Beta 93 modified hemoglobin: kinetic and conformational consequences.

The reactive sulfhydryl on Cys beta93 in human adult hemoglobin (HbA) has been the focus of much attention. It has purported functional roles such as a transporter of nitric oxide and a detoxifier of super oxide. In addition, it has a proposed role in the allosteric mechanism. The present study addresses the functional and conformational consequences of modifying the beta93 sulfhydryl using either maleimide or disulfide-based reactions. The geminate and bimolecular recombination of CO derivatives of several different beta93-modified Hbs in both solution and sol-gel matrixes provide a window into functional modifications associated with both the R and T states of these proteins. Nanosecond time-resolved visible resonance Raman spectroscopy is used to probe conformational consequences associated with the proximal heme environment. The results show functional and conformational consequences that depend on the specific chemistry used to modify beta93. Maleimide-based modification show the most significant alterations of R-state properties including a consistent pattern of a reduced geminate yield and a loss of the favorable heme-proximal histidine interaction normally seen for liganded R-state HbA. A mechanism based on a displacement of the side chain of Tyr beta145 is explored as a basis for this effect as well as other situations where there is loss of the quaternary enhancement effect. The quaternary enhancement effect refers to the enhancement of ligand binding properties of the alphabeta dimers when they are associated into the R-state tetramer.

Sol-gel trapping of functional intermediates of hemoglobin: geminate and bimolecular recombination studies.

The encapsulation of proteins in porous sol-gels is a promising technique for generating, trapping, and probing functionally significant nonequilibrium protein species. An essential step needed in the pursuit of that goal is establishing the degree to which the sol-gel limits conformational change upon adding or removing substrates. In the present study, geminate recombination and solvent phase bimolecular recombination of CO to human adult hemoglobin (HbA) are used as sensitive probes of the degree of conformational constraint within the sol-gel. Two forms of CO saturated encapsulated HbA are generated. In one case, designated [COHbA], the equilibrium form of COHbA is directly encapsulated. In the second case, designated as [deoxyHbA] + CO, the equilibrium form of deoxyHbA is encapsulated and only after the sample has aged is CO introduced to the HbA through the porous sol-gel matrix. Three different preparative protocols are used to generate the sol-gels for each of the two forms of encapsulated COHbA. The kinetic traces obtained from these encapsulated samples allow for an easy evaluation of the extent to which the sol-gel is locking in the initial tertiary/quaternary structure. The results show that the sol-gel encapsulated samples can be used with pulsed laser sources and that one of the tested encapsulation protocols is far superior with respect to conformational locking. This protocol is used to trap and probe nonequilibrium forms such as the liganded T state of HbA, a species whose properties are needed to fully explore allostery in HbA.