Tryptophan-containing alpha-subunits of the Escherichia coli tryptophan synthase. Enzymatic and urea stability properties.

Early studies suggested that the Escherichia coli tryptophan synthase alpha-subunit unfolded in a two-step process in which there was a stable intermediate composed of a native alpha-1 folding unit (residues 1-188) and a completely unfolded alpha-2 folding unit (residues 189-268). More recent evidence has indicated that such a structure for the intermediate seems unlikely. In this report, single Trp residues (absent in the wild-type alpha-subunit) are substituted separately for Phe residues at positions 139 (in alpha-1) and 258 (in alpha-2) to produce the F139W, F258W, and F139W/F258W mutant alpha-subunits. The UV absorbance and fluorescence properties of the F139W/F258W double mutant are identical with those of equimolar mixtures of the single mutants, suggesting that the Trp residue at each position can independently report the behavior of its respective folding unit. Each mutant alpha-subunit is wild-type enzymatically, and when UV absorbance is monitored, the urea-induced unfolding of the three tryptophan-containing alpha-subunits is virtually identical to the wild-type protein. These wild-type properties make these proteins attractive candidates for a fluorescence examination of the behavior of the individual folding units and the structure of potential intermediate(s) and as host proteins for the insertion of our existing destabilizing and/or stabilizing mutational alterations.

Crystal structure of Azotobacter cytochrome c5 at 2.5 A resolution.

The crystal structure of cytochrome c5 from Azotobacter vinelandii has been solved and refined to an R value of 0.29 at 2.5 A resolution. The structure of the oxidized protein was solved using a monoclinic crystal form. The structure was solved by multiple isomorphous replacements, re-fit to a solvent-leveled multiple isomorphous replacement map, and refined by restrained least squares. The structure reveals monomers associated about the crystallographic 2-fold axis by hydrophobic contacts at the "exposed heme edge". The overall conformation for the monomer is similar to that of Pseudomonas aeruginosa cytochrome c551. However, relative to a common heme conformation, c5 and c551 differ by an average of 6.8 A over 82 alpha-carbon positions and the propionates of c5 are much more exposed to solvent. The shortest heme--heme contact at the "dimer" interface is 6.3 A (Fe to Fe 16.4 A). Alignment of c5 and c551 shows that the two cytochromes, in spite of sequence differences, have remarkably similar charge distributions. A disulfide stacks on a tyrosine between the N- and C-terminal helices.