbriated bacteria readily agglutinate yeast cells (a rich source of mannan).The FimH adhesin is located at the tip of each fimbria and also is interspersed along the fimbrial shaft (6, 10). The results of linker insertion mutagenesis (16) and analyses of naturally occurring variants (17–19) and hybrid proteins constructed by fusing FimH to FocH (8) and MalE (21) suggest that the FimH protein consists of two major domains, each constituting roughly one-half of the molecule; the N-terminal domain seems to contain the receptor-binding site, while the C-terminal domain seems to contain the recognition sequences for export and bioassembly.In previous studies we investigated the ability of FimH to display heterologous peptides in connection with the development of vaccine systems. Various heterologous sequences, representing immune-relevant sectors of foreign proteins, were authentically displayed on the bacterial surface in FimH (12). These observations led us to believe that the FimH protein is an ideal candidate for display of random peptide sequences and for construction of designer adhesins (i.e., proteins manipulated to bind to targets of choice). Here we describe simultaneous heterobifunctional binding of recombinant cells expressing chimeric FimH proteins to metal and d-mannose targets.