Perturbations of aromatic amino acids are associated with iron cluster assembly in ribonucleotide reductase

The β2 subunit of class Ia ribonucleotide reductases (RNR) contains an antiferromagnetically coupled μ-oxo bridged diiron cluster and a tyrosyl radical (Y122•). In this study, an ultraviolet resonance Raman (UVRR) difference technique describes the structural changes induced by the assembly of the iron cluster and by the reduction of the tyrosyl radical. Spectral contributions from aromatic amino acids are observed through UV resonance enhancement at 229 nm. Vibrational bands are assigned by comparison to histidine, phenylalanine, tyrosine, tryptophan, and 3-methylindole model compound data and by isotopic labeling of histidine in the β2 subunit. Reduction of the tyrosyl radical reveals Y122• Raman bands at 1499 and 1556 cm(-1) and Y122 Raman bands at 1170, 1199, and 1608 cm(-1). There is little perturbation of other aromatic amino acids when Y122• is reduced. Assembly of the iron cluster is shown to be accompanied by deprotonation of histidine. A p(2)H titration study supports the assignment of an elevated pK for the histidine. In addition, structural perturbations of tyrosine and tryptophan are detected. For tryptophan, comparison to model compound data suggests an increase in hydrogen bonding and a change in conformation when the iron cluster is removed. pH and (2)H(2)O studies imply that the perturbed tryptophan is in a low dielectric environment that is close to the metal center and protected from solvent exchange. Tyrosine contributions are attributed to a conformational or hydrogen-bonding change. In summary, our work shows that electrostatic and conformational perturbations of aromatic amino acids are associated with metal cluster assembly in RNR. These conformational changes may contribute to the allosteric effects, which regulate metal binding.

Raman structural markers of tryptophan and histidine side chains in proteins

The Raman spectrum of a protein contains a wealth of information on the structure and interaction of the protein. To extract the structural information from the Raman spectrum, it is necessary to identify and interpret the marker bands that reflect the structure and interaction in the protein. Recently, new Raman structural markers have been proposed for the tryptophan and histidine side chains by examining the spectra-structure correlations of model compounds. Raman structural markers are now available for the conformation, hydrogen bonding, hydrophobic interaction, and cation-pi interaction of the indole ring of Trp. For His, protonation, tautomerism, and metal coordination of the imidazole ring can be studied by using Raman markers. The high-resolution X-ray crystal structures of proteins provide the basis for testing and modifying the Raman structural markers of Trp and His. The structures derived from Raman spectra are generally consistent with the X-ray crystal structures, giving support for the applicability of most Raman structural makers. Possible modifications and limitations to some marker bands are also discussed.

Assignment of the 1511 cm(-1) UV resonance Raman marker band of hemoglobin to tryptophan

New UV resonance Raman (UVRR) data provide convincing evidence that a characteristic 1511 cm(-1) band in the T - R difference spectra of hemoglobin is due to the overtone of the Trp W18 fundamental at 756 cm(-1). Measured isotope shifts for 2-H and 15-N substitution at the indole NH group are twice as large for the 1511 cm(-1) band as for W18, and the 1511 cm(-1) intensity scales with that of W18 in the difference spectrum. Moreover, the UVRR excitation profile of the 1511 cm(-1) band tracks that of another tryptophan band, W16. Both are redshifted in hemoglobin, relative to aqueous tryptophan, reflecting H bonding within a hydrophobic environment in the protein. The 2xW18 assignment had been thrown into question by the observation of remnant 1511 cm(-1) intensity in the T - R spectra of hemoglobin labeled with tryptophan-d(5), a substitution that shifts W18 over 50 cm(-1). However, reexamination of the data suggests that this remnant intensity may result from a subtraction artifact arising from the downshift of another difference band, W3, from 1549 cm(-1) in unlabeled protein to 1522 cm(-1) in labeled protein. Restoration of the 2xW18 assignment establishes that the 1511 cm(-1) difference band, which is a useful indicator of the extent of T-state formation in hemoglobin, arises from the same residue, Trpbeta37, that gives rise to essentially all of the T - R signal from tryptophan.