Ion transport and energy transduction of P-type ATPases: Implications from electrostatic calculations

This paper summarizes our present electrostatic calculations on P-type ATPases and their contribution to understand the molecular details of the reaction mechanisms. One focus was set on analyzing the proton countertransport of the sarcoplasmic reticulum Ca²⁺-ATPase (SERCA1a). Protonation of acidic residues was calculated in dependence of pH for different enzyme states in the reaction cycle of the Ca²⁺-ATPase. We proposed that the acidic Ca²⁺ ligands Glu 771, Asp 800 and Glu 908 participate in the proton countertransport whereas Glu 309 is more likely to serve as a proton shuttle between binding site I and the cytoplasm. Complementary to infrared measurements, we assigned infrared bands to specific Ca²⁺ ligands that are hydrogen bonded. Ion pathways were proposed based on the calculations and structural data. Another focus was set on analyzing the energy transduction mechanism of P-type ATPases. In accordance to electrophysiological experiments, we simulated an electric field across the membrane. The impact of the electric field was studied by an accumulated number of residue conformational and ionization changes on specific transmembrane helices. Our calculations on the Ca²⁺-ATPase and the Na⁺/K⁺-ATPase indicated that the highly conserved transmembrane helix M5 is one structural element that is likely to act as energy transduction element in P-type ATPases. Perspectives and limitations of the electrostatic calculations for future computational studies are pointed out.     

Structure and function of the P-type ATPases.

The P-type ATPases are integral membrane proteins that generate essential transmembrane ion gradients in virtually all living cells. The structures of two of these have recently been elucidated at a resolution of 8 A. When considered together with the large body of biochemical information that has accrued for these transporters and for enzymes in general, this new structural information is providing tantalizing insights regarding the molecular mechanism of active ion transport catalyzed by these proteins.     

Topological Adaptation of Transmembrane Domains to the Force-Modulated Lipid Bilayer Is a Basis of Sensing Mechanical Force

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Amyloidogenic Propensities and Conformational Properties of ProIAPP and IAPP in the Presence of Lipid Bilayer Membranes

Human islet amyloid polypeptide (hIAPP), which is considered the primary culprit for β-cell loss in type 2 diabetes mellitus patients, is synthesized in β-cells of the pancreas from its precursor pro-islet amyloid polypeptide (proIAPP), which may be important in early intracellular amyloid formation as well. We compare the amyloidogenic propensities and conformational properties of proIAPP and hIAPP in the presence of negatively charged lipid membranes, which have been discussed as loci of initiation of the fibrillation reaction. Circular dichroism studies verify the initial secondary structures of proIAPP and hIAPP to be predominantly unordered with small amounts of ordered secondary structure elements, and exhibit minor differences between these two peptides only. Using attenuated total reflection-Fourier transform infrared spectroscopy and thioflavin T fluorescence spectroscopy, as well as atomic force microscopy, we show that in the presence of negatively charged membranes, proIAPP exhibits a much higher amyloidogenic propensity than in bulk solvent. Compared to hIAPP, it is still much less amyloidogenic, however. Although differences in the secondary structures of the aggregated species of hIAPP and proIAPP at the lipid interface are small, they are reflected in morphological changes. Unlike hIAPP, proIAPP forms essentially oligomeric-like structures at the lipid interface. Besides the interaction with anionic membranes [1,2-dioleoyl-sn-glycero-3-phosphocholine (DOPC) + x1,2-dioleoyl-sn-glycero-3-[phospho-rac-(1-glycerol)]], interaction with zwitterionic homogeneous (DOPC) and heterogeneous (1,2-dipalmitoyl-sn-glycero-3-phosphocholine:DOPC:cholesterol 1:2:1 model raft mixture) membranes has also been studied. Both peptides do not aggregate significantly at DOPC bilayers. In the presence of the model raft membrane, hIAPP aggregates markedly as well. Conversely, proIAPP clusters into less ordered structures and to a minor extent at raft membranes only. The addition of proIAPP to hIAPP retards the hIAPP fibrillation process also in the presence of negatively charged lipid bilayers. In excess proIAPP, increased aggregation levels are finally observed, however, which could be attributed to seed-induced cofibrillation of proIAPP.     

Proton and calcium pumping P-type ATPases and their regulation of plant responses to the environment

Plant plasma membrane H⁺-ATPases and Ca²⁺-ATPases maintain low cytoplasmic concentrations of H⁺ and Ca²⁺, respectively, and are essential for plant growth and development. These low concentrations allow plasma membrane H⁺-ATPases to function as electrogenic voltage stats, and Ca²⁺-ATPases as “off” mechanisms in Ca²⁺-based signal transduction. Although these pumps are autoregulated by cytoplasmic concentrations of H⁺ and Ca²⁺, respectively, they are also subject to exquisite regulation in response to biotic and abiotic events in the environment. A common paradigm for both types of pumps is the presence of terminal regulatory (R) domains that function as autoinhibitors that can be neutralized by multiple means, including phosphorylation. A picture is emerging in which some of the phosphosites in these R domains appear to be highly, nearly constantly phosphorylated, whereas others seem to be subject to dynamic phosphorylation. Thus, some sites might function as major switches, whereas others might simply reduce activity. Here, we provide an overview of the relevant transport systems and discuss recent advances that address their relation to external stimuli and physiological adaptations.

The regulation of plasma membrane H^+-ATPases and autoinhibited Ca2^+-ATPases exhibits a complex and dynamic network of posttranslational regulation. The regulation of plasma membrane H⁺-ATPases and autoinhibited Ca²⁺-ATPases exhibits a complex and dynamic network of posttranslational regulation.

P-type ATPases are found in all domains of life and constitute a large superfamily of membrane-bound pumps that share a common machinery, including a reaction cycle that involves catalytic phosphorylation of an Asp, resulting in a phosphorylated intermediate (reviewed in Palmgren and Nissen, 2011; (hence the name P-type; Box 1). The catalytic phosphoryl-aspartate intermediate is not to be confused with regulatory phosphorylation, which occurs on Ser, Thr, and Tyr residues. Five major families of P-type ATPases have been characterized (P1–5), each of which is divided into a number of subfamilies (named with letters). Plasma membrane H⁺-ATPases are classified as P3A ATPases, whereas Ca²⁺ pumps constitute P2A and P2B ATPases. In plants, these pumps are best characterized in the model plant Arabidopsis thaliana (Arabidopsis).Box 1Enzymology of P-type ATPases.P-type ATPases (reviewed in Palmgren and Nissen, 2011) alternate between two extreme conformations during their catalytic cycle: a high-affinity (with respect to ATP and the ion to be exported) Enzyme1 (E1) state, and a low-affinity Enzyme2 (E2) state. Many P-type ATPases are autoinhibited by built-in molecular constraints, namely their C- and N-terminal (for plasma membrane H⁺-ATPases; Palmgren et al., 1999) or N-terminal (for P2B Ca²⁺-ATPases; Malmström et al., 1997) regulatory (R) domains of approximately 100 amino acid residues, which act as brakes by stabilizing the pumps in a low-affinity conformation (Palmgren and Nissen, 2011), most likely E2. Neutralizing the R domain results in a shift in conformational equilibrium towards a high-affinity state, likely E1. In this way, the R domains of plasma membrane H⁺-ATPases and Ca²⁺-ATPases allow posttranslational modification events to control the turnover numbers of these pumps. A structure of a plasma membrane H⁺-ATPase (from the distantly related yeast S. cerevisiae) in its autoinhibited state has been solved (Heit et al., 2021). Its R domain is situated adjacent to the P domain, which would suggest that the R domain functions to restrict the conformational flexibility of the pump. Normally, the hydrolysis of ATP and transport are tightly coupled in P-type ATPases. Therefore, P-type ATPases hydrolyze bound ATP as soon as their ligand-binding site(s) in the membrane region are occupied, but not before. Thus, increasing the ligand affinity of an ATPase simultaneously increases its turnover number, provided that the concentration of ATP is not limiting, which is rarely the case in cells. A specific feature of plasma membrane H⁺-ATPases is that in the autoinhibited state, ATP hydrolysis is only loosely coupled to H⁺ pumping, whereas pump activation results in tight coupling, with one H⁺ pumped per ATP split (Pedersen et al., 2018).In response to internal and/or external cues, plasma membrane H⁺-ATPase and Ca²⁺-ATPase activities are controlled by intracellular concentrations of H⁺ and Ca²⁺, respectively, via interacting proteins, through posttranslational modification by phosphorylation, and by regulated trafficking of the pump to and from the plasma membrane. Their regulation sometimes involves changes in gene expression and turnover, although this is rare, perhaps because both processes are time- and energy-consuming (Haruta et al., 2018).     

Interplay of the Czc system and two P-type ATPases in conferring metal resistance to Ralstonia metallidurans

Cadmium and zinc are removed from cells of Ralstonia metallidurans by the CzcCBA efflux pump and by two soft-metal-transporting P-type ATPases, CadA and ZntA. The czcCBA genes are located on plasmid pMOL30, and the cadA and zntA genes are on the bacterial chromosome. Expression of zntA from R. metallidurans in Escherichia coli predominantly mediated resistance to zinc, and expression of cadA predominantly mediated resistance to cadmium. Both transporters decreased the cellular content of zinc or cadmium in this host. In the plasmid-free R. metallidurans strain AE104, single gene deletions of cadA or zntA had only a moderate effect on cadmium and zinc resistance, but zinc resistance decreased 6-fold and cadmium resistance decreased 350-fold in double deletion strains. Neither single nor double gene deletions affected zinc resistance in the presence of czcCBA. In contrast, cadmium resistance of the cadA zntA double mutant could be elevated only partially by the presence of CzcCBA. lacZ reporter gene fusions indicated that expression of cadA was induced by cadmium but not by zinc in R. metallidurans strain AE104. In the absence of the zntA gene, expression of cadA occurred at lower cadmium concentrations and zinc now served as an inducer. In contrast, expression of zntA was induced by both zinc and cadmium, and the induction pattern did not change in the presence or absence of CadA. However, expression of both genes, zntA and cadA, was diminished in the presence of CzcCBA. This indicated that CzcCBA efficiently decreased cytoplasmic cadmium and zinc concentrations. It is discussed whether these data favor a model in which the cations are removed either from the cytoplasm or the periplasm by CzcCBA.     

Regulation of Ion Channel Function by the Host Lipid Bilayer Examined by a Stopped-Flow Spectrofluorometric Assay

To examine the function of ligand-gated ion channels in a defined membrane environment, we developed a robust sequential-mixing fluorescence-based stopped-flow assay. Channel activity is determined using a channel-permeable quencher (e.g., thallium, Tl⁺) of a water-soluble fluorophore (8-aminonaphthalene-1,3,6-trisulfonic acid) encapsulated in large unilamellar vesicles in which the channel of interest has been reconstituted, which allows for rapid solution changes. To validate the method, we explored the activation of wild-type KcsA channel, as well as it's noninactivating (E71A) KcsA mutant, by extravesicular protons (H⁺). For both channel types, the day-to-day variability in the reconstitution yield (as judged from the time course of fluorescence quenching) is <10%. The activation curve for E71A KcsA is similar to that obtained previously using single-channel electrophysiology, and the activation curves for wild-type and E71A KcsA are indistinguishable, indicating that channel activation and inactivation are separate processes. We then investigated the regulation of KcsA activation by changes in lipid bilayer composition. Increasing the acyl chain length (from C_18:1 to C_22:1 in diacylphosphatidylcholine), but not the mole fraction of POPG (>0.25) in the bilayer-forming phospholipid mixture, alters KcsA H⁺ gating. The bilayer-thickness-dependent shift in the activation curve is suggestive of a decrease in an apparent H⁺ affinity and cooperativity. The control over bilayer environment and time resolution makes this method a powerful assay for exploring ligand activation and inactivation of ion channels, and how channel gating varies with changes in the channels’ lipid bilayer environment or other regulatory processes.     

Regulation of Ion Channel Function by the Host Lipid Bilayer Examined by a Stopped-Flow Spectrofluorometric Assay

To examine the function of ligand-gated ion channels in a defined membrane environment, we developed a robust sequential-mixing fluorescence-based stopped-flow assay. Channel activity is determined using a channel-permeable quencher (e.g., thallium, Tl⁺) of a water-soluble fluorophore (8-aminonaphthalene-1,3,6-trisulfonic acid) encapsulated in large unilamellar vesicles in which the channel of interest has been reconstituted, which allows for rapid solution changes. To validate the method, we explored the activation of wild-type KcsA channel, as well as it''s noninactivating (E71A) KcsA mutant, by extravesicular protons (H⁺). For both channel types, the day-to-day variability in the reconstitution yield (as judged from the time course of fluorescence quenching) is <10%. The activation curve for E71A KcsA is similar to that obtained previously using single-channel electrophysiology, and the activation curves for wild-type and E71A KcsA are indistinguishable, indicating that channel activation and inactivation are separate processes. We then investigated the regulation of KcsA activation by changes in lipid bilayer composition. Increasing the acyl chain length (from C_18:1 to C_22:1 in diacylphosphatidylcholine), but not the mole fraction of POPG (>0.25) in the bilayer-forming phospholipid mixture, alters KcsA H⁺ gating. The bilayer-thickness-dependent shift in the activation curve is suggestive of a decrease in an apparent H⁺ affinity and cooperativity. The control over bilayer environment and time resolution makes this method a powerful assay for exploring ligand activation and inactivation of ion channels, and how channel gating varies with changes in the channels’ lipid bilayer environment or other regulatory processes.     

Phospholipid Flippase Activities and Substrate Specificities of Human Type IV P-type ATPases Localized to the Plasma Membrane

Type IV P-type ATPases (P4-ATPases) are believed to translocate aminophospholipids from the exoplasmic to the cytoplasmic leaflets of cellular membranes. The yeast P4-ATPases, Drs2p and Dnf1p/Dnf2p, flip nitrobenzoxadiazole-labeled phosphatidylserine at the Golgi complex and nitrobenzoxadiazole-labeled phosphatidylcholine (PC) at the plasma membrane, respectively. However, the flippase activities and substrate specificities of mammalian P4-ATPases remain incompletely characterized. In this study, we established an assay for phospholipid flippase activities of plasma membrane-localized P4-ATPases using human cell lines stably expressing ATP8B1, ATP8B2, ATP11A, and ATP11C. We found that ATP11A and ATP11C have flippase activities toward phosphatidylserine and phosphatidylethanolamine but not PC or sphingomyelin. By contrast, ATPase-deficient mutants of ATP11A and ATP11C did not exhibit any flippase activity, indicating that these enzymes catalyze flipping in an ATPase-dependent manner. Furthermore, ATP8B1 and ATP8B2 exhibited preferential flippase activities toward PC. Some ATP8B1 mutants found in patients of progressive familial intrahepatic cholestasis type 1 (PFIC1), a severe liver disease caused by impaired bile flow, failed to translocate PC despite their delivery to the plasma membrane. Moreover, incorporation of PC mediated by ATP8B1 can be reversed by simultaneous expression of ABCB4, a PC floppase mutated in PFIC3 patients. Our findings elucidate the flippase activities and substrate specificities of plasma membrane-localized human P4-ATPases and suggest that phenotypes of some PFIC1 patients result from impairment of the PC flippase activity of ATP8B1.     

Application of the iterative helical real-space reconstruction method to large membranous tubular crystals of P-type ATPases

Since the development of three-dimensional helical reconstruction methods in the 1960's, advances in Fourier-Bessel methods have facilitated structure determination to near-atomic resolution. A recently developed iterative helical real-space reconstruction (IHRSR) method provides an alternative that uses single-particle analysis in conjunction with the imposition of helical symmetry. In this work, we have adapted the IHRSR algorithm to work with frozen-hydrated tubular crystals of P-type ATPases. In particular, we have implemented layer-line filtering to improve the signal-to-noise ratio, Wiener-filtering to compensate for the contrast transfer function, solvent flattening to improve reference reconstructions, out-of-plane tilt compensation to deal with flexibility in three dimensions, systematic calculation of Fourier shell correlations to track the progress of the refinement, and tools to control parameters as the refinement progresses. We have tested this procedure on datasets from Na(+)/K(+)-ATPase, rabbit skeletal Ca(2+)-ATPase and scallop Ca(2+)-ATPase in order to evaluate the potential for sub-nanometer resolution as well as the robustness in the presence of disorder. We found that Fourier-Bessel methods perform better for well-ordered samples of skeletal Ca(2+)-ATPase and Na(+)/K(+)-ATPase, although improvements to IHRSR are discussed that should reduce this disparity. On the other hand, IHRSR was very effective for scallop Ca(2+)-ATPase, which was too disordered to analyze by Fourier-Bessel methods.     

P-type ATPases in Caenorhabditis and Drosophila: Implications for Evolution of the P-type ATPase Subunit Families with Special Reference to the Na,K-ATPase and H,K-ATPase Subgroup

Here we show a complete list of the P-type ATPase genes in Caenorhabditis elegans and Drosophila melanogaster. A detailed comparison of the deduced amino-acid sequences in combination with phylogenetic and chromosomal analyses has revealed the following: (1) The diversity of this gene family has been achieved by two major evolutionary steps; the establishment of the major P-type ATPase subgroups with distinct substrate (ion) specificities in a common ancestor of vertebrate and invertebrate, followed by the evolution of multiple isoforms occurring independently in vertebrate and invertebrate phyla. (2) Pairs of genes that have intimate phylogenetic relationship are frequently found in proximity on the same chromosome. (3) Some of the Na,K- and H,K-ATPase isoforms in D. melanogaster and C. elegans lack motifs shown to be important for alpha/beta-subunit assembly, suggesting that such alpha- and beta-subunits might exist by themselves (lonely subunits). The mutation rates for these subunits are much faster than those for the subunits with recognizable assembly domains. (4) The lonely alpha-subunits also lack the major site for ouabain binding that apparently arose before the separation of vertebrates and invertebrates and thus well before the separation of vertebrate Na,K-ATPases and H,K-ATPases. These findings support the idea that a relaxation of functional constraints would increase the rate of evolution and provide clues for identifying the origins of inhibitor sensitivity, subunit assembly, and separation of Na,K- and H,K-ATPases.     

Chimeras of P-type ATPases and their transcriptional regulators: contributions of a cytosolic amino-terminal domain to metal specificity

Zn²⁺‐responsive repressor ZiaR and Co²⁺‐responsive activator CoaR modulate production of P₁‐type Zn²⁺‐ (ZiaA) and Co²⁺‐ (CoaT) ATPases respectively. What dictates metal selectivity? We show that Δ ziaΔcoa double mutants had similar Zn²⁺ resistance to Δzia single mutants and similar Co²⁺ resistance to Δcoa single mutants. Controlling either ziaA or coaT with opposing regulators restored no resistance to metals sensed by the regulators, but coincident replacement of the deduced cytosolic amino‐terminal domain CoaT_N with ZiaA_N (in ziaR‐_p ziaA‐ziaA_NcoaT) conferred Zn²⁺ resistance to ΔziaΔcoa, Zn²⁺ content was lowered and residual Co²⁺ resistance lost. Metal‐dependent molar absorptivity under anaerobic conditions revealed that purified ZiaA_N binds Co²⁺ in a pseudotetrahedral two‐thiol site, and Co²⁺ was displaced by Zn²⁺. Thus, the amino‐terminal domain of ZiaA inverts the metals exported by zinc‐regulated CoaT from Co²⁺ to Zn²⁺, and this correlates simplistically with metal‐binding preferences; K_ZiaAN Zn²⁺ tighter than Co²⁺. However, Zn²⁺ did not bleach Cu⁺‐ZiaA_N, and only Cu⁺ co‐migrated with ZiaA_N after competitive binding versus Zn²⁺. Bacterial two‐hybrid assays that detected interaction between the Cu⁺‐metallochaperone Atx1 and the amino‐terminal domain of Cu⁺‐transporter PacS_N detected no interaction with the analogous, deduced, ferredoxin‐fold subdomain of ZiaA_N. Provided that there is no freely exchangeable cytosolic Cu⁺, restricted contact with the Cu⁺‐metallochaperone can impose a barrier impairing the formation of otherwise favoured Cu⁺–ZiaA_N complexes.     

Transmembrane Domain Three Contributes to the Ion Conductance Pathway of Channelrhodopsin-2

Channelrhodopsin-2 (ChR2) is a light-activated nonselective cation channel that is found in the eyespot of the unicellular green alga Chlamydomonas reinhardtii. Despite the wide employment of this protein to control the membrane potential of excitable membranes, the molecular determinants that define the unique ion conductance properties of this protein are not well understood. To elucidate the cation permeability pathway of ion conductance, we performed cysteine scanning mutagenesis of transmembrane domain three followed by labeling with methanethiosulfonate derivatives. An analysis of our experimental results as modeled onto the crystal structure of the C1C2 chimera demonstrate that the ion permeation pathway includes residues on one face of transmembrane domain three at the extracellular side of the channel that face the center of ChR2. Furthermore, we examined the role of a residue at the extracellular side of transmembrane domain three in ion conductance. We show that ion conductance is mediated, in part, by hydrogen bonding at the extracellular side of transmembrane domain three. These results provide a starting point for examining the cation permeability pathway for ChR2.     

From Induced Fit to Conformational Selection: A Continuum of Binding Mechanism Controlled by the Timescale of Conformational Transitions

In receptor-ligand binding, a question that generated considerable interest is whether the mechanism is induced fit or conformational selection. This question is addressed here by a solvable model, in which a receptor undergoes transitions between active and inactive forms. The inactive form is favored while unbound but the active form is favored while a ligand is loosely bound. As the active-inactive transition rates increase, the binding mechanism gradually shifts from conformational selection to induced fit. The timescale of conformational transitions thus plays a crucial role in controlling binding mechanisms.     

The Chemoreceptor Dimer Is the Unit of Conformational Coupling and Transmembrane Signaling

Transmembrane chemoreceptors are central components in bacterial chemotaxis. Receptors couple ligand binding and adaptational modification to receptor conformation in processes that create transmembrane signaling. Homodimers, the fundamental receptor structural units, associate in trimers and localize in patches of thousands. To what degree do conformational coupling and transmembrane signaling require higher-order interactions among dimers? To what degree are they altered by such interactions? To what degree are they inherent features of homodimers? We addressed these questions using nanodiscs to create membrane environments in which receptor dimers had few or no potential interaction partners. Receptors with many, few, or no interaction partners were tested for conformational changes and transmembrane signaling in response to ligand occupancy and adaptational modification. Conformation was assayed by measuring initial rates of receptor methylation, a parameter independent of receptor-receptor interactions. Coupling of ligand occupancy and adaptational modification to receptor conformation and thus to transmembrane signaling occurred with essentially the same sensitivity and magnitude in isolated dimers as for dimers with many neighbors. Thus, we conclude that the chemoreceptor dimer is the fundamental unit of conformational coupling and transmembrane signaling. This implies that in signaling complexes, coupling and transmembrane signaling occur through individual dimers and that changes between dimers in a receptor trimer or among trimer-based signaling complexes are subsequent steps in signaling.In motile bacterial cells, thousands of transmembrane chemoreceptor proteins cluster in polar patches (8, 13, 14, 30, 42). The fundamental structural unit of these receptors is a homodimer (18, 32). Dimers interact at their membrane-distal tips to create trimers (18, 38, 39). Interactions among receptor homodimers in trimers and in higher-order associations (Fig. ​(Fig.1A)1A) are thought to be important for function (36, 37), particularly for the high-performance features of the chemotaxis sensory system (15). Understanding the role of receptor-receptor interactions in chemoreceptor function will require definition of the extent to which each receptor activity is an inherent property of individual receptor dimers and the extent to which activities require or are influenced by interactions with neighboring receptors. These issues had not been addressed experimentally because the receptor-receptor interactions could not be easily controlled in vivo or in vitro. However, we found that nanodiscs (2, 5) could be utilized to manipulate the potential for interactions among membrane-embedded chemoreceptors and thus to investigate the influence of receptor-receptor interactions upon chemoreceptor activities (4).Open in a separate windowFIG. 1.Chemoreceptors. (A) Cartoon of interactions of membrane-embedded chemoreceptors showing a homodimer, a trimer of dimers, and a patch of chemoreceptors. (B) Cartoon of a nanodisc with a single receptor dimer inserted in the plug of the lipid bilayer. (C) Diagram of the chemoreceptor conformational equilibrium.     

Lipid requirements of the plasma membrane ATPases from oat roots and yeast

The lipid specificity of the plasma membrane ATPases from oat roots and yeast has been investigated by reconstituting delipidated enzyme with phospholipid vesicles and with micelles of lysophospholipids and other detergents. The plant ATPase is activated by Triton X-100 and by all phospholipid and lysophospholipid species, exhibiting only a slight preference for zwitterionic polar heads (phosphorylcholine and phosphorylethanolamine). No unsaturation is required on the hydrophobic chain. On the other hand, the yeast ATPase requires a negatively charged polar head (with preference for phosphorylglycerol and phosphorylinositol) and an unsaturated hydrophobic chain.