Rapid electrogenic sulfate-chloride exchange mediated by chemically modified band 3 in human erythrocytes

One of the modes of action of the red blood cell anion transport protein is the electrically silent net exchange of 1 Cl- for 1 SO4= and 1 H+. Net SO4(=)-Cl- exchange is accelerated by low pH or by conversion of the side chain of glutamate 681 into an alcohol by treatment of intact cells with Woodward's reagent K (WRK) and BH4-. The studies described here were performed to characterize the electrical properties of net SO4(=)-Cl- exchange in cells modified with WRK/BH4-. The SO4= conductance measured in 100 mM SO4= medium is smaller in modified cells than in control cells. However, the efflux of [35S] SO4= into a 150-mM KCl medium is 80-fold larger in modified cells than in control cells and is inhibited 99% by 10 microM H2DIDS. No detectable H+ flux is associated with SO4(=)-Cl- exchange in modified cells. In the presence of gramicidin to increase the cation permeability, the stoichiometry of SO4(=)-Cl- exchange is not distinguishable from 1:1. In modified cells loaded with SO4=, the valinomycin-mediated efflux of 86Rb+ into an Na- gluconate medium is immediately stimulated by the addition of 5 mM extracellular Cl-. Therefore, SO4(=)-Cl- exchange in modified cells causes an outward movement of negative charge, as expected for an obligatory 1:1 SO4(=)-Cl- exchange. This is the first example of an obligatory, electrogenic exchange process in band 3 and demonstrates that the coupling between influx and efflux does not require that the overall exchange be electrically neutral. The effects of membrane potential on SO4(=)-SO4= exchange and SO4(=)-Cl- exchange in modified cells are consistent with a model in which nearly a full net positive charge moves inward through the transmembrane field during the inward Cl- translocation event, and a small net negative charge moves with SO4= during the SO4= translocation event. This result suggests that, in normal cells, the negative charge on Glu 681 traverses most of the transmembrane electric field, accompanied by Cl- and the equivalent of two protein-bound positive charges.     

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.     

Evidence for a second binding/transport site for chloride in erythrocyte anion transporter AE1 modified at glutamate 681

Transport kinetics have been examined in erythrocyte anion transporter AE1 that has been chemically modified to convert glutamate 681 to an alcohol (E681OH AE1). Outward conductive Cl(-) flux in E681OH AE1 is inhibited by removal of extracellular Cl(-); this effect is the opposite of that in native AE1 and is consistent with coupled electrogenic 2:1 Cl(-)/Cl(-) exchange. A second Cl(-) binding/transport site is also suggested by the characteristics of (35)SO(4)(2-) flux in E681OH AE1: bilateral and cis Cl(-), which are normally inhibitory, accelerate (35)SO(4)(2-) flux. These effects would be expected if Cl(-) binds to a second transport site on SO(4)(2-)-loaded E681OH AE1, thereby allowing Cl(-)/SO(4)(2-) cotransport. Alternatively, the data can be explained without proposing Cl(-)/SO(4)(2-) cotransport if the rate-limiting event for (35)SO(4)(2-)/SO(4)(2-) exchange is external SO(4)(2-) release, and the binding of external Cl(-) accelerates SO(4)(2-) release. With either interpretation, these data indicate that E681OH AE1 has a binding/transport site for Cl(-) that is distinct from the main transport site. The effects of graded modification of E681 or inhibition by H(2)DIDS are consistent with the idea that the new Cl(-) binding site is on the same E681OH-modified subunit of the AE1 dimer as the normal transport site.     

Binding Sites for l-[3H]Glutamate on Hippocampal Synaptic Membranes: Three Populations Differentially Affected by Chloride and Calcium Ions

The effects of Cl- and Ca2+ were studied on the specific binding of L-[3H]glutamate to multiple sites on rat hippocampal synaptic membranes. Quisqualate (5 microM) or DL-2-amino-4-phosphonobutyrate (2-APB) (300 microM) was used to discriminate two previously identified classes of binding sites. Saturation isotherms and displacement curves constructed under different ionic conditions suggested that the effects of Cl- and Ca2+ could best be explained by postulating the existence of three major binding site populations in this preparation rather than two. The binding of L-glutamate to Glu A sites exhibits an absolute dependence on Cl-, and Ca2+ markedly increases the maximum density of these sites. Glu A sites bind quisqualate and 2-APB with relatively high affinity. Cl- (47 mM) more than doubles the maximum density of Glu B sites, but Ca2+ appears to have no effect. Glu B sites can be discriminated from the other classes by their relatively low affinity for quisqualate and 2-APB. There is reason to think that the Glu B population is heterogeneous. The novel Glu C population can be virtually selectively labeled by exposing 2-APB-sensitive binding sites to radioligand in Tris-HOAc buffer with Ca2+. Binding of L-[3H]glutamate to these sites is enhanced by both Cl- and Ca2+, but requires neither ion. Ca2+ appears to increase both the affinity of Glu C sites for L-glutamate and their maximum binding site density. In the presence of Ca2+ and Cl-, Glu C sites bind the radioligand with micromolar affinity (KD approximately 2 microM) and high capacity (Bmax approximately 160 pmol/mg protein).(ABSTRACT TRUNCATED AT 250 WORDS)     

The effects of dansylation on the pH dependence of SO4(2-) and Cl- equilibrium exchange and on the H+/SO4(2-) cotransport across the red blood cell membrane

Treatment of the erythrocyte membrane with dansyl chloride leads to the following effects: (i) SO4(2-) transport is enhanced, Cl- transport is reduced. At maximal acceleration of sulfate exchange, Cl- exchange is only partially inhibited. The two effects are lineary related suggesting that the Cl- and SO4(2-) transporting forms of band 3 are derived from the same pool. (ii) The maximum of the pH dependence of SO4(2-) equilibrium exchange as measured at low sulfate concentrations is replaced by a plateau. It now resembles the pH dependence of Cl- exchange in untreated red cells. The pH dependence of SO4(2-) equilibrium exchange as measured at high sulfate concentrations is virtually unchanged after dansylation. The pH dependence of the partially inhibited Cl- equilibrium exchange across the dansylated membrane as measured at high chloride concentrations remains similar as in the untreated red cells but is somewhat less pronounced. (iii) SO4(2-)/H+ cotransport remains essentially unaltered after modification by dansyl chloride. The effects of dansylation are discussed in terms of a model similar to the titratable carrier model originally proposed by Gunn (Gunn, R.B. (1972) in Oxygen Affinity of Hemoglobin and Red Cell Acid Base Status (Rorth, M. and Astrup, P., eds.), pp. 823-827, Munksgaard, Copenhagen).     

Mouse Ae1 E699Q mediates SO42-i/anion-o exchange with [SO42-]i-dependent reversal of wild-type pHo sensitivity

The SLC4A1/AE1 gene encodes the electroneutral Cl(-)/HCO(3)(-) exchanger of erythrocytes and renal type A intercalated cells. AE1 mutations cause familial spherocytic and stomatocytic anemias, ovalocytosis, and distal renal tubular acidosis. The mutant mouse Ae1 polypeptide E699Q expressed in Xenopus oocytes cannot mediate Cl(-)/HCO(3)(-) exchange or (36)Cl(-) efflux but exhibits enhanced dual sulfate efflux mechanisms: electroneutral exchange of intracellular sulfate for extracellular sulfate (SO(4)(2-)(i)/SO(4)(2-)(o) exchange), and electrogenic exchange of intracellular sulfate for extracellular chloride (SO(4)(2-)(i)/Cl(-)(o) exchange). Whereas wild-type AE1 mediates 1:1 H(+)/SO(4)(2-) cotransport in exchange for either Cl(-) or for the H(+)/SO(4)(2-) ion pair, mutant Ae1 E699Q transports sulfate without cotransport of protons, similar to human erythrocyte AE1 in which the corresponding E681 carboxylate has been chemically converted to the alcohol (hAE1 E681OH). We now show that in contrast to the normal cis-stimulation by protons of wild-type AE1-mediated SO(4)(2-) transport, both SO(4)(2-)(i)/Cl(-)(o) exchange and SO(4)(2-)(i)/SO(4)(2-)(o) exchange mediated by mutant Ae1 E699Q are inhibited by acidic pH(o) and activated by alkaline pH(o). hAE1 E681OH displays a similarly altered pH(o) dependence of SO(4)(2-)(i)/Cl(-)(o) exchange. Elevated [SO(4)(2-)](i) increases the K(1/2) of Ae1 E699Q for both extracellular Cl(-) and SO(4)(2-), while reducing inhibition of both exchange mechanisms by acid pH(o). The E699Q mutation also leads to increased potency of self-inhibition by extracellular SO(4)(2-). Study of the Ae1 E699Q mutation has revealed the existence of a novel pH-regulatory site of the Ae1 polypeptide and should continue to provide valuable paths toward understanding substrate selectivity and self-inhibition in SLC4 anion transporters.     

Effects of membrane potential on electrically silent transport. Potential-independent translocation and asymmetric potential-dependent substrate binding to the red blood cell anion exchange protein

Tracer anion exchange flux measurements have been carried out in human red blood cells with the membrane potential clamped at various values with gramicidin. The goal of the study was to determine the effect of membrane potential on the anion translocation and binding events in the catalytic cycle for exchange. The conditions were arranged such that most of the transporters were recruited into the same configuration (inward-facing or outward-facing, depending on the direction of the Cl- gradient). We found that the membrane potential has no detectable effect on the anion translocation event, measured as 36Cl(-)-Cl- or 36Cl(-)-HCO3- exchange. The lack of effect of potential is in agreement with previous studies on red cells and is different from the behavior of the mouse erythroid band 3 gene expressed in frog oocytes (Grygorczyk, R., W. Schwarz, and H. Passow. 1987. J. Membr. Biol. 99:127-136). A negative potential decreases the potency of extracellular SO4= as an inhibitor of either Cl- or HCO3- influx. Because of the potential-dependent inhibition by SO4=, conditions could be found in which a negative intracellular potential actually accelerates 36Cl- influx. This effect is observed only in media containing multivalent anions. The simplest interpretation of the effect is that the negative potential lowers the inhibitory potency of the multivalent anion by lowering its local concentration near the transport site. The magnitude of the effect is consistent with the idea that the anions move through 10-15% of the transmembrane potential between the extracellular medium and the outward-facing transport site. In contrast to its effect on extracellular substrate binding, there is no detectable effect of membrane potential on the competition between intracellular Cl- and SO4= for transport sites. The lack of effect of potential on intracellular substrate binding suggests that the access pathway leading to the inward-facing transport site is of lower electrical resistance than that leading to the extracellular substrate site.     

Human spleen histone H1. Isolation and amino acid sequence of a main variant, H1b

The complete amino acid sequence of a main variant, H1b, of human spleen histone H1 was determined, following previous determinations of human spleen histones H2B, H2A, H3, and H4. High-performance liquid chromatography on C8 silica of the H1 fraction yielded the homogeneous H1b subfraction; this variant was estimated to account for 60% of the total of the four H1 variants. The sequence determination was performed with four main fragments, I to IV, obtained by limited chymotryptic digestion of H1b. Together with direct sequencing by automated Edman degradation of fragments II, III, and IV, fragment I, blocked at the N-terminal, and fragment IV, the C-terminal half the H1b molecule, were sequenced after further digestion with staphylococcal protease and others. The four fragments were aligned with three overlapping peptides each derived from chymotryptic partial fragments, I-II and I-II-III, and intact H1b. Carboxypeptidase digestion of intact H1b confirmed the C-terminal sequence of the molecule. Thus, the total sequence of H1b was completely determined; it consists of a total of 218 amino acid residues, has a molecular weight of 21,734 in the unmodified form, and is completely acetylated at the N-terminal serine residue and partially methylated at the lysine residue 25. This sequence is compared with two mammalian somatic H1 sequences.     

Differential inhibition of AE1 and AE2 anion exchangers by oxonol dyes and by novel polyaminosterol analogs of the shark antibiotic squalamine.

Oxonol and polyaminosterol drugs were examined as inhibitors of recombinant mouse AE1 and AE2 anion exchangers expressed in Xenopus laevis oocytes and were compared as inhibitors of AE1-mediated anion flux in red cells and in HL-60 cells that express AE2. The oxonols WW-781, diBA(5)C4, and diBA(3)C4 inhibited HL-60 cell Cl-/Cl- exchange with IC50 values from 1 to 7 microM, 100-1000 times less potent than their IC50 values for red cell Cl-/anion exchange. In Xenopus oocytes, diBA(5)C4 inhibited AE1-mediated Cl- efflux several hundred times more potently than that mediated by AE2. Several novel squalamine-related polyaminosterols were also evaluated as anion exchange inhibitors. In contrast to diBA(5)C4, polyaminosterol 1361 inhibited oocyte-expressed AE2 8-fold more potently than AE1 (IC50 0.6 versus 5.2 microM). The 3-fold less potent desulfo-analog, 1360, showed similar preference for AE2. It was found that 1361 also partially inhibited Cl- efflux from red cells, whereas neither polyaminosterol inhibited Cl efflux from HL60 cells. Thus, the oxonol diBA(5)C4 is >100-fold more potent as an inhibitor of AE1 than of AE2, whereas the polyaminosterols 1360 and 1361 are 8-fold more potent as inhibitors of AE2 than of AE1. Assay conditions and cell type influenced IC50 values for both classes of compounds.     

Sulfate transport in human neutrophils

The mechanism by which SO4(2-) is transported across the plasma membrane of isolated human neutrophils was investigated. Unlike the situation in erythrocytes, SO4(2-) and other divalent anions are not substrates for the principal Cl-/HCO3- exchange system in these cells. At an extracellular concentration of 2 mM, total one-way 35SO4(2-) influx and efflux in steady-state cells amounted to approximately 17 mumol/liter of cell water per min. The intracellular SO4(2-) content was approximately 1 mM, approximately 25-fold higher than the passive distribution level. Internal Cl- trans stimulated 35SO4(2-) influx. Conversely, 35SO4(2-) efflux was trans stimulated by external Cl- (Km approximately 25 mM) and by external SO4(2-) (Km approximately 14 mM), implying the presence of a SO4(2-)/Cl- countertransport mechanism. The exchange is noncompetitively inhibited by 4-acetamido-4'-isothiocyanostilbene-2,2' -disulfonate (SITS) (Ki approximately 50 microM) and competitively blocked by alpha-cyano-4-hydroxycinnamate (Ki approximately 230 microM) and by ethacrynate (Ki approximately 7 microM); furosemide and probenecid also suppressed activity. The carrier exhibits broad specificity for a variety of monovalent (NO3- approximately Cl- greater than Br- greater than formate- greater than I- approximately p-aminohippurate-) and divalent WO4(2-) greater than oxalate2- greater than SO4(2-) greater than MoO4(2-) greater than SeO4(2-) greater than AsO4(2-) anions. There was little, if any, affinity for HCO3-, phosphate, or glucuronate. The influx of SO4(2-) is accompanied by an equivalent cotransport of H+, the ion pair H+ + SO4(2-) being transported together in exchange for Cl-, thereby preserving electroneutrality. These findings indicate the existence of a separate SO4(2-)/Cl- exchange carrier that is distinct from the neutrophil's Cl-/HCO3- exchanger. The SO4(2-) carrier shares several properties in common with the classical inorganic anion exchange mechanism of erythrocytes and with other SO4(2-) transport systems in renal and intestinal epithelia, Ehrlich ascites tumor cells, and astroglia.     

A functional arginine residue in the vacuolar H(+)-ATPase of higher plants.

The arginine-specific reagent phenylglyoxal inactivated the vacuolar H(+)-ATPase of red beet. Inactivation by phenylglyoxal followed pseudo-first-order kinetics and a double log plot of the t1/2 of inactivation versus phenylglyoxal concentration yielded a slope of 1.18. Neither inorganic anions nor DIDS protected from phenylglyoxal-mediated inactivation of the H(+)-ATPase. Indeed, Cl- stimulated the rate of phenylglyoxal-mediated H(+)-ATPase inactivation relative to SO4(2-). ATP, but not MgATP or ADP, protected from phenylglyoxal-mediated inactivation and inactivation resulted in a decrease in the Vmax of the H(+)-ATPase with little effect on the Km. Collectively, these results are consistent with phenylglyoxal-mediated inactivation of the vacuolar H(+)-ATPase resulting from modification of a single arginine residue in the catalytic nucleotide binding site of the vacuolar H(+)-ATPase. Stimulation of phenylglyoxal-mediated inactivation by Cl- indicates that exposure of the phenylglyoxal-sensitive functional arginine residue is enhanced in the presence of Cl-. The failure of MgATP to protect from phenylglyoxal inactivation suggests that ATP, rather than MgATP, binds directly to the catalytic site and that Mg2+ may act to promote catalysis subsequent to ATP binding.     

Structure of the polyglutamyl side chain posttranslationally added to alpha-tubulin.

Polyglutamylation, a new posttranslational modification of tubulin identified originally on the acidic alpha variants by Eddé et al. (Eddé, B., Rossier, J., Le Caer, J. P., Desbruyeres, E., Gros, F., and Denoulet, P. (1990) Science 247, 83-85), consists of the successive addition of glutamyl units to the Glu445. To characterize their linkage mode mouse tubulin was posttranslationally labeled with [3H]glutamate. After digestion of [3H]tubulin with thermolysin, up to eight radioactive peaks were separated on an anion exchange column (DEAE). Combined use of Edman degradation sequencing and mass spectrometry analysis of the first 6 one indicated that they all correspond to the same COOH-terminal sequence 440VEGEGEEEGEE450 bearing one to six glutamyl units on the Glu445. The first glutamyl residue is amide-linked to the gamma-carboxyl group of Glu445, but the additional residues can be linked to the gamma- or alpha-carboxyl groups of the preceding one. All possible linkages for the biglutamylated tubulin peptides (gamma 1 alpha 2, gamma 1 gamma 2) and triglutamylated (gamma 1 alpha 2 alpha 3, gamma 1 alpha 2 gamma 3, gamma 1 alpha 2 gamma 2, gamma 1 gamma 2 alpha 3, gamma 1 gamma 2 gamma 3) were synthesized. These different peptides were successfully separated on a C18 5-micron reverse phase column. We found that the bi- and triglutamylated tubulin peptides behave as the gamma 1 alpha 2 and gamma 1 alpha 2 alpha 3 synthetic peptides, respectively. These results indicate that the second and third glutamyl residues of the polyglutamyl side chain are amide-linked to the alpha-carboxyl group of the preceding unit.     

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., the modification process) exposes a cryptic, conformationally active chloride-binding site which functions to modulate allosterically the conformational state of the band 3 dimer. Chloride binding was determined by measuring the effect of increasing chloride concentration on the rate of DBDS (4,4'-dibenzamido-2,2'-stilbenedisulfonate) release from band 3 using a stopped-flow fluorescence kinetic inhibitor replacement assay with DIDS (4,4'-diisothiocyanato-2,2'-stilbenedisulfonate) as the replacing inhibitor. The time course for DBDS release from unmodified, control band 3 was monophasic and exponential. Chloride binding to the transport site accelerated the rate of DBDS release, with the observed rate constant showing a hyperbolic dependence on chloride concentration, while the total change in reaction fluorescence remained constant. After modification of glutamate 681, DBDS release was monophasic in the absence of chloride, but the rapid addition of chloride at constant ionic strength induced a doubling in the fluorescence quantum yield for the bound DBDS molecules. This was associated with the development of 50:50 biphasic kinetics for DBDS release. Such changes were independent of the degree of modification of the band 3 subunit population between the 66% and 91% levels. Titration of the increase in total reaction fluorescence gave an apparent chloride binding K(d) of between 7 and 10 mM, which is 25-40-fold higher in affinity than chloride binding to the transport site. The dependence of the kinetic constants for both phases of the DBDS release reaction on chloride concentration was nonhyperbolic, which contrasts with unmodified band 3, and is indicative of the presence of two classes of chloride-binding sites on the modified transporter. We have also found that the fraction of subunits capable of binding DBDS reversibly, or DIDS covalently, decreased nonlinearly in the absence of chloride as the level of modification of the band 3 subunit population increased. In contrast, the same DBDS binding correlation plot showed a maximum in the presence of saturating chloride. The observation of such nonlinear correlation plots is consistent with a noncooperative dimer model for the modification process, where each dimeric species must possess different properties with respect to stilbenedisulfonate binding capacity and with respect to the spectral-kinetic response of bound stilbenedisulfonate molecules to the addition of chloride. Within the context of this model, the fractions of the three molecular dimeric species (i.e., the unmodified dimer, the dimer with one subunit modified, and the fully modified band 3 dimer) are calculated as a function of the level of modification of the band 3 subunit population. Nonlinear correlation plots are generated by then assigning the following specific properties to each dimeric species. The unmodified dimer binds DBDS but does not change its fluorescence quantum yield upon addition of chloride. The half-modified dimer binds DBDS on both modified and unmodified subunits, and both of those DBDS molecules increase their fluorescence quantum yield by 2-fold when chloride is added, and the system develops 50:50 biphasic DBDS release kinetics. Finally, the model requires that the fully modified dimer does not bind DBDS or DIDS. This model generates theoretical correlation plots that can represent the data presented in this study. We propose that neutralization of glutamate 681 on the half-modified band 3 dimer exposes an allosteric, chloride-binding modifier site which functions to facilitate the anion/proton cotransport process (a) by blocking the "redocking" of the carboxyl side chain of glutamate (thus raising its pK) and (b) by inducing amate (thus raising its pK) and (b) by inducing a conformational change in the band 3 dimer from a symmetrical to an asymmetrical state.     

Sulfate transport in toad skin: evidence for mitochondria-rich cell pathways in common with halide ions

1. In short-circuited toad skin preparations exposed bilaterally to NaCl-Ringer's containing 1 mM SO2(-4), influx of sulfate was larger than efflux showing that the skin is capable of transporting sulfate actively in an inward direction. 2. This active transport was not abolished by substituting apical Na+ for K+. 3. Following voltage activation of the passive Cl- permeability of the mitochondria-rich (m.r.) cells sulfate flux-ratio increased to a value predicted from the Ussing flux-ratio equation for a monovalent anion. 4. In such skins, which were shown to exhibit vanishingly small leakage conductances, the variation of the rate coefficient for sulfate influx (y) was positively correlated with the rate coefficient for Cl- influx (x), y = 0.035 x - 0.0077 cm/sec (r = 0.9935, n = 15). 5. Addition of the phosphodiesterase inhibitor, 3-isobutyl-1-methyl-xanthine to the serosal bath of short-circuited preparations resulted in a significant stimulation of the passive Cl- and SO2(-4) permeabilities. 6. It is suggested that SO2(-4) and Cl- ions are transported along the same pathway of the m.r. cells. Depending on the transport mode of the apical Cl- transport system, electro-diffusion, active transport (sulfate:bicarbonate exchange) and self-exchange diffusion take place. Irrespective of the mechanism of transport, sulfate is probably transported as a monovalent anion species.     

The amino acid sequence of myoglobin from skeletal muscles of red deer(Cervus elaphus)

Red deer myoglobin has been fragmented by restricted tryptic digestion and by treatment with cyanogen bromide. The fragments have been separated by gel permeation. The core peptide derived from cyanogen bromide cleavage have been further digested with trypsin and the resulting peptides have been separated on Dowex 1X2. All fragments have been characterized by their amino acid composition, by determination of their N-terminal sequence using automatic Edman degradation and of their C-terminal sequence following the kinetics of amino acid cleavage by carboxypeptidases A and B. The complete sequence has been found to be identical with the already known sequence of sheep myoglobin except for residue 145 which is Gln in red deer globin and Glu in sheep globin. Reinvestigation of the corresponding sequence in sheep globin has shown that residue 145 of sheep globin is also Gln.     

Deficient HCO3- transport in an AE1 mutant with normal Cl- transport can be rescued by carbonic anhydrase II presented on an adjacent AE1 protomer

Cl-/HCO3- exchange activity mediated by the AE1 anion exchanger is reduced by carbonic anhydrase II (CA2) inhibition or by prevention of CA2 binding to the AE1 C-terminal cytoplasmic tail. This type of AE1 inhibition is thought to represent reduced metabolic channeling of HCO3- to the intracellular HCO3- binding site of AE1. To test the hypothesis that CA2 binding might itself allosterically activate AE1 in Xenopus oocytes, we compared Cl-/Cl- and Cl-/HCO3- exchange activities of AE1 polypeptides with truncation and missense mutations in the C-terminal tail. The distal renal tubular acidosis-associated AE1 901X mutant exhibited both Cl-/Cl- and Cl-/HCO3- exchange activities. In contrast, AE1 896X, 891X, and AE1 missense mutants in the CA2 binding site were inactive as Cl-/HCO3- exchangers despite exhibiting normal Cl-/Cl- exchange activities. Co-expression of CA2 enhanced wild-type AE1-mediated Cl-/HCO3- exchange, but not Cl-/Cl- exchange. CA2 co-expression could not rescue Cl-/HCO3- exchange activity in AE1 mutants selectively impaired in Cl-/HCO3- exchange. However, co-expression of transport-incompetent AE1 mutants with intact CA2 binding sites completely rescued Cl-/HCO3- exchange by an AE1 missense mutant devoid of CA2 binding, with activity further enhanced by CA2 co-expression. The same transport-incompetent AE1 mutants failed to rescue Cl-/HCO3- exchange by the AE1 truncation mutant 896X, despite preservation of the latter's core CA2 binding site. These data increase the minimal extent of a functionally defined CA2 binding site in AE1. The inter-protomeric rescue of HCO3- transport within the AE1 dimer shows functional proximity of the C-terminal cytoplasmic tail of one protomer to the anion translocation pathway in the adjacent protomer within the AE1 heterodimer. The data strongly support the hypothesis that an intact transbilayer anion translocation pathway is completely contained within an AE1 monomer.     

On the question of integration of Agrobacterium tumefaciens deoxyribonucleic acid by tomato plants.

Treatment of tomato plants with Agrobacterium tumefaciens causes subsequently administered [3H]thymidine to be preferentially incorporated into a satellite deoxyribonucleic acid (DNA) whose buoyant density is between that of bacterial DNA (rho = 1.718 g/cm3) and plant main band DNA (rho = 1.692 g/cm3). Satellite DNA upon shearing or sonic treatment releases fragments of higher and lower buoyant density, as reported by earlier investigators. The satellite has no significant base sequence homology with A. tumefaciens DNA, for its rate of reassociation is not accelerated by the addition of high concentrations of the latter. Tomato DNA isolated from shoots or from leaf nuclei accelerates renaturation of labeled satellite DNA. We conclude that the intermediate density labeled DNA is a plant satellite and not the product of covalent joining of bacterial and plant DNA as suggested by earlier investigators.     

Membrane topology of mammalian cytochromes P-450 from liver endoplasmic reticulum. Determination by trypsinolysis of phenobarbital-treated microsomes

We have studied the membrane topology of liver microsomal cytochromes P-450 derived from phenobarbital-treated rabbits via trypsinolysis of intact microsomes, recovery of solubilized peptide fragments by ultracentrifugation and liquid chromatography, primary structure determination by Edman microsequence analysis, and database searching to match isolated fragments with parent sequences. Relative to the primary structure of isozyme 2, the major phenobarbital-inducible form, fragments were isolated beginning at residues Glu86, Ile101, Arg126, Cys152, Leu198, Ser211, Asn237, Glu327, Asn385, Thr407, Phe408, Phe413, and Thr444. Such results show that this family of structurally related cytochromes is bound to the endoplasmic reticulum membrane by only one or two transmembrane segments, located at the NH2-terminal end of the polypeptide chain. The remainder of the protein, from residue approximately 50 to the COOH terminus must exist as a catalytic, heme-containing domain exposed on the cytosolic side of the membrane. Furthermore, our results indicate that the catalytic domain must be peripherally associated with the membrane surface. This would imply that substrates might have access to the active site of the cytochrome P-450 either by diffusion from the cytosol or from within the lipid bilayer.     

Role of chloride on carrier-mediated transport of p-aminohippurate in rat renal basolateral membrane vesicles

Effect of inorganic anions on p-amino[3H]hippurate transport in renal basolateral membranes has been studied using the vesicles preloaded with unlabeled p-aminohippurate (countertransport condition). The uptake of p-amino[3H]hippurate was stimulated by the outward gradient of unlabeled p-aminohippurate and the labeled substrate was accumulated into the vesicles against its concentration gradient in the presence of Cl-. The substitution of SCN- and SO4(2-) for Cl- in both sides of the vesicles depressed the initial rate and the overshoot magnitude of p-amino[3H]hippurate uptake. These results suggest that Cl- may play an important role for the carrier-mediated transport system of organic anion in renal basolateral membranes.     

Transport and metabolism of folates by bacteria.

Transport of labeled folic acid (PteGlu), pteroylpolyglutamates (PteGlu3-5), 5-methyl-tetrahydrofolate (5-methyl-H4PteGlu), and methotrexate in late-log phase cells of Lactobacillus casei was active, and subject to inhibition by unlabeled pteroylmonoglutamates, pteroylpolyglutamates, and iodoacetate, but not glutamate or glutamate dipeptides. Pteroylpolyglutamates were transported without prior hydrolysis and shared a common uptake system with pteroylmonoglutamates. The affinity and maximum velocity of PteGlun uptake decreased with increasing glutamate chin length (Km:PteGlu1, 0.03 mum; PteGlu3, 0.32 mum; PteGlu4, 1.9 mum; PteGlu5, 3.7 mum) and comparisons with growth response curves suggested that polyglutamates were more effectively utilized by L. casei, once transported, than monoglutamate. No concentration of 5-methyl-H4PteGlu3-8 inside the cells was observed. The major folate metabolites found in L. casei preloaded with high levels of [3H]PteGlu (0.5 mum) were 10-formyl-H4PteGlu2 and 10-formyl-PteGlu. Both compounds were released, the monoglutamate more rapidly. Pteroyltriglutamate formation appeared to be a rate-limiting step in intracellular metabolism. No 10-formyl-Pte-Glu was found in iodoacetate-treated cells and efflux was inhibited. Cells preloaded with low levels of [3H]PteGlu (7 nm) metabolized the vitamin to polyglutamate forms, the major derivatives being H4PteGlun. First order exit rates of labeled folate from preloaded L. casei indicated an inhibition of PteGlu uptake with time. Exit rates dropped from 0.05 min-1 to greater than 0.002 min-1 as intracellular folate was metabolized from monoglutamate to polyglutamate derivatives (n larger than or equal to 3). In the latter case, materials lost by efflux were breakdown products and no folate of glutamate chain length greater than two was released. Pediococcus cerevisiae actively transported 5-methyl-H4PteGlu but did not take up to 5-methyl-H4PTeGlu3-8. No active accumulation of 5-methyl-H4PteGlu was observed in Streptococcus faecalis.