Optimized protocols for the isolation of specific protein-binding peptides or peptoids from combinatorial libraries displayed on beads.

Many methods have been published by which combinatorial libraries may be screened for compounds capable of manipulating the function(s) of a target protein. One of the simplest approaches is to identify compounds in a library that bind the protein of interest, since these binding events usually occur on functionally important surfaces of the protein. These protein-binding compounds could also be of utility as protein capture agents in the construction of protein-detecting microarrays or related analytical devices and as reagents for the affinity purification of proteins from complex mixtures. In this article, we provide optimized methods for screening libraries of molecules displayed on the beads on which they were synthesized. This is a particularly convenient format for library screening for laboratories with limited budgets and modest robotics capabilities.

Synthetic molecules as antibody replacements.

Antibodies are by far the most versatile, valuable, and widely used protein-binding agents. They are essential tools in biological research and are increasingly being developed as therapeutic reagents. However, antibodies have a number of practical limitations, and it would be desirable in many applications to replace them with simpler, more robust synthetic molecules. Unfortunately, synthetic protein-binding agents rarely exhibit the high affinity and specificity typical of a good antibody. This article reviews efforts to overcome these limitations and to develop a facile, high-throughput methodology for the isolation of synthetic protein ligands with antibody-like binding characteristics.

Transformation of low-affinity lead compounds into high-affinity protein capture agents.

A simple and potentially general approach to the isolation of high-affinity and -specificity protein binding synthetic molecules is presented. A modest affinity lead compound is appended to the end of each molecule in a combinatorial library of oligomeric compounds, such as peptides or peptoids. The library is then screened under conditions too demanding for the lead to support robust binding to the protein target. It was anticipated that this procedure would select for bivalent ligands in which the oligomer library provides both a second binding element as well as an appropriate linker between this element and the lead compound. We report here synthetic ligands for the Mdm2 protein and ubiquitin able to capture their target proteins from dilute solutions in the presence of a large excess of other proteins.

Thermodynamic characterization of monomeric and dimeric forms of CcdB (controller of cell division or death B protein).

The protein CcdB (controller of cell division or death B) is an F-plasmid-encoded toxin that acts as an inhibitor of Escherichia coli DNA gyrase. The stability and aggregation state of CcdB have been characterized as a function of pH and temperature. Size-exclusion chromatography revealed that the protein is a dimer at pH 7.0, but a monomer at pH 4.0. CD analysis and fluorescence spectroscopy showed that the monomer is well folded, and has similar tertiary structure to the dimer. Hence intersubunit interactions are not required for folding of individual subunits. The stability of both forms was characterized by isothermal denaturant unfolding and calorimetry. The free energies of unfolding were found to be 9.2 kcal x mol(-1) (1 cal approximately 4.184 J) and 21 kcal x mol(-1) at 298 K for the monomer and dimer respectively. The denaturant concentration at which one-half of the protein molecules are unfolded (C(m)) of the dimer is dependent on protein concentration, whereas the C(m) of the monomer is independent of protein concentration, as expected. Although thermal unfolding of the protein in aqueous solution is irreversible at neutral pH, it was found that thermal unfolding is reversible in the presence of GdmCl (guanidinium chloride). Differential scanning calorimetry in the presence of low concentrations of GdmCl in combination with isothermal denaturation melts as a function of temperature were used to derive the stability curve for the protein. The value of Delta C (p) (representing the change in excess heat capacity upon protein denaturation) is 2.8+/-0.2 kcal x mol(-1) x K(-1) for unfolding of dimeric CcdB, and only has a weak dependence on denaturant concentration.

Isolation of protein ligands from large peptoid libraries.

The isolation of ligands for large numbers of proteins is an important goal in proteomics. Whereas peptide libraries are rich sources of protein-binding molecules, native peptides have certain undesirable properties, such as sensitivity to proteases that make them less than ideal for some applications. We report here the construction and characterization of large, chemically diverse combinatorial libraries of peptoids (N-substituted oligoglycines). A protocol for the isolation of specific protein-binding molecules from these libraries is described. These data suggest that peptoid libraries will prove to be inexpensive and convenient sources of protein ligands.

Mixed-element capture agents: a simple strategy for the construction of synthetic, high-affinity protein capture ligands.

Demonstration of a simple strategy to generate synthetic high-affinity protein capture agents of practical utility for protein-detecting microarrays. The model study highlights capture of the MBP-Mdm2 fusion protein on a solid support by a linear sequence of peptides that bind to the two individual polypeptide chains.