Roles of Leu249, Lys252, and Leu253 in membrane segment M3 of sarcoplasmic reticulum Ca2+-ATPase in control of Ca2+ migration and long-range intramolecular communication

Point mutants with alterations to Leu249, Lys252, Leu253, Asp254, and Glu255 in membrane segment M3, and Pro824, Lys825, and Glu826 in loop L6-7, of the sarcoplasmic reticulum Ca2+-ATPase were analyzed functionally by steady-state and transient kinetic methods. In mutants Leu249Ala, Lys252Glu, and Leu253Ala, the rate of Ca2+ dissociation from the cytoplasmically facing high-affinity Ca2+ sites was increased 4- to 7-fold relative to wild type, and in Leu249Ala and Lys252Glu the rate of Ca2+ binding was increased as well. Substitution of Lys252 with arginine, alanine, glutamine, or methionine affected Ca2+ interaction much less, indicating that the negative charge of the glutamate is particularly disturbing. These findings may be understood on the basis of the hypothesis that a water-accessible channel leading between membrane segments M1 and M3 in the thapsigargin-bound Ca2+-free structure [Toyoshima, C., and Nomura, H. (2002) Nature 418, 605-611] is closely related to the migration pathway for Ca2+. The effects of alanine mutations to Leu249 and Leu253 on Ca2+ dissociation may arise from destabilization of the hydrophobic wall lining the pathway. In mutant Lys252Glu, unfavorable interaction between the glutamate and L6-7 may open the pathway. In addition, Leu253Ala, and to a lesser extent some of the other mutations, reduced the rate of the E1PCa2 to E2P transition of the phosphoenzyme, enhanced the rate of dephosphorylation of E2P, and reduced the apparent affinity for vanadate, suggesting interference with the conformational change of the phosphoenzyme and the function of the catalytic site in E2 and E2P.     

Functional consequences of alterations to Thr247, Pro248, Glu340, Asp813, Arg819, and Arg822 at the interfaces between domain P, M3, and L6-7 of sarcoplasmic reticulum Ca2+-ATPase. Roles in Ca2+ interaction and phosphoenzyme processing

Point mutants with alterations to amino acid residues Thr(247), Pro(248), Glu(340), Asp(813), Arg(819), and Arg(822) of sarcoplasmic reticulum Ca(2+)-ATPase were analyzed by transient kinetic measurements. In the Ca(2+)-ATPase crystal structures, most of these residues participate in a hydrogen-bonding network between the phosphorylation domain (domain P), the third transmembrane helix (M3), and the cytoplasmic loop connecting the sixth and the seventh transmembrane helices (L6-7). In several of the mutants, a pronounced phosphorylation "overshoot" was observed upon reaction of the Ca(2+)-bound enzyme with ATP, because of accumulation of dephosphoenzyme at steady state. Mutations of Glu(340) and its partners, Thr(247) and Arg(822), in the bonding network markedly slowed the Ca(2+) binding transition (E2 --> E1 --> Ca(2)E1) as well as Ca(2+) dissociation from Ca(2+) site II back toward the cytosol but did not affect the apparent affinity for vanadate. These mutations may have caused a slowing, in both directions, of the conformational change associated directly with Ca(2+) interaction at Ca(2+) site II. Because mutation of Asp(813) inhibited the Ca(2+) binding transition, but not Ca(2+) dissociation, and increased the apparent affinity for vanadate, the effect on the Ca(2+) binding transition seems in this case to be exerted by slowing the E2 --> E1 conformational change. Because the rate was not significantly enhanced by a 10-fold increase of the Ca(2+) concentration, the slowing is not the consequence of reduced affinity of any pre-binding site for Ca(2+). Furthermore, the mutations interfered in specific ways with the phosphoenzyme processing steps of the transport cycle; the transition from ADP-sensitive phosphoenzyme to ADP-insensitive phosphoenzyme (Ca(2)E1P --> E2P) was accelerated by mutations perturbing the interactions mediated by Glu(340) and Asp(813) and inhibited by mutation of Pro(248), and mutations of Thr(247) induced charge-specific changes of the rate of dephosphorylation of E2P.     

Functional consequences of glutamate, aspartate, glutamine, and asparagine mutations in the stalk sector of the Ca2+-ATPase of sarcoplasmic reticulum

Nucleotides encoding glutamate, glutamine, aspartate, or asparagine residues within the stalk sector of the sarcoplasmic reticulum Ca2+-ATPase were altered by oligonucleotide-directed site-specific mutagenesis. The mutant cDNAs were expressed in COS-1 cells, and mutant Ca2+-ATPases were assayed for Ca2+ transport function and phosphoenzyme formation. Multiple mutations introduced into stalks, 1, 2, and 3 resulted in partial loss of Ca2+ transport function. In most cases, subsequent mutation of individual amino acids in the cluster had no effect on Ca2+ transport activity. In one cluster, however, it was possible to assign the reduction in Ca2+ transport activity to alterations of Asn111 and Asn114. The mutant Asn114 to alanine retained about 50% activity, whereas the change Asn111 to alanine retained only 10% activity. None of the mutations affected phosphorylation of the enzyme by ATP in the presence of Ca2+ or by inorganic phosphate in the absence of Ca2+. The combined experiments suggest that the reduced Ca2+ uptake observed in the Asn111 and Asn114 mutants was not due to a defect in enzyme activation by Ca2+ or in formation of the phosphorylated enzyme intermediate but rather to incompetent handling of the bound Ca2+ following ATP utilization. These results demonstrate that the acidic and amidated residues within the stalk region do not constitute the high affinity Ca2+-binding sites whose occupancy is required for enzyme activation. They may, however, act to sequester cytoplasmic Ca2+ and to channel it to domains that are involved in enzyme activation and cation translocation. Simultaneous mutation of 4 glutamate residues to alanine in the lumenal loop between transmembrane sequences M1 and M2 did not affect Ca2+ transport activity, indicating that acidic residues in this lumenal loop do not play an essential role in Ca2+ transport. Similarly, mutation of Glu192 and Asp196 in the beta-strand domain between stalk helices 2 and 3 did not affect Ca2+ transport activity, although mutation of Asp196 did diminish expression of the protein.     

Functional consequences of alterations to Glu309, Glu771, and Asp800 in the Ca(2+)-ATPase of sarcoplasmic reticulum.

Site-specific mutagenesis was used to replace Glu309, Glu771, and Asp800 in the Ca(2+)-ATPase of rabbit fast twitch muscle sarcoplasmic reticulum with their corresponding amides. These residues are predicted to lie in the transmembrane domain and have been suggested as oxygen ligands for Ca2+ binding at high affinity sites (Clarke, D. M., Loo, T. W., Inesi, G., and MacLennan, D. H. (1989) Nature 339, 476-478). The Glu309----Gln and Asp800----Asn mutants were unable to form a phosphoenzyme from ATP at the Ca2+ concentrations examined (up to 12.5 mM), whereas the Glu771----Gln mutant phosphorylated from ATP at 2.5 mM Ca2+. In all three mutants, Ca2+ at concentrations well below 12.5 mM prevented or inhibited phosphorylation with Pi, suggesting that at least one calcium-binding site was functioning in each mutant. In the mutants Glu309----Gln and Glu771----Gln, the ADP-insensitive phosphoenzyme intermediate was unusually stable, as indicated by a very low rate of dephosphorylation observed in kinetic experiments and by an increased apparent affinity for Pi determined in equilibrium phosphorylation experiments. These data indicate a central role of Glu309 and Glu771 in the energy-transducing conformational changes and/or in the activation of phosphoenzyme hydrolysis.     

Functional consequences of proline mutations in the cytoplasmic and transmembrane sectors of the Ca2(+)-ATPase of sarcoplasmic reticulum

Site-specific mutagenesis was used to investigate whether Pro160, Pro195, Pro308, Pro312, Pro803, and Pro812 play essential roles in the function of the sarcoplasmic reticulum Ca2(+)-ATPase. All six prolines were substituted with alanine; and in addition, Pro308 was replaced by glycine and Pro312 by glycine as well as by leucine. Mutant cDNAs were expressed in COS-1 cells, and mutant Ca2(+)-ATPases located in the isolated microsomal fraction were examined with respect to Ca2+ uptake activity, Ca2+ dependence of phosphorylation from ATP, and the kinetic properties of the phosphoenzyme intermediates formed from both ATP and Pi. The enzymatic cycle was little affected by substitution of Pro160, Pro195, and Pro812, which are located in the cytoplasmic domain; but replacement of Pro308, Pro312, and Pro803, in the putative transmembrane helices, had a profound impact on the function of the enzyme. All mutations of Pro308 and Pro803 led to ATPases which were characterized by a reduced affinity for Ca2+. These prolines may therefore be involved in the structure of the high affinity Ca2(+)-binding sites in the enzyme. Substitution of Pro312 with alanine or glycine gave rise to mutants unable to transport Ca2+ even though their apparent affinities for Ca2+ in the phosphorylation reaction with ATP were increased. In these enzymes, the ADP-sensitive phosphoenzyme intermediate was stable for at least 5 min at 0 degrees C, whereas the ADP-insensitive phosphoenzyme intermediate decay at a rate similar to that of the wild type. Thus, the inability to transport Ca2+ could be accounted for by a block of ADP-sensitive to ADP-insensitive phosphoenzyme intermediate conformational transition. In contrast, substitution of Pro312 with leucine gave rise to a mutant enzyme that retained about 7% of the normal Ca2+ transport rate. Phosphoenzyme turnover in this mutant also occurred at a low but significant rate, suggesting that the leucine side chain can substitute to some extent for proline.     

Critical role of Val-304 in conformational transitions that allow Ca2+ occlusion and phosphoenzyme turnover in the Ca2+ transport ATPase

Site-directed mutations were produced in the distal segments of the Ca(2+)-ATPase (SERCA) transmembrane region. Mutations of Arg-290 (M3-M4 loop), Lys-958, and Thr-960 (M9 - M10 loop) had minor effects on ATPase activity and Ca(2+) transport. On the other hand, Val-304 (M4) mutations to Ile, Thr, Lys, Ala, or Glu inhibited transport by 90-95% while reducing ATP hydrolysis by 83% (Ile, Thr, and Lys), 56% (Ala), or 45% (Glu). Val-304 participates in Ca(2+) coordination with its main-chain carbonyl oxygen, and this function is not expected to be altered by mutations of its side chain. In fact, despite turnover inhibition, the Ca(2+) concentration dependence of residual ATPase activity remained unchanged in Val-304 mutants. However, the rates (but not the final levels) of phosphoenzyme formation, as well the rates of its hydrolytic cleavage, were reduced in proportion to the ATPase activity. Furthermore, with the Val-304 --> Glu mutant, which retained the highest residual ATPase activity, it was possible to show that occlusion of bound Ca(2+) was also impaired, thereby explaining the stronger inhibition of Ca(2+) transport relative to ATPase activity. The effects of Val-304 mutations on phosphoenzyme turnover are attributed to interference with mechanical links that couple movements of transmembrane segments and headpiece domains. The effects of thermal activation energy on reaction rates are thereby reduced. Furthermore, inadequate occlusion of bound Ca(2+) following utilization of ATP in Val-304 side-chain mutations is attributed to inadequate stabilization of the Glu-309 side chain and consequent defect of its gating function.     

Ca2+ occlusion and gating function of Glu309 in the ADP-fluoroaluminate analog of the Ca2+-ATPase phosphoenzyme intermediate

In the absence of ATP the sarcoplasmic reticulum ATPase (SERCA) binds two Ca(2+) with high affinity. The two bound Ca(2+) rapidly undergo reverse dissociation upon addition of EGTA, but can be distinguished by isotopic exchange indicating fast exchange at a superficial site (site II), and retardation of exchange at a deeper site (site I) by occupancy of site II. Site II mutations that allow high affinity binding to site I, but only low affinity binding to site II, show that retardation of isotopic exchange requires higher Ca(2+) concentrations with the N796A mutant, and is not observed with the E309Q mutant even at millimolar Ca(2+). Fluoroaluminate forms a complex at the catalytic site yielding stable analogs of the phosphoenzyme intermediate, with properties similar to E2-P or E1-P.Ca(2). Mutational analysis indicates that Asp(351), Lys(352), Thr(353), Asp(703), Asn(706), Asp(707), Thr(625), and Lys(684) participate in stabilization of fluoroaluminate and Mg(2+) at the phosphorylation site. In the presence of fluoroaluminate and Ca(2+), ADP (or AMP-PCP) favors formation of a stable ADP.E1-P.Ca(2) analog. This produces strong occlusion of Ca(2+) bound to both sites (I and II), whereby dissociation occurs very slowly even following addition of EGTA. Occlusion by fluoraluminate and ADP is not observed with the E309Q mutant, suggesting a gating function of Glu(309) at the mouth of a binding cavity with a single path of entry. This phenomenon corresponds to the earliest step of the catalytic cycle following utilization of ATP. Experiments on limited proteolysis reveal that a long range conformational change, involving displacement of headpiece domains and transmembrane helices, plays a mechanistic role.     

Site-directed disulfide mapping of residues contributing to the Ca2+ and K+ binding pocket of the NCKX2 Na+/Ca2+-K+ exchanger

The Na+/Ca2+-K+ exchanger (NCKX) gene products are polytopic membrane proteins that utilize the existing cellular Na+ and K+ gradients to extrude cytoplasmic Ca2+. NCKX proteins are made up of two clusters of hydrophobic segments, both thought to consist of five putative membrane-spanning alpha-helices, and separated by a large cytoplasmic loop. The two most conserved regions within the NCKX sequence are known as the alpha1 and alpha2 repeats, and are found within the first and second set of transmembrane domains, respectively. The alpha repeats have previously been shown to contain residues critical for transport function. Here we used site-directed disulfide mapping to report that the alpha repeats are found in close proximity in three-dimensional space, bringing together key functional NCKX residues, e.g., the two critical acidic residues, Glu188 and Asp548. Glu188Cys in the alpha1 repeat could form a disulfide cross-link with Asp548Cys in the alpha2 repeat. Surprisingly, cysteine substitutions of Ser185 in the alpha1 repeat could form disulfide cross-links with cysteine substitutions of three residues in the alpha2 repeat (Ser545, Asp548, and Ser552), thought to cover close to two full turns of an alpha helix, implying an area of increased flexibility. Using the same method, Asp575, a residue critical for the K+ dependence of NCKX, was shown to be in the proximity of Ser185 and Glu188, consistent with its role in enabling K+ to bind to a single Ca2+ and K+ binding pocket.     

Importance of Glu(282) in transmembrane segment M3 of the Na(+),K(+)-ATPase for control of cation interaction and conformational changes

Glu(282) located in the NH(2)-terminal part of transmembrane helix M3 of the Na(+),K(+)-ATPase was replaced by alanine, glycine, leucine, lysine, aspartate, or glutamine, and the effects of the mutations on the overall and partial reactions of the enzyme were analyzed. The mutations affected at least 3 important functions of the Na(+),K(+)-ATPase: (i) the conformational transitions between E(1) and E(2) forms of dephospho- and phosphoenzyme, (ii) Na(+) binding at the cytoplasmically facing sites of E(1), and (iii) long-range interaction controlling dephosphorylation. In mutants Glu(282) --> Lys and Glu(282) --> Asp, the E(1) form was favored during ATP hydrolysis, whereas the E(2) form was favored in Glu(282) --> Ala and Glu(282) --> Gly. Regardless of the change of conformational equilibrium, all the mutants displayed a reduced apparent affinity for Na(+), at least 3-fold for Glu(282) --> Lys and Glu(282) --> Asp, suggesting a direct effect on the Na(+) binding properties of E(1). Glu(282) --> Ala and Glu(282) --> Gly exhibited an extraordinary high rate of ATP hydrolysis in the mere presence of Na(+) without K(+) ("Na(+)-ATPase activity"), because of an increased rate of dephosphorylation of E(2)P. These results are in accordance with the hypothesis that Glu(282) is involved in the communication between the cation binding pocket and the catalytic site and in control of the cytoplasmic entry pathway for Na(+).     

Functional consequences of mutations of conserved amino acids in the beta-strand domain of the Ca2(+)-ATPase of sarcoplasmic reticulum

The sequences Thr-Gly-Glu-Ser184 and Asp-Gln-Ser178 and individual residues Asp149, Asp157, and Asp162 in the sarcoplasmic reticulum Ca2(+)-ATPase are highly conserved throughout the family of cation-transporting ATPases. Mutant Thr181----Ala, Gly182----Ala, Glu183----Ala, and Glu183----Gln, created by in vitro mutagenesis, were devoid of Ca2+ transport activity. None of these mutations, however, affected phosphorylation of the enzyme by ATP in the presence of Ca2+ or by inorganic phosphate in the absence of Ca2+, indicating that the high affinity Ca2(+)-binding sites and the nucleotide-binding sites were intact. In each of these mutants, the ADP-sensitive phosphoenzyme intermediate (E1P) decayed to the ADP-insensitive form (E2P) very slowly relative to the wild-type enzyme, whereas E2P decayed at a rate similar to that of the wild-type enzyme. Thus, the inability of the mutants to transport Ca2+ was accounted for by an apparent block of the transport reaction at the E1P to E2P conformational transition. These results suggest that Thr181, Gly182, and Glu183 play essential roles in the conformational change between E1P and E2P. Mutation of Ser184, Asp157, or Ser178 had little or no effect on either Ca2+ transport activity or expression. Mutations of Asp149, Asp162, and Gln177, however, were poorly expressed. Where expression could be measured, in mutations to Asp162 and Gln177, Ca2+ transport activity was essentially equivalent to that of the wild-type enzyme.     

Importance of stalk segment S5 for intramolecular communication in the sarcoplasmic reticulum Ca2+-ATPase

Sixteen residues in stalk segment S5 of the Ca(2+)-ATPase of sarcoplasmic reticulum were studied by site-directed mutagenesis. The rate of the Ca(2+) binding transition, determined at 0 degrees C, was enhanced relative to wild type in mutants Ile(743) --> Ala, Val(747) --> Ala, Glu(748) --> Ala, Glu(749) --> Ala, Met(757) --> Gly, and Gln(759) --> Ala and reduced in mutants Asp(737) --> Ala, Asp(738) --> Ala, Ala(752) --> Leu, and Tyr(754) --> Ala. In mutant Arg(762) --> Ile, the rate of the Ca(2+) binding transition was wild type like at 0 degrees C, whereas it was 3.5-fold reduced relative to wild type at 25 degrees C. The rate of dephosphorylation of the ADP-insensitive phosphoenzyme was increased conspicuously in mutants Ile(743) --> Ala and Tyr(754) --> Ala (close to 20-fold in the absence of K(+)) and increased to a lesser extent in Asn(739) --> Ala, Glu(749) --> Ala, Gly(750) --> Ala, Ala(752) --> Gly, Met(757) --> Gly, and Arg(762) --> Ile, whereas it was reduced in mutants Asp(737) --> Ala, Val(744) --> Gly, Val(744) --> Ala, Val(747) --> Ala, and Ala(752) --> Leu. In mutants Ile(743) --> Ala, Tyr(754) --> Ala, and Arg(762) --> Ile, the apparent affinities for vanadate were enhanced 23-, 30-, and 18-fold, respectively, relative to wild type. The rate of Ca(2+) dissociation was 11-fold increased in Gly(750) --> Ala and 2-fold reduced in Val(747) --> Ala. Mutants with alterations to Arg(751) either were not expressed at a significant level or were completely nonfunctional. The findings show that S5 plays a crucial role in mediating communication between the Ca(2+) binding pocket and the catalytic domain and that Arg(751) is important for both structural and functional integrity of the enzyme.     

Side-chain protonation and mobility in the sarcoplasmic reticulum Ca2+-ATPase: implications for proton countertransport and Ca2+ release

Protonation of acidic residues in the sarcoplasmic reticulum Ca(2+)-ATPase (SERCA 1a) was studied by multiconformation continuum electrostatic calculations in the Ca(2+)-bound state Ca(2)E1, in the Ca(2+)-free state E2(TG) with bound thapsigargin, and in the E2P (ADP-insensitive phosphoenzyme) analog state with MgF(4)(2-) E2(TG+MgF(4)(2-)). Around physiological pH, all acidic Ca(2+) ligands (Glu(309), Glu(771), Asp(800), and Glu(908)) were unprotonated in Ca(2)E1; in E2(TG) and E2(TG+MgF(4)(2-)) Glu(771), Asp(800), and Glu(908) were protonated. Glu(771) and Glu(908) had calculated pK(a) values larger than 14 in E2(TG) and E2(TG+MgF(4)(2-)), whereas Asp(800) titrated with calculated pK(a) values near 7.5. Glu(309) had very different pK(a) values in the Ca(2+)-free states: 8.4 in E2(TG+MgF(4)(2-)) and 4.7 in E2(TG) because of a different local backbone conformation. This indicates that Glu(309) can switch between a high and a low pK(a) mode, depending on the local backbone conformation. Protonated Glu(309) occupied predominantly two main, very differently orientated side-chain conformations in E2(TG+MgF(4)(2-)): one oriented inward toward the other Ca(2+) ligands and one oriented outward toward a protein channel that seems to be in contact with the cytoplasm. Upon deprotonation, Glu(309) adopted completely the outwardly orientated side-chain conformation. The contact of Glu(309) with the cytoplasm in E2(TG+MgF(4)(2-)) makes this residue unlikely to bind lumenal protons. Instead it might serve as a proton shuttle between Ca(2+)-binding site I and the cytoplasm. Glu(771), Asp(800), and Glu(908) are proposed to take part in proton countertransport.     

Functional consequences of alterations to amino acids located in the catalytic center (isoleucine 348 to threonine 357) and nucleotide-binding domain of the Ca2+-ATPase of sarcoplasmic reticulum

The sequence of 10 amino acids (ICSDKTGTLT357) at the site of phosphorylation of the rabbit fast twitch muscle Ca2+-ATPase is highly conserved in the family of cation-transporting ATPases. We changed each of the residues flanking Asp351, Lys352, and Thr353 to an amino acid differing in size or polarity and assayed the mutant for Ca2+ transport activity and autophosphorylation with ATP or P1. We found that conservative changes (Ile----Leu, Thr----Ser, Gly----Ala) or the alteration of Cys349 to alanine did not destroy Ca2+ transport activity or phosphoenzyme formation, whereas nonconservative changes (Ile----Thr, Leu----Ser) did disrupt function. These results indicate that very conservative changes in the amino acids flanking Asp351, Lys352, and Thr353 can be accommodated. A number of mutations were also introduced into amino acids predicted to be involved in nucleotide binding, in particular those in the conserved sequences KGAPE519, RDAGIRVIMITGDNK629, and KK713. Our results indicate that amino acids KGAPE519, Arg615, Gly618, Arg620, and Lys712-Lys713 are not essential for nucleotide binding, although changes to Lys515 diminished Ca2+ transport activity but not phosphoenzyme formation. Changes of Gly626 and Asp627 abolished phosphoenzyme formation with both ATP and Pi, indicating that these residues may contribute to the conformation of the catalytic center.     

Detailed characterization of the cooperative mechanism of Ca(2+) binding and catalytic activation in the Ca(2+) transport (SERCA) ATPase

Expression of heterologous SERCA1a ATPase in Cos-1 cells was optimized to yield levels that account for 10-15% of the microsomal protein, as revealed by protein staining on electrophoretic gels. This high level of expression significantly improved our characterization of mutants, including direct measurements of Ca(2+) binding by the ATPase in the absence of ATP, and measurements of various enzyme functions in the presence of ATP or P(i). Mutational analysis distinguished two groups of amino acids within the transmembrane domain: The first group includes Glu771 (M5), Thr799 (M6), Asp800 (M6), and Glu908 (M8), whose individual mutations totally inhibit binding of the two Ca(2+) required for activation of one ATPase molecule. The second group includes Glu309 (M4) and Asn796 (M6), whose individual or combined mutations inhibit binding of only one and the same Ca(2+). The effects of mutations of these amino acids were interpreted in the light of recent information on the ATPase high-resolution structure, explaining the mechanism of Ca(2+) binding and catalytic activation in terms of two cooperative sites. The Glu771, Thr799, and Asp800 side chains contribute prominently to site 1, together with less prominent contributions by Asn768 and Glu908. The Glu309, Asn796, and Asp800 side chains, as well as the Ala305 (and possibly Val304 and Ile307) carbonyl oxygen, contribute to site 2. Sequential binding begins with Ca(2+) occupancy of site 1, followed by transition to a conformation (E') sensitive to Ca(2+) inhibition of enzyme phosphorylation by P(i), but still unable to utilize ATP. The E' conformation accepts the second Ca(2+) on site 2, producing then a conformation (E' ') which is able to utilize ATP. Mutations of residues (Asp813 and Asp818) in the M6/M7 loop reduce Ca(2+) affinity and catalytic turnover, suggesting a strong influence of this loop on the correct positioning of the M6 helix. Mutation of Asp351 (at the catalytic site within the cytosolic domain) produces total inhibition of ATP utilization and enzyme phosphorylation by P(i), without a significant effect on Ca(2+) binding.     

Functional consequences of alterations to amino acids located in the hinge domain of the Ca(2+)-ATPase of sarcoplasmic reticulum.

Site-specific mutagenesis of the sarcoplasmic reticulum Ca(2+)-ATPase was used to investigate the functional roles of 18 amino acid residues located at or near the "hinge-domain," a highly conserved region of the cation-transporting ATPases. Mutation of Lys684 to arginine, alanine, histidine, and glutamine resulted in complete loss of calcium transport function and ATPase activity. For the Lys684----Ala, histidine, and glutamine mutants, this coincided with a loss of the ability to form a phosphorylated intermediate from ATP or Pi. The Lys684----Arg mutant retained the ability to phorphorylate from ATP with normal apparent affinity, demonstrating the importance of the positive charge. On the other hand, no phosphorylation was observed with Pi as substrate in this mutant. Examination of the partial reactions after phosphorylation from ATP in the Lys684----Arg mutant demonstrated a reduction of the rate of transformation of the ADP-sensitive phosphoenzyme intermediate (E1P) to the ADP-insensitive phosphoenzyme intermediate (E2P), which could account for the loss of transport function. Once accumulated, the E2P intermediate was able to decompose rapidly in the presence of K+ at neutral pH. These results may be interpreted in terms of a preferential destabilization of protein phosphate interactions in the E2P form of this mutant. The Asp703----Ala and Asn-Asp707----Ala-Ala mutants were completely inactive and unable to form phosphoenzyme intermediates from ATP or Pi. In these mutants as well as in the Lys684----Ala mutant, nucleotides were found to protect with normal affinity against intramolecular cross-linking induced with glutaraldehyde, indicating that the nucleotide binding site was intact. Mutation of Glu646, Glu647, Asp659, Asp660, Glu689, Asp695, Glu696, Glu715, and Glu732 to alanine did not affect the maximum rates of calcium transport and ATP hydrolysis or the apparent affinities for calcium and ATP. Mutation of the 2 highly conserved proline residues, Pro681 and Pro709, as well as Lys728, to alanine resulted in partially inhibited Ca(2+)-ATPase enzymes with retention of the ability to form a phosphoenzyme intermediate from ATP or Pi and with normal apparent affinities for ATP and calcium. The proline mutants retained the biphasic ATP concentration dependence of ATPase activity, characteristic of the wild-type, and therefore the partial inhibition of turnover could not be ascribed to a disruption of the low affinity modulatory ATP site.(ABSTRACT TRUNCATED AT 400 WORDS)     

Dissection of the functional differences between sarco(endo)plasmic reticulum Ca2+-ATPase (SERCA) 1 and 2 isoforms and characterization of Darier disease (SERCA2) mutants by steady-state and transient kinetic analyses

Steady-state and rapid kinetic studies were conducted to functionally characterize the overall and partial reactions of the Ca2+ transport cycle mediated by the human sarco(endo)plasmic reticulum Ca2+-ATPase 2 (SERCA2) isoforms, SERCA2a and SERCA2b, and 10 Darier disease (DD) mutants upon heterologous expression in HEK-293 cells. SERCA2b displayed a 10-fold decrease in the rate of Ca2+ dissociation from E1Ca2 relative to SERCA2a (i.e. SERCA2b enzyme manifests true high affinity at cytosolic Ca2+ sites) and a lower rate of dephosphorylation. These fundamental kinetic differences explain the increased apparent affinity for activation by cytosolic Ca2+ and the reduced catalytic turnover rate in SERCA2b. Relative to SERCA1a, both SERCA2 isoforms displayed a 2-fold decrease of the rate of E2 to E1Ca2 transition. Furthermore, seven DD mutants were expressed at similar levels as wild type. The expression level was 2-fold reduced for Gly23 --> Glu and Ser920 --> Tyr and 10-fold reduced for Gly749 --> Arg. Uncoupling between Ca2+ translocation and ATP hydrolysis and/or changes in the rates of partial reactions account for lack of function for 7 of 10 mutants: Gly23 --> Glu (uncoupling), Ser186 --> Phe, Pro602 --> Leu, and Asp702 --> Asn (block of E1 approximately P(Ca2) to E2-P transition), Cys318 --> Arg (uncoupling and 3-fold reduction of E2-P to E2 transition rate), and Thr357 --> Lys and Gly769 --> Arg (lack of phosphorylation). A 2-fold decrease in the E1 approximately P(Ca2) to E2-P transition rate is responsible for the 2-fold decrease in activity for Pro895 --> Leu. Ser920 --> Tyr is a unique DD mutant showing an enhanced molecular Ca2+ transport activity relative to wild-type SERCA2b. In this case, the disease may be a consequence of the low expression level and/or reduction of Ca2+ affinity and sensitivity to inhibition by lumenal Ca2+.     

The N-terminal portion of the main cytosolic loop mediates K+ sensitivity in the retinal rod Na+/Ca2+-K+-exchanger.

Two types of Na+/Ca2+-exchangers have been characterized in the literature: The first is the cardiac, skeletal muscle and brain type, which exchanges 1 Ca2+ for 3 Na+, the second, found in retinal photosensor cells, transports 1 Ca2+ and 1 K+ in exchange for 4 Na+. The present work describes the properties of chimeric constructs of the two exchanger types. Ca2+ gel overlay experiments have identified a high affinity (Kd in the 1 microM range) Ca2+-binding domain between Glu601 and Asp733 in the main cytosolic loop of the retinal protein, just after transmembrane domain 5. Insertion of the retinal Ca2+-binding domain in the cytosolic loop of the cardiac exchanger conferred K+-dependence to the Ca2+ uptake activity of the chimeric constructs expressed in HeLa cells. The apparent Km of the K+ effect was about 1 mM. Experiments with C-terminally truncated versions of the retinal insert indicated that the sequence between Leu643 and Asp733 was critical in mediating K+ sensitivity of the recombinant chimeras. Thus, the high affinity Ca2+-binding domain in the main cytosolic loop of the retinal exchanger may regulate the activity of the retinal protein by binding Ca2+, and by conferring to it K+ sensitivity.     

Importance of transmembrane segment M3 of the sarcoplasmic reticulum Ca2+-ATPase for control of the gateway to the Ca2+ sites

The specific functional roles of various parts of the third transmembrane segment (M3) of the sarcoplasmic reticulum Ca(2+)-ATPase were examined by functionally characterizing a series of mutants with multiple or single substitutions of M3 residues. Steady-state and transient kinetic measurements, assisted by computer simulation of the time and Ca(2+) dependences of the phosphorylation level, were used to study the partial reaction steps of the enzyme cycle, including the binding and dissociation of Ca(2+) at the high affinity cytoplasmically facing sites. The mutation Lys-Leu-Asp-Glu(255) --> Glu-Ile-Glu-His resulted in a conspicuous increase in the rate of Ca(2+) dissociation as well as a displacement of the major conformational equilibria of the phosphoenzyme and dephosphoenzyme forms. The point mutant Phe(256) --> Ala also showed an increased rate of Ca(2+) dissociation, whereas a conspicuous decrease both in the rate of Ca(2+) dissociation and in the rate of Ca(2+) binding was found for the mutant Gly-Glu-Gln-Leu(260) --> Ile-His-Leu-Ile. These findings suggest that the NH(2)-terminal half of M3 is involved in control of the gateway to the Ca(2+) sites. The main effect of two mutations to the COOH-terminal half of M3, Ser-Lys-Val-Ile-Ser(265) --> Thr-Gly-Val-Ala-Val and Leu-Ile-Cys-Val-Ala-Val-Trp-Leu-Ile(274) --> Phe-Leu-Gly-Val-Ser-Phe-Phe-Ile-Leu, was a block of the dephosphorylation.     

Inhibition of sarcoplasmic reticulum Ca2+-ATPase by Mg2+ at high pH

Steady state turnover of Ca2+-ATPase of sarcoplasmic reticulum has generally been reported to have a bell-shaped pH profile, with an optimum near pH 7.0. While a free [Mg2+] of 2 mM is optimal for activity at pH 7.0, it was found that this level was markedly inhibitory (K1/2 = 2 mM) at pH 8.0, thus accounting for the generally observed low activity at high pH. High activity was restored at pH 8.0 using an optimum free [Mg2+] of 0.2 mM. The mechanism of the Mg2+-dependent inhibition at pH 8.0 was probed. Inhibition was not due to Mg2+ competition with Ca2+ for cytoplasmic transport sites nor to inhibition of formation of steady state phosphoenzyme from ATP. Mg2+ inhibited (K1/2 = 1.8 mM) decay of steady state phosphoenzyme; thus, the locus of inhibition was one of the phosphoenzyme interconversion steps. Transient kinetic experiments showed that Mg2+ competitively inhibited (Ki = 0.7 mM) binding of Ca2+ to lumenal transport sites, blocking the ability of Ca2+ to reverse the catalytic cycle to form ADP-sensitive, from ADP-insensitive, phosphoenzyme. The data were consistent with a hypothesis in which Mg2+ binds lumenal Ca2+ transport sites with progressively higher affinity at higher pH to form a dead-end complex; its dissociation would then be rate-limiting during steady state turnover.     

Identification of acidic residues in the extracellular loops of the seven-transmembrane domain of the human Ca2+ receptor critical for response to Ca2+ and a positive allosteric modulator

We investigated the role of the eight acidic residues in the extracellular loops (exo-loops) of the seven-transmembrane domain of the human Ca(2+) receptor (hCaR) in receptor activation by Ca(2+) and in response to a positive allosteric modulator, NPS R-568. Both in the context of the full-length receptor and of a truncated receptor lacking the extracellular domain (Rho-C-hCaR), we mutated each acidic residue to alanine, singly and in combination, and tested the effect on expression of the receptor, on activation by Ca(2+), and on NPS R-568 augmentation of sensitivity to Ca(2+). Of the eight acidic residues, mutation of any of three in exo-loop 2, Asp(758), Glu(759), and Glu(767), increased the sensitivity of both the full-length hCaR and of Rho-C-hCaR to activation by Ca(2+). Mutation of all five acidic residues in exo-loop 2, whether in the full-length receptor or in Rho-C-hCaR, impaired cell surface expression of the mutant receptor and thereby largely abolished response to Ca(2+). Mutation of Glu(837) in exo-loop 3 to alanine did not alter Ca(2+) sensitivity of the full-length receptor, but in both the latter context and in Rho-C-hCaR, alanine substitution of Glu(837) drastically reduced sensitivity to NPS R-568. Our data point to a key role of three specific acidic residues in exo-loop 2 in hCaR activation and to Glu(837) at the junction between exo-loop 3 and transmembrane helix seven in response to NPS R-568. We speculate on the basis of these results that the three acidic residues we identified in exo-loop 2 help maintain an inactive conformation of the seven-transmembrane domain of the hCaR.