The N-terminal region of the transmembrane domain of human erythrocyte band 3. Residues critical for membrane insertion and transport activity

We studied the role of the N-terminal region of the transmembrane domain of the human erythrocyte anion exchanger (band 3; residues 361-408) in the insertion, folding, and assembly of the first transmembrane span (TM1) to give rise to a transport-active molecule. We focused on the sequence around the 9-amino acid region deleted in Southeast Asian ovalocytosis (Ala-400 to Ala-408), which gives rise to nonfunctional band 3, and also on the portion of the protein N-terminal to the transmembrane domain (amino acids 361-396). We examined the effects of mutations in these regions on endoplasmic reticulum insertion (using cell-free translation), chloride transport, and cell-surface movement in Xenopus oocytes. We found that the hydrophobic length of TM1 was critical for membrane insertion and that formation of a transport-active structure also depended on the presence of specific amino acid sequences in TM1. Deletions of 2 or 3 amino acids including Pro-403 retained transport activity provided that a polar residue was located 2 or 3 amino acids on the C-terminal side of Asp-399. Finally, deletion of the cytoplasmic surface sequence G(381)LVRD abolished chloride transport, but not surface expression, indicating that this sequence makes an essential structural contribution to the anion transport site of band 3.     

The functional role of arginine 901 at the C-terminus of the human anion transporter band 3 protein

To determine which arginine residues are responsible for band 3-mediated anion transport, we analyzed hydroxyphenylglyoxal (HPG)-modified band 3 protein in native erythrocyte membranes. HPG-modification leads to inhibition of the transport of phosphoenolpyruvate, a substrate for band 3-mediated transport. We analyzed the HPG-modified membranes by reverse phase-HPLC, and determined that arginine 901 was modified by HPG. To determine the role of Arg 901 in the conformational change induced by anion exchange, we analyzed HPG-modification of the membranes when 4,4'-dinitrostilbene-2,2'-disulfonic acid (DNDS) or diethypyrocarbonate (DEPC) was present. DNDS and DEPC fix band 3 in the outward and inward conformations, respectively. HPG-modification was unaffected in the presence of DEPC but decreased in the presence of DNDS. In addition to that, 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid (DIDS), which specifically reacts with the outward conformation of band 3, did not react with HPG-modified membranes. Furthermore, we expressed a band 3 mutant in which Arg 901 was replaced by alanine (R901A) on yeast membranes. The kinetic parameters indicated that the R901A mutation affected the rate of conformational change of the band 3 protein. From these results, we conclude that the most C-terminal arginine, Arg 901, has a functional role in the conformational change that is necessary for anion transport.     

Anion-proton cotransport through the human red blood cell band 3 protein. Role of glutamate 681.

The band 3 protein of the human red blood cell membrane contains a glutamate residue that must be protonated in order for divalent (SO4=) anion transport to take place at an appreciable rate. The carboxyl side chain on this glutamate residue can be converted to the primary alcohol by treatment of intact cells with Woodward's reagent K (N-ethyl-5-phenylisoxazolium 3'-sulfonate) followed by reductive cleavage with BH4-. Edman degradation of CNBr fragments from band 3 labeled in intact cells with Woodward's reagent K and [3H]BH4- showed that Glu681 is heavily labeled under conditions in which Cl- exchange is inhibited, SO4= exchange is accelerated, and Cl- conductance is accelerated. No other glutamate residue in band 3 is detectably labeled under the conditions of these experiments, as demonstrated either by Edman degradation or by the lack of label in major known proteolytic fragments. It is concluded that Glu681 is the binding site for the H+ that is transported with SO4= during band 3-catalyzed H+/SO4= cotransport. This residue is conserved among all species of red cell band 3 (AE1) as well as the related proteins AE2 and AE3. Glu681 is the first amino acid residue in band 3 which has been identified as a binding site for a transported substrate (H+). The functional characteristics of this residue suggest that it lies within the transport pathway and can be alternately exposed to the intracellular and extracellular media.     

Fatty acid composition of lipids which copurify with band 3

In a previous study (L. R. Maneri and P. S. Low (1988) J. Biol. Chem. 263, 16170-16178) we determined that the anion transport protein, band 3, was significantly stabilized by lipids containing saturated and/or long chain fatty acids. To determine whether this thermodynamic preference is reflected in the composition of lipids tightly associating with the anion transporter in vivo, we have analyzed the fatty acid content of phospholipids co-isolating with the purified integral domain of band 3. Our data demonstrate that although stearic acid comprises only 14% of the bulk lipid fatty acids of the red cell membrane, it constitutes -68% of the fatty acids of lipids co-isolating with band 3. Certain other long chain fatty acids were also enriched in the adherent lipids. These results suggest that the fatty acids which most effectively stabilize band 3 also have the highest affinity for the transport protein.     

Immunological evidence that band 3 is the major glucose transporter of the human erythrocyte membrane

We have previously reported that human erythrocyte band 3 contains 90-95% of the reconstitutable glucose transport activity of the erythrocyte membrane (Shelton, R.L. and Langdon, R.G. (1983) Biochim. Biophys. Acta 733, 25-33). We have now found that monoclonal and polyclonal antibodies to epitopes on band 3 specifically removed band 3 and more than 90% of the reconstitutable glucose transport activity from unfractionated octylglucoside extracts of erythrocyte membranes; nonimmune serum removed neither. Western blots of whole membrane extracts revealed that the polyclonal antibody to band 4.5 used to isolate cDNA clones presumed to code for the transporter (Mueckler, M., Caruso, C., Baldwin, C.A., Pancio, M., Blench, J., Morris, H.B., Allard, W.J., Lienhard, G.E. and Lodish, H.F. (1985) Science 229, 941-945) reacts strongly with six discrete bands in the 4.5 region. A monoclonal antibody to band 3 also reacts with a Mr 55,000 component of band 4.5. We conclude that band 3 contains the major glucose transporter of human erythrocytes, and that the transport activity in band 4.5 might be attributable to a band 3 fragment. Band 3 is probably a multifunctional transport protein responsible for transport of glucose, anions, and water.     

Use of niflumic acid to determine the nature of the asymmetry of the human erythrocyte anion exchange system

Niflumic acid is a noncompetitive inhibitor of chloride exchange, which binds to a site different from the transport or modifier sites. When the internal Cl- concentration is raised, at constant extracellular Cl- , the inhibitory potency of niflumic acid increases. This effect cannot be attributed to changes in membrane potential, but rather it suggests that niflumic acid binds to the anion exchange protein band 3 only when the transport site faces outward. When the chloride gradient is reversed, with Clo greater than Cli , the inhibitory potency of niflumic acid decreases greatly, which indicates that the affinity of niflumic acid for band 3 with the transport site facing inward is almost 50 times less than when the transport site faces outward. Experiments in which Cli = Clo show no significant change in the inhibition by niflumic acid when Cl- is lowered from 150 to 10 mM. These data suggest that the intrinsic dissociation constants for Cl- at the two sides of the membrane are nearly equal. Thus, the chloride- loaded transport sites have an asymmetric orientation like that of the unloaded transport sites, with approximately 15 times more sites facing the inside than the outside. The asymmetry reflects an approximately 1.5 kcal/mol free energy difference between the inward-facing and outward-facing chloride-loaded forms of band 3. High concentrations of chloride (with Cli = Clo), which partially saturate the modifier site, have no effect on niflumic acid inhibition, which indicates that chloride binds equally well to the modifier site regardless of the orientation of the transport site.     

Distinct regions of human glycophorin A enhance human red cell anion exchanger (band 3; AE1) transport function and surface trafficking

Human red cell glycophorin A (GPA) enhances the expression of band 3 anion transport activity at the cell surface of Xenopus oocytes. This effect of GPA could occur in two ways, enhancement of band 3 anion transport function or enhancement of band 3 trafficking to the cell surface. We have examined the GPA effect using GPA mutants. We compared the sequences of GPA and its homolog glycophorin B (GPB; which does not facilitate band 3 cell-surface activity or trafficking) to identify candidate regions of GPA for study. We constructed several GPA or GPB mutants, including naturally occurring GPA/GPB hybrid molecules and insertion, deletion, and substitution mutants. We analyzed the effects of the mutant proteins on band 3-specific chloride transport and surface presentation using co-expression in Xenopus oocytes. We find that the C-terminal cytoplasmic tail of GPA enhances trafficking of band 3 to the cell surface, whereas the extracellular residues 68-70 increase the specific anion transport activity of band 3. In addition, examination of the oligomerization of GPA mutants showed that single amino acid substitutions N-terminal to the transmembrane domain greatly reduce SDS-stable GPA dimer formation, implying that regions outside the transmembrane domain of GPA are important for GPA dimer formation.     

Identification and characterization of a Na(+)-independent neutral amino acid transporter that associates with the 4F2 heavy chain and exhibits substrate selectivity for small neutral D- and L-amino acids

A cDNA was isolated from the mouse brain that encodes a novel Na(+)-independent neutral amino acid transporter. The encoded protein, designated as Asc-1 (asc-type amino acid transporter 1), was found to be structurally related to recently identified mammalian amino acid transporters for the transport systems L, y(+)L, x(C)(-), and b(0,+), which are linked, via a disulfide bond, to the type II membrane glycoproteins, 4F2 heavy chain (4F2hc), or rBAT (related to b(0,+) amino acid transporter). Asc-1 required 4F2hc for its functional expression. In Western blot analysis in the nonreducing condition, a 118-kDa band, which seems to correspond to the heterodimeric complex of Asc-1 and 4F2hc, was detected in the mouse brain. The band shifted to 33 kDa in the reducing condition, confirming that Asc-1 and 4F2hc are linked via a disulfide bond. Asc-1-mediated transport was not dependent on the presence of Na(+) or Cl(-). Although Asc-1 showed a high sequence homology (66% identity at the amino acid level) to the Na(+)-independent broad scope neutral amino acid transporter LAT2 (Segawa, H., Fukasawa, Y., Miyamoto, K., Takeda, E., Endou, H., and Kanai, Y. (1999) J. Biol. Chem. 274, 19745-19751), Asc-1 also exhibited distinctive substrate selectivity and transport properties. Asc-1 preferred small neutral amino acids such as Gly, L-Ala, L-Ser, L-Thr, and L-Cys, and alpha-aminoisobutyric acid as substrates. Asc-1 also transported D-isomers of the small neutral amino acids, in particular D-Ser, a putative endogenous modulator of N-methyl-D-aspartate-type glutamate receptors, with high affinity. Asc-1 operated preferentially, although not exclusively, in an exchange mode. Asc-1 mRNA was detected in the brain, lung, small intestine, and placenta. The functional properties of Asc-1 seem to be consistent with those of a transporter subserving the Na(+)-independent small neutral amino acid transport system asc.     

Selective phenylglyoxalation of functionally essential arginyl residues in the erythrocyte anion transport protein

The red cell anion transport protein, band 3, can be selectively modified with phenylglyoxal, which modifies arginyl residues (arg) in proteins, usually with a phenylglyoxal: arg stoichiometry of 2:1. Indiscriminate modification of all arg in red cell membrane proteins occurred rapidly when both extra- and intracellular pH were above 10. Selective modification of extracellularly exposed arg was achieved when ghosts with a neutral or acid intracellular pH were treated with phenylglyoxal in an alkaline medium. The rate and specificity of modification depend on the extracellular chloride concentration. At 165 mM chloride maximum transport inactivation was accompanied by the binding of four phenylglyoxals per band 3 molecule. After removal of extracellular chloride, maximum transport inhibition was accompanied by the incorporation of two phenylglyoxals per band 3, which suggests that transport function is inactivated by the modification of a single arg. After cleavage of band 3 with extracellular chymotrypsin, [14C]phenylglyoxal was located almost exclusively in a 35,000-dalton peptide. In contrast, the primary covalent binding site of the isothiocyanostilbenedisulfonates is a lysyl residue in the second cleavage product, a 65,000-dalton fragment. This finding supports the view that the transport region of band 3 is composed of strands from both chymotryptic fragments. The binding of phenylglyoxal and the stilbene inhibitors interfered with each other. The rate of phenylglyoxal binding was reduced by a reversibly binding stilbenedisulfonate (DNDS), and covalent binding of [3H]DIDS to phenylglyoxal-modified membranes was strongly delayed. At DIDS concentrations below 10 10 micrometers, only 50% of the band 3 molecules were labeled with [3H]-DIDS during 90 min at 38 degrees C, thereby demonstrating an interaction between binding of the two inhibitors to the protomers of the oligomeric band 3 molecules.     

The binding of Ca2+ to solubilized band 3 protein of the human erythrocyte membrane

The binding of 45Ca2+ to isolated band 3 protein, the anion transport protein of the human erythrocyte membrane, was studied by equilibrium dialysis. The protein was solubilized and purified by either the nonionic detergent Ammonyx-L0 or acetic acid. Each preparation of band 3 protein showed a single high-affinity Ca2+ binding site and several Ca2+ binding sites of lower affinity. The association constant of the high-affinity site was 4-13 X 10(4)M-1; it was only moderately dependent on ionic strength. Mg2+ effectively competed with Ca2+ for the site. Anion exchange across the human erythrocyte membrane is inhibited by micromolar concentrations of intracellular Ca2+. Our results suggest that this inhibition is due to the binding of the cation to a single site on band 3 protein.     

Chemical modification and labeling of glutamate residues at the stilbenedisulfonate site of human red blood cell band 3 protein

A new method has been developed for the chemical modification and labeling of carboxyl groups in proteins. Carboxyl groups are activated with Woodward's reagent K (N-ethyl-5-phenylisoxazolium 3'-sulfonate), and the adducts are reduced with [3H]BH4. The method has been applied to the anion transport protein of the human red blood cell (band 3). Woodward's reagent K is a reasonably potent inhibitor of band 3-mediated anion transport; a 5-min exposure of intact cells to 2 mM reagent at pH 6.5 produces 80% inhibition of transport. The inhibition is a consequence of modification of residues that can be protected by 4,4'-dinitrostilbene-2,2'-disulfonate. Treatment of intact cells with Woodward's reagent K followed by B3H4 causes extensive labeling of band 3, with minimal labeling of intracellular proteins such as spectrin. Proteolytic digestion of the labeled protein reveals that both the 60- and the 35-kDa chymotryptic fragments are labeled and that the labeling of each is inhibitable by stilbenedisulfonate. If the reduction is performed at neutral pH the major labeled product is the primary alcohol corresponding to the original carboxylic acid. Liquid chromatography of acid hydrolysates of labeled affinity-purified band 3 shows that glutamate but not aspartate residues have been converted into the hydroxyl derivative. This is the first demonstration of the conversion of a glutamate carboxyl group to an alcohol in a protein. The labeling experiments reveal that there are two glutamate residues that are sufficiently close to the stilbenedisulfonate site for their labeling to be blocked by 4,4'-diisothiocyanodihydrostilbene-2,2'-disulfonate and 4,4'-dinitrostilbene-2,2'-disulfonate.     

Peroxynitrite oxidizes erythrocyte membrane band 3 protein and diminishes its anion transport capacity

We describe an altered membrane band 3 protein-mediated anion transport in erythrocytes exposed to peroxynitrite, and relate the loss of anion transport to cell damage and to band 3 oxidative modifications. We found that peroxynitrite down-regulate anion transport in a dose dependent relation (100-300 μmoles/l). Hemoglobin oxidation was found at all peroxynitrite concentrations studied. A dose-dependent band 3 protein crosslinking and tyrosine nitration were also observed. Band 3 protein modifications were concomitant with a decrease in transport activity. ( - )-Epicatechin avoids band 3 protein nitration but barely affects its transport capacity, suggesting that both processes are unrelated. N-acetyl cysteine partially reverted the loss of band 3 transport capacity. It is concluded that peroxynitrite promotes a decrease in anion transport that is partially due to the reversible oxidation of band 3 cysteine residues. Additionally, band 3 tyrosine nitration seems not to be relevant for the loss of its anion transport capacity.     

Identification of an amino acid transporter associated with the cystinuria-related type II membrane glycoprotein.

We identified an amino acid transporter that is associated with the cystinuria-related type II membrane glycoprotein, rBAT (related to b(0,+) amino acid transporter). The transporter designated BAT1 (b(0, +)-type amino acid transporter 1) from rat kidney was found to be structurally related to recently identified amino acid transporters for system L, system y(+)L, and system x(-)C, which are linked, via a disulfide bond, to the other type II membrane glycoprotein, 4F2hc (4F2 heavy chain). In the nonreducing condition, a 125-kDa band, which seems to correspond to the heterodimeric complex of BAT1 and rBAT, was detected in rat kidney with anti-BAT1 antibody. The band was shifted to 41 kDa in the reducing condition, confirming that BAT1 and rBAT are linked via a disulfide bond. The BAT1 and rBAT proteins were shown to be colocalized in the apical membrane of the renal proximal tubules where massive cystine transport had been proposed. When expressed in COS-7 cells with rBAT, but not with 4F2hc, BAT1 exhibited a Na(+)-independent transport of cystine as well as basic and neutral amino acids with the properties of system b(0,+). The results from the present investigation were used to establish a family of amino acid transporters associated with type II membrane glycoproteins.     

Molecular mapping of human band 3 anion transport regions using synthetic peptides

Band 3 is a ubiquitous membrane transport protein found in Golgi, mitochondrial, nuclear, and cell membranes. It is the most heavily used anion transport system in the body because it is responsible for CO2 exchange in all tissues and organs and for acid-base balance. The anion transport regions are mapped along the band 3 molecule using synthetic peptides (pep) from extracellular regions of band 3 and/or suspected anion transport regions. Assays include anion transport/inhibition and immunoblotting with anti-idiotypic antibodies to a transport inhibitor. Results indicate that anion binding/transport regions of band 3 reside within residues 549-594, (588-594 being the most active) and 804-839 (822-839 being the most active), and 869-883. Pep-COOH (residues 812-827), which is part of senescent cell antigen, is an anion binding site with most of the activity localized to residues 813-818 (the six amino acids on the amino side of pep-COOH). The stilbene disulfonate inhibitors of transport bind to peptide 812-830, and possibly peptides 788-805 and 800-818, as determined with anti-idiotypic antibodies. Residues 538-554, which have been reported to be a transport segment of band 3, do not bind sulfate. Band 3 external loops containing residues 539-553 and 812-830, and internal segments containing residues 588-594 and 869-883, are in close spacial proximity in the membrane. The contribution of lysine and/or arginine to anion transport is examined by synthesizing peptides in which glycines or arginines are substituted for lysines or arginines. Lysines can contribute to anion binding but are not required.     

Anion binding characteristics of the band 3 / 4,4-dibenzamidostilbene-2,2-disulfonate binary complex: evidence for both steric and allosteric interactions.

A novel kinetic approach was used to measure monovalent anion binding to better define the mechanistic basis for competition between stilbenedisulfonates and transportable anions on band 3. An anion-induced acceleration in the release of 4,4'-dibenzamidostilbene-2,2'-disulfonate (DBDS) from its complex with band 3 was measured using monovalent anions of various size and relative affinity for the transport site. The K1/2 values for anion binding were determined and correlated with transport site affinity constants obtained from the literature and the dehydrated radius of each anion. The results show that anions with ionic radii of 120-200 pm fall on a well-defined correlation line where the ranking of the K1/2 values matched the ranking of the transport site affinity constants (thiocyanate < nitrate approximately bromide < chloride < fluoride). The K1/2 values for the anions on this line were about 4-fold larger than expected for anion binding to inhibitor-free band 3. Such a lowered affinity can be explained in terms of allosteric site-site interactions, since the K1/2 values decreased with increasing anionic size. In contrast, iodide, with an ionic radius of about 212 pm, had a 10-fold lower affinity than predicted by the correlation line established by the smaller monovalent anions. These results indicate that smaller monovalent anions have unobstructed access to the transport site within the band 3 / DBDS binary complex, while iodide experiences significant steric hindrance when binding. The observation of steric hindrance in iodide binding to the band 3 / DBDS binary complex, but not in the binding of smaller monovalent anions, suggests that the stilbenedisulfonate binding site is located at the outer surface of an access channel leading to the transport site.     

Evidence from electron paramagnetic resonance for function-related conformation changes in the anion-transport protein of human erythrocytes

The erythrocyte membrane protein involved in anion transport (band 3) was isolated in its native lipid milieu in the form of leaky vesicles and then was spin-labelled with N-(1-oxyl-2,2,6,6-tetramethyl-4-piperidinyl)-meleimide (MalMe4PipO). The resulting electron paramagnetic resonance spectrum of band-3-bound MalMe4PipO was resolved into a rapid tumbling component and another, relatively immobile component. The percentage of the signal contributed by the mobile component (Q), was sensitive to various characteristic factors known to affect erythrocyte anion transport: Q was a hyperbolic function of chloride concentration displaying a half-saturation constant K1/2 similar to that of chloride transport. On the other hand Q showed a biphasic response to sulfate concentration, in line with the relatively high affinity of sulfate for the anion modifier site. Q was a saturable function of pH, either in presence of Cl- or SO4(-2), showing a pKa between pH 6.0 and 6.5, in analogy with the pH titration curve of Cl- and SO4(-2), transport. Spin-labelled vesicles treated with a covalent inhibitor of anion transport, 4-acetamido-4'-isothiocyanostilbene-2,2'-disulfonic acid, were markedly less susceptible to changes in Cl- concentration. It is suggested that the electron paramagnetic resonance spectrum of MalMe4PipO covalently bound to the band-3 protein, reports conformational changes which are related to the anion-transport function of this protein.     

N-hydroxysulfosuccinimido active esters and the L-(+)-lactate transport protein in rabbit erythrocytes

Esters of N-hydroxysulfosuccinimide strongly inhibit L-(+)-lactate transport in rabbit erythrocytes, probably by acylating amino groups on the transport protein. Lactate transport studies using bis(sulfosuccinimido) suberate (BS3), bis(sulfosuccinimido) adipate (BS2A), bis(sulfosuccinimido) dithiobis(propionate), and a variety of monocarboxylate esters suggest that an exofacial amino group of the lactate transport protein is essential for lactate transport. Also, reductive methylation studies show that even when positive charge is preserved in modified amino groups, the transport is strongly inhibited. At pH less than 6, band 3 mediated inorganic anion transport is enhanced in BS3-treated cells, while at pH greater than 6, it is inhibited. BS3-induced inhibition of L-(+)-lactate transport does not have this pH dependence. BS3 reduces the labeling of a 40-50-kDa membrane polypeptide (band R) by tritiated 4,4'-diisothiocyanato-2,2-dihydrostilbenedisulfonate ([3H]H2DIDS) and by tritiated bis(sulfosuccinimido) adipate ([3H]BS2A). Tritiated sulfosuccinimido acetate (S2[3H]acetate) also labels band R, over a range of concentrations where lactate transport is inhibited in a dose-dependent manner by S2 acetate. BS3 is a known impermeant protein cross-linker. S2 acetate permeates rabbit red cell membranes by an H2DIDS-inhibitable mechanism. BS3 cross-links the proteolytic fragments of rabbit band 3 produced by extracellular chymotrypsin. These labeling experiments support an association between band R and specific monocarboxylate transport.     

Protoporphyrin-induced photodynamic effects on band 3 protein of human erythrocyte membranes

In previous studies it has been shown that protoporphyrin-induced photodynamic effects on red blood cells are caused by photooxidation of amino acid residues in membrane proteins and by the subsequent covalent cross-linking of these proteins. Band 3, the anion transport protein of the red blood cell membrane, has a relatively low sensitivity to photodynamic cross-linking. This cannot be attributed to sterical factors inherent in the specific localization of band 3 in the membrane structure. Solubilized band 3, for instance, showed a similar low sensitivity to cross-linking. By extracellular chymotrypsin cleavage of band 3 into fragments of 60 000 and 35 000 daltons it could be shown that both fragments were about equally sensitive to photodynamic cross-linking. The 17 000 dalton transmembrane segment, on the other hand, was completely insensitive. Inhibition of band 3-mediated sulfate transport proceeded much faster than band 3 interpeptide cross-linking, presumably indicating that the inhibition of transport is caused by photooxidation of essential amino acid residues or intrapeptide cross-linking. A close parallel was observed between photodynamic inhibition of anion transport and decreased binding of 4,4′-diisothiocyanodihydrostilbene-2,2′-disulfonate (H₂DIDS), suggesting that a photooxidation in the immediate vicinity of the H₂DIDS binding site may be responsible for transport inhibition.     

Anion transport across the erythrocyte membrane, in situ proteolysis of band 3 protein, and cross-linking of proteolytic fragments by 4,4'-diisothiocyano dihydrostilbene-2,2'-disulfonate.

Extracellular chymotrypsin cleaves the 95 000 dalton protein that migrates in band 3 of SDS-polyacrylamide gel electropherograms of the erythrocyte membrane into fragments of 60 000 and 35 000 daltons, but not further. Minor components of band 3 that remain at the original 95 000 dalton location may be eluted from the membrane by 0.1 N NaOH, indicating that, in contrast to the major component and the chymotryptic fragments, they are not integral membrane constituents. Incubation at neutral pH of chymotrypsinized erythrocytes with the bifunctional anion transport inhibitor 4,4'-diisothiocyano dihydrostilbene-2,2'-disulfonic acid results in covalent binding of that inhibitor primarily to the 60 000 dalton fragment and some cross-linking of the 60 000 dalton fragment with the 35 000 dalton fragment. Increasing the pH to 9.5 leads to a cross-linking of virtually all of the pairs of chymotryptic fragments and thus to a reconstitution of band 3 with its typical diffuse appearance in the 95 000 dalton region of the SDS-polyacrylamide gels. This indicates that (1) each integral 95 000 dalton protein molecule is capable of binding at least one 4,4'-diisothiocyano dihydrostilbene-2,2'-disulfonic acid molecule; (2) the 35 000 dalton fragment, though it is only weakly stained with Coomassie blue, is present in an amount that is equimolar with that of the 60 000 dalton fragment. Since the number of 4,4'-diisothiocyano dihydrostilbene-2,2'-disulfonic acid binding sites on the protein in band 3/cell is known to be close to the number of band 3 molecules/cell, it is suggested that the cross-linking takes place at a region of the band 3 molecule that is involved in the control of anion transport, Like chymotrypsin, papain digests the band 3 protein from the outer membrane surface. Unlike chymotrypsin, however, papain digestion results in an inhibition of anion exchange. Papain produces a major fragment of 60 000 daltons that differs from the major chymotryptic fragment by at most six amino acid residues. The only detectable difference between the noninhibitory action of chymotrypsin and the inhibitory action of papain on the band 3 protein is that papain is capable of partially digesting the 35000 dalton fragment. No reconstitution of band 3 by cross-linking of the fragments with 4,4'-diisothiocyano dihydrostilbene-2,2'-disulfonic acid can be achieved. Since the 35 000 dalton fragment reacts with one of the two reactive groups of 4,4'-diisothiocyano dihydrostilbene-2,2'-disulfonic acid and is also susceptible to digestion by the inhibitory papain, we suggest that a portion of this peptide participates, together with a portion of the 60 000 dalton fragment, in the control anion transport.     

On the structures of flavoprotein D-amino acid oxidase purple intermediates. A resonance Raman study

Resonance Raman (RR) spectra were obtained in H2O or D2O solution for the purple intermediates of D-amino acid oxidase (DAO) with isotopically labeled substrates, i.e., [1-13C]-, [2-13C]-, [3-13C]-, [15N]-, and [3,3,3-D3]alanine; [carboxyl-13C]- and [15N]proline. RR spectra were also measured for the intermediates of DAO reconstituted with isotopically labeled FAD's, i.e., [4a-13C]-, [4,10a-13C2]-, [2-13C]-, [5-15N]-, and [1,3-15N2]FAD in D2O. The isotopic shift of the 1692 cm-1 band upon [15N]- or [2-13C]-substitution of alanine indicates that the band is due to the C = N stretching mode of an imino acid derived from D-alanine, i.e., alpha-iminopropionate. The 1658 cm-1 band with D-proline was also assigned to the C = N stretching mode of an imino acid derived from D-proline, i.e., delta 1-pyrrolidine-2-carboxylate, since the band shifts to 1633 cm-1 upon [15N]-substitution and its stretching frequency is generally found in this frequency region. Since the band shifts to low frequency in D2O, the imino acid should have a protonated imino group such as the C = N+1H form. The intense band at 1363 cm-1 with D-alanine was assigned to a mixing of the CO2- symmetric stretching and CH3 symmetric deformation modes in alpha-iminopropionate, based on the isotope effects. The 1359 cm-1 band with D-proline has probably contributions of CO2- symmetric stretching and CH2 wagging, considering the isotope effects with [carboxyl-13C]proline. The 1359 cm-1 band with D-proline was split into 1371 cm-1 and 1334 cm-1 bands in D2O. As this splitting of the 1359 cm-1 band with D-proline in D2O can not be interpreted only by the replacement of the C = N+1-H proton by deuterium, the carboxylate of the imino acid probably interacts with the enzyme through some proton(s) exchangeable by deuterium(s) in D2O. The bands around 1605 cm-1 which shift upon [4a-13C]- and [4,10a-13C2]-labeling of FAD are derived from a fully reduced flavin, because the isotopic shifts of the band are very different from those of the bands of oxidized or semiquinoid flavin observed near 1605 cm-1.(ABSTRACT TRUNCATED AT 400 WORDS)