The active site of the oxygen-avid truncated hemoglobin from Bacillus subtilis has been characterized by infrared absorption and resonance Raman spectroscopies, and the dynamics of CO rebinding after photolysis has been investigated by picosecond transient absorption spectroscopy. Resonance Raman experiments on the CO bound adduct revealed the presence of two Fe-CO stretching bands at 545 and 520 cm-1, respectively. Accordingly, two C-O stretching bands at 1924 and 1888 cm-1 were observed in infrared absorption and resonance Raman measurements. The very low C-O stretching frequency at 1888 cm-1 (corresponding to the extremely high RR stretching frequency at 545 cm-1) indicates unusually strong hydrogen bonding between CO and distal residues. On the basis of a comparison with other truncated hemoglobin it is envisaged that the two CO conformers are determined by specific interactions with the TrpG8 and TyrB10 residues. Mutation of TrpG8 to Leu deeply alters the hydrogen-bonding network giving rise mainly to a CO conformer characterized by a Fe-CO stretching band at 489 cm-1 and a CO stretching band at 1958 cm-1. Picosecond laser photolysis experiments carried out on the CO bound adduct revealed dynamical processes that take place within a few nanoseconds after photolysis. Picosecond dynamics is largely dominated by CO geminate rebinding and is consistent with strong H-bonding contributions of TyrB10 and TrpG8 to ligand stabilization.
Pyridoxal 5′‐phosphate‐dependent enzymes may be grouped into five structural superfamilies of proteins, corresponding to as many fold types. The fold type I is by far the largest and most investigated group. An important feature of this fold, which is characterized by the presence of two domains, appears to be the existence of three clusters of evolutionarily conserved hydrophobic contacts. Although two of these clusters are located in the central cores of the domains and presumably stabilize their scaffold, allowing the correct alignment of the residues involved in cofactor and substrate binding, the role of the third cluster is much less evident. A site‐directed mutagenesis approach was used to carry out a model study on the importance of the third cluster in the structure of a well characterized member of the fold type I group, serine hydroxymethyltransferase from Escherichia coli. The experimental results obtained indicated that the cluster plays a crucial role in the stabilization of the quaternary, native assembly of the enzyme, although it is not located at the subunit interface. The analysis of the crystal structure of serine hydromethyltransferase suggested that this stabilizing effect may be due to the strict structural relation between the cluster and two polypeptide loops, which, in fold type I enzymes, mediate the interactions between the subunits and are involved in cofactor binding, substrate binding and catalysis.
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