We report gas-phase electronic structure calculations on helical peptides that act as scaffolds for imidazole-based hydrogen-bonding networks (proton wires). We have modeled various 21-residue poly-alanine peptides substituted at regular intervals with histidines (imidazole-bearing amino acids), using a combined hybrid approach with a semi-empirical method (AM1) for peptide scaffolds and density functional theory (B3LYP) for proton wires. We have computed energy landscapes including barriers for Grotthuss-shuttling-type proton motions though wires supported on 310-, α- and π-helical structures, showing the 310- and α-helices to be attractive targets in terms of high proton affinities, low Grotthuss shuttling barriers, and high stabilities. Moreover, bias forces provided by the helical dipole moments were found to promote unidirectional proton translocation.

Haemoglobin I from Lucina pectinata is a monomeric protein consisting of 142 amino acids. Its active site contains a peculiar arrangement of phenylalanine residues (PheB10, PheCD1 and PheE11) and a distal Gln at position E7. Active site mutations at positions B10, E7 and E11 were performed in deoxy haemoglobin I (HbI), followed by 10 ns molecular dynamic simulations. The results showed that the mutations induced changes in domains far from the active site producing more flexible structures than the native HbI. Distance analyses revealed that the heme pocket amino acids at positions E7 and B10 are extremely sensitive to any heme pocket residue mutation. The high flexibility observed by the E7 position suggests an important role in the ligand binding kinetics in ferrous HbI, while both positions play a major role in the ligand stabilisation processes. Furthermore, our results showed that E11Phe plays a pivotal role in protein stability.

BACKGROUND: Major histocompatibility complex proteins are believed to undergo significant conformational changes concomitant with peptide binding, but structural characterization of these changes has remained elusive. METHODOLOGY/PRINCIPAL FINDINGS: Here we use molecular dynamics simulations and experimental probes of protein conformation to investigate the peptide-free state of class II MHC proteins. Upon computational removal of the bound peptide from HLA-DR1-peptide complex, the alpha50-59 region folded into the P1-P4 region of the peptide binding site, adopting the same conformation as a bound peptide. Strikingly, the structure of the hydrophobic P1 pocket is maintained by engagement of the side chain of Phe alpha54. In addition, conserved hydrogen bonds observed in crystal structures between the peptide backbone and numerous MHC side chains are maintained between the alpha51-55 region and the rest of the molecule. The model for the peptide-free conformation was evaluated using conformationally-sensitive antibody and superantigen probes predicted to show no change, moderate change, or dramatic changes in their interaction with peptide-free DR1 and peptide-loaded DR1. The binding observed for these probes is in agreement with the movements predicted by the model. CONCLUSION/SIGNIFICANCE: This work presents a molecular model for peptide-free class II MHC proteins that can help to interpret the conformational changes known to occur within the protein during peptide binding and release, and can provide insight into possible mechanisms for DM action.

The distal pocket of hemoglobin II (HbII) from Lucina pectinata is characterized by the presence of a GlnE7 and a TyrB10. To elucidate the functional properties of HbII, biophysical studies were conducted on HbII and a HbI PheB10Tyr site-directed mutant. The pH titration data at neutral conditions showed visible bands at 486, 541, 577 and 605 nm for both proteins. This suggests the possible existence of a conformational equilibrium between an open and closed configuration due to the interactions of the TyrB10, ligand, and heme iron. The kinetic behavior for the reaction of both ferric proteins with H2O2 indicates that the rate for the formation of the ferryl intermediates species varies with pH, suggesting that the reaction is strongly dependent on the conformational states. At basic pH values, the barrier for the reaction increases as the tyrosine adopts a closed conformation and the ferric hydroxyl replaces the met-aquo species. The existence of these conformers is further supported by resonance Raman (RR) data, which indicate that in a neutral environment, the ferric HbII species is present as a possible mixture of coordination and spin states, with values at 1558 and 1580 cm(-1) for the nu2 marker, and 1479, 1492, and 1503 cm(-1) for the nu3 mode. Moreover, the presence of the A3 and A(o) conformers at 1924 and 1964 cm(-1) in the HbII-CO infrared spectra confirms the existence of an open and closed conformation due to the orientation of the TyrB10 with respect to the heme active center.

Ferryl compounds [Fe(IV)=O] in living organisms play an essential role in the radical catalytic cycle and degradation processes of hemeproteins. We studied the reactions between H(2)O(2) and hemoglobin II (HbII)(GlnE7, TyrB10, PheCD1, PheE11), recombinant hemoglobin I (HbI)(GlnE7, PheB10, PheCD1, PheE11), and the HbI PheB10Tyr mutant of L. pectinata. We found that the tyrosine residue in the B10 position tailors, in two very distinct ways, the reactivity of the ferryl species, compounds I and II. First, increasing the reaction pH from 4.86 to 7.50, and then to 11.2, caused the the second-order rate constant for HbII to decrease from 141.60 to 77.78 M(-1) s(-1), and to 2.96 M(-1) s(-1), respectively. This pH dependence is associated with the disruption of the heme-tyrosine (603 nm) protein moiety, which controls the access of the H(2)O(2) to the hemeprotein active center, thus regulating the formation of the ferryl species. Second, the presence of compound I was evident in the UV-vis spectra (648-nm band) in the reactions of HbI and recombinant HbI with H(2)O(2), This band, however, is completely absent in the analogous reaction with HbII and the HbI PheB10Tyr mutant. Therefore, the existence of a hydrogen-bonding network between the heme pocket amino acids (i.e., TyrB10) and the ferryl compound I created a path much faster than 3.0x10(-2) s(-1) for the decay of compound I to compound II. Furthermore, the decay of the heme ferryl compound I to compound II was independent of the proximal HisF8 trans-ligand strength. Thus, the pH dependence of the heme-tyrosine moiety complex determined the overall reaction rate of the oxidative reaction limiting the interaction with H(2)O(2 )at neutral pH. The hydrogen-bonding strength between the TyrB10 and the heme ferryl species suggests the presence of a cycle where the ferryl consumption by the ferric heme increases significantly the pseudoperoxidase activity of these hemeproteins.