Inhibition of anion transport associated with chymotryptic cleavages of red blood cell band 3 protein

Right-side-out vesicles derived from red blood cells treated with chymotrypsin retain specific anion transport function (defined as transport sensitive to the specific inhibitor, 4,4′-diisothiocyano-2,2′-stilbenedisulfonic acid (DIDS)), even though the transport protein, band 3, is cleaved into two segments of 60 and 35 kdaltons. In contrast, vesicles derived from alkali-stripped ghosts treated with relatively high concentrations of chymotrypsin retain almost no specific anion function. The loss of function appears to be related to additional cleavages of band 3 protein that occur in treated ghosts, the 60-kdalton segment being reduced first to a 17- and then to a 15-kdalton segment and the 35-kdalton segment being reduced to a 9-kdalton segment plus a carbohydrate containing fragment. The chymotryptic cleavages of band 3 protein of ghosts are preferentially inhibited by high ionic strength, the production of the 9-kdalton segment being somewhat slower than that of the 15-kdalton segment. Vesicles derived from ghosts treated with chymotrypsin at different ionic strengths show a graded reduction in specific anion transport activity, but it was not possible to determine, definitively, which of the additional cleavages was inhibitory. In the light of these data and other information, the functional role of the segments of band 3 is discussed.     

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 crosslinking 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 non-inhibitory 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 of anion 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.     

The location of a disulfonic stilbene binding site in band 3, the anion transport protein of the red blood cell membrane

The binding site for 4,4′-diisothiocyano-2,2′-stilbenedisulfonic acid, a specific, potent, irreversible inhibitor of anion transport in red blood cells is located in a 15 000 dalton transmembrane segment of band 3, produced by chymotrypsin treatment of ghosts stripped of extrinsic proteins. The segment was cleaved into three fragments of 7000, 4000 and 4000 daltons by CNBr. The C-terminus of the segment is located in the 7000 dalton fragment; the N-terminus in one of the 4000 dalton fragments; and the binding site for 4,4′-diisothiocyano-2,2′-stilbenedisulfonic acid in the middle 4000 dalton fragment. The latter was cleaved by $\text{N-}\text{bromosuccinimide}$ into two fragments of 2000 daltons. The binding site for 4,4′-diisothiocyano-2,2′-stilbenedisulfonic acid was located on the fragment containing the newly formed N-terminus. It is concluded that the binding site is located about 9000 daltons from the C-terminus (at the outside face of the membrane) and 6000 daltons from the N-terminus (at the cytoplasmic face). In view of the existing evidence that the binding site may be located near the outside face of the membrane, it is suggested that the 15 000 dalton segment is folded, so that it crosses the bilayer three times.     

Intrinsic segments of band 3 that are associated with anion transport across red blood cell membranes

Summary After treatment of red cell ghosts with chymotrypsin, the predominant intrinsic peptides remaining in the membrane fraction are 15,000 and 9,000 daltons mol wt. After partial extraction with Triton X-100, the residual membrane vesicles have almost no other stained peptides and such vesicles are reported to carry out anion transport activities sensitive to specific inhibitors. In vesicles derived from cells treated with DIDS(4,4-diisothiocyano-2,2-stilbene disulfonic acid), an irreversible inhibitor of anion transport that is highly localized in an abundant intrinsic protein known as band 3, the probe is largely recovered in the 15,000 dalton peptide. The part of band 3 from which it is derived is a previously reported 17,000 transmembrane segment (Steck, T.L., Ramos, R., Strapazon, E., 1976,Biochemistry 15:1154). The 9,000-dalton peptide is present in the vesicles in a one-to-one mole ratio with the 15,000-dalton peptide, suggesting that both are derived from the same protein. This conclusion is supported by the finding that the 35,000-dalton C-terminal end of band 3, derived by chymotrypsin treatment of cells, is further proteolysed if the cells are converted to ghosts and its disappearance coincides with the appearance of the 9,000-dalton fragment. Evidence is presented that the 9,000-dalton fragment crosses the bilayer and that it is closely associated with the 15,000-dalton peptide.This paper is dedicated to the memory of Walther Wilbrandt.     

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.     

Enhancement of anion permeability in lecithin vesicles by hydrophobic proteins extracted from red blood cell membranes.

Triton X-100 extracts of membrane proteins from ghosts of normal and pronase treated cells enhance the anion permeability of lecithin vesicles. With proteins from cells pretreated with DIDS (4,4′-diisothiocyano-2,2′-stilbene disulfonate), a specific inhibitor of anion transport, the anion permeability is not enhanced. On the basis that the Triton X-100 extracts are considerably enriched in a protein component of 95,000 molecular weight (or a 65,000 molecular weight segment in the case of pronase treated cells), and that DIDS is bound almost exclusively to the same proteins, it is suggested that the pronase resistant, 65,000 molecular weight segment of the 95,000 molecular weight protein is directly involved in anion transport.     

Transmembrane effects of irreversible inhibitors of anion transport in red blood cells. Evidence for mobile transport sites

Experiments were designed to determine whether band 3, the anion transport protein of the red cell membrane, contains a mobile element that acts as a carrier to move the anions across a permeability barrier. The transport site-specific, nonpenetrating irreversible inhibitor 4,4'-diisothiocyano-2,2'-stilbene disulfonate (DIDS) was found to be effective only when applied extracellularly. It was used to sequester transport sites on the extracellular side of the membrane in intact cells. The membranes were then coverted into inside-out vesicles. The number of anion transport sites available on the cytoplasmic side of the vesicle membranes was then estimated by measuring the binding of N-(-4-azido-2-nitrophenyl)-2-aminoethyl-sulfonate (NAP-taurine), a photoreactive probe. Pretreatment with DIDS from the extracullular side substantially reduced the binding of NAP-taurine at the cytoplasmic side. Since NAP-taurine does not appear to penetrate into the intravesicular (normally extracellular) space, a transmembrane effect is apparently involved. About 70% of the DIDS-sensitive NAP-taurine binding sites are located in band 3, with the remainder largely in a lower molecular weight (band 4) region. A similar pattern of reduction in NAP-taurine binding is produced by high concentrations of Cl-, but this anion has little or no effect in vesicles from cells pretreated with DIDS. Thus the DIDS-modulated sites seem to be capable of binding either NAP-taurine or Cl. It is suggested that band 3 contains a mobile transport element that can be recruited to the extracellular surface by DIDS, thus becoming unavailable to NAP-taurine at the cytoplasmic face of the membrane. The results are consistent with a model of carrier-mediated transport in which the movement of the transport site is associated with a local conformational change in band 3 protein.     

A relationship between anion transport and a structural transition of the human erythrocyte membrane

Scanning microcalorimetry was employed as an aid in examining some structural features of the anion transport system in red blood cell vesicles. Two structural transitions were previously shown to be sensitive to several covalent and non-covalent inhibitors of anion transport in red cells. In this study, these transitions were selectively removed, either thermally or enzymatically, and the subsequent effect on ³⁵SO₄^2? efflux in red cell vesicles was determined. It is shown that removal of one of these transitions (B₂) has a negligible inhibitory effect on anion transport. Cytoplasmic, intermolecular disulfide linkages between band 3 dimers are known to form during the B₂ transition. The integrity of the 4,4′-diisothiocyanostilbene-2,2′-disulfonate-sensitive C transition, on the other hand, is shown to be a requirement for anion transport. The localized region of the membrane giving rise to this transition contains the transmembrane segment of band 3, as well as membrane phospholipids. The calorimetric results suggest a structure of band 3 which involves independent structural domains, and are consistent with the transmembrane segment playing a direct role in the transport process.     

The amino acid conjugate formed by the interaction of the anion transport inhibitor 4,4′-diisothiocy ano-2,2′- stilbenedisulfonic acid (DIDS) with band 3 protein from human red blood cell membranes

The specific anion transport inhibitor 4,4′-diisothiocyano-2,2′-stilbenedisulfonic acid (DIDS) and its reduced analog (H₂DIDS), when irreversibly bound to band 3 protein of the red blood cell membrane, form amino acid conjugates through interaction with the ?-amino group of a particular lysine residue. The specific residue is located in a transmembrane segment of band 3 protein and appears to be a close neighbor of the transport site.     

Inhibition of anion permeability of sarcoplasmic reticulum vesicles by stilbene derivatives and the identification of an inhibitor-binding protein

The permeability of sarcoplasmic reticulum vesicles to sulfate ions was inhibited by diisothiocyano-1,2-diphenylethane-2,2′-disulfonic acid (H₂DIDS), which is a potent inhibitor of anion permeability in red blood cell membrane. The amount of H₂DIDS bound to the vesicles was determined by using [³H]-H₂DIDS. Apparent half inhibition of sulfate permeation was observed on the binding of 2.5 μmol/g protein. SDS-polyacrylamide gel electrophoresis of the vesicles treated with [³H]H₂DIDS showed that about 10% of the total bound H₂DIDS corresponds to a 100 000-dalton protein, but the remaining 90% to non-protein components. The content of the H₂DIDS-binding protein was about 0.5 μmol/g protein. These results suggest that the H₂DIDS-binding protein is different from the calcium pump protein and is possibly an anion transport system similar to band 3 in red blood cell membrane.     

Fluorescence labeling of the human erythrocyte anion transport system. Subunit structure studied with energy transfer

The anion transport system of human red cells was isolated in vesicles containing the original membrane lipids and the 95 000 dalton polypeptides (band 3) by the method of Wolosin et al. (J. Biol. Chem. (1977) 252, 2419–2427). The vesicles have a functional anion transport system since they display sulfate transport that is inhibited by the fluorescent probe 8-anilinonaphthalene 1-sulfonate (ANS) with similar potency as in red cells. The vesicles were labeled with the SH-specific probe fluorescein mercuric acetate (FMA). Labeling lowers FMA fluorescence, and is prevented or reversed by dithiothreitol, suggesting that the reaction is with a thiol group on the protein. Fluorescence titrations show a maximum labeling stoichiometry of 1.3 ± 0.4 mol FMA/mol 95 000 dalton polypeptide. The polarization of bound FMA fluorescence is high indicating that the probe is highly immobilized. Pretreatment with Cu²⁺ + o-phenanthroline under conditions that crosslink band 3 in ghosts decreases FMA labeling 50%. Differences in kinetics of FMA labeling in sealed and leaky vesicles suggest that the reactive SH group is located in the intravesicular portion of the protein (corresponding to the cytoplasmic surface of the red cell) and that FMA can cross the membrane. Inhibitors of anion transport have no effect on FMA labeling kinetics suggesting it is not transported via the anion     

Identification of an anion channel protein from electric organ of Narke japonica

The anion permeability of membrane vesicles prepared from the electric organ of $\text{Narke japonica}$ was inhibited by the addition of 4,4′-diisothiocyano-stilbene-2,2′-disulfonic acid (DIDS). The permeability was measured by measuring changes in the scattered-light intensity caused by the osmotic volume change of vesicles; and also by the efflux measurement of ions from the vesicles using radioisotopes. Sodium dodecyl sulfate polyacrylamide gel electrophoresis of membrane vesicles treated with dihydro analog of DIDS ([³H]H₂DIDS) showed that the H₂DIDS binding protein has a molecular weight of 180,000, and exists in membrane vesicles as a dimer formed by a disulfide bond between monomers of molecular weight 90,000.     

Proteolytic dissection of band 3, the predominant transmembrane polypeptide of the human erythrocyte membrane.

Band 3 is the major, membrane-spanning, approximately90 000 dalton polypeptide of the human erythrocyte membrane. To facilitate the analysis of its structural integration into the membrane, we have cleaved this protein in situ into large fragments and ascertained their disposition. Digestion of intact cells with chymotrypsin yielded band 3 fragments with apparent molecular weights of 38 000 and 55 000. Both fragments resisted elution by NaOH and acetic acid, suggesting that they are anchored in the apolar core of the membrane. Both pieces communicate with the extracellular space, and the 55 000 dalton species extends to the cytoplasmic surface as well. Digestion of unsealed ghosts with chymotrypsin produced a hydrophobic 17 000 dalton species, a segment of the 55 000 dalton fragment, which spans and is firmly anchored in the core of the membrane. Trypsin and papain at low concentration generated integral band 3 fragments of 52 000 daltons and released major band 3 fragments of less than or equal to 41 000 daltons from the cytoplasmic side of the membrane. The latter water-soluble polypeptides remained associated in discrete complexes which retained the capacity to bind glyceraldehyde-3-phosphate dehydrogenase. An interchain disulfide bond, which can be induced only at the cytoplasmic surface, cross-linked intact band 3, and certain of its water-soluble fragments. Finally, fragments of 23 000 daltons were generated from the innersurface domain by reacting disulfide-linked band 3 dimers with cyanide or reduced polypeptides with 2-nitro-5-thiocyanobenzoate. A provisional ordering of these fragments is proposed.     

Transfer of band 3, the erythrocyte anion transporter, between phospholipid vesicles and cells

Band 3, the anion transport protein of human erythrocyte membranes, can be transferred from cells to liposomes and from liposomes back to cell membranes, retaining function and native orientation. After incubation with cells, sonicated phosphatidylcholine vesicles bind a transmembrane protein that comigrates with band 3 on sodium dodecyl sulfate-polyacrylamide gels. Like native red cell band 3, the vesicle-bound protein is cleaved by chymotrypsin into 65- and 30-kdalton fragments and is not cleaved by trypsin. The protein can be cross-linked by copper-phenanthroline oxidation either before or after transfer to vesicles; in either case, the vesicle fractions contain high molecular weight material that is dissociated into 95-kdalton species by mercaptoethanol. Band 3-vesicle complexes contain no detectable cell lipid and are specifically permeable to anions. Greater than 99% of their anion uptake can be blocked by the band 3 inhibitor 4,4'-diisothiocyano-2,2'-stilbenedisulfonic acid (DIDS). Red cells whose band 3 function has been blocked irreversibly by DIDS or eosin maleimide regain part of their anion permeability upon incubation with band 3-vesicle complexes. Under the conditions employed, an average of one copy of functional band 3 is delivered to half of the cells, increasing by 2.3-fold the number of cells containing functional anion transporters. Incubation of pure lipid vesicles or red cell membrane buds with either normal red cells or eosin maleimide inhibited cells has no detectable effect on the cells' anion permeability.     

The interaction of human erythrocyte band 3 with cytoskeletal components

Band 3 of the human erythrocyte is involved in anion transport and binding of the cytoskeleton to the membrane bilayer. Human erythrocytes were treated to incorporate varying concentrations of DIDS (4,4′-diisothiocyanostilbene-2,2′-disulfonic acid) a non-penetrating, irreversible inhibitor of anion transport, and both functions of Band 3 were analyzed. The rate of efflux of ³⁵SO₄. was measured and the binding of cytoskeletal components to the membrane was evaluated by extracting the membranes with 0.1 n NaOH and analyzing for the peptides remaining with the membrane. It was found that 0.1 n NaOH extracts all the extrinsic proteins from membranes of untreated cells, while, in the case of the membranes from cells treated with DIDS, a portion of the cytoskeletal components, spectrin (Bands 1 and 2) and Band 2.1 (ankyrin, syndein) remain with the membrane. The amount of these cytoskeletal components remaining with the membrane depends on the concentrations of DIDS incorporated. The effect of DIDS on the extractability of the spectrin-Band 2.1 complex correlates well with DIDS inhibition of anion transport (r = 0.91). At DIDS concentrations which completely inhibit anion transport, about 10% of total spectrin-Band 2.1 complex remains unextracted. Another anion-transport inhibitor, pyridoxal phosphate, has no effect on binding of the cytoskeleton to the membrane. On the other hand, digestion of DIDS-pretreated intact erythrocytes with Pronase, chymotrypsin, or trypsin releases the tight binding of Band 3 to cytoskeleton on the inside of the membrane. Since trypsin does not hydrolyze Band 3 the data suggest that a second membrane protein which is trypsin sensitive may be involved with Band 3 in cytoskeletal binding.     

Fluorescence labeling of the human erythrocyte anion transport system.

The anion transport system of human red cells was isolated in vesicles containing the original membrane lipids and the 95 000 dalton polypeptides (band 3) by the method of Wolosin et al. (J. Biol. Chem. (1977) 252, 2419--2427). The vesicles have a functional anion transprot system since they display sulfate transport that is inhibited by the fluorescent probe 8-anilinonaphthalene 1-sulfonate (ANS) with similar potency as in red cells. The vesicles were labeled with the SH-specific probe fluorescein mercuric acetate (FMA). Labeling lowers FMA fluorescence, and is prevented or reversed by dithiothreitol, suggesting that the reaction is with a thiol group on the protein. Fluorescnece titrations show a maximum labeling stoichiometry of 1.3 +/- 0.4 mol FMA/mol 95 000 dalton polypeptide. The polarization of bound FMA fluorescence is high indicating that the probe is highly immobilized. Pretreatment with Cu2+ + o-phenanthroline under conditions that crosslink band 3 in ghosts decreases FMA labeling 50%. Differences in kinetics of FMA labeling in sealed and leaky vesicles suggest that the reactive SH group is located in the intravesicular portion of the protein (corresponding to the cytoplasmic surface of the red cell) and that FMA can cross the membrane. Inhibitors of anion transport have no effect on FMA labeling kinetics suggesting it is not transported via the anion transport system. Sulfate transport in the labeled vesicles remains fully functional. We detected self-energy transfer between bound FMA molecules by fluorescence depolarization. With excitation at 450--50 nm P decreases from 0.4, when less than half of the proteins are labeled, to 0.1 at saturation. This depolarization is not observed with red edge excitation (510--530 nm). Addition of 0.1% sodium dodecyl sulfate (SDS) changes P to 0.32, regardless of the excitation wavelength or degree of saturation with FMA. These results indicate that the band 3 proteins are close enough to allow energy transfer between fluorophores(Ro = 37.4 A), which does not occur upon red edge excitation or when the proteins are separated by SDS. We conclude that the functional anion transport system exists as a dimer or higher oligomer of band 3 proteins in these membranes, confirming previous suggestions derived using other methods. Future applications are discussed.     

Limited proteol ysis of coupling factor-latent ATPase from Mycobacterium phlei. Effects of different enzymes and modifying agents

The activation of the coupling factor-latent ATPase enzyme by tryptic proteolysis may resemble the activation of many proenzymes by limited proteolysis. The beta (53 000 dalton) subunit of solubilized coupling factor-latent ATPase from Mycobacterium phlei was selectively lost in some trypsin-treated samples. Since a concomitant loss of ATPase activity was not observed, the beta subunit may not be essential for ATPase catalytic activity. Treatment of solublized coupling factor with chymotrypsin rapidly produced an A′-type (61 000 dalton) species from the native alpha (64 000 dalton) subunits with partial activation of the ATPase enzyme. Secondary chymotryptic cleavage yielded an A″-type (58 000 dalton) species and a less-active enzyme. Storage of fresh coupling factor samples at ?20°C in the presence of 4 mM MgCl₂ with several freeze-thaw cycles resulted in loss of ATPase activity without apparent change in alpha subunit structure. Storage at 4°C in the presence or absence of MgCl₂ both decreased ATPase activity and generated A′-type alpha subunit species. Since presence of phenylmethylsulfonyl fluoride prevented these changes, an unknown protease was suspected. The peptide bonds first cleaved by trypsin, chymotrypsin, and the unknown protease are all apparently located within the same small segment of alpha subunit polypeptide chain.     

Identification of the Cl− transport site of human red blood cells by a kinetic analysis of the inhibitory effects of a chemical probe

H₂DIDS, the dihydro analog of DIDS (4,4′-diisothiocyanostilbene-2,2′-disulfonic acid) can interact covalently with membrane sites, resulting in an irreversible inhibition of anion exchange. At low temperatures (0°C) and for relatively short times, however, its interaction is largely reversible, so that a kinetic analysis of the nature of its inhibitory effect on Cl^? self exchange can be performed. The effects of variations in the chloride concentration on the inhibitory potency of H₂DIDS are consistent with the concept that Cl^? and H₂DIDS compete for the transport site of the anion exchange system. The value of K_i for H₂DIDS is 0.046 μM, indicating that H₂DIDS has a higher affinity for the transport system than any other inhibitor so far examined. If, as seems probable, the covalent labelling of H₂DIDS occurs at the same site as the reversible binding, H₂DIDS can be used as a covalent label for the transport site. The specific localization of H₂DIDS in the band-3 protein thus indicates that this protein participates directly in anion exchange.     

Topology of the anion exchange protein AE1: the controversial sidedness of lysine 743

The topology of the band 3 (AE1) polypeptide of the erythrocyte membrane is not fully established despite extensive study. Residues near lysine 743 (K743) have been reported to be extracellular in some studies and cytoplasmic in others. In the work presented here, we have attempted to establish the sidedness of K743 using in situ proteolysis. Trypsin, papain, and proteinase K do not cleave band 3 at or near K743 in intact red cells, even under conditions that cause cleavage on the C-terminal side of the glycosylation site (N642) in extracellular loop 4. In contrast, trypsin sealed inside red cell ghosts cleaves at K743, as does trypsin treatment of inside-out vesicles (IOVs). The transport inhibitor 4,4'-diisothiocyanatodihydrostilbene-2,2'-disulfonate (H(2)DIDS), acting from the extracellular side, blocks trypsin cleavage at K743 in unsealed membranes by inducing a protease-resistant conformation. H(2)DIDS added to IOVs does not prevent cleavage at K743; therefore, trypsin cleavage at K743 in IOVs is not a consequence of cleavage of right-side-out or leaky vesicles. Finally, microsomes were prepared from HEK293 cells expressing the membrane domain of AE1 lacking the normal glycosylation site. This polypeptide does not traffic to the surface membrane; trypsin treatment of microsomes containing this polypeptide produces the 20 kDa fragment, providing further evidence that K743 is exposed at the cytoplasmic surface. Therefore, the actions of trypsin on intact cells, resealed ghosts, unsealed ghosts, inside-out vesicles, and microsomes from HEK293 cells all indicate that K743 is cytoplasmic and not extracellular.