The average conformation at micromolar [Ca2+] of Ca2+-atpase with bound nucleotide differs from that adopted with the transition state analog ADP.AlFx or with AMPPCP under crystallization conditions at millimolar [Ca2+]

Isolation of the Sarcoplasmic Reticulum Ca2+-ATPase from Rabbit Fast-Twitch Muscle

The sarcoendoplasmic reticulum Ca2+-ATPase (SERCA) is a membrane protein that is destabilized during purification in the absence of calcium ions. The disaccharide trehalose is a protein stabilizer that accumulates in the yeast cytoplasm when under stress. In the present work, SERCA was purified by including trehalose in the purification protocol. The purified SERCA showed high protein purity (~95%) and ATPase activity. ATP hydrolysis was dependent on the presence of Ca2+ and the enzyme kinetics showed a hyperbolic dependence on ATP (Km = 12.16 ± 2.25 μM ATP). FITC labeling showed the integrity of the ATP-binding site and the identity of the isolated enzyme as a P-type ATPase. Circular dichroism (CD) spectral changes at a wavelength of 225 nm were observed upon titration with ATP, indicating α-helical rearrangements in the nucleotide-binding domain (N-domain), which correlated with ATP affinity (Km). The presence of Ca2+ did not affect FITC labeling or the ATP-mediated structural changes at the N-domain. The use of trehalose in the SERCA purification protocol stabilized the enzyme. The isolated SERCA appears to be suitable for structural and ligand binding studies, e.g., for testing newly designed or natural inhibitors. The use of trehalose is recommended for the isolation of unstable enzymes.

Redistribution of SERCA calcium pump conformers during intracellular calcium signaling

The conformational changes of a calcium transport ATPase were investigated with molecular dynamics (MD) simulations as well as fluorescence resonance energy transfer (FRET) measurements to determine the significance of a discrete structural element for regulation of the conformational dynamics of the transport cycle. Previous MD simulations indicated that a loop in the cytosolic domain of the SERCA calcium transporter facilitates an open-to-closed structural transition. To investigate the significance of this structural element, we performed additional MD simulations and new biophysical measurements of SERCA structure and function. Rationally designed in silico mutations of three acidic residues of the loop decreased SERCA domain-domain contacts and increased domain-domain separation distances. Principal component analysis of MD simulations suggested decreased sampling of compact conformations upon N-loop mutagenesis. Deficits in headpiece structural dynamics were also detected by measuring intramolecular FRET of a Cer-YFP-SERCA construct (2-color SERCA). Compared with WT, the mutated 2-color SERCA shows a partial FRET response to calcium, whereas retaining full responsiveness to the inhibitor thapsigargin. Functional measurements showed that the mutated transporter still hydrolyzes ATP and transports calcium, but that maximal enzyme activity is reduced while maintaining similar calcium affinity. In live cells, calcium elevations resulted in concomitant FRET changes as the population of WT 2-color SERCA molecules redistributed among intermediates of the transport cycle. Our results provide novel insights on how the population of SERCA pumps responds to dynamic changes in intracellular calcium.

Structural and Biochemical Studies on the Reaction Mechanism of Uridine-Cytidine Kinase

Uridine-cytidine kinase catalyzes phosphorylation of the pyrimidine nucleosides uridine and cytidine and plays an important role in nucleotide metabolism. However, the detailed molecular mechanism of these reactions remains to be elucidated. Here, we determined the structure of the ternary complex of Uridine-cytidine kinase from Thermus thermophilus HB8 with both cytidine and β,γ-methyleneadenosine 5'-triphosphate, a non-hydrolysable ATP analogue. Substrate binding is accompanied by substantial domain movement that allows the substrate-binding cleft to close. The terminal phosphodiester bond of the ATP analogue is in an ideal location for an inline attack of the 5'-hydroxyl group of cytidine. Asp40 is located near the 5'-hydroxyl group of cytidine. Mutation of this conserved residue to Asn or Ala resulted in a complete loss of enzyme activity, which is consistent with the notion that Asp40 acts as a general base that activates the 5'-hydroxyl group of cytidine. The pH profile of the activity showed an apparent pK a value of 7.4. Based on this structure, a likely mechanism of the catalytic step is discussed.

SERCA mutant E309Q binds two Ca(2+) ions but adopts a catalytically incompetent conformation

The sarco(endo)plasmic reticulum Ca(2+)-ATPase (SERCA) couples ATP hydrolysis to transport of Ca(2+). This directed energy transfer requires cross-talk between the two Ca(2+) sites and the phosphorylation site over 50 Å distance. We have addressed the mechano-structural basis for this intramolecular signal by analysing the structure and the functional properties of SERCA mutant E309Q. Glu(309) contributes to Ca(2+) coordination at site II, and a consensus has been that E309Q only binds Ca(2+) at site I. The crystal structure of E309Q in the presence of Ca(2+) and an ATP analogue, however, reveals two occupied Ca(2+) sites of a non-catalytic Ca2E1 state. Ca(2+) is bound with micromolar affinity by both Ca(2+) sites in E309Q, but without cooperativity. The Ca(2+)-bound mutant does phosphorylate from ATP, but at a very low maximal rate. Phosphorylation depends on the correct positioning of the A-domain, requiring a shift of transmembrane segment M1 into an 'up and kinked position'. This transition is impaired in the E309Q mutant, most likely due to a lack of charge neutralization and altered hydrogen binding capacities at Ca(2+) site II.

The sarcoplasmic Ca2+-ATPase: design of a perfect chemi-osmotic pump

The sarcoplasmic (SERCA 1a) Ca2+-ATPase is a membrane protein abundantly present in skeletal muscles where it functions as an indispensable component of the excitation-contraction coupling, being at the expense of ATP hydrolysis involved in Ca2+/H+ exchange with a high thermodynamic efficiency across the sarcoplasmic reticulum membrane. The transporter serves as a prototype of a whole family of cation transporters, the P-type ATPases, which in addition to Ca2+ transporting proteins count Na+, K+-ATPase and H+, K+-, proton- and heavy metal transporting ATPases as prominent members. The ability in recent years to produce and analyze at atomic (2·3-3 Å) resolution 3D-crystals of Ca2+-transport intermediates of SERCA 1a has meant a breakthrough in our understanding of the structural aspects of the transport mechanism. We describe here the detailed construction of the ATPase in terms of one membraneous and three cytosolic domains held together by a central core that mediates coupling between Ca2+-transport and ATP hydrolysis. During turnover, the pump is present in two different conformational states, E1 and E2, with a preference for the binding of Ca2+ and H+, respectively. We discuss how phosphorylated and non-phosphorylated forms of these conformational states with cytosolic, occluded or luminally exposed cation-binding sites are able to convert the chemical energy derived from ATP hydrolysis into an electrochemical gradient of Ca2+ across the sarcoplasmic reticulum membrane. In conjunction with these basic reactions which serve as a structural framework for the transport function of other P-type ATPases as well, we also review the role of the lipid phase and the regulatory and thermodynamic aspects of the transport mechanism.

What can be learned about the function of a single protein from its various X-ray structures: the example of the sarcoplasmic calcium pump

Improvements in the handling of membrane proteins for crystallization, combined with better synchrotron sources for X-ray diffraction analysis, are leading to clarification of the structural details of an ever increasing number of membrane transporters and receptors. Here we describe how this development has resulted in the elucidation at atomic resolution of a large number of structures of the sarcoplasmic Ca(2+)-ATPase (SERCA1a) present in skeletal muscle. The structures corresponding to the various intermediary states have been obtained after stabilization with structural analogues of ATP and of metal fluorides as mimicks of inorganic phosphate. From these results it is possible, in accordance with previous biochemical and molecular biology data, to give a detailed structural description of both ATP hydrolysis and Ca(2+) transport through the membrane, to serve as the starting point for a fuller understanding of the pump mechanism and, in future studies, on the regulatory role of this ubiquitous intracellular Ca(2+)-ATPase in cellular Ca(2+) metabolism in normal and pathological conditions.

Changes in electrostatic surface potential of Na+/K+-ATPase cytoplasmic headpiece induced by cytoplasmic ligand(s) binding

A set of single-tryptophan mutants of the Na(+)/K(+)-ATPase isolated, large cytoplasmic loop connecting transmembrane helices M4 and M5 (C45) was prepared to monitor effects of the natural cytoplasmic ligands (i.e., Mg(2+) and/or ATP) binding. We introduced a novel method for the monitoring of the changes in the electrostatic surface potential (ESP) induced by ligand binding, using the quenching of the intrinsic tryptophan fluorescence by acrylamide or iodide. This approach opens a new way to understanding the interactions within the proteins. Our experiments revealed that the C45 conformation in the presence of the ATP (without magnesium) substantially differed from the conformation in the presence of Mg(2+) or MgATP or in the absence of any ligand not only in the sense of geometry but also in the sense of the ESP. Notably, the set of ESP-sensitive residues was different from the set of geometry-sensitive residues. Moreover, our data indicate that the effect of the ligand binding is not restricted only to the close environment of the binding site and that the information is in fact transmitted also to the distal parts of the molecule. This property could be important for the communication between the cytoplasmic headpiece and the cation binding sites located within the transmembrane domain.

Determination of the dissociation constants for Ca2+ and calmodulin from the plasma membrane Ca2+ pump by a lipid probe that senses membrane domain changes

The purpose of this work was to obtain information about conformational changes of the plasma membrane Ca(2+)-pump (PMCA) in the membrane region upon interaction with Ca(2+), calmodulin (CaM) and acidic phospholipids. To this end, we have quantified labeling of PMCA with the photoactivatable phosphatidylcholine analog [(125)I]TID-PC/16, measuring the shift of conformation E(2) to the auto-inhibited conformation E(1)I and to the activated E(1)A state, titrating the effect of Ca(2+) under different conditions. Using a similar approach, we also determined the CaM-PMCA dissociation constant. The results indicate that the PMCA possesses a high affinity site for Ca(2+) regardless of the presence or absence of activators. Modulation of pump activity is exerted through the C-terminal domain, which induces an apparent auto-inhibited conformation for Ca(2+) transport but does not modify the affinity for Ca(2+) at the transmembrane domain. The C-terminal domain is affected by CaM and CaM-like treatments driving the auto-inhibited conformation E(1)I to the activated E(1)A conformation and thus modulating the transport of Ca(2+). This is reflected in the different apparent constants for Ca(2+) in the absence of CaM (calculated by Ca(2+)-ATPase activity) that sharply contrast with the lack of variation of the affinity for the Ca(2+) site at equilibrium. This is the first time that equilibrium constants for the dissociation of Ca(2+) and CaM ligands from PMCA complexes are measured through the change of transmembrane conformations of the pump. The data further suggest that the transmembrane domain of the PMCA undergoes major rearrangements resulting in altered lipid accessibility upon Ca(2+) binding and activation.

Formation of the stable structural analog of ADP-sensitive phosphoenzyme of Ca2+-ATPase with occluded Ca2+ by beryllium fluoride: structural changes during phosphorylation and isomerization

As a stable analog for ADP-sensitive phosphorylated intermediate of sarcoplasmic reticulum Ca(2+)-ATPase E1PCa(2).Mg, a complex of E1Ca(2).BeF(x), was successfully developed by addition of beryllium fluoride and Mg(2+) to the Ca(2+)-bound state, E1Ca(2). In E1Ca(2).BeF(x), most probably E1Ca(2).BeF(3)(-), two Ca(2+) are occluded at high affinity transport sites, its formation required Mg(2+) binding at the catalytic site, and ADP decomposed it to E1Ca(2), as in E1PCa(2).Mg. Organization of cytoplasmic domains in E1Ca(2).BeF(x) was revealed to be intermediate between those in E1Ca(2).AlF(4)(-) ADP (transition state of E1PCa(2) formation) and E2.BeF(3)(-).(ADP-insensitive phosphorylated intermediate E2P.Mg). Trinitrophenyl-AMP (TNP-AMP) formed a very fluorescent (superfluorescent) complex with E1Ca(2).BeF(x) in contrast to no superfluorescence of TNP-AMP bound to E1Ca(2).AlF(x). E1Ca(2).BeF(x) with bound TNP-AMP slowly decayed to E1Ca(2), being distinct from the superfluorescent complex of TNP-AMP with E2.BeF(3)(-), which was stable. Tryptophan fluorescence revealed that the transmembrane structure of E1Ca(2).BeF(x) mimics E1PCa(2).Mg, and between those of E1Ca(2).AlF(4)(-).ADP and E2.BeF(3)(-). E1Ca(2).BeF(x) at low 50-100 microm Ca(2+) was converted slowly to E2.BeF(3)(-) releasing Ca(2+), mimicking E1PCa(2).Mg --> E2P.Mg + 2Ca(2+). Ca(2+) replacement of Mg(2+) at the catalytic site at approximately millimolar high Ca(2+) decomposed E1Ca(2).BeF(x) to E1Ca(2). Notably, E1Ca(2).BeF(x) was perfectly stabilized for at least 12 days by 0.7 mm lumenal Ca(2+) with 15 mm Mg(2+). Also, stable E1Ca(2).BeF(x) was produced from E2.BeF(3)(-) at 0.7 mm lumenal Ca(2+) by binding two Ca(2+) to lumenally oriented low affinity transport sites, as mimicking the reverse conversion E2P. Mg + 2Ca(2+) --> E1PCa(2).Mg.

Concerted but noncooperative activation of nucleotide and actuator domains of the Ca-ATPase upon calcium binding

Calcium-dependent domain movements of the actuator (A) and nucleotide (N) domains of the SERCA2a isoform of the Ca-ATPase were assessed using constructs containing engineered tetracysteine binding motifs, which were expressed in insect High-Five cells and subsequently labeled with the biarsenical fluorophore 4',5'-bis(1,3,2-dithioarsolan-2-yl)fluorescein (FlAsH-EDT(2)). Maximum catalytic function is retained in microsomes isolated from High-Five cells and labeled with FlAsH-EDT(2). Distance measurements using the nucleotide analog 2',3'-O-(2,4,6-trinitrophenyl) adenosine 5'-triphosphate (TNP-ATP), which acts as a fluorescence resonance energy transfer (FRET) acceptor from FlAsH, identify a 2.4 A increase in the spatial separation between the N- and A-domains induced by high-affinity calcium binding; this structural change is comparable to that observed in crystal structures. No significant distance changes occur across the N-domain between FlAsH and TNP-ATP, indicating that calcium activation induces rigid body domain movements rather than intradomain conformational changes. Calcium-dependent decreases in the fluorescence of FlAsH bound, respectively, to either the N- or A-domains indicate coordinated and noncooperative domain movements, where both A- and N-domains display virtually identical calcium dependencies (i.e., K(d) = 4.8 +/- 0.4 microM). We suggest that occupancy of a single high-affinity calcium binding site induces the rearrangement of the A- and N-domains of the Ca-ATPase to form an intermediate state, which facilitates phosphoenzyme formation from ATP upon occupancy of the second high-affinity calcium site.

ATP and magnesium drive conformational changes of the Na+/K+-ATPase cytoplasmic headpiece

Conformational changes of the Na(+)/K(+)-ATPase isolated large cytoplasmic segment connecting transmembrane helices M4 and M5 (C45) induced by the interaction with enzyme ligands (i.e. Mg(2+) and/or ATP) were investigated by means of the intrinsic tryptophan fluorescence measurement and molecular dynamic simulations. Our data revealed that this model system consisting of only two domains retained the ability to adopt open or closed conformation, i.e. behavior, which is expected from the crystal structures of relative Ca(2+)-ATPase from sarco(endo)plasmic reticulum for the corresponding part of the entire enzyme. Our data revealed that the C45 is found in the closed conformation in the absence of any ligand, in the presence of Mg(2+) only, or in the simultaneous presence of Mg(2+) and ATP. Binding of the ATP alone (i.e. in the absence of Mg(2+)) induced open conformation of the C45. The fact that the transmembrane part of the enzyme was absent in our experiments suggested that the observed conformational changes are consequences only of the interaction with ATP or Mg(2+) and may not be related to the transported cations binding/release, as generally believed. Our data are consistent with the model, where ATP binding to the low-affinity site induces conformational change of the cytoplasmic part of the enzyme, traditionally attributed to E2-->E1 transition, and subsequent Mg(2+) binding to the enzyme-ATP complex induces in turn conformational change traditionally attributed to E1-->E2 transition.

Use of glycerol-containing media to study the intrinsic fluorescence properties of detergent-solubilized native or expressed SERCA1a

Rapid irreversible inactivation of Ca (2+)-free states of detergent-solubilized SERCA1a (sarco-endoplasmic reticulum calcium ATPase 1a) has so far prevented the use of Trp fluorescence for functional characterization of this ATPase after its solubilization in various detergents. Here we show that using 20-40% glycerol for protection makes this fluorescence characterization possible. Most of the ligand-induced Trp fluorescence changes previously demonstrated to occur for SERCA1a embedded in native sarcoplasmic reticulum membranes were observed in the combined presence of glycerol and detergent, although the results greatly depended on the detergent used, namely, octaethylene glycol mono- n-dodecyl ether (C 12E 8) or dodecyl maltoside (DDM). In particular, at pH 6, we found a C 12E 8-dependent unexpectedly huge reduction in SERCA1a affinity for Ca (2+). We suggest that a major reason for the different effects of the two detergents is that high concentrations of C 12E 8, but not of DDM, slow down the E2 to E1 transition in solubilized and delipidated SERCA1a. Independently of the characterization of the specific effects of various detergents on SR vesicles, our results open the way to functional characterization by Trp fluorescence of heterologously expressed and purified mutants of SERCA1a in the presence of detergent, without their preliminary reconstitution into liposomes. As an example, we used the E309Q mutant to demonstrate our previous suspicion that Ca (2+) binding to Site I of SERCA1a in fact slightly reduces Trp fluorescence, and consequently that the rise in this fluorescence generally observed when two Ca (2+) ions bind to WT SERCA1a mainly reflects Ca (2+) binding at Site II of SERCA1a.

Structural aspects of ion pumping by Ca2+-ATPase of sarcoplasmic reticulum

Ca2+-ATPase of muscle sarcoplasmic reticulum is an ATP-powered Ca2+-pump that establishes a >10,000-fold concentration gradient across the membrane. Its crystal structures have been determined for nine different states that cover nearly the entire reaction cycle. Presented here is a brief structural account of the ion pumping process, which is achieved by a series of very large domain rearrangements.

Crystal structure of D351A and P312A mutant forms of the mammalian sarcoplasmic reticulum Ca(2+) -ATPase reveals key events in phosphorylation and Ca(2+) release

In recent years crystal structures of the sarcoplasmic reticulum Ca(2+)-ATPase (SERCA1a), stabilized in various conformations with nucleotide and phosphate analogs, have been obtained. However, structural analysis of mutant forms would also be valuable to address key mechanistic aspects. We have worked out a procedure for affinity purification of SERCA1a heterologously expressed in yeast cells, producing sufficient amounts for crystallization and biophysical studies. We present here the crystal structures of two mutant forms, D351A and P312A, to address the issue whether the profound functional changes seen for these mutants are caused by major structural changes. We find that the structure of P312A with ADP and AlF(4)(-) bound (3.5-A resolution) and D351A with AMPPCP or ATP bound (3.4- and 3.7-A resolution, respectively) deviate only slightly from the complexes formed with that of wild-type ATPase. ATP affinity of the D351A mutant was very high, whereas the affinity for cytosolic Ca(2+) was similar to that of the wild type. We conclude from an analysis of data that the extraordinary affinity of the D351A mutant for ATP is caused by the electrostatic effects of charge removal and not by a conformational change. P312A exhibits a profound slowing of the Ca(2+)-translocating Ca(2)E1P-->E2P transition, which seems to be due to a stabilization of Ca(2)E1P rather than a destabilization of E2P. This can be accounted for by the strain that the Pro residue induces in the straight M4 helix of the wild type, which is removed upon the replacement of Pro(312) with alanine in P312A.

Structural analysis of 2D crystals of gastric H+,K+-ATPase in different states of the transport cycle

The H+,K+-ATPase uses ATP to pump protons across the gastric membrane. We used electron crystallography and limited trypsin proteolysis to study conformational changes in the H+,K+-ATPase. Well-ordered 2D crystals were obtained with detergent-solubilized H+,K+-ATPase at low pH in the absence of nucleotides, E1 state, and in the presence of fluoroaluminate and ADP, mimicking the E1PADP state. Projection maps obtained with frozen-hydrated two-dimensional crystals of the H+,K+-ATPase in these two states looked very similar, suggesting only small conformational changes during the transition from the E1 to the E1P x ADP state. This result differs from the X-ray crystal structures of the related ATPase SERCA, which revealed substantially different conformations in the E1 and E1P x ADP states. To further characterize the conformational changes in the H+,K+-ATPase during its transport cycle, we performed limited proteolysis with trypsin. All examined states of the H+,K+-ATPase, including the E1 and E1P x ADP states present in the 2D crystals,showed characteristic differences in the digestion patterns. While the results from the limited proteolysis experiments thus show that the H+,K+-ATPase adopts distinct conformations during different stages of the transport cycle, the projection maps indicate that the structural rearrangements in the H+,K+-ATPase are much smaller than those observed in the related SERCA ATPase.

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.

Critical role of Glu40-Ser48 loop linking actuator domain and first transmembrane helix of Ca2+-ATPase in Ca2+ deocclusion and release from ADP-insensitive phosphoenzyme

The functional importance of the length of the A/M1 linker (Glu(40)-Ser(48)) connecting the actuator domain and the first transmembrane helix of sarcoplasmic reticulum Ca(2+)-ATPase was explored by its elongation with glycine insertion at Pro(42)/Ala(43) and Gly(46)/Lys(47). Two or more glycine insertions at each site completely abolished ATPase activity. The isomerization of phosphoenzyme (EP) intermediate from the ADP-sensitive form (E1P) to the ADP-insensitive form (E2P) was markedly accelerated, but the decay of EP was completely blocked in these mutants. The E2P accumulated was therefore demonstrated to be E2PCa(2) possessing two occluded Ca(2+) ions at the transport sites, and the Ca(2+) deocclusion and release into lumen were blocked in the mutants. By contrast, the hydrolysis of the Ca(2+)-free form of E2P produced from P(i) without Ca(2+) was as rapid in the mutants as in the wild type. Analysis of resistance against trypsin and proteinase K revealed that the structure of E2PCa(2) accumulated is an intermediate state between E1PCa(2) and the Ca(2+)-released E2P state. Namely in E2PCa(2), the actuator domain is already largely rotated from its position in E1PCa(2) and associated with the phosphorylation domain as in the Ca(2+)-released E2P state; however, in E2PCa(2), the hydrophobic interactions among these domains and Leu(119)/Tyr(122) on the top of second transmembrane helix are not yet formed properly. This is consistent with our previous finding that these interactions at Tyr(122) are critical for formation of the Ca(2+)-released E2P structure. Results showed that the EP isomerization/Ca(2+)-release process consists of the following two steps: E1PCa(2) --> E2PCa(2) --> E2P + 2Ca(2+); and the intermediate state E2PCa(2) was identified for the first time. Results further indicated that the A/M1 linker with its appropriately short length, probably because of the strain imposed in E2PCa(2), is critical for the correct positioning and interactions of the actuator and phosphorylation domains to cause structural changes for the Ca(2+) deocclusion and release.

Proton paths in the sarcoplasmic reticulum Ca(2+) -ATPase

The sarcoplasmic reticulum Ca(2+)-ATPase (SERCA1a) pumps Ca(2+) and countertransport protons. Proton pathways in the Ca(2+) bound and Ca(2+)-free states are suggested based on an analysis of crystal structures to which water molecules were added. The pathways are indicated by chains of water molecules that interact favorably with the protein. In the Ca(2+) bound state Ca(2)E1, one of the proposed Ca(2+) entry paths is suggested to operate additionally or alternatively as proton pathway. In analogs of the ADP-insensitive phosphoenzyme E2P and in the Ca(2+)-free state E2, the proton path leads between transmembrane helices M5 to M8 from the lumenal side of the protein to the Ca(2+) binding residues Glu-771, Asp-800 and Glu-908. The proton path is different from suggested Ca(2+) dissociation pathways. We suggest that separate proton and Ca(2+) pathways enable rapid (partial) neutralization of the empty cation binding sites. For this reason, transient protonation of empty cation binding sites and separate pathways for different ions are advantageous for P-type ATPases in general.

Domain organization and movements in heavy metal ion pumps: papain digestion of CopA, a Cu+-transporting ATPase

To study domain organization and movements in the reaction cycle of heavy metal ion pumps, CopA, a bacterial Cu+-ATPase from Thermotoga maritima was cloned, overexpressed, and purified, and then subjected to limited proteolysis using papain. Stable analogs of intermediate states were generated using AMPPCP as a nonhydrolyzable ATP analog and AlFx as a phosphate analog, following conditions established for Ca2+-ATPase (SERCA1). Characteristic digestion patterns obtained for different analog intermediates show that CopA undergoes domain rearrangements very similar to those of SERCA1. Digestion sites were identified on the loops connecting the A-domain and the transmembrane helices M2 and M3 as well as on that connecting the N-terminal metal binding domain (NMBD) and the first transmembrane helix, Ma. These digestion sites were protected in the E1P.ADP and E2P analogs, whereas the M2-A-domain loop was cleaved specifically in the absence of ions to be transported, just as in SERCA1. ATPase activity was lost when the link between the NMBD and the transmembrane domain was cleaved, indicating that the NMBD plays a critical role in ATP hydrolysis in T. maritima CopA. The change in susceptibility of the loop between the NMBD and Ma helix provides evidence that the NMBD is associated to the A-domain and recruited into domain rearrangements and that the Ma helix is the counterpart of the M1 helix in SERCA1 and Mb and Mc are uniquely inserted before M2.

Ca2+ versus Mg2+ coordination at the nucleotide-binding site of the sarcoplasmic reticulum Ca2+-ATPase

The recently determined crystal structure of the sarcoplasmic reticulum Ca2+-ATPase (SERCA1a) with a bound ATP analogue (AMPPCP) reveals a compact state, similar to that found in the presence of ADP and aluminium fluoride. However, although the two Ca2+-binding sites in the membrane are known to be occluded in the latter state, in the AMPPCP-bound state the Ca2+-binding sites are not occluded under conditions with physiological levels of Mg2+ and Ca2+. It has been shown that the high concentration (10 mM) of Ca2+ used for crystallization (in the presence of Mg2+) may be responsible for the discrepancy. To determine whether Ca2+ competes with Mg2+ and affects the nucleotide-binding site, we have subjected the AMPPCP and ADP:AlF4- bound forms to crystallographic analysis by anomalous difference Fourier maps, and we have compared AMPPCP-bound forms crystallized in the absence or in the presence of Mg2+. We found that Ca2+ rather than Mg2+ binds together with AMPPCP at the phosphorylation site, whereas the ADP:AlF4- complex is associated with two magnesium ions. These results address the structure of the phosphorylation site before and during phosphoryl transfer. The bound CaAMPPCP nucleotide may correspond to the activated pre-complex, formed immediately before phosphorylation, whereas the Mg(2)ADP:AlF4- transition state complex reflects the preference for Mg2+ in catalysis. In addition, we have identified a phosphatidylcholine lipid molecule bound at the cytosol-membrane interface.

Concerted conformational effects of Ca2+ and ATP are required for activation of sequential reactions in the Ca2+ ATPase (SERCA) catalytic cycle

We relate solution behavior to the crystal structure of the Ca2+ ATPase (SERCA). We find that nucleotide binding occurs with high affinity through interaction of the adenosine moiety with the N domain, even in the absence of Ca2+ and Mg2+, or to the closed conformation stabilized by thapsigargin (TG). Why then is Ca2+ crucial for ATP utilization? The influence of adenosine 5'-(beta,gamma-methylene) triphosphate (AMPPCP), Ca2+, and Mg2+ on proteolytic digestion patterns, interpreted in the light of known crystal structures, indicates that a Ca2+-dependent conformation of the ATPase headpiece is required for a further transition induced by nucleotide binding. This includes opening of the headpiece, which in turn allows inclination of the "A" domain and bending of the "P" domain. Thereby, the phosphate chain of bound ATP acquires an extended configuration allowing the gamma-phosphate to reach Asp351 to form a complex including Mg2+. We demonstrate by Asp351 mutation that this "productive" conformation of the substrate-enzyme complex is unstable because of electrostatic repulsion at the phosphorylation site. However, this conformation is subsequently stabilized by covalent engagement of the -phosphate yielding the phosphoenzyme intermediate. We also demonstrate that the ADP product remains bound with high affinity to the transition state complex but dissociates with lower affinity as the phosphoenzyme undergoes a further conformational change (i.e., E1-P to E2-P transition). Finally, we measured low-affinity ATP binding to stable phosphoenzyme analogues, demonstrating that the E1-P to E2-P transition and the enzyme turnover are accelerated by ATP binding to the phosphoenzyme in exchange for ADP.

Structures of the Ca2+-ATPase complexes with ATP, AMPPCP and AMPPNP. An FTIR study

We studied binding of ATP and of the ATP analogs adenosine 5'-(beta,gamma-methylene)triphosphate (AMPCP) and beta,gamma-imidoadenosine 5'-triphosphate (AMPPNP) to the Ca(2+)-ATPase of the sarcoplasmic reticulum membrane (SERCA1a) with time-resolved infrared spectroscopy. In our experiments, ATP reacted with ATPase which had AMPPCP or AMPPNP bound. These experiments monitored exchange of ATP analog by ATP and phosphorylation to the first phosphoenzyme intermediate Ca(2)E1P. These reactions were triggered by the release of ATP from caged ATP. Only small differences in infrared absorption were observed between the ATP complex and the complexes with AMPPCP and AMPPNP indicating that overall the interactions between nucleotide and ATPase are similar and that all complexes adopt a closed conformation. The spectral differences between ATP and AMPPCP complex were more pronounced at high Ca(2+) concentration (10 mM). They are likely due to a different position of the gamma-phosphate which affects the beta-sheet in the P domain.

The structural basis for coupling of Ca2+ transport to ATP hydrolysis by the sarcoplasmic reticulum Ca2+-ATPase

Recently, a series of structure determinations has nearly completed a structural description of the transport cycle of the sarcoplasmic reticulum Ca(2+)-ATPase, especially those steps concerned with the phosphorylation by ATP and the dephosphorylation reaction. From these structures Ca(2+)-ATPase emerges as a molecular machine, where globular cytosolic domains and transmembrane helices work in concert like a mechanical pump, as can be vividly demonstrated in animated versions of the pump cycle. The structures show that both ATP phosphorylation and dephosphorylation at Asp351 take place as nucleophilic SN2 reactions, which are associated with Ca(2+) and H(+) occluded states, respectively. These transitory steps ensure efficient coupling between Ca(2+) transport and ATP hydrolysis.

ATP-binding to P-type ATPases as revealed by biochemical, spectroscopic, and crystallographic experiments

P-type ATPases form a large family of cation translocating ATPases. Recent progress in crystallography yielded several high-resolution structures of Ca(2+)-ATPase from sarco(endo)plasmic reticulum (SERCA) in various conformations. They could elucidate the conformational changes of the enzyme, which are necessary for the translocation of cations, or the mechanism that explains how the nucleotide binding is coupled to the cation transport. However, crystals of proteins are usually obtained only under conditions that significantly differ from the physiological ones and with ligands that are incompatible with the enzyme function, and both of these factors can inevitably influence the enzyme structure. Biochemical (such as mutagenesis, cleavage, and labeling) or spectroscopic experiments can yield only limited structural information, but this information could be considered relevant, because measurement can be performed under physiological conditions and with true ligands. However, interpretation of some biochemical or spectroscopic data could be difficult without precise knowledge of the structure. Thus, only a combination of both these approaches can extract the relevant information and identify artifacts. Briefly, there is good agreement between crystallographic and other experimental data concerning the overall shape of the molecule and the movement of cytoplasmic domains. On the contrary, the E1-AMPPCP crystallographic structure is, in details, in severe conflict with numerous spectroscopic experiments and probably does not represent the physiological state. Notably, the E1-ADP-AlF(4) structure is almost identical to the E1-AMPPCP, again suggesting that the structure is primarily determined by the crystal-growth conditions. The physiological relevance of the E2 and E2-P structures is also questionable, because the crystals were prepared in the presence of thapsigargin, which is known to be a very efficient inhibitor of SERCA. Thus, probably only crystals of E1-2Ca conformation could reflect some physiological state. Combination of biochemical, spectroscopic, and crystallographic data revealed amino acids that are responsible for the interaction with the nucleotide. High sequence homology of the P-type ATPases in the cytoplasmic domains enables prediction of the ATP-interacting amino acids also for other P-type ATPases.

Comprehensive analysis of expression and function of 51 sarco(endo)plasmic reticulum Ca2+-ATPase mutants associated with Darier disease

We examined possible defects of sarco(endo)plasmic reticulum Ca2+-ATPase 2b (SERCA2b) associated with its 51 mutations found in Darier disease (DD) pedigrees, i.e. most of the substitution and deletion mutations of residues reported so far. COS-1 cells were transfected with each of the mutant cDNAs, and the expression and function of the SERCA2b protein was analyzed with microsomes prepared from the cells and compared with those of the wild type. Fifteen mutants showed markedly reduced expression. Among the other 36, 29 mutants exhibited completely abolished or strongly inhibited Ca2+-ATPase activity, whereas the other seven possessed fairly high or normal ATPase activity. In four of the aforementioned seven mutants, Ca2+ transport activity was significantly reduced or almost completely lost, therefore uncoupled from ATP hydrolysis. The other three were exceptional cases as they were seemingly normal in protein expression and Ca2+ transport function, but were found to have abnormalities in the kinetic properties altered by the three mutations, which happened to be in the three DD pedigrees found by us previously (Sato, K., Yamasaki, K., Daiho, T., Miyauchi, Y., Takahashi, H., Ishida-Yamamoto, A., Nakamura, S., Iizuka, H., and Suzuki, H. (2004) J. Biol. Chem. 279, 35595-35603). Collectively, our results indicated that in most cases (48 of 51) DD mutations cause severe disruption of Ca2+ homeostasis by the defects in protein expression and/or transport function and hence DD, but even a slight disturbance of the homeostasis will result in the disease. Our results also provided further insight into the structure-function relationship of SERCAs and revealed critical regions and residues of the enzyme.

Transport mechanism of the sarcoplasmic reticulum Ca2+ -ATPase pump

The sarcoplasmic reticulum Ca(2+)-ATPase (SERCA1a) belongs to the group of P-type ATPases, which actively transport inorganic cations across membranes at the expense of ATP hydrolysis. Three-dimensional structures of several transport intermediates of SERCA1a, stabilized by structural analogues of ATP and phosphoryl groups, are now available at atomic resolution. This has enabled the transport cycle of the protein to be described, including the coupling of Ca(2+) occlusion and phosphorylation by ATP, and of proton counter-transport and dephosphorylation. From these structures, Ca(2+)-ATPase gradually emerges as a molecular mechanical device in which some of the transmembrane segments perform Ca(2+) transport by piston-like movements and by the transmission of reciprocating movements that affect the chemical reactivity of the cytosolic globular domains.

Effects of inhibitors on luminal opening of Ca2+ binding sites in an E2P-like complex of sarcoplasmic reticulum Ca22+-ATPase with Be22+-fluoride

We document here the intrinsic fluorescence and 45Ca2+ binding properties of putative "E2P-related" complexes of Ca2+-free ATPase with fluoride, formed in the presence of magnesium, aluminum, or beryllium. Intrinsic fluorescence measurements suggest that in the absence of inhibitors, the ATPase complex with beryllium fluoride (but not those with magnesium or aluminum fluoride) does constitute an appropriate analog of the "ADP-insensitive" phosphorylated form of Ca2+-ATPase, the so-called "E2P" state. 45Ca2+ binding measurements, performed in the presence of 100 mm KCl, 5 mm Mg2+, and 20% Me2SO at pH 8, demonstrate that this ATPase complex with beryllium fluoride (but again not those with magnesium or aluminum fluoride) has its Ca2+ binding sites accessible for rapid, low affinity (submillimolar) binding of Ca2+ from the luminal side of SR. In addition, we specifically demonstrate that in this E2P-like form of ATPase, the presence of thapsigargin, 2,5-di-tert-butyl-1,4-dihydroxybenzene, or cyclopiazonic acid prevents 45Ca2+ binding (i.e. presumably prevents opening of the 45Ca2+ binding sites on the SR luminal side). Since crystals of E2P-related forms of ATPase have up to now been described in the presence of thapsigargin only, these results suggest that crystallizing an inhibitor-free E2P-like form of ATPase (like its complex with beryllium fluoride) would be highly desirable, to unambiguously confirm previous predictions about the exit pathway from the ATPase transmembrane Ca2+ binding sites to the SR luminal medium.