Expression, purification, and characterization of the functional dimeric cytoplasmic domain of human erythrocyte band 3 in Escherichia coli.

The cytoplasmic domain of the human erythrocyte membrane protein, band 3 (cdb3), contains binding sites for hemoglobin, several glycolytic enzymes, band 4.1, band 4.2, and ankyrin, and constitutes the major linkage between the membrane skeleton and the membrane. Although erythrocyte cdb3 has been partially purified from proteolyzed red blood cells, further separation of the water-soluble 43-kDa and 41-kDa proteolytic fragments has never been achieved. In order to obtain pure cdb3 for crystallization and site-directed mutagenesis studies, we constructed an expression plasmid that has a tandemly linked T7 promoter placed upstream of the N-terminal 379 amino acids of the erythrocyte band 3 gene. Comparison of several Escherichia coli strains led to the selection of the BL21 (DE3) strain containing the pLysS plasmid as the best host for efficient production of cdb3. About 10 mg of recombinant cdb3 can be easily purified from 4 L of E. coli culture in two simple steps. Comparison of cdb3 released from the red blood cell by proteolysis with recombinant cdb3 reveals that both have the same N-terminal sequence, secondary structure, and pH-dependent conformational change. The purified recombinant cdb3 is also a soluble stable dimer with the same Stokes radius as erythrocyte cdb3. The affinities of the two forms of cdb3 for ankyrin are essentially identical; however, recombinant cdb3 with its unblocked N-terminus exhibits a slightly lower affinity for aldolase.     

Characterization of the reversible conformational equilibrium of the cytoplasmic domain of erythrocyte membrane band 3

The cytoplasmic domain of the erythrocyte membrane protein, band 3, contains binding sites for hemoglobin, several glycolytic enzymes, and ankyrin, the linkage to the cytoskeleton. In an earlier study, we found evidence which suggested that band 3 might undergo a native conformational change. We demonstrate here that the cytoplasmic domain of band 3 does exist in a reversible, pH-dependent conformational equilibrium among 3 native states. At physiological salt concentrations this equilibrium is characterized by apparent pKa values of 7.2 and 9.2; however, these apparent pKa values change if the domain's sulfhydryl groups are modified. A major component of the structural change appears to involve the pivoting of two subdomains of the cytoplasmic domain at a central hinge, as evidenced by both hydrodynamic and fluorescence energy transfer measurements. The probable site of this hinge is between residues 176 and 191, a region highly accessible to proteases and also rich in proline. These structural rearrangements also apparently extend to the cluster of tryptophan residues near the N terminus, since the domain's intrinsic fluorescence more than doubles between pH 6.5 and 9.5. No measurable change in band 3 secondary or quaternary structure could be detected during the conformational transitions. A structural model of the cytoplasmic domain of band 3 is presented to show the possible spatial relationships between the regions of conformational change and the sites of peripheral protein binding.     

Identification of a critical ankyrin-binding loop on the cytoplasmic domain of erythrocyte membrane band 3 by crystal structure analysis and site-directed mutagenesis

The cytoplasmic domain of erythrocyte membrane band 3 (cdb3) serves as a center of membrane organization, interacting with such proteins as ankyrin, protein 4.1, protein 4.2, hemoglobin, several glycolytic enzymes, a tyrosine phosphatase, and a tyrosine kinase, p72(syk). The crystallographic structure of the cdb3 dimer has revealed that residues 175-185 assume a beta-hairpin loop similar to a putative ankyrin-binding motif at the cytoplasmic surface of the Na(+)/K(+)-ATPase. To test whether this hairpin loop constitutes an ankyrin-binding site on cdb3, we have deleted amino acids 175-185 and substituted the 11-residue loop with a Gly-Gly dipeptide that bridges the deletion without introducing strain into the structure. Although the deletion mutant undergoes the same native conformational changes exhibited by wild type cdb3 and binds other peripheral proteins normally, the mutant exhibits no affinity for ankyrin. This suggests that the exposed beta-hairpin turn indeed constitutes a major ankyrin-binding site on cdb3. Other biochemical studies suggest that ankyrin also docks at the NH(2) terminus of band 3. Thus, antibodies to the NH(2) terminus of cdb3 block ankyrin binding to the cdb3, and ankyrin binding to cdb3 prevents p72(syk) phosphorylation of cdb3 at its NH(2) terminus (predominantly at Tyr-8). However, a truncation mutant of cdb3 lacking the NH(2)-terminal 50 residues displays the same binding affinity as wild type cdb3. These data thus suggest that the NH(2) terminus of cdb3 is proximal to but not required for the cdb3-ankyrin interaction.     

Structure and stability of hereditary spherocytosis mutants of the cytosolic domain of the erythrocyte anion exchanger 1 protein

Anion exchanger 1 (AE1, Band 3) is the predominant membrane protein of erythrocytes. Its 52 kDa C-terminal domain functions as a chloride-bicarbonate exchanger, while its 43 kDa N-terminal cytosolic domain (cdb3) anchors the cytoskeleton to the membrane. Several proteins bind to cdb3, including protein 4.2, a cytoskeletal protein. Three mutations in cdb3 are associated with hereditary spherocytosis (HS) and decreased levels of protein 4.2 in erythrocytes. In this study, these cdb3 mutants (E40K, G130R, and P327R) were expressed in and purified from Escherichia coli. Sedimentation experiments showed that the wild-type and mutant proteins are dimers. No difference in secondary structure between mutant and wild-type proteins was detected using circular dichroism (CD) analysis. The wild-type and mutant proteins underwent similar pH-dependent conformational changes when monitored by intrinsic tryptophan fluorescence. Urea denaturation of proteins monitored by intrinsic fluorescence showed no significant differences in the sensitivity of the proteins to this chemical denaturant. Thermal denaturation monitored by CD and by calorimetry revealed that only the P327R mutant had a significantly lower midpoint of transition (approximately 5 degrees C) than the wild-type protein, suggesting a modest decrease in stability. The results show that the HS mutant cdb3 proteins do not differ to any great extent in structure from the wild-type protein, suggesting that the HS mutations may directly affect protein 4.2 binding.     

Localization of the ankyrin-binding site on erythrocyte membrane protein, band 3

The predominant attachment site of the spectrin-based cytoskeleton to the erythrocyte membrane occurs via the interaction of ankyrin with the cytoplasmic domain of band 3 (cdb3). In order to further characterize this interaction, we have conducted experiments to localize the ankyrin-binding site on cdb3. Four monoclonal and three antipeptide polyclonal antibodies were raised against cdb3 and used in competition studies to identify regions of close association of cdb3 with ankyrin. Antibodies to regions of cdb3 near the cytoplasmic domain-membrane spanning domain junction had no effect on 125I-ankyrin binding. Likewise, an antibody to a highly conserved region between residues 142 and 154 did not inhibit ankyrin binding. However, antibodies at or near the cysteine 201-317 cluster and the proposed proline-rich hinge in the center of cdb3 were potent inhibitors of ankyrin association, as were antibodies to the acidic NH2 terminus. Additional evidence for interaction of ankyrin with the NH2-terminal region of cdb3 was obtained by demonstrating the ability of ankyrin to inhibit tyrosine phosphorylation of cdb3 at its NH2 terminus by a purified calf thymus tyrosine kinase. These studies reveal two regions of cdb3, distant in primary sequence, which interact with ankyrin. A specific conformation of cdb3 may be required to permit these regions to simultaneously associate with ankyrin and allow binding to occur.     

Expression and purification of recombinant cytoplasmic domain of human erythrocyte band 3 with hexahistidine tag or chitin-binding tag in Escherichia coli

The cytoplasmic domain of erythrocyte band 3 (cdb3) serves as a center of membrane organization in the erythrocytes by its interaction with multiple proteins including ankyrin, protein 4.1, protein 4.2, hemoglobin, and several glycolytic enzymes. In this paper, human cdb3 was cloned into three different expression vectors controlled by T7 polymerase promoter and induced with isopropyl beta-D-thiogalactopyranoside in Escherichia coli. Two of the fusion proteins containing hexahistidine tag in the N-terminal or C-terminal were purified by immobilized metal affinity column chromatography. The third recombinant cdb3 containing the affinity chitin-binding tag was purified using chitin beads followed by specific self-cleavage, which released cdb3 according to the mechanism of protein splicing. The molecular weights of purified recombinant proteins were verified by mass spectrometry. The pH-dependent properties of the intrinsic tryptophan fluorescence of the three kinds of recombinant cdb3 were compared with that of the cdb3 extracted from the erythrocytes, showing that there were no significant differences between them. Using pull-down assay combined with Western blot analysis, the interaction between recombinant cdb3 and protein 4.2 C3 fragment was verified. These demonstrated that the recombinant proteins were both structurally and functionally active. The typical yields of cdb3 purified with hexahistidine tag in the N-terminal, C-terminal, and cleaved from chitin bead were 10.6, 9.6, and 1.5 mg from 1L culture medium, respectively.     

Kinetics and regulation of the ankyrin-band 3 interaction of the human red blood cell membrane

In an attempt to identify potential regulatory mechanisms for erythrocyte membrane-cytoskeletal interactions, the kinetics and pH dependence of the band 3-ankyrin interaction were investigated. Association of 125I-ankyrin with KI-stripped inside-out erythrocyte membrane vesicles was found to proceed in two kinetic phases. The initial, fast phase (t1/2 approximately 15-30 min) involved predominantly the binding of ankyrin to low affinity sites (KD approximately 130 nM) in a pH-dependent manner. The apparent pKa values describing this reversible pH dependence (7.2 +/- 0.1 and 9.2 +/- 0.1) defined states of band 3 with high, moderate, and no capacity to bind ankyrin (in order of increasing pH). Since the cytoplasmic domain of band 3 also exists in 3 distinct conformational states characterized by apparent pKa values of 7.2 and 9.2, it was hypothesized that the reversible structural equilibrium in band 3 could influence ankyrin binding. The second or slow phase of ankyrin binding to band 3 involved the conversion of low to high affinity sites (KD approximately 13 nM). This phase, which was largely temperature and pH independent, required roughly an order of magnitude longer to reach completion than the fast phase. Unfortunately, even though the slow phase could be cleanly separated from the fast phase at low pH, insufficient data were available to formulate a physical interpretation of its origin. Significantly, however, even after completion of the slow phase under the most quantitative binding conditions identified, a maximum of only 26% of the band 3 was found to bind ankyrin in situ. Although higher ankyrin-band 3 stoichiometries may be achievable with the isolated cytoplasmic fragment of band 3, we interpret the above 1:4 stoichiometry to suggest that the tetramer of band 3 constitutes the predominant ankyrin binding oligomer of band 3 on the membrane.     

Rate of rupture and reattachment of the band 3-ankyrin bridge on the human erythrocyte membrane

The principal bridge connecting the erythrocyte membrane to the spectrin-based skeleton is established by band 3 and ankyrin; mutations leading to reduced bridge formation or increased bridge rupture result in morphological and mechanical abnormalities. Because membrane mechanical properties are determined in part by the protein interactions that stabilize the membrane, we have evaluated the rates of rupture and reattachment of band 3-ankyrin bridges under both resting and mechanically stressed conditions. To accomplish this, we have examined the rate of ankyrin displacement from inside-out vesicles by the hexahistidine-tagged cytoplasmic domain of band 3, cdb3-(His)6 and the rate of substitution of cdb3-(His)6 into endogenous band 3-ankyrin bridges in resealed erythrocytes in the presence and absence of shear stress. We demonstrate that 1) exogenous cdb3-(His)6 displaces endogenous ankyrin from IOVs with a half-time and first order rate constant of 42 +/- 14 min and 0.017 +/- 0.0058 min(-1), respectively; 2) exogenous cdb3-(His)6 substitutes endogenous band 3 in its linkage to ankyrin in resealed cells with a half-time and first order rate constant of 12 +/- 3.6 min and 0.060 +/- 0.019 min(-1), respectively; 3) cdb3-(His)6-mediated rupture of the band 3-ankyrin bridge in resealed cells results in decreased membrane mechanical stability, decreased deformability, abnormal morphology, and spontaneous vesiculation of the cells; and 4) the above on/off rates are not significantly accelerated by mechanical shear stress. We conclude that the off rates of the band 3-ankyrin interaction are sufficiently slow to allow sustained erythrocyte deformation without loss of elasticity.     

Conformational changes in the cytoplasmic domain of human anion exchanger 1 revealed by luminescence resonance energy transfer

The cytoplasmic domain of the human erythrocyte anion exchanger 1 (cdAE1) serves as a center of organization for the red blood cell cytoskeleton as well as several metabolic enzymes and hemoglobin. The protein is known to undergo a reversible pH-dependent conformational change characterized by a 2-fold change in the intrinsic fluorescence and an 11 A change in the Stokes radius. While the exact changes in the molecular structure are unknown, on the basis of the crystal structure of the protein at pH 4.8 and site-directed mutagenesis studies, Zhou and Low (19) have proposed that the peripheral protein binding (PPB) domain of cdAE1 moves away from the dimerization domain in response to increasing alkalinity. To test this hypothesis, we have applied luminescence resonance energy transfer (LRET) to measure the intermonomer distance between donor and acceptor probes at the Cys201 site (located in the PPB domain) within the cdAE1 dimer. This distance was found to increase as the pH is increased from 5 to 10, in recombinant forms of both the wild type and a mutant (C317S) of cdAE1. Furthermore, LRET measurements in red blood cell inside-out vesicles indicate that when cdAE1 is linked to the membrane, the intermonomer distance is larger at pH 5, compared to that of the purified cdAE1 segments, and exhibits a different pH-dependent behavior. An increase in the distance was also observed on binding of a metabolic enzyme, glyceraldehyde-3-phosphate dehydrogenase, to cdAE1. These data provide the first demonstration of a defined change in the molecular structure of cdAE1, and also indicate that the structure under physiological conditions is different from the crystal structure determined at low pH.     

Determination of structural models of the complex between the cytoplasmic domain of erythrocyte band 3 and ankyrin-R repeats 13-24

The adaptor protein ankyrin-R interacts via its membrane binding domain with the cytoplasmic domain of the anion exchange protein (AE1) and via its spectrin binding domain with the spectrin-based membrane skeleton in human erythrocytes. This set of interactions provides a bridge between the lipid bilayer and the membrane skeleton, thereby stabilizing the membrane. Crystal structures for the dimeric cytoplasmic domain of AE1 (cdb3) and for a 12-ankyrin repeat segment (repeats 13-24) from the membrane binding domain of ankyrin-R (AnkD34) have been reported. However, structural data on how these proteins assemble to form a stable complex have not been reported. In the current studies, site-directed spin labeling, in combination with electron paramagnetic resonance (EPR) and double electron-electron resonance, has been utilized to map the binding interfaces of the two proteins in the complex and to obtain inter-protein distance constraints. These data have been utilized to construct a family of structural models that are consistent with the full range of experimental data. These models indicate that an extensive area on the peripheral domain of cdb3 binds to ankyrin repeats 18-20 on the top loop surface of AnkD34 primarily through hydrophobic interactions. This is a previously uncharacterized surface for binding of cdb3 to AnkD34. Because a second dimer of cdb3 is known to bind to ankyrin repeats 7-12 of the membrane binding domain of ankyrin-R, the current models have significant implications regarding the structural nature of a tetrameric form of AE1 that is hypothesized to be involved in binding to full-length ankyrin-R in the erythrocyte membrane.     

The structural characteristics of human preprotein translocase of the inner mitochondrial membrane Tim23: implications for its physiological activities

The preprotein translocase of the inner mitochondrial membrane (TIM23 complex) is the main entry gate for proteins of the matrix and the inner membrane. Tim23 forms a pore for preprotein transportation in TIM23 complex, which spans the inner membrane with transmembrane segments and exposes a hydrophilic domain in the intermembrane space. In this study, we expressed and purified the intermembrane space (IMS) domain of human Tim23 (Tim23(IMS)). The far-UV CD spectra of Tim23(IMS) in native and denatured states revealed that the protein has a limited secondary structure and a not well-defined tertiary packing. Its Stokes radius was larger than both its expected size as a folded globular protein and the size determined by size exclusion chromatography. A large increase in 8-anilino-1-naphthalene-sulfonate (ANS) fluorescence (>50-fold) was observed, indicating that hydrophobic clusters are exposed at its surface. And GlobPlot/DisEMBL program predicted that the protein is in a loose folding state. We therefore conclude that, the non-bound hydrophilic domain of the human Tim23 is in a molten globule configuration with marginal stability. Furthermore, size exclusion chromatography and sedimentation equilibrium analysis showed that Tim23(IMS) exists as a dimer. And the results, showed by ANS binding and fluorescence quenching, indicated that a pH-dependent conformational change of Tim23(IMS) occurs, and at pH 4 and 3, it forms a compact structure.     

A study on the C-terminal membrane anchoring of Escherichia coli penicillin-binding protein 5.

Escherichia coli penicillin-binding protein 5 (PBP5) anchors to the inner membrane in a pH-dependent manner via a C-terminal amphiphilic alpha-helix. Low pH was found to enhance both levels of PBP5 membrane anchoring and levels of alpha-helicity in an aqueous PBP5 C-terminal homologue, which led to the suggestion that levels of PBP5 membrane anchoring are related to levels of PBP5 C-terminal alpha-helicity. Here we have used Fourier-transformed infrared spectroscopy (FTIR) and a peptide homologue of the PBP5 C-terminal sequence to investigate the effect of pH on the conformational behavior of this sequence at a lipid interface and on its ability to interact with lipid. Our results suggest that the membrane-anchoring mechanism of PBP5 is unlikely to involve conformational change in the protein's C-terminal region and may therefore involve conformational changes in the protein's ectomembranous domain.     

Evidence that membrane insertion of the cytosolic domain of Bcl-xL is governed by an electrostatic mechanism

Signals from different cellular networks are integrated at the mitochondria in the regulation of apoptosis. This integration is controlled by the Bcl-2 proteins, many of which change localization from the cytosol to the mitochondrial outer membrane in this regulation. For Bcl-xL, this change in localization reflects the ability to undergo a conformational change from a solution to integral membrane conformation. To characterize this conformational change, structural and thermodynamic measurements were performed in the absence and presence of lipid vesicles with Bcl-xL. A pH-dependent model is proposed for the solution to membrane conformational change that consists of three stable conformations: a solution conformation, a conformation similar to the solution conformation but anchored to the membrane by its C-terminal transmembrane domain, and a membrane conformation that is fully associated with the membrane. This model predicts that the solution to membrane conformational change is independent of the C-terminal transmembrane domain, which is experimentally demonstrated. The conformational change is associated with changes in secondary and, especially, tertiary structure of the protein, as measured by far and near-UV circular dichroism spectroscopy, respectively. Membrane insertion was distinguished from peripheral association with the membrane by quenching of intrinsic tryptophan fluorescence by acrylamide and brominated lipids. For the cytosolic domain, the free energy of insertion (DeltaG degrees x) into lipid vesicles was determined to be -6.5 kcal mol(-1) at pH 4.9 by vesicle binding experiments. To test whether electrostatic interactions were significant to this process, the salt dependence of this conformational change was measured and analyzed in terms of Gouy-Chapman theory to estimate an electrostatic contribution of DeltaG degrees el approximately -2.5 kcal mol(-1) and a non-electrostatic contribution of DeltaG degrees nel approximately -4.0 kcal mol(-1) to the free energy of insertion, DeltaG degrees x. Calcium, which blocks ion channel activity of Bcl-xL, did not affect the solution to membrane conformational change more than predicted by these electrostatic considerations. The lipid cardiolipin, that is enriched at mitochondrial contact sites and reported to be important for the localization of Bcl-2 proteins, did not affect the solution to membrane conformational change of the cytosolic domain, suggesting that this lipid is not involved in the localization of Bcl-xL in vivo. Collectively, these data suggest the solution to membrane conformational change is controlled by an electrostatic mechanism. Given the distinct biological activities of these conformations, the possibility that this conformational change might be a regulatory checkpoint for apoptosis is discussed.     

利用核糖体展示技术筛选功能性蛋白质方法的建立

核糖体展示(ribosomedisplay)是一种体外筛选功能性蛋白质的有力的工具.利用体外转录和翻译偶联系统可以方便而快捷地完成核糖体展示.筛选系统利用一对能够紧密结合的蛋白质:人锚蛋白(ankyrin)和红血球膜带3蛋白细胞质区域(cytoplasmicdomainoferythrocytemembraneproteinBand3,Cdb3)作为模式分子,希望利用cdb3蛋白通过核糖体展示亲和选择得到锚蛋白基因.用于核糖体展示的人锚蛋白基因结构由组装PCR构建,通过PCR技术引入核糖体展示所需的结构元件.在亲和筛选步骤后,只能利用红血球膜带3蛋白筛选得到锚蛋白基因,而不能利用对照牛血清白蛋白(bovineserumalbumin,BSA)筛选得到,从而说明建立的核糖体展示技术能够正常发挥作用.     

Formation of an unfolding intermediate state of soluble chloride intracellular channel protein CLIC1 at acidic pH

CLIC proteins function as anion channels when their structures convert from a soluble form to an integral membrane form. While very little is known about the mechanism of the conversion process, channel formation and activity are highly pH-dependent. In this study, the structural properties and conformational stability of CLIC1 were determined as a function of pH in the absence of membranes to improve our understanding of how its conformation changes when the protein encounters the acidic environment at the surface of a membrane. Although the global conformation and size of CLIC1 are not significantly altered by pH in the range of 5.5-8.2, equilibrium unfolding studies reveal that the protein molecule becomes destabilized at low pH, resulting in the formation of a highly populated intermediate with a solvent-exposed hydrophobic surface. Unlike the intermediates formed by many soluble pore-forming proteins for their insertion into membranes, the CLIC1 intermediate is not a molten globule. Acid-induced destabilization and partial unfolding of CLIC1 involve helix alpha1 which is the major structural element of the transmembrane region. We propose that the acidic environment encountered by CLICs at the surface of membranes primes the transmembrane region in the N-domain, thereby lowering the energy barrier for the conversion of soluble CLICs to their membrane-inserted forms.     

Mimicking lipid-binding-induced conformational changes in the human apolipoprotein E N-terminal receptor binding domain effects of low pH and propanol.

We studied the effects of n-propanol and pH on the structure of the apolipoprotein E3 N-terminal receptor binding domain, apo E3(1-191), to determine whether conditions similar to those occurring near lipid surfaces (decreased dielectric constant and pH) can mimic lipid-induced conformational changes in apo E3. The addition of 30% n-propanol, at pH 7, induces a conformational change in apo E3(1-191) as shown by changes in the intrinsic tryptophan fluorescence and by an increase in the Stokes radius of the majority of the protein from 3.0 to 4.1 nm, although the protein remains monomeric as shown by chemical cross-linking. These changes are accompanied by increased resistance to limited proteolysis with trypsin, chymotrypsin, subtilisin and endoproteinase glu-C, as is the case for apo E3(1-191) reconstituted into phospholipid/cholesterol lipid bicelles. Far and near UV circular dichroism showed that n-propanol increases the amount of calculated alpha-helical structure (42-65%) and alters the tertiary structure of the protein although not as much as when apo E3(1-191) is incorporated into lipid bicelles. In the absence of n-propanol, lowering the pH to 4.5 decreases the Stokes radius of the majority of the protein somewhat, with little effect upon the secondary and the tertiary structures. The addition of 30% n-propanol at pH 4.5 increases the Stokes radius of apo E3(1-191) from 2.2 to 5.0 nm, even more than at pH 7 (3.0-4.1 nm) although the protein still remains predominantly monomeric. There is increased resistance to limited proteolysis with endoproteinase glu-C. As assessed by far and near UV circular dichroism, the addition of 30% n-propanol at pH 4.5, in contrast to pH 7, markedly increases the alpha-helical structure and changes the tertiary structure of the protein similarly to that resulting from the incorporation of apo E3(1-191) into lipid bicelles. The results suggest that a combination of n-propanol and low pH in aqueous solutions may be useful as a simple model system for studying conformational changes in apo E3 similar to those, which occur upon interaction of the protein with lipids.     

Conformations of the active and inactive states of opsin

The signaling state metarhodopsin II of the visual pigment rhodopsin decays to the apoprotein opsin and all-trans retinal, which are then regenerated to rhodopsin by the visual cycle. Opsin is known to have at neutral pH only a small residual constitutive activity toward its G protein transducin, which is thought to play a considerable role in light adaptation (bleaching desensitization). In this study we show with Fourier-transform infrared spectroscopy that after metarhodopsin II decay, opsin exists in two conformational states that are in a pH-dependent equilibrium at 30 degrees C with a pK of 4.1 in the presence of hydroxylamine scavenging the endogenous all-trans retinal. Despite the lack of the native agonist in its binding pocket, the low pH opsin conformation is very similar to that of metarhodopsin II and is likewise stabilized by peptides derived from rhodopsin's cognate G protein, transducin. The high pH form, on the other hand, has some conformational similarity to the inactive metarhodopsin I state. We therefore conclude that the opsin apoprotein displays intrinsic conformational states that are merely modulated by bound all-trans retinal.     

pH-Dependent Conformational Changes in Bacterial Hsp90 Reveal a Grp94-Like Conformation at pH 6 That Is Highly Active in Suppression of Citrate Synthase Aggregation

The molecular chaperone Hsp90 depends upon large conformational rearrangements for its function. One driving force for these rearrangements is the intrinsic ATPase activity of Hsp90, as seen with other chaperones. However, unlike other chaperones, structural and kinetic studies have shown that the ATPase cycle of Hsp90 is not conformationally deterministic. That is, rather than dictating the conformational state, ATP binding and hydrolysis shift the equilibrium between a preexisting set of conformational states in an organism-dependent manner. While many conformations of Hsp90 have been described, little is known about how they relate to chaperone function. In this study, we show that the conformational equilibrium of the bacterial Hsp90, HtpG, can be shifted with pH. Using small-angle X-ray scattering, we identify a two-state pH-dependent conformational equilibrium for apo HtpG. Our structural modeling reveals that this equilibrium is observed between the previously observed extended state and a second state that is strikingly similar to the recently solved Grp94 crystal structure. In the presence of nonhydrolyzable 5′-adenylyl-β,γ-imidodiphosphate, a third state, which is identical with the solved AMPPNP-bound structure from yeast Hsp90, is populated. Electron microscopy confirmed the observed conformational equilibria. We also identify key histidine residues that control this pH-dependent equilibrium; using mutagenesis, we successfully modulate the conformational equilibrium at neutral pH. Using these mutations, we show that the Grp94-like state provides stronger aggregation protection compared to the extended apo conformation in the context of a citrate synthase aggregation assay. These studies provide a more detailed view of HtpG's conformational dynamics and provide the first linkage between a specific conformation and chaperone function.     

The distal C-terminal region of the KcsA potassium channel is a pH-dependent tetramerization domain

The intracellular C-terminal domain (CTD) of KcsA, a bacterial homotetrameric potassium channel, is a 40-residue-long segment that natively adopts a helical bundle conformation with 4-fold symmetry. A hallmark of KcsA behavior is pH-induced conformational change, which leads to the opening of the channel at acidic pH. Previous studies have reached conflicting conclusions as to the role of the CTD in this transition. Here, we investigate the involvement of this domain in pH-mediated channel opening by NMR using a soluble peptide corresponding to residues 128-160 of the CTD (CTD34). At neutral pH, CTD34 exhibits concentration-dependent spectral changes consistent with oligomer formation. We prove this slowly tumbling species to be a tetramer with a dissociation constant of (2.0±0.5)×10(-)(11)?M(3) by NMR and sedimentation equilibrium experiments. Whereas monomeric CTD34 is only mildly helical, secondary chemical shifts prove that the tetrameric species adopts a tight native-like helical bundle conformation. The tetrameric species undergoes pH-dependent dissociation, and CTD34 is fully monomeric below pH?5.0. The structural basis for this phenomenon is the destabilization of the tetrameric CTD34 by protonation of residue H145 in the monomeric form of the peptide. We conclude that (i) the CTD34 peptide is independently capable of forming a tetrameric helical bundle, and (ii) this structurally significant conformational shift is modulated by the effects of solution pH on residue H145. Therefore, the involvement of this domain in the pH gating of the channel is strongly suggested.     

Equilibrium and kinetic measurements of the redox potentials of cytochromes c2 in vitro and in vivo.

The equilibrium oxidation-reduction mipoint potential (Em) of isolated Rhodopseudomonas sphaeroides cytochrome c2 exhibits a pH-dependent behavior which can be ascribed to a pK on the oxidized form at pH 8.0 (Pettigrew et al. (1975) Biochim. Biophys. Acta 430, 197-208). However, as with mammalian cytochrome c (Brandt, K.G. Parks, P.C., Czerlinski, G.H. and Hess, G.P. (1966) J. Biol. Chem. 241, 4180-4185) this pK can more properly be attributed to the combination of a pK beyond pH 11, and a slow conformational change of the ferricytochrome. This has been demonstrated by resolving the Em of cytochrome c2 before and after the conformational change. The Em of the unaltered form is essentially pH independent between pH 7 and 11.5, and the lower equilibrium Em is due solely to the conformational change. In vivo the conformational change is prevented by the binding of the cytochrome c2 to the photochemical reaction center, and the cytochrome exhibits an essentially pH-independent Em from pH 5 to 11. The alkaline transition thus has little physiological significance, and it is unlikely that the redox reactions of cytochrome c2 in vivo involve protons.