Modulatory ATP binding affinity in intermediate states of E2P dephosphorylation of sarcoplasmic reticulum Ca2+-ATPase.

The mechanism of ATP modulation of E2P dephosphorylation of sarcoplasmic reticulum Ca(2+)-ATPase wild type and mutant forms was examined in nucleotide binding studies of states analogous to the various intermediates of the dephosphorylation reaction, obtained by binding of metal fluorides, vanadate, or thapsigargin. Wild type Ca(2+)-ATPase displays an ATP affinity of 4 µM for the E2P ground state analog, 1 µM for the E2P transition state and product state analogs, and 11 µM for the E2 dephosphoenzyme. Hence, ATP binding stabilizes the transition and product states relative to the ground state, thereby explaining the accelerating effect of ATP on dephosphorylation. Replacement of Phe(487) (N-domain) with serine, Arg(560) (N-domain) with leucine, or Arg(174) (A-domain) with alanine or glutamate reduces ATP affinity in all E2/E2P intermediate states. Alanine substitution of Ile(188) (A-domain) increases the ATP affinity, although ATP acceleration of dephosphorylation is disrupted, thus indicating that the critical role of Ile(188) in ATP modulation is mechanistically based rather than being associated with the binding of nucleotide. Mutants with alanine replacement of Lys(205) (A-domain) or Glu(439) (N-domain) exhibit an anomalous inhibition by ATP of E2P dephosphorylation, due to ATP binding increasing the stability of the E2P ground state relative to the transition state. The ATP affinity of Ca(2)E2P, stabilized by inserting four glycines in the A-M1 linker, is similar to that of the E2P ground state, but the Ca(2+)-free E1 state of this mutant exhibits 3 orders of magnitude reduction of ATP affinity.

Determination of the ATP Affinity of the Sarcoplasmic Reticulum Ca(2+)-ATPase by Competitive Inhibition of [γ-(32)P]TNP-8N3-ATP Photolabeling.

The photoactivation of aryl azides is commonly employed as a means to covalently attach cross-linking and labeling reagents to proteins, facilitated by the high reactivity of the resultant aryl nitrenes with amino groups present in the protein side chains. We have developed a simple and reliable assay for the determination of the ATP binding affinity of native or recombinant sarcoplasmic reticulum Ca(2+)-ATPase, taking advantage of the specific photolabeling of Lys(492) in the Ca(2+)-ATPase by [γ-(32)P]2',3'-O-(2,4,6-trinitrophenyl)-8-azido-adenosine 5'-triphosphate ([γ-(32)P]TNP-8N3-ATP) and the competitive inhibition by ATP of the photolabeling reaction. The method allows determination of the ATP affinity of Ca(2+)-ATPase mutants expressed in mammalian cell culture in amounts too minute for conventional equilibrium binding studies. Here, we describe the synthesis and purification of the [γ-(32)P]TNP-8N3-ATP photolabel, as well as its application in ATP affinity measurements.

Critical interaction of actuator domain residues arginine 174, isoleucine 188, and lysine 205 with modulatory nucleotide in sarcoplasmic reticulum Ca2+-ATPase.

ATP plays dual roles in the reaction cycle of the sarcoplasmic reticulum Ca2+-ATPase by acting as the phosphorylating substrate as well as in nonphosphorylating (modulatory) modes accelerating conformational transitions of the enzyme cycle. Here we have examined the involvement of actuator domain residues Arg174, Ile188, Lys204, and Lys205 by mutagenesis. Alanine mutations to these residues had little effect on the interaction of the Ca2E1 state with nucleotide or on the HnE 2 to Ca2E1 transition of the dephosphoenzyme. The phosphoenzyme processing steps, Ca2E1P to E2P and E2P dephosphorylation, and their stimulation by MgATP/ATP were markedly affected by mutations to Arg174, Ile188, and Lys205. Replacement of Ile188 with alanine abolished nucleotide modulation of dephosphorylation but not the modulation of the Ca2E1P to E2P transition. Mutation to Arg174 interfered with nucleotide modulation of either of the phosphoenzyme processing steps, indicating a significant overlap between the modulatory nucleotide-binding sites involved. Mutation to Lys205 enhanced the rates of the phosphoenzyme processing steps in the absence of nucleotide and disrupted the nucleotide modulation of the Ca2E1P to E2P transition. Remarkably, the mutants with alterations to Lys205 showed an anomalous inhibition by ATP of the dephosphorylation, and in the alanine mutant the affinity for the inhibition by ATP was indistinguishable from that for stimulation by ATP of the wild type. Hence, the actuator domain is an important player in the function of ATP as modulator of phosphoenzyme processing, with Arg174, Ile188, and Lys205 all being critically involved, although in different ways. The data support a variable site model for the modulatory effects with the nucleotide binding somewhat differently in each of the conformational states occurring during the transport cycle.

ATP-binding modes and functionally important interdomain bonds of sarcoplasmic reticulum Ca2+-ATPase revealed by mutation of glycine 438, glutamate 439, and arginine 678.

ATP binds to sarcoplasmic reticulum Ca(2+)-ATPase both in a phosphorylating (catalytic) mode and in a nonphosphorylating (modulatory) mode, the latter leading to acceleration of phosphoenzyme turnover (Ca(2)E(1)P --> E(2)P and E(2)P --> E(2) reactions) and Ca(2+) binding (E(2) --> Ca(2)E(1)). In some of the Ca(2+)-ATPase crystal structures, Arg(678) and Glu(439) seem to be involved in the binding of nucleotide or an associated Mg(2+) ion. We have replaced Arg(678), Glu(439), and Gly(438) with alanine to examine their importance for the enzyme cycle and the modulatory effects of ATP and MgATP. The results point to the key role of Arg(678) in nucleotide binding and to the importance of interdomain bonds Glu(439)-Ser(186) and Arg(678)-Asp(203) in stabilizing the E(2)P and E(2) intermediates, respectively. Mutation of Arg(678) had conspicuous effects on ATP/MgATP binding to the E(1) form and ADP binding to Ca(2)E(1)P, as well as ATP/MgATP binding in modulatory modes to E(2)P and E(2), whereas the effects on ATP/MgATP acceleration of the Ca(2)E(1)P --> E(2)P transition were small, suggesting that the nucleotide that accelerates Ca(2)E(1)P --> E(2)P binds differently from that modulating the E(2)P --> E(2) and E(2) --> Ca(2)E(1) reactions. Mutation of Glu(439) hardly affected nucleotide binding to E(1), Ca(2)E(1)P, and E(2), but it led to disruption of the modulatory effect of ATP on E(2)P --> E(2) and acceleration of the latter reaction, indicating that ATP normally modulates E(2)P --> E(2) by interfering with the interaction between Glu(439) and Ser(186). Gly(438) seems to be important for this interaction as well as for nucleotide binding, probably because of its role in formation of the helix containing Glu(439) and Thr(441).

Asparagine 706 and glutamate 183 at the catalytic site of sarcoplasmic reticulum Ca2+-ATPase play critical but distinct roles in E2 states.

Mutants with alteration to Asn(706) of the highly conserved (701)TGDGVND(707) motif in domain P of sarcoplasmic reticulum Ca(2+)-ATPase were analyzed for changes in transport cycle kinetics and binding of the inhibitors vanadate, BeF, AlF, and MgF. The fluorides likely mimic the phosphoryl group/P(i) in the respective ground, transition, and product states of phosphoenzyme hydrolysis (Danko, S., Yamasaki, K., Daiho, T., and Suzuki, H. (2004) J. Biol. Chem. 279, 14991-14998). Binding of BeF, AlF, and MgF was also studied for mutant Glu(183) --> Ala, where the glutamate of the (181)TGES(184) motif in domain A is replaced. Mutations of Asn(706) and Glu(183) have in common that they dramatically impede the function of the enzyme in E2 states, but have little effect in E1. Contrary to the Glu(183) mutant, in which E2P slowly accumulates (Clausen, J. D., Vilsen, B., McIntosh, D. B., Einholm, A. P., and Andersen, J. P. (2004) Proc. Natl. Acad. Sci. U. S. A. 101, 2776-2781), E2P formation was not detectable with the Asn(706) mutants. Differential sensitivities of the mutants to inhibition by AlF, MgF, and BeF made it possible to distinguish different roles of Asn(706) and Glu(183). Hence, Asn(706) is less important than Glu(183) for gaining the transition state during E2P hydrolysis but plays critical roles in stabilization of E2P ground and E2.P(i) product states and in the major conformational changes associated with the Ca(2)E1P --> E2P and E2 --> Ca(2)E1 transitions, which seem to be facilitated by interaction of Asn(706) with domain A.

Importance of conserved N-domain residues Thr441, Glu442, Lys515, Arg560, and Leu562 of sarcoplasmic reticulum Ca2+-ATPase for MgATP binding and subsequent catalytic steps. Plasticity of the nucleotide-binding site.

Nine single mutations were introduced to amino acid residues Thr441, Glu442, Lys515, Arg560, Cys561, and Leu562 located in the nucleotide-binding domain of sarcoplasmic reticulum Ca2+-ATPase, and the functional consequences were studied in a direct nucleotide binding assay, as well as by steady-state and transient kinetic measurements of the overall and partial reactions of the transport cycle. Some partial reaction steps were also examined in mutants with alterations to Phe487, Arg489, and Lys492. The results implicate all these residues, except Cys561, in high affinity nucleotide binding at the substrate site. Mutations Thr441 --> Ala, Glu442 --> Ala, and Leu562 --> Phe were more detrimental to MgATP binding than to ATP binding, thus pointing to a role for these residues in the binding of Mg2+ or to a difference between the interactions with MgATP and ATP. Subsequent catalytic steps were also selectively affected by the mutations, showing the involvement of the nucleotide-binding domain in these reactions. Mutation of Arg560 inhibited phosphoryl transfer but enhanced the E1PCa2 --> E2P conformational transition, whereas mutations Thr441 --> Ala, Glu442 --> Ala, Lys492 --> Leu, and Lys515 --> Ala inhibited the E1PCa2 --> E2P transition. Hydrolysis of the E2P phosphoenzyme intermediate was enhanced in Glu442 --> Ala, Lys492 --> Leu, Lys515 --> Ala, and Arg560 --> Glu. None of the mutations affected the low affinity activation by nucleotide of the phosphoenzyme-processing steps, indicating that modulatory nucleotide interacts differently from substrate nucleotide. Mutation Glu442 --> Ala greatly enhanced reaction of Lys515 with fluorescein isothiocyanate, indicating that the two residues form a salt link in the native protein.

Roles of conserved P domain residues and Mg2+ in ATP binding in the ground and Ca2+-activated states of sarcoplasmic reticulum Ca2+-ATPase.

Residues in conserved motifs (625)TGD, (676)FARXXPXXK, and (701)TGDGVND in domain P of sarcoplasmic reticulum Ca(2+)-ATPase, as well as in motifs (601)DPPR and (359)NQR(/K)MSV in the hinge segments connecting domains N and P, were examined by mutagenesis to assess their roles in nucleotide and Mg(2+) binding and stabilization of the Ca(2+)-activated transition state for phosphoryl transfer. In the absence of Mg(2+), mutations removing the charges of domain P residues Asp(627), Lys(684), Asp(703), and Asp(707) increased the affinity for ATP and 2',3'-O-(2,4,6-trinitrophenyl)-8-azidoadenosine 5'-triphosphate. These mutations, as well as Gly(626)--> Ala, were inhibitory for ATP binding in the presence of Mg(2+) and for tight binding of the beta,gamma-bidentate chromium(III) complex of ATP. The hinge mutations had pronounced, but variable, effects on ATP binding only in the presence of Mg(2+). The data demonstrate an unfavorable electrostatic environment for binding of negatively charged nucleotide in domain P and show that Mg(2+) is required to anchor the phosphoryl group of ATP at the phosphorylation site. Mutants Gly(626) --> Ala, Lys(684) --> Met, Asp(703) --> Ala/Ser/Cys, and mutants with alteration to Asp(707) exhibited very slow or negligible phosphorylation, making it possible to measure ATP binding in the pseudo-transition state attained in the presence of both Mg(2+) and Ca(2+). Under these conditions, ATP binding was almost completely blocked in Gly(626) --> Ala and occurred with 12- and 7-fold reduced affinities in Asp(703) --> Ala and Asp(707) --> Cys, respectively, relative to the situation in the presence of Mg(2+) without Ca(2+), whereas in Lys(684) --> Met and Asp(707) --> Ser/Asn the affinity was enhanced 14- and 3-5-fold, respectively. Hence, Gly(626) and Asp(703) seem particularly critical for mediating entry into the transition state for phosphoryl transfer upon Ca(2+) binding at the transport sites.