Na+,K+‐ATPase (NKA) plays a pivotal role in establishing electrochemical gradients for Na+ and K+ across the cell membrane by alternating between the E1 (showing high affinity for Na+ and low ...affinity for K+) and E2 (low affinity to Na+ and high affinity to K+) forms. Presented here are two crystal structures of NKA in E1·Mg2+ and E1·3Na+ states at 2.9 and 2.8 Å resolution, respectively. These two E1 structures fill a gap in our description of the NKA reaction cycle based on the atomic structures. We describe how NKA converts the K+‐bound E2·2K+ form to an E1 (E1·Mg2+) form, which allows high‐affinity Na+ binding, eventually closing the cytoplasmic gate (in E1 ~ P·ADP·3Na+) after binding three Na+, while keeping the extracellular ion pathway sealed. We now understand previously unknown functional roles for several parts of NKA and that NKA uses even the lipid bilayer for gating the ion pathway.
Crystal structures of Na+,K+‐ATPase in the E1·3Na+ and E1·Mg2+ states fill a gap in our description of the reaction cycle of this important ion pump in atomic detail. They reveal structural principles that govern the conversion of the K+‐bound form to the Na+‐bound form, opening and closure of the cytoplasmic gate and presentation and hiding of the mouth of the cytoplasmic ion pathway.
Phospholamban is a 52-residue integral membrane protein that regulates the activity of the sarcoplasmic reticulum calcium pump in cardiac muscle. Its inhibitory action is relieved when phospholamban ...is phosphorylated at Ser16 by cAMP-dependent protein kinase. To computationally explore all possible conformations of the phosphorylated form, and thereby to understand the structural effects of phosphorylation, replica-exchange molecular dynamics (REMD) was applied to the cytoplasmic domain that includes Ser16. The simulations showed that (i) without phosphorylation, the region from Lys3 to Ser16 takes all α-helical conformations; (ii) when phosphorylated, the α-helix is partially unwound in the C-terminal part (from Ser10 to Ala15) resulting in less extended conformations; (iii) the phosphate at Ser16 forms salt bridges with Arg9, Arg13, and/or Arg14; and (iv) the salt bridges with Arg13 and Arg14 distort the α-helix and induce unwinding of the C-terminal part. We then applied conventional all-atom molecular dynamics simulations to the full-length phospholamban in the phospholipid bilayer. The results were consistent with those obtained with REMD simulations, suggesting that the transmembrane part of phospholamban and the lipid bilayer itself have only minor effects on the conformational changes in the cytoplasmic domain. The distortions caused by the salt bridges involving the phosphate at Ser16 readily explain the relief of the inhibitory effect of phospholamban by phosphorylation, as they will substantially reduce the population of all helical conformations, which are presumably required for the binding to the calcium pump. This will also be the mechanism for releasing the phosphorylated phospholamban from kinase.
The structures of the Ca2+‐ATPase (SERCA1a) have been determined for five different states by X‐ray crystallography. Detailed comparison of the structures in the Ca2+‐bound form and unbound (but ...thapsigargin‐bound) form reveals that very large rearrangements of the transmembrane helices take place accompanying Ca2+ dissociation and binding and that they are mechanically linked with equally large movements of the cytoplasmic domains. The meanings of the rearrangements of the transmembrane helices and those of the cytoplasmic domains, and the mechanistic roles of the phosphorylation are now becoming clear.
The calcium pump from sarcoplasmic reticulum (Ca2+-ATPase) is typical of the large family of P-type cation pumps. These couple ATP hydrolysis with cation transport, generating cation gradients across ...membranes. Ca2+-ATPase specifically maintains the low cytoplasmic calcium concentration of resting muscle by pumping calcium into the sarcoplasmic reticulum; subsequent release is used to initiate contraction. No high-resolution structure of a P-type pump has yet been determined, although a 14-Å structure ofCa2+-ATPase, obtained by electron microscopy of frozen-hydrated, tubular crystals, showed a large cytoplasmic head connected to the transmembrane domain by a narrow stalk. We have now improved the resolution to 8 Å and can discern ten transmembrane α-helices, four of which continue into the stalk. On the basis of constraints from transmembrane topology, site-directed mutagenesis and disulphide crosslinking, we have made tentative assignments for these α-helices within the amino-acid sequence. A distinct cavity leads to the putative calcium-binding site, providing a plausible path for calcium release to the lumen of the sarcoplasmic reticulum.
The ionization states of the acidic residues around the Ca2+-binding sites of sarcoplasmic reticulum Ca2+ ATPase are studied by continuum electrostatic calculations and all-atom molecular dynamics ...simulations with explicit solvent and phospholipids. The two methods consistently indicate that Glu58 and Glu908 are protonated at neutral pH. The Ca2+ coordination and the H-bonds formed by the protonation of Glu58 and Glu908 are stable in an MD simulation, whereas the H-bonds are disrupted and the Ca2+ coordination geometry is severely altered in another simulation treating these residues unprotonated. The results clearly indicate that the H-bonds formed by protonation of Glu58 and Glu908 provide extra stability for the Ca2+-binding sites of Ca2+ ATPase.
P-type ATPases are ATP-powered ion pumps that establish ion concentration gradients across cell and organelle membranes. Here, we describe the crystal structure of the Ca2+ pump of skeletal muscle ...sarcoplasmic reticulum, a representative member of the P-type ATPase superfamily, with an ATP analogue, a Mg2+ and two Ca2+ ions in the respective binding sites. In this state, the ATP analogue reorganizes the three cytoplasmic domains (A, N and P), which are widely separated without nucleotide, by directly bridging the N and P domains. The structure of the P-domain itself is altered by the binding of the ATP analogue and Mg2+. As a result, the A-domain is tilted so that one of the transmembrane helices moves to lock the cytoplasmic gate of the transmembrane Ca2+-binding sites. This appears to be the mechanism for occluding the bound Ca2+ ions, before releasing them into the lumen of the sarcoplasmic reticulum.
Protection of the Ca2+ATPase (SERCA) from proteinase K digestion has been observed following the addition of Ca2+, Mg2+, and nucleotide and interpreted as a substrate-dependent conformational change ...(1). The protected digestion site is located on the loop connecting the A domain and the M3 transmembrane helix. We studied by mutational analysis the protective effect of AMP-PCP, an ATP analog that is not utilized for enzyme phosphorylation. We found that the nucleotide protective effect is interfered with by single mutations of Arg-560 and Glu-439 in the N domain and Lys-352, Lys-684, Thr-353, Asp-703, and Asp-707 in the P domain. This is consistent with a transition from the open to the compact configuration of the ATPase headpiece and approximation of the N and P domains by interactions with the nucleotide adenosine and phosphate moieties, respectively. The A domain-M3 loop is consequently involved. Protection by nucleotide substrate increased following the mutations of Asp-351 (the residue undergoing phosphorylation by ATP) and neighboring Asn-706 to Ala, underlying the importance of side chain specificity in positioning the nucleotide terminal phosphate and limiting the stability of the substrate-enzyme complex. Protection is not observed when AMP-PCP is added in the absence of Ca2+ or following mutations (E771Q or N796A) that interfere with Ca2+ binding. Therefore, nucleotide binds to the Ca2+-activated enzyme in the open headpiece conformation and the consequent approximation of the N and P domains occurs while the transmembrane domain is still in the Ca2+-bound conformation. Mg2+ is not required for the protective effect of nucleotide, even though it is specifically required for the subsequent catalytic reactions.
XK-related 8 (XKR8), in complex with the transmembrane glycoprotein basigin, functions as a phospholipid scramblase activated by the caspase-mediated cleavage or phosphorylation of its C-terminal ...tail. It carries a putative phospholipid translocation path of multiple hydrophobic and charged residues in the transmembrane region. It also has a crucial tryptophan at the exoplasmic end of the path that regulates its scrambling activity. We herein investigated the tertiary structure of the human XKR8–basigin complex embedded in lipid nanodiscs at an overall resolution of 3.66 Å. We found that the C-terminal tail engaged in intricate polar and van der Waals interactions with a groove at the cytoplasmic surface of XKR8. These interactions maintained the inactive state of XKR8. Point mutations to disrupt these interactions strongly enhanced the scrambling activity of XKR8, suggesting that the activation of XKR8 is mediated by releasing the C-terminal tail from the cytoplasmic groove. We speculate that the cytoplasmic tail region of XKR8 functions as a plug to prevent the scrambling of phospholipids.