Large-scale functional analysis using peptide or protein arrays.

The array format for analyzing peptide and protein function offers an attractive experimental alternative to traditional library screens. Powerful new approaches have recently been described, ranging from synthetic peptide arrays to whole proteins expressed in living cells. Comprehensive sets of purified peptides and proteins permit high-throughput screening for discrete biochemical properties, whereas formats involving living cells facilitate large-scale genetic screening for novel biological activities. In the past year, three major genome-scale studies using yeast as a model organism have investigated different aspects of protein function, including biochemical activities, gene disruption phenotypes, and protein-protein interactions. Such studies show that protein arrays can be used to examine in parallel the functions of thousands of proteins previously known only by their DNA sequence.

Cystic fibrosis transmembrane conductance regulator: expression and helicity of a double membrane-spanning segment.

The gene responsible for cystic fibrosis encodes a membrane protein--the 1480-residue cystic fibrosis transmembrane conductance regulator (CFTR)--in which membrane-based CF-phenotypic mutants alter pore structure and/or impair ion transport. We report the preparation in milligram quantities and conformational characterization of a polypeptide comprised of CFTR transmembrane (TM) segments 3-4, a putative 'helical hairpin' portion of the CFTR TM1-6 domain. The TM segment 3-4 of CFTR was expressed in E. coli as a fusion protein linked to the C-terminus of His-tagged thioredoxin. Nickel chelate affinity chromatography, followed by release from the carrier by digestion with thrombin protease, gave free CFTR(TM3-4). Monitoring of the folding properties and conformational state(s) of the TM3-4 polypeptide using circular dichroism spectroscopy indicated a partial alpha-helical conformation in aqueous buffer, with up to 30% increase in alpha-helical content observed in membrane-mimetic environments.