Gene/Protein
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Enzyme
Compound
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Gene/Protein
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Target Concepts:
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Query: UNIPROT:P50583 (
asymmetrical
)
12,197
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The kinetic properties of sulfate transport mediated by the anion exchangers
AE1
and AE2 have been examined. Microsomes isolated from HEK cells transiently overexpressing either protein were reconstituted in unilamellar, 200-600-nm diameter proteoliposomes. Transport mediated by the exchangers was monitored by loading the reconstituted proteoliposomes with the slowly transportable anion SO4(2-) using [35S]SO4(2-) as a tracer and performing [35S]SO4(2-)/SO4(2-) exchange. The following data suggest that
AE1
and AE2 have been functionally reconstituted: (i) the rate of SO4(2-) transport in
AE1
and AE2 containing proteoliposomes was 10-20 times higher than in proteoliposomes derived from control microsomes; (ii) the transport of SO4(2-) was strongly dependent on the presence of a trans anion; and (iii) the anion exchanger inhibitors, 4,4'-diisothiocyanostilbene-2,2'-disulfonate (DIDS) and 4,4'-dinitrostilbene-2,2'-di-sulfonate (DIDS) totally abolished SO4(2-) transport. furthermore, DIDS inhibits SO4(2-) transport only when occluded inside the vesicles, indicating a uniform,
asymmetrical
, inside-out orientation of the reconstituted exchangers. The Ki values of the stilbene disulfonate compound DNDS were 2.5 and 4 microM for
AE1
and AE2, respectively, suggesting that the two exchangers possess similar high affinity sites for stilbene compounds. Both
AE1
and AE2 showed the same steep pH dependence of sulfate transport, which was maximal at pH 5.5 and reduced to less than 10% (of the value at pH 5.5) at pH 8.5, suggesting that an acidic residue shared by
AE1
and AE2 participates in the pH regulation of sulfate transport.
...
PMID:Sulfate transport mediated by the mammalian anion exchangers in reconstituted proteoliposomes. 774 59
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.
...
PMID: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. 1257 72
