The oxidative denitrosylation mechanism and nitric oxide release from human fetal and adult hemoglobin, an experimentally based model simulation study.

Generation of unbound nitric oxide (NO) via the oxidative denitrosylation (ODN) mechanism is proposed to involve the simultaneous reaction of nitrite with oxy and deoxy hemoglobin (Hb(O2) (k1) and Hb (k13)) to yield respectively, *NO2 and Hb(+2)(NO). These two reaction pathways are coupled when *NO2 reacts with Hb(+2)(NO) to yield Hb(+3)(NO) (k22), a species that releases NO rapidly. Here, I have constructed an experimentally based molecular model of the ODN mechanism (k1-k31), focusing on the high nitrite reductase activity of R-state hemoglobin.

Reaction of nitrite with human fetal oxyhemoglobin: a model simulation study with implications for blood flow regulation in sickle cell disease (SCD).

Nitrite can react in parallel with adult oxy- and deoxy-hemoglobin (HbA), resulting in oxidative denitrosylation of nitrosyl-hemoglobin and rapid dissociation of nitric oxide. Here, simulation studies are presented using a new model to analyze data in the literature comparing the reaction of nitrite with isolated human oxy-HbA, oxy-fetal hemoglobin (oxy-HbF) and oxy-Hb Bart's (a gamma-chain tetramer). The results show that the kinetic constant at the rate-limiting step is 25-fold larger for the reaction of human oxy-HbF, and 63-fold larger for oxy-Hb Bart's both compared to oxy-HbA.

Kinetic evidence for modulation by glycophorin A of a conformational equilibrium between two states of band 3 (SLC4A1) bound reversibly by the competitive inhibitor DIDS.

Recent evidence has suggested that erythrocytes naturally deficient in glycophorin A (GPA) have a reduced V(max) for monovalent anion exchange. Unanswered is whether miss-folding of band 3 during biosynthesis, or the absence of GPA modulation of properly folded band 3 is responsible. Here, I determine the effect of selective depletion of GPA on the kinetics of reversible binding of the competitive transport inhibitor DIDS (4,4'-diisothiocyanato-2,2'-stilbenedisulfonate) to properly folded band 3.

Kinetics of reaction of nitrite with deoxy hemoglobin after rapid deoxygenation or predeoxygenation by dithionite measured in solution and bound to the cytoplasmic domain of band 3 (SLC4A1).

The reaction of deoxyhemoglobin with nitrite was characterized in the presence of dithionite using hemoglobin in solution or bound to the cytoplasmic domain of band 3 (CDB3). Deoxyhemoglobin was generated by predeoxygenation (nitrogen flushing followed by addition of dithionite), or transiently, by rapidly mixing oxyhemoglobin with nitrite and dithionite simultaneously. Wavelength-dependent kinetic studies confirmed the formation of nitrosyl hemoglobin.

Band 3 (AE1, SLC4A1)-mediated transport of stilbenedisulfonates. III: Role of solute and protein structure in proton-activated stilbenedisulfonate influx.

DBDS (4,4'-dibenzamido-2,2'-stilbenedisulfonate) influx into magnesium resealed ghosts (MRSG) occurs over the anion/proton co-transport pH range (pK approximately 5.0). Here, factors are studied which may influence the pH dependence of DBDS transport.

Band 3 (AE1, SLC4A1)-mediated transport of stilbenedisulfonates. I: Functional identification of the proton-activated stilbenedisulfonate influx site.

Stilbenedisulfonates (SD) bind to a "primary" SD (PSD) site on the outer membrane surface of band 3, and inhibit anion exchange (AE) allosterically. Yet, evidence [Membr. Biochem.

Band 3 (AE1, SLC4A1)-mediated transport of stilbenedisulfonates. II: Evidence for transmembrane allosteric interactions between the "primary" stilbenedisulfonate binding site and the stilbenedisulfonate efflux site.

Results from the first paper in this series indicated that the "primary" stilbenedisulfonate (PSD) site was not located on the DBDS (4, 4'-dibenzamido-2, 2'-stilbenedisulfonate) transport pathway into magnesium resealed ghosts (MRSG). Rather, transport correlated with DBDS binding to the "second" class of proton-activated binding sites located on the membrane domain of band 3 [Biochem. J.

Identification and characterization of a second 4,4'-dibenzamido-2,2'-stilbenedisulphonate (DBDS)-binding site on band 3 and its relationship with the anion/proton co-transport function.

Band 3 mediates both electroneutral AE (anion exchange) and APCT (anion/proton co-transport). Protons activate APCT and inhibit AE with the same pK (approximately 5.0).

Slow transitions between two conformational states of band 3 (AE1) modulate divalent anion transport and DBDS binding to a second site on band 3 which is activated by lowering the pH (pK approximately 5.0).

Evidence is emerging which indicates that the anion transport activity of band 3 may be regulated. I review the molecular basis for regulation of the anion transport function of band 3 in terms of evidence showing that divalent anion transport involves a slow "hysteretic" transition between two functional states, mediated by interactions between subunits within band 3 oligomers. In addition, I briefly describe recent work from my laboratory where we have discovered a novel manifestation of slow conformational changes in band 3.

The carboxyl side chain of glutamate 681 interacts with a chloride binding modifier site that allosterically modulates the dimeric conformational state of band 3 (AE1). Implications for the mechanism of anion/proton cotransport.

Glutamate 681 is thought to be located within the transport channel of band 3 (AE1, the chloride/bicarbonate exchanger), where it acts as a proton donor for the anion/proton cotransport function. Here we show that neutralization of the negative charge on glutamate 681 by chemically modifying band 3 with Woodward's reagent K plus sodium borohydride (i.e.