Modulation of ligand binding in engineered human hemoglobin distal pocket.

Functional and structural studies on hemoglobin and myoglobin from different animals and engineered variants have enlightened the great importance of the physico-chemical properties of the side-chains at topological position B10 and E7. These residues proved to be crucial to the discrimination and stabilisation of gaseous ligands. In view of the data obtained on the high oxygen affinity hemoglobin from Ascaris worms and a new mutant of sperm whale myoglobin, we selected the two mutations Leu B10-->Tyr and His E7-->Gln as potentially relevant to control ligand binding parameters in the alpha and beta-chains of human hemoglobin. Here, we present an investigation of three new mutants: HbalphaYQ (alpha2YQbeta2A), HbbetaYQ (alpha2Abeta2YQ) and HbalphabetaYQ (alpha2YQbeta2YQ). They are characterised by a very low reactivity for NO, O2 and CO, and a reduced cooperativity. Their functional properties are not inconsistent with the behaviour expected for a two-state allosteric model. Proteins with these substitutions may be considered as candidates for the synthesis of a possible "blood substitute", which should yield an O2 adduct stable to autoxidation and slowly reacting with NO. The mutant HbalphabetaYQ is particularly interesting because the rate of reaction of NO with the oxy and deoxy derivatives is reduced. A structural interpretation of our data is presented based on the 3D structure of deoxy HbalphabetaYQ determined by crystallography at 1.8 A resolution.

Intermediates in the catalytic cycle of lentil (Lens esculenta) seedling copper-containing amine oxidase.

Spectrophotometry and rapid-scanning stopped-flow spectroscopy have been used to investigate the visible absorbance changes that occur in the course of the reduction of lentil (Lens esculenta) seedling amine oxidase by substrate. The catalytic cycle of the enzyme employs several intermediates but, owing to kinetic limitations, some of them were not identified in previous studies. In this study we have examined several substrates, either rapidly reacting (e.g. putrescine) or slowly reacting (e.g. gamma-aminobutanoic acid). Two forms of the enzyme, namely the Cu(I)-aminoresorcinol and quinone ketimine derivatives, whose characterization was elusive in previous studies, have been identified and assigned an optical spectrum. Moreover the reduced form of the enzyme is shown to be an equilibrium mixture of two species, the Cu(I)-semiquinolamine radical and Cu(II)-aminoresorcinol; these have been resolved by pH dependence and assigned spectra as well as a second-order rate constant for the reaction with oxygen. Thus the results presented here identify all the catalytic intermediates suggested by the chemical nature of the coenzyme and define their spectroscopic and reactivity properties.

The unusual stability of saporin, a candidate for the synthesis of immunotoxins.

Saporin, a monomeric protein extracted from the seeds of Saponaria officinalis, is an enzyme capable of specific depurination of the eukaryotic ribosomes. Because of its toxicity, saporin proved useful for the synthesis of immunotoxins, chimeric conjugates of a toxin and an antibody specifically directed against cancer cells or other targets. In this paper we report a study of the structural properties of saporin in the presence of denaturing agents and/or proteolytic enzymes. We found that saporin is extremely resistant to denaturation by urea or guanidine (up to 4 M), even at relatively high temperature (up to 55 degrees C). Moreover a structural change detected as a reduction of the fluorescence emission of the single Trp residue is reversible and is not paralleled by changes of the far UV CD spectrum, suggesting that even under harsh experimental conditions unfolding is limited. In good agreement with these results, guanidine-treated saporin is not attacked by proteolytic enzymes. The remarkable resistance of saporin to denaturation and proteolysis suggests this protein as an ideal candidate for biotechnological applications.