Molecular complexes of four monoclonal anti-morphine antibodies (mAb) with the opiate ligands morphine, oxymorphone, and naloxone were studied using UV-VIS absorption spectroscopy. Although strong overlaps in the absorption spectra of the antibodies, ligands, and complexes were observed, a curve-fitting method was developed to correlate the absorbance with the concentration of the ligand-antibody complex. Using this technique, we determined the intrinsic association constants for the mAb with morphine to be in the nanomolar range, while association constants for oxymorphone and naloxone were in the micromolar range. These values were found to be in agreement with previous radioimmunoassay determinations. We also observed different changes in the absorbancy of the mAb upon complexation with different ligands and such changes were found to be different for all four mAb examined. Upon complexation with the ligand morphine, two of the mAb (clone numbers MOR368-21 and MOR10.5) displayed distinct charge-transfer spectral bands in the 320-nm region. These observations suggest that mAb binding site tryptophans may participate in the formation of the antibody-ligand complex and such complexation involves a charge-transfer interaction.
Molecular complexation between a set of five monoclonal antibodies (MAbs) and a N,N',N"-trisubstituted guanidinium sweetener (TGS) was studied by monitoring the intrinsic fluorescence of the MAbs. Changes in the emission spectral properties of the MAbs were found to be related to the location of tryptophan residues in the antibody complementarity determining regions (CDRs). Two of the MAbs, NC10.10 and NC10.8, showed fluorescence quenching and hypsochromic (blue) shifts in the emission maxima upon complexation with the TGS ligand. Experiments with three other MAbs, NC10.1, NC6.8 and NC2.3, revealed only monotonic fluorescence quenching. The association constants obtained by spectroscopic techniques for the different MAb-TGS complexes were found to be comparable with those determined using a conventional RIA. The thermodynamic parameters of the MAb-TGS complexation were also examined. The intermolecular complexation was found to be exothermic for four of the five MAbs in this study. However, MAb NC2.3 was found to be an exception, in that it was associated with a small positive enthalpic change. This type of spectrofluorimetric analysis can aid in the identification of interactive residues and molecular dynamics involved in TGS recognition by this set of MAb. Such information may prove useful in understanding the molecular recognition motifs responsible for the intense taste properties of high potency guanidine sweeteners.
Dithionite is often used to deoxygenate aqueous solutions because it reacts readily with oxygen. However, milder reducing agents, that do not ordinarily react readily with oxygen, may do so in the presence of an appropriate redox catalyst. We show that dithiothreitol reacts rapidly with oxygen in concentrated hemoglobin solutions to produce a mixture of deoxy-, met- and sulf-hemoglobin. The reaction in neutral phosphate buffer is not significantly affected by superoxide dismutase, benzoate or EDTA. However, addition of catalase or horseradish peroxidase decreases the proportions of met- and sulf-hemoglobin produced. We conclude that both hemoglobin and horse radish peroxidase accept dithiothreitol as the reducing substrate in heme catalyzed reactions with their respective oxidizing substrates (dioxygen and hydrogen peroxide). As a result, deoxy-hemoglobin suitable for physical studies can be prepared with a combination of a stoichiometric excess of dithiothreitol and a catalytic amount of horse radish peroxidase.
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