Manganese selectivity of pmr1, the yeast secretory pathway ion pump, is defined by residue gln783 in transmembrane segment 6. Residue Asp778 is essential for cation transport

We have solubilized and purified the histidine-tagged yeast secretory pathway/Golgi ion pump Pmr1 to near homogeneity in one step, using nickel affinity chromatography. The purified pump demonstrates both Ca(2+)- and Mn(2+)-dependent ATP hydrolysis and phosphoenzyme intermediate formation in forward (ATP) and reverse (P(i)) directions. This preparation has allowed us to examine, in detail, the properties of mutations D778A and Q783A in transmembrane segment M6 of Pmr1. In phenotypic screens of Ca(2+) chelator and Mn(2+) toxicity reported separately (Wei, Y., Chen, J., Rosas, G., Tompkins, D.A., Holt, P.A., and Rao, R. (2000) J. Biol. Chem. 275, XXXX-XXXX), D778A was a loss-of-function mutant apparently defective for transport of both Ca(2+) and Mn(2+), whereas mutant Q783A displayed a differential sensitivity consistent with the selective loss of Mn(2+) transport. We show that mutant D778A is devoid of cation-dependent ATP hydrolytic activity and phosphoenzyme formation from ATP. However, reverse phosphorylation from P(i) is preserved but is insensitive to inhibition by Ca(2+) or Mn(2+) ions, which is evidence for a specific inability to bind cations in this mutant. We also show that Ca(2+) can activate ATP hydrolysis in the purified Q783A mutant, with a half-maximal concentration of 0.06 micrometer, essentially identical to that of wild type (0.07 micrometer). Mn(2+) activation of ATP hydrolysis was half-maximal at 0.02 micrometer in wild type, establishing a normal selectivity profile of Mn(2+) > Ca(2+). Strikingly, Mn(2+)-ATPase in the Q783A mutant was nearly abolished, even at concentrations of up to 10 micrometer. These results were confirmed in assays of phosphoenzyme intermediates. Molecular modeling of the packing between helices M4 and M6 suggests that residue Gln(783) in M6 may form a critical hydrophobic interaction with Val(335) in M4, such that the Ala substitution modifies the packing or tilt of the helices and thus the ion pore. The data emphasize the critical role of transmembrane segment M6 in defining the cation binding pocket of P-type ATPases.     

Phenotypic screening of mutations in Pmr1, the yeast secretory pathway Ca2+/Mn2+-ATPase, reveals residues critical for ion selectivity and transport

Thirty-five mutations were generated in the yeast secretory pathway/Golgi ion pump, Pmr1, targeting oxygen-containing side chains within the predicted transmembrane segments M4, M5, M6, M7, and M8, likely to be involved in coordination of Ca(2+) and Mn(2+) ions. Mutants were expressed in low copy number in a yeast strain devoid of endogenous Ca(2+) pumps and screened for loss of Ca(2+) and Mn(2+) transport on the basis of hypersensitivity to 1, 2-bis(2-aminophenoxy)ethane-N,N,N',N'-tetraacetic acid (BAPTA) and Mn(2+) toxicity, respectively. Three classes of mutants were found: mutants indistinguishable from wild type (Class 1), mutants indistinguishable from the pmr1 null strain (Class 2), and mutants with differential sensitivity to BAPTA and Mn(2+) toxicity (Class 3). We show that Class 1 mutants retain normal/near normal properties, including (45)Ca transport, Golgi localization, and polypeptide conformation. In contrast, Class 2 mutants lacked any detectable (45)Ca transport; of these, a subset also showed defects in trafficking and protein folding, indicative of structural problems. Two residues identified as Class 2 mutants in this screen, Asn(774) and Asp(778) in M6, also play critical roles in related ion pumps and are therefore likely to be common architectural components of the cation-binding site. Class 3 mutants appear to have altered selectivity for Ca(2+) and Mn(2+) ions, as exemplified by mutant Q783A in M6. These results demonstrate the utility of phenotypic screening in the identification of residues critical for ion transport and selectivity in cation pumps.     

Functional consequences of alterations to hydrophobic amino acids located at the M4S4 boundary of the Ca(2+)-ATPase of sarcoplasmic reticulum.

Site-specific mutagenesis was used to investigate the functional roles of amino acids in the relatively hydrophobic sequence Ile-Thr-Thr-Cys-Leu-Ala-320, located at the M4S4 boundary of the sarcomplasmic reticulum Ca(2+)-ATPase. Each of the residues was replaced with either a less hydrophogic, a polar, or a charged residue. Mutants Ile-315----Arg and Leu-319----Arg were devoid of any Ca2+ transport function or ATPase activity, while the mutant Thr-317----Asp retained about 5 and 7% of the wild-type Ca2+ transport and ATPase activities, respectively. These three mutants were able to form the ADP-sensitive phosphoenzyme intermediate (E1P) by reaction with ATP, but this intermediate decayed very slowly to the ADP-insensitive phosphoenzyme intermediate (E2P). In the mutants Ile-315----Arg and Leu-319----Arg, the level of E2P formed in the backward reaction with inorganic phosphate was extremely low, but hydrolysis of E2P occurred at a normal rate. These mutants, in addition, displayed a higher apparent affinity for Ca2+ than the wild-type enzyme. In the mutants Ile-315----Ser and Ile-315----Asp, the Ca2+ transport and ATPase activities were moderately reduced to 30-40% of the wild-type activities, but normal affinities for Ca2+, Pi, and ATP were retained, as was the low affinity modulatory effect of ATP. Mutation of Thr-316 to Asp, Thr-317 to Ala, Cys-318 to Ala and Ala-320 to Arg had little or no effect on Ca2+ transport or ATPase activities. Introduction of two negative and one positive charge by triple mutation of the Ile-Thr-Thr-317 sequence created a mutant enzyme that, although completely inactive, was inserted into the membrane, consistent with a location of these residues on the cytoplasmic side of the M4S4 interface. Our findings suggest that the amphipathic character of the S4 helix and/or the distribution of charges in S4 is important for the stability of the E2P intermediate.     

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.     

Golgi manganese transport is required for rapamycin signaling in Saccharomyces cerevisiae

The Pmr1 Golgi Ca2+/Mn2+ ATPase negatively regulates target of rapamycin complex (TORC1) signaling, the rapamycin-sensitive TOR complex in Saccharomyces cerevisiae. Since pmr1 causes resistance to rapamycin and tor1 causes hypersensitivity, we looked for genetic interactions of pmr1 with tor1. Deletion of TOR1 restored two wild-type phenotypes. Loss of TOR1 restored the ability of the pmr1 strain to grow on media containing 2 mm MnCl2 and conferred wild type as well as the wild-type sensitivity to rapamycin. Mn2+ additions to media partially suppressed rapamycin resistance of wild type and pmr1 tor1, suggesting that Tor1 and Tor2 are regulated by manganese. We parsed the roles of Ca2+ and Mn2+ transport and the compartments in rapamycin response using separation-of-function mutants available for Pmr1. A strain containing the D53A mutant (Mn2+ transporting) of Pmr1 is rapamycin sensitive, but the Q783A mutant (Ca2+ transporting) strain is rapamycin resistant. Mn2+ transport into the Golgi lumen appears to be required for rapamycin sensitivity. Overexpression of Ca2+ pump SERCA1, Ca2+/H+ antiporter Vcx1, or a Mn2+ transporting mutant of Vcx1 (Vcx1-M1) failed to restore rapamycin sensitivity, and loss of Pmr1 but not other transporters of Ca2+ or Mn2+ results in rapamycin resistance. Overexpression of Ccc1, a Fe2+ and Mn2+ transporter that has been localized to Golgi and the vacuole, does restore rapamycin sensitivity to pmr1Delta. We conclude that Mn2+ in the Golgi inhibits TORC1 signaling.     

Structural insights into activation of phosphatidylinositol 4-kinase (Pik1) by yeast frequenin (Frq1)

Yeast frequenin (Frq1), a small N-myristoylated EF-hand protein, activates phosphatidylinositol 4-kinase Pik1. The NMR structure of Ca2+-bound Frq1 complexed to an N-terminal Pik1 fragment (residues 121-174) was determined. The Frq1 main chain is similar to that in free Frq1 and related proteins in the same branch of the calmodulin superfamily. The myristoyl group and first eight residues of Frq1 are solvent-exposed, and Ca2+ binds the second, third, and fourth EF-hands, which associate to create a groove with two pockets. The Pik1 peptide forms two helices (125-135 and 156-169) connected by a 20-residue loop. Side chains in the Pik1 N-terminal helix (Val-127, Ala-128, Val-131, Leu-132, and Leu-135) interact with solvent-exposed residues in the Frq1 C-terminal pocket (Leu-101, Trp-103, Val-125, Leu-138, Ile-152, and Leu-155); side chains in the Pik1 C-terminal helix (Ala-157, Ala-159, Leu-160, Val-161, Met-165, and Met-167) contact solvent-exposed residues in the Frq1 N-terminal pocket (Trp-30, Phe-34, Phe-48, Ile-51, Tyr-52, Phe-55, Phe-85, and Leu-89). This defined complex confirms that residues in Pik1 pinpointed as necessary for Frq1 binding by site-directed mutagenesis are indeed sufficient for binding. Removal of the Pik1 N-terminal region (residues 8-760) from its catalytic domain (residues 792-1066) abolishes lipid kinase activity, inconsistent with Frq1 binding simply relieving an autoinhibitory constraint. Deletion of the lipid kinase unique motif (residues 35-110) also eliminates Pik1 activity. In the complex, binding of Ca2+-bound Frq1 forces the Pik1 chain into a U-turn. Frq1 may activate Pik1 by facilitating membrane targeting via the exposed N-myristoyl group and by imposing a structural transition that promotes association of the lipid kinase unique motif with the kinase domain.     

Thr-774 (transmembrane segment M5), Val-920 (M8), and Glu-954 (M9) are involved in Na+ transport, and Gln-923 (M8) is essential for Na,K-ATPase activity

The highly conserved amino acids of rat Na,K-ATPase, Thr-774 in the transmembrane helices M5, Val-920 and Gln-923 in M8, and Glu-953 and Glu-954 in M9, the side chains of which appear to be in close proximity, were mutated, and the resulting proteins, T774A, E953A/K, and E954A/K, V920E and Q923N/E/D/L, were expressed in HeLa cells. Ouabain-resistant cell lines were obtained from T774A, V920E, E953A, and E954A, whereas Q923N/E/D/L, E953K, and E954K could only be transiently expressed as fusion proteins with an enhanced green fluorescent protein. The apparent K0.5 values for Na+, as estimated by the Na+-dependent phosphoenzyme formation (K0.5(Na,EP)) or Na,K-ATPase activity (K(0.5)(Na,ATPase)), were increased by around 2 approximately 8-fold in the case of T774A, V920E, and E954A. The apparent K0.5 values for K+, as estimated by the Na,K-ATPase (K0.5(K,ATPase)) or p-nitrophenylphosphatase activity (K0.5(K,pNPPase)), were affected only slightly by the 3 mutations, except that V920E showed a 1.7-fold increase in the K0.5(K,ATPase). The apparent K0.5 values for ATP (K0.5(EP)), as estimated by phosphorylation (a high affinity ATP effect), were increased by 1.6 approximately 2.6-fold in the case of T774A, V920E, and E954A. Those estimated by Na,K-ATPase activity (K0.5(ATPase)) and ATP-induced inhibition (K(i,0.5)(pNPPase)) of K-pNPPase activity (low affinity ATP effects) were, respectively, increased by 1.8-fold and unchanged in the case of T774A but decreased by 2- and 4.8-fold in the case of V920E and were slightly changed and increased by 1.7-fold in the case of E954A. The E953A showed little significant change in the apparent affinities. These results suggest that Gln-923 in M8 is crucial for the active transport of Na+ and/or K+ across membranes and that the side chain oxygen atom of Thr-774 in M5, the methyl group(s) of Val-920 in M8, and the carboxyl oxygen(s) of Glu-954 in M9 mainly play some role in the transport of Na+ and also in the high and low affinity ATP effects rather than the transport of K+.     

Symmetrical stabilization of bound Ca2+ ions in a cooperative pair of EF-hands through hydrogen bonding of coordinating water molecules in calbindin D(9k)

Water molecules are found to complete the Ca2+ coordination sphere when a protein fails to provide enough ligating oxygens. Hydrogen bonding of these water molecules to the protein backbone or side chains may contribute favorably to the Ca2+ affinity, as suggested in an earlier study of two calbindin D(9k) mutants [E60D and E60Q; Linse et al. (1994) Biochemistry 33, 12478-12486]. To investigate the generality of this conclusion, another side chain, Gln 22, which hydrogen bonds to a Ca2+-coordinating water molecule in calbindin D(9k), was mutated. Two calbindin D(9k) mutants, (Q22E+P43M) and (Q22N+P43M), were constructed to examine the interaction between Gln 22 and the water molecule in the C-terminal calcium binding site II. Shortening of the side chain, as in (Q22N+P43M), reduces the affinity of binding two calcium ions by a factor of 18 at low ionic strength, whereas introduction of a negative charge, as in (Q22E+P43M), leads to a 12-fold reduction. In 0.15 M KCl, a 7-fold reduction in affinity was observed for both mutants. The cooperativity of Ca2+ binding increases for (Q22E+P43M), while it decreases for (Q22N+P43M). The rates of Ca2+ dissociation are 5.5-fold higher for the double mutants than for P43M at low ionic strength. For both mutants, reduced strength of hydrogen bonding to calcium-coordinating water molecules is a likely explanation for the observed effects on Ca2+ affinity and dissociation. In the apo forms, the (Q22E+P43M) mutant has lower stability toward urea denaturation than (Q22N+P43M) and P43M. 2D (1)H NMR and crystallographic experiments suggest that the structure of (Q22E+P43M) and (Q22N+P43M) is unchanged relative to P43M, except for local perturbations in the loop regions.     

One of the Ca2+ binding sites of recoverin exclusively controls interaction with rhodopsin kinase

Recoverin is a neuronal calcium sensor protein that controls the activity of rhodopsin kinase in a Ca(2+)-dependent manner. Mutations in the EF-hand Ca2+ binding sites are valuable tools for investigating the functional properties of recoverin. In the recoverin mutant E121Q (Rec E121Q ) the high-affinity Ca2+ binding site is disabled. The non-myristoylated form of Rec E121Q binds one Ca2+ via its second Ca(2+)-binding site (EF-hand 2), whereas the myristoylated variant does not bind Ca2+ at all. Binding of Ca2+ to non-myristoylated Rec E121Q apparently triggers exposure of apolar side chains, allowing for association with hydrophobic matrices. Likewise, an interaction surface for the recoverin target rhodopsin kinase is constituted upon Ca2+ binding to the non-acylated mutant. Structural changes resulting from Ca(2+)-occupation of EF-hand 2 in myristoylated and non-myristoylated recoverin variants are discussed in terms of critical conditions required for biological activity.     

Dissecting the total transition state stabilization provided by amino acid side chains at orotidine 5'-monophosphate decarboxylase: a two-part substrate approach

Kinetic analysis of decarboxylation catalyzed by S154A, Q215A, and S154A/Q215A mutant yeast orotidine 5'-monophosphate decarboxylases with orotidine 5'-monophosphate (OMP) and with a truncated nucleoside substrate (EO) activated by phosphite dianion shows (1) the side chain of Ser-154 stabilizes the transition state through interactions with the pyrimidine rings of OMP or EO, (2) the side chain of Gln-215 interacts with the phosphodianion group of OMP or with phosphite dianion, and (3) the interloop hydrogen bond between the side chains of Ser-154 and Gln-215 orients the amide side chain of Gln-215 to interact with the phosphodianion group of OMP or with phosphite dianion.     

Involvement of thioredoxin peroxidase type II (Ahp1p) of Saccharomyces cerevisiae in Mn2+ homeostasis

To identify new proteins involved in Mn2+ homeostasis, we isolated Mn(2+)-resistant mutants of Saccharomyces cerevisiae starting from a calcineurin-deficient, Mn2+ hypersensitive strain (delta cmp1 delta cmp2). The mutations were found to lie in the PMR1 gene, known to encode a "P-type" Ca(2+)-ATPase that transports Ca2+ and Mn2+ from the cytosol to the Golgi apparatus. A second gene, AHP1, was cloned as a suppressor of the Mn2+ tolerance of a delta cmp1 delta cmp2 pmr1 mutant. Ahp1p was recently described as a thioredoxin peroxidase type II, an antioxidant protein with alkyl hydroperoxide defense properties in yeast. AHP1 disruption in strain W303 decreased tolerance to Mn2+ and H2O2. We found that a GFP-Ahp1p fusion construct was in the cytosol when cells were grown in glucose, and in the mitochondria when cells were grown in oleate. Based on Mn2+ transport data, we concluded that Ahp1p is involved in cellular Mn2+ homeostasis in trafficking of Mn2+ from cytosol to mitochondria and from cytosol for export across the plasma membrane.     

Roles of Residues Arg-61 and Gln-38 of Human DNA Polymerase η in Bypass of Deoxyguanosine and 7,8-Dihydro-8-oxo-2′-deoxyguanosine

Like the other Y-family DNA polymerases, human DNA polymerase η (hpol η) has relatively low fidelity and is able to tolerate damage during DNA synthesis, including 7,8-dihydro-8-oxo-2′-deoxyguanosine (8-oxoG), one of the most abundant DNA lesions in the genome. Crystal structures show that Arg-61 and Gln-38 are located near the active site and may play important roles in the fidelity and efficiency of hpol η. Site-directed mutagenesis was used to replace these side chains either alone or together, and the wild type or mutant proteins were purified and tested by replicating DNA past deoxyguanosine (G) or 8-oxoG. The catalytic activity of hpol η was dramatically disrupted by the R61M and Q38A/R61A mutations, as opposed to the R61A and Q38A single mutants. Crystal structures of hpol η mutant ternary complexes reveal that polarized water molecules can mimic and partially compensate for the missing side chains of Arg-61 and Gln-38 in the Q38A/R61A mutant. The combined data indicate that the positioning and positive charge of Arg-61 synergistically contribute to the nucleotidyl transfer reaction, with additional influence exerted by Gln-38. In addition, gel filtration chromatography separated multimeric and monomeric forms of wild type and mutant hpol η, indicating the possibility that hpol η forms multimers in vivo.     

Steroid-induced conformational changes of FITC-labelled sarcoplasmic reticulum Ca2+-ATPase

Interactions between transmembrane and cytoplasmic domains of Ca2+-ATPase from sarcoplasmic reticulum (SR) have been studied. To affect the hydrophobic transmembrane domain, we used four amphiphilic steroids - esters of a dibasic acid and 20-oxypregnene. All four steroids contained cholesterol-like nuclei and differed by the structure of side chains. Steroids with carboxyl groups in the side chains inhibited the rates of ATP hydrolysis and Ca2+ transport, whereas a steroid without the carboxyl group did not appreciably affect Ca2+-ATPase function. Fluorimetric titration of FITC-labelled Ca2+-ATPase in SR vesicles by Nd3+ showed that steroids increased the apparent dissociation constant for Nd3+ bound to the hydrolytic site, the potency order of the steroids being the same as for the sterol-induced inhibition of the hydrolytic activity of Ca2+-ATPase. These results suggest structural changes in the active site. Ca2+ transport was inhibited more efficiently by steroids than the hydrolytic activity of the enzyme. This could be partially due to the increase of the membrane passive permeability induced by steroids, which, in turn, reflected the efficiency of the interaction of the steroids with lipid bilayers. The effects of the steroids were largely dependent on their amphiphilicity (the availability of polar groups in regions A and D), the structure of the side chains, and, possibly, on the distance between the molecular polar groups. We suggest that the inhibition of hydrolytic and transport functions of Ca2+-ATPase in the SR membrane is due to the interaction of the steroids with the transmembrane alpha-helical segments.     

Functional consequences of alterations to polar amino acids located in the transmembrane domain of the Ca2(+)-ATPase of sarcoplasmic reticulum

Glu309, Glu771, Asn796, Thr799, Asp800, and Glu908 (ligands 1 to 6, respectively) appear to form the high affinity Ca2(+)-binding sites of the Ca2(+)-ATPase. The plasticity of the Ca2(+)-binding sites was tested by separate replacement of each of the ligands with a structurally similar oxygen-containing residue using site-specific mutagenesis. Mutant cDNAs were transfected into COS-1 cells, and ATP-dependent Ca2+ transport or partial reactions were studied in microsomes containing the expressed Ca2(+)-ATPases. In most cases where amino acid substitutions were carried out, the expressed enzymes lacked Ca2+ transport function and Ca2(+)-dependent phosphorylation by ATP. Furthermore, the mutant enzymes were phosphorylated by inorganic phosphate, even in the presence of Ca2+, which inhibits phosphorylation of the wild-type enzyme possessing intact Ca2(+)-binding sites. On mutant, however, containing an isosteric replacement of Glu by Gln at ligand 6, exhibited wild-type levels of Ca2+ transport activity and Ca2+ affinity. Two mutants exhibited properties consistent with a reduction in Ca2+ affinity. In the mutant in which Thr was replaced by Ser at ligand 4, Ca2+ transport activity was 70% of wild-type, while half-maximal activation by Ca2+ occurred at 0.8 microM as compared to 0.3 microM for the wild-type enzyme. In the mutant Glu309----Asp at ligand 1, Ca2+ transport activity was lost, but Ca2(+)-activated phosphorylation by ATP was retained. The concentration of Ca2+ required to activate phosphorylation was increased about 10-fold, however, compared to wild type. These results support our hypothesis that ligands 1 to 6, believed to reside within the transmembrane domain, interact with Ca2+ ions during the transport process. The roles of 12 other oxygen-containing residues and of His278 located in the transmembrane domain were also examined by mutation. Although the oxygen-containing side chains of these residues are potential Ca2+ ligands, their replacement with nonpolar amino acids did not abolish Ca2+ transport function, leading to the conclusion that they are not essential ligands for high affinity Ca2+ binding by the Ca2+ pump.     

Three-dimensional structures of H-ras p21 mutants: molecular basis for their inability to function as signal switch molecules

The X-ray structures of the guanine nucleotide binding domains (amino acids 1-166) of five mutants of the H-ras oncogene product p21 were determined. The mutations described are Gly-12----Arg, Gly-12----Val, Gln-61----His, Gln-61----Leu, which are all oncogenic, and the effector region mutant Asp-38----Glu. The resolutions of the crystal structures range from 2.0 to 2.6 A. Cellular and mutant p21 proteins are almost identical, and the only significant differences are seen in loop L4 and in the vicinity of the gamma-phosphate. For the Gly-12 mutants the larger side chains interfere with GTP binding and/or hydrolysis. Gln-61 in cellular p21 adopts a conformation where it is able to catalyze GTP hydrolysis. This conformation has not been found for the mutants of Gln-61. Furthermore, Leu-61 cannot activate the nucleophilic water because of the chemical nature of its side chain. The D38E mutation preserves its ability to bind GAP.     

Functional expression in yeast of the human secretory pathway Ca(2+), Mn(2+)-ATPase defective in Hailey-Hailey disease.

The discovery and biochemical characterization of the secretory pathway Ca(2+)-ATPase, PMR1, in Saccharomyces cerevisiae, has paved the way for identification of PMR1 homologues in many species including rat, Caenorhabditis elegans, and Homo sapiens. In yeast, PMR1 has been shown to function as a high affinity Ca(2+)/Mn(2+) pump and has been localized to the Golgi compartment where it is important for protein sorting, processing, and glycosylation. However, little is known about PMR1 homologues in higher organisms. Loss of one functional allele of the human gene, hSPCA1, has been linked to Hailey-Hailey disease, characterized by skin ulceration and improper keratinocyte adhesion. We demonstrate that expression of hSPCA1 in yeast fully complements pmr1 phenotypes of hypersensitivity to Ca(2+) chelators and Mn(2+) toxicity. Similar to PMR1, epitope-tagged hSPCA1 also resides in the Golgi when expressed in yeast or in chinese hamster ovary cells. (45)Ca(2+) transport by hSPCA1 into isolated yeast Golgi vesicles shows an apparent Ca(2+) affinity of 0.26 microm, is inhibitable by Mn(2+), but is thapsigargin-insensitive. In contrast, heterologous expression of vertebrate sarcoplasmic reticulum and plasma membrane Ca(2+)-ATPases in yeast complement the Ca(2+)- but not Mn(2+)-related phenotypes of the pmr1-null strain, suggesting that high affinity Mn(2+) transport is a unique feature of the secretory pathway Ca(2+)-ATPases.     

Passive transport of Ca2+ in vesiculated preparations of myocardial sarcolemma

The highly purified vesicles of myocardial sarcolemma oriented outward mainly by the cytoplasmic side are used to show that Ca2+-calmodulin-dependent phosphorylation inhibits passive Ca2+-transport, while R24571, a blocking agent of calmodulin-dependent processes, removes this inhibitory effect. Passive Ca2+ transport is also inhibited by nicardipin with Ki (5 X 10(-8) M) and Mg2+. Tetrodotoxin and tetraethylammonium exert no effect on Ca2+-transport.     

Energy-dependent Mn2+ and Ca2+ uptake by the embryonic chick chorioallantoic membrane.

The chick chorioallantoic membrane is an epithelial tissue which actively transports large amounts of Ca2+ during embryonic development. In this paper Mn2+ uptake by the tissue was studied and compared to Ca2+ uptake in parallel experiments. The purpose of these experiments was to determine if Mn2+ could be used to gain more information about the Ca2+ transport system. It was found that Mn2+ uptake was reduced significantly under conditions that reduced Ca2+ uptake and that Mn2+, like Ca2+, was taken up preferentially by the ectodermal side of the tissue. Mn2+ uptake showed saturation kinetics with a Km of 0.33 MM. Mn2+ uptake was also competitively inhibited by Ca2+, and Ca2+ uptake inhibited by Mn2+. Electron microprobe studies showed that Mn2+ was localized in the ectoderm of the tissue in the same way as Ca2+. It was concluded from these studies that significant amounts of Mn2+ were accumulated by the active Ca2+ transport mechanism and that Mn2+ could be useful paramagnetic probe of divalent cation transport in this tissue.     

Escherichia coli H(+)-ATPase: role of the delta subunit in binding Fl to the Fo sector.

The roles of the Escherichia coli H(+)-ATPase (FoFl) delta subunit (177 amino acid residues) was studied by analyzing mutants. The membranes of nonsense (Gln-23----end, Gln-29----end, Gln-74----end) and missense (Gly-150----Asp) mutants had very low ATPase activities, indicating that the delta subunit is essential for the binding of the Fl portion to Fo. The Gln-176----end mutant had essentially the same membrane-bound activity as the wild type, whereas in the Val-174----end mutant most of the ATPase activity was in the cytoplasm. Thus Val-174 (and possibly Leu-175 also) was essential for maintaining the structure of the subunit, whereas the two carboxyl terminal residues Gln-176 and Ser-177 were dispensable. Substitutions were introduced at various residues (Thr-11, Glu-26, Asp-30, Glu-42, Glu-82, Arg-85, Asp-144, Arg-154, Asp-161, Ser-163), including apparently conserved hydrophilic ones. The resulting mutants had essentially the same phenotypes as the wild type, indicating that these residues do not have any significant functional role(s). Analysis of mutations (Gly-150----Asp, Pro, or Ala) indicated that Gly-150 itself was not essential, but that the mutations might affect the structure of the subunit. These results suggest that the overall structure of the delta subunit is necessary, but that individual residues may not have strict functional roles.     

A glutamine residue conserved in the neurotransmitter:sodium:symporters is essential for the interaction of chloride with the GABA transporter GAT-1

Neurotransmitter:sodium symporters are crucial for efficient synaptic transmission. The transporter GAT-1 mediates electrogenic cotransport of GABA, sodium, and chloride. The presence of chloride enables the transporter to couple the transport of the neurotransmitter to multiple sodium ions, thereby enabling its accumulation against steep concentration gradients. Here we study the functional impact of mutations of the putative chloride-binding residues on transport by GAT-1, with the emphasis on a conserved glutamine residue. In contrast to another putative chloride coordinating residue, Ser-331, where mutation to glutamate led to chloride-independent GABA transport, the Q291E mutant was devoid of any transport activity, despite substantial expression at the plasma membrane. Low but significant transport activity was observed with substitution mutants with small side chains such as Q291S/A/G. Remarkably, when these mutations were combined with the S331E mutation, transport was increased significantly, even though the activity of the S331E single mutant was only ～25% of that of wild type GAT-1. Transport by these double mutants was largely chloride-independent. Like mutants of other putative chloride coordinating residues, the apparent affinity of the active Gln-291 single mutants for chloride was markedly reduced along with a change their anion selectivity. In addition to the interaction of the transporter with chloride, Gln-291 is also required at an additional step during transport. Electrophysiological analysis of the Q291N and Q291S mutants, expressed in Xenopus laevis oocytes, is consistent with the idea that this additional step is associated with the gating of the transporter.