SERCA mutant E309Q binds two Ca2+ ions but adopts a catalytically incompetent conformation

The sarco(endo)plasmic reticulum Ca²⁺‐ATPase (SERCA) couples ATP hydrolysis to transport of Ca²⁺. This directed energy transfer requires cross‐talk between the two Ca²⁺ 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. Glu³⁰⁹ contributes to Ca²⁺ coordination at site II, and a consensus has been that E309Q only binds Ca²⁺ at site I. The crystal structure of E309Q in the presence of Ca²⁺ and an ATP analogue, however, reveals two occupied Ca²⁺ sites of a non‐catalytic Ca₂E1 state. Ca²⁺ is bound with micromolar affinity by both Ca²⁺ sites in E309Q, but without cooperativity. The Ca²⁺‐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 Ca²⁺ site II.     

A thermosensitive defect in the ATP binding pocket of FtsA can be suppressed by allosteric changes in the dimer interface

In Escherichia coli, initial assembly of the Z ring for cell division requires FtsZ plus the essential Z ring‐associated proteins FtsA and ZipA. Thermosensitive mutations in ftsA, such as ftsA27, map in or near its ATP binding pocket and result in cell division arrest at non‐permissive temperatures. We found that purified wild‐type FtsA bound and hydrolysed ATP, whereas FtsA27 was defective in both activities. FtsA27 was also less able to localize to the Z ring in vivo. To investigate the role of ATP transactions in FtsA function in vivo, we isolated intragenic suppressors of ftsA27. Suppressor lesions in the ATP site restored the ability of FtsA27 to compete with ZipA at the Z ring, and enhanced ATP binding and hydrolysis in vitro. Notably, suppressors outside of the ATP binding site, including some mapping to the FtsA‐FtsA subunit interface, also enhanced ATP transactions and exhibited gain of function phenotypes in vivo. These results suggest that allosteric effects, including changes in oligomeric state, may influence the ability of FtsA to bind and/or hydrolyse ATP.     

Synthesis,Biological Evaluation,and Molecular Docking Studies of Novel 4‐[4‐Arylpyridin‐1(4H)‐yl]benzoic Acid Derivatives as Anti‐HIV‐1 Agents

The structural similarities between N1 substituted 1,4‐dihydropyridines and the known gp41 inhibitors, NB ‐2 and NB ‐64 , were considered in the current research for the design of some novel anti‐HIV‐1 agents. A series of novel 4‐[4‐arylpyridin‐1(4H)‐yl]benzoic acid derivatives were synthesized and after a comprehensive structural elucidation were screened for in vitro anti‐HIV‐1 activity. Most of the tested compounds displayed moderate to good inhibitory activity against HIV‐1 growth and were evaluated for in vitro cytotoxic activity using XTT assay at the concentration of 100 μm . Among the tested compounds, 1c , 1d and 1e showed potent anti‐HIV‐1 activity against P24 expression at 100 μm with inhibition percentage of 84.00%, 76.42% and 80.50%, respectively. All the studied compounds possessed no significant cytotoxicity on MT‐2 cell line. The binding modes of these compounds to gp41 binding site were determined through molecular docking study. Docking studies proved 1a as the most potent compound and binding maps exhibited that the activities might be attributed to the electrostatic and hydrophobic interactions and additional H‐bonds with the gp41 binding site. The Lipinski's ‘rule of five’ and drug‐likeness criteria were also calculated for the studied compounds. All derivatives obeyed the Lipinski's ‘rule of five’ and had drug‐like features. The findings of this study suggest that novel 4‐[4‐arylpyridin‐1(4H)‐yl]benzoic acid might be a promising scaffold for the discovery and development of novel anti‐HIV‐1 agents.     

Strategies for maximizing ATP supply in the microsporidian Encephalitozoon cuniculi: direct binding of mitochondria to the parasitophorous vacuole and clustering of the mitochondrial porin VDAC

Microsporidia are obligate intracellular parasites with extremely reduced genomes and a dependence on host‐derived ATP. The microsporidium Encephalitozoon cuniculi proliferates within a membranous vacuole and we investigated how the ATP supply is optimized at the vacuole–host interface. Using spatial EM quantification (stereology), we found a single layer of mitochondria coating substantial proportions of the parasitophorous vacuole. Mitochondrial binding occurred preferentially over the vegetative ‘meront’ stages of the parasite, which bulged into the cytoplasm, thereby increasing the membrane surface available for mitochondrial interaction. In a broken cell system mitochondrial binding was maintained and was typified by electron dense structures (< 10 nm long) bridging between outer mitochondrial and vacuole membranes. In broken cells mitochondrial binding was sensitive to a range of protease treatments. The function of directly bound mitochondria, as measured by the membrane potential sensitive dye JC‐1, was indistinguishable from other mitochondria in the cell although there was a generalized depression of the membrane potential in infected cells. Finally, quantitative immuno‐EM revealed that the ATP‐delivering mitochondrial porin, VDAC, was concentrated atthe mitochondria‐vacuole interaction site. Thus E. cuniculi appears to maximize ATP supply by direct binding of mitochondria to the parasitophorous vacuole bringing this organelle within 0.020 microns of the growing vegetative form of the parasite. ATP‐delivery is further enhanced by clustering of ATP transporting porins in those regions of the outer mitochondrial membrane lying closest to the parasite.     

A bestrophin‐like protein modulates the proton motive force across the thylakoid membrane in Arabidopsis

During photosynthesis, photosynthetic electron transport generates a proton motive force(pmf) across the thylakoid membrane, which is used for ATP biosynthesis via ATP synthase in the chloroplast. The pmf is composed of an electric potential(△Ψ) and an osmotic component(△pH).Partitioning between these components in chloroplasts is strictly regulated in response to fluctuating environments.However, our knowledge of the molecular mechanisms that regulate pmf partitioning is limited. Here, we report a bestrophin-like protein(At Best), which is critical for pmf partitioning. While the Dp H component was slightly reduced in atbest, the △Ψ component was much greater in this mutant than in the wild type, resulting in less efficient activation of nonphotochemical quenching(NPQ) upon both illumination and a shift from low light to high light. Although no visible phenotype was observed in the atbest mutant in the greenhouse, this mutant exhibited stronger photoinhibition than the wild type when grown in the field. At Best belongs to the bestrophin family proteins, which are believed to function as chloride(Cl~-) channels. Thus, our findings reveal an Researimportant Cl~- channel required for ion transport and homeostasis across the thylakoid membrane in higher plants. These processes are essential for fine-tuning photosynthesis under fluctuating environmental conditions.     

Nucleotide recognition by CopA,a Cu+‐transporting P‐type ATPase

Heavy metal pumps constitute a large subgroup in P‐type ion‐transporting ATPases. One of the outstanding features is that the nucleotide binding N‐domain lacks residues critical for ATP binding in other well‐studied P‐type ATPases. Instead, they possess an HP‐motif and a Gly‐rich sequence in the N‐domain, and their mutations impair ATP binding. Here, we describe 1.85 Å resolution crystal structures of the P‐ and N‐domains of CopA, an archaeal Cu⁺‐transporting ATPase, with bound nucleotides. These crystal structures show that CopA recognises the adenine ring completely differently from other P‐type ATPases. The crystal structure of the His462Gln mutant, in the HP‐motif, a disease‐causing mutation in human Cu⁺‐ATPases, shows that the Gln side chain mimics the imidazole ring, but only partially, explaining the reduction in ATPase activity. These crystal structures lead us to propose a role of the His and a mechanism for removing Mg²⁺ from ATP before phosphoryl transfer.     

ATP synthase complex and the mitochondrial permeability transition pore: poles of attraction

The identity of the mitochondrial permeability transition (mPT) pore, a megachannel embedded in the inner membrane opened by Ca²⁺, is fiercely debated. Unraveling the components structuring this pore is critical for combating diseases as diverse as neurodegeneration, cancer, autoimmunity, and myopathies in which this phenomenon is implicated. Current consensus is that the pore is formed within, or in‐between F₀F₁ ATP synthase dimers, but not through their c‐subunit ring. Two recent studies in this issue of EMBO Reports throw more light on these aspects, one by Giorgio et al 1 showing that the β subunit of the ATP synthase harbors a Ca²⁺‐binding site responsible for triggering mPT, and the other by Bonora et al 2 demonstrating that permeability transition requires dissociation of F₀F₁ ATP synthase dimers, albeit in a manner involving the c‐subunit ring.     

GIL,a new c‐di‐GMP‐binding protein domain involved in regulation of cellulose synthesis in enterobacteria

In contrast to numerous enzymes involved in c‐di‐GMP synthesis and degradation in enterobacteria, only a handful of c‐di‐GMP receptors/effectors have been identified. In search of new c‐di‐GMP receptors, we screened the Escherichia coli ASKA overexpression gene library using the Differential Radial Capillary Action of Ligand Assay (DRaCALA) with fluorescently and radioisotope‐labelled c‐di‐GMP. We uncovered three new candidate c‐di‐GMP receptors in E. coli and characterized one of them, BcsE. The bcsE gene is encoded in cellulose synthase operons in representatives of Gammaproteobacteria and Betaproteobacteria. The purified BcsE proteins from E. coli, Salmonella enterica and Klebsiella pneumoniae bind c‐di‐GMP via the domain of unknown function, DUF2819, which is hereby designated GIL, G GDEF I ‐site l ike domain. The RxGD motif of the GIL domain is required for c‐di‐GMP binding, similar to the c‐di‐GMP‐binding I‐site of the diguanylate cyclase GGDEF domain. Thus, GIL is the second protein domain, after PilZ, dedicated to c‐di‐GMP‐binding. We show that in S. enterica, BcsE is not essential for cellulose synthesis but is required for maximal cellulose production, and that c‐di‐GMP binding is critical for BcsE function. It appears that cellulose production in enterobacteria is controlled by a two‐tiered c‐di‐GMP‐dependent system involving BcsE and the PilZ domain containing glycosyltransferase BcsA.     

Ca2+ binding to F‐ATP synthase β subunit triggers the mitochondrial permeability transition

F‐ATP synthases convert the electrochemical energy of the H⁺ gradient into the chemical energy of ATP with remarkable efficiency. Mitochondrial F‐ATP synthases can also undergo a Ca²⁺‐dependent transformation to form channels with properties matching those of the permeability transition pore (PTP), a key player in cell death. The Ca²⁺ binding site and the mechanism(s) through which Ca²⁺ can transform the energy‐conserving enzyme into a dissipative structure promoting cell death remain unknown. Through in vitro, in vivo and in silico studies we (i) pinpoint the “Ca²⁺‐trigger site” of the PTP to the catalytic site of the F‐ATP synthase β subunit and (ii) define a conformational change that propagates from the catalytic site through OSCP and the lateral stalk to the inner membrane. T163S mutants of the β subunit, which show a selective decrease in Ca²⁺‐ATP hydrolysis, confer resistance to Ca²⁺‐induced, PTP‐dependent death in cells and developing zebrafish embryos. These findings are a major advance in the molecular definition of the transition of F‐ATP synthase to a channel and of its role in cell death.     

Chemical Modification Reveals Involvement of Different Sites for Nucleotide Analogues in the Phosphatase Activity of the Red Cell Calcium Pump

The calcium pump of plasma membranes catalyzes the hydrolysis of ATP and phosphoric esters like p-nitrophenyl phosphate (pNPP). The latter activity requires the presence of ATP and/or calmodulin, and Ca²⁺ [22, 25]. We have studied the effects of nucleotide-analogues and chemical modifications of nucleotide binding sites on Ca²⁺-pNPPase activity. Treatment with fluorescein isothiocyanate (FITC), abolished Ca²⁺-ATPase and ATP-dependent pNPPase, but affected only 45% of the calmodulin-dependent pNPPase activity. The nucleotide analogue eosin-Y had an inhibitory effect on calmodulin-dependent pNPPase (Ki _eosin-Y= 2 μm). FITC treatment increased Ki _eosin-Y 15 times. Acetylation of lysine residues with N-hydroxysuccinimidyl acetate inactivates Ca²⁺-ATPase by modifying the catalytic site, and impairs stimulation by modulators by modifying residues outside this site [9]. Acetylation suppressed the ATP-dependent pNPPase with biphasic kinetics. ATP or pNPP during acetylation cancels the fast component of inactivation. Acetylation inhibited only partially the calmodulin-dependent pNPPase, but neither ATP nor pNPP prevented this inactivation. From these results we conclude: (i) ATP-dependent pNPPase depends on binding of ATP to the catalytic site; (ii) the catalytic site plays no role in calmodulin-dependent pNPPase. The decreased affinity for eosin-Y of the FITC-modified enzyme, suggests that the sites for these two molecules are closely related but not overlapped. Acetimidation of the pump inhibited totally the calmodulin-dependent pNPPase, but only partially the ATP-pNPPase. Since calmodulin binds to E₁, the E₁ conformation or the E₂? E₁ transition would be involved during calmodulin-dependent pNPPase activity. Received: 20 January 1998     

Alkaliphiles:'basic'molecular problems of pH tolerance and bioenergetics

Alkaliphilic Bacillus species provide experimental opportunities for examination of physiological processes under conditions in which the stress of the extreme environment brings issues of general biological importance into special focus. The alkaliphile, like many other cells, uses Na⁺/H⁺ antiporters in pH regulation, but its array of these porters, and other ion-flux pathways that energize and support their activity, result in an extraordinary capacity for pH homeostasis; this process nonetheless becomes the factor that limits growth at the upper edge of the pH range. Above pH 9.5, aerobic alkaliphiles maintain a cytoplasmic pH that is two or more units below the external pH. This chemiosmotically adverse δpH is bypassed by use of an electrochemical gradient of Na⁺ rather than of protons to energize solute uptake and motility. By contrast, ATP synthesis occurs via completely proton-coupled oxidative phosphorylation that proceeds just as well, or better, at pH10 and above as it does in the same bacteria growing at lower pH, without the adverse pH gradient. Various mechanisms that might explain this conundrum are described, and the current state of the evidence supporting them is summarized.     

Acidic residues and a predicted,highly conserved α‐helix are critical for the endonuclease/strand separation functions of bacteriophage λ’s TerL

Complementation, endonuclease, strand separation, and packaging assays using mutant TerL^λ’s, coupled with bioinformatic information and modeling of its endonuclease, identified five residues, D401, E408, D465, E563, and E586, as critical acidic residues of TerL^λ’s endonuclease. Studies of phage and viral TerL nucleases indicate acidic residues participate in metal ion‐binding, part of a two‐ion metal catalysis mechanism, where metal ion A activates a water for DNA backbone hydrolysis. Modeling places D401, D465, and E586 in locations analogous to those of the metal‐binding residues of many phage and viral TerLs. Our work leads to a model of TerL^λ’s endonuclease domain where at least three acidic residues from a ~185 residue segment (D401 to E586) are near each other in the structure, forming the endonuclease catalytic center at cosN, the nicking site. DNA interactions required to bring the rotationally symmetric cosN precisely to the catalytic center are proposed to rely on an ~60 residue region that includes a conserved α‐helix for dimerization. Metal ion A, positioned by TerL^λ’s acidic D401 and E586, would be placed at cosN for water activation, ensuring high accuracy for DNA backbone hydrolysis.     

pH homeostasis and ATP synthesis: studies of two processes that necessitate inward proton translocation in extremely alkaliphilic Bacillus species

Alkaliphilic Bacillus species that are isolated from nonmarine, moderate salt, and moderate temperature environments offer the opportunity to explore strategies that have developed for solving the energetic challenges of aerobic growth at pH values between 10 and 11. Such bacteria share many structural, metabolic, genomic, and regulatory features with nonextremophilic species such as Bacillus subtilis. Comparative studies can therefore illuminate the specific features of gene organization and special features of gene products that are homologs of those found in non-extremophiles, and potentially identify novel gene products of importance in alkaliphily. We have focused our studies on the facultative alkaliphile Bacillus firmus OF4, which is routinely grown on malate-containing medium at either pH 7.5 or 10.5. Current work is directed toward clarification of the characteristics and energetics of membrane-associated proteins that must catalyze inward proton movements. One group of such proteins are the Na⁺/H⁺ antiporters that enable cells to adapt to a sudden upward shift in pH and to maintain a cytoplasmic pH that is 2–2.3 units below the external pH in the most alkaline range of pH for growth. Another is the proton-translocating ATP synthase that catalyzes robust production of ATP under conditions in which the external proton concentration and the bulk chemiosmotic driving force are low. Three gene loci that are candidates for Na⁺/H⁺ antiporter encoding genes with roles in Na⁺- dependent pH homeostasis have been identified. All of them have homologs in B. subtilis, in which pH homeostasis can be carried out with either K⁺ or Na⁺. The physiological importance of one of the B. firmus OF4 loci, nhaC, has been studied by targeted gene disruption, and the same approach is being extended to the others. The atp genes that encode the alkaliphile's F₁F_O-ATP synthase are found to have interesting motifs in areas of putative importance for proton translocation. As an initial step in studies that will probe the importance and possible roles of these motifs, the entire atp operon from B. firmus OF4 has been cloned and functionally expressed in an Escherichia coli mutant that has a full deletion of its atp genes. The transformant does not exhibit growth on succinate, but shows reproducible, modest increases in the aerobic growth yields on glucose as well as membrane ATPase activity that exhibits characteristics of the alkaliphile enzyme. Received: January 22, 1998 / Accepted: February 16, 1998     

Kinase activity and calmodulin binding are essential for growth signaling by the phytosulfokine receptor PSKR1

The cell growth‐promoting peptide phytosulfokine (PSK) is perceived by leucine‐rich repeat (LRR) receptor kinases. To elucidate PSK receptor function we analyzed PSKR1 kinase activity and binding to Ca²⁺ sensors and evaluated the contribution of these activities to growth control in planta. Ectopically expressed PSKR1 was capable of auto‐ and transphosphorylation. Replacement of a conserved lysine within the ATP‐binding region by a glutamate resulted in the inhibition of auto‐ and transphosphorylation kinase activities. Expression of the kinase‐inactive PSKR1(K762E) receptor in the pskr null background did not restore root or shoot growth. Instead, the mutant phenotype was enhanced suggesting that the inactive receptor protein exerts growth‐inhibitory activity. Bioinformatic analysis predicted a putative calmodulin (CaM)‐binding site within PSKR1 kinase subdomain VIa. Bimolecular fluorescence complementation analysis demonstrated that PSKR1 binds to all isoforms of CaM, more weakly to the CaM‐like protein CML8 but apparently not to CML9. Mutation of a conserved tryptophan (W831S) within the predicted CaM‐binding site strongly reduced CaM binding. Expression of PSKR1(W831S) in the pskr null background resulted in growth inhibition that was similar to that of the kinase‐inactive receptor. We conclude that PSK signaling requires Ca²⁺/CaM binding and kinase activity of PSKR1 in planta. We further propose that the inactivated kinase interferes with other growth‐promoting signaling pathway(s).     

Deciphering the ‘Elixir of Life’: Dynamic Perspectives into the Allosteric Modulation of Mitochondrial ATP Synthase by J147, a Novel Drug in the Treatment of Alzheimer's Disease

The discovery of J147 represented a significant milestone in the treatment of age‐related disorders, which was further augmented by the recent identification of mitochondrial ATP synthase as the therapeutic target. However, the underlying molecular events associated with the modulatory activity of J147 have remained unresolved till date. Herein, we present, for the first time, a dynamical approach to investigate the allosteric regulation of mATP synthase by J147, using a reliable human αγβ protein model. The highlight of our findings is the existence of the J147‐bound protein in distinct structural associations at different MD simulation periods coupled with concurrent open?close transitions of the β catalytic and α allosteric (ATP5A) sites as defined by Cα distances (d), TriCα (Θ) and dihedral (φ) angular parameters. Firstly, there was an initial pairing of the αγ subunits away from the β subunit followed by the formation of the ‘non‐catalytic’ αβ pair at a distance from the γ subunit. Interestingly, J147‐induced structural arrangements were accompanied by the systematic transition of the β catalytic site from a closed to an open state, while there was a concurrent transition of the allosteric site from an open α_E conformation to a closed state. Consequentially, J147 reduced the structural activity of the whole αγβ complex, while the unbound system exhibited high atomistic deviations and structural flexibility. Furthermore, J147 exhibited favorable binding at the allosteric site of mATP synthase with considerable electrostatic energy contributions from Gln215, Gly217, Thr219, Asp312, Asp313, Glu371 and Arg406. These findings provide details on the possible effects of J147 on mitochondrial bioenergetics, which could facilitate the structure‐based design of novel small‐molecule modulators of mATP synthase in the management of Alzheimer's disease and other neurodegenerative disorders.     

A role for the FtsQLB complex in cytokinetic ring activation revealed by an ftsL allele that accelerates division

The cytokinetic apparatus of bacteria is initially formed by the polymerization of the tubulin‐like FtsZ protein into a ring structure at midcell. This so‐called Z‐ring facilitates the recruitment of many additional proteins to the division site to form the mature divisome machine. Although the assembly pathway leading to divisome formation has been well characterized, the mechanisms that trigger cell constriction remain unclear. In this report, we study a ‘forgotten’ allele of ftsL from Escherichia coli, which encodes a conserved division gene of unknown function. We discovered that this allele promotes the premature initiation of cell division. Further analysis also revealed that the mutant bypasses the requirement for the essential division proteins ZipA, FtsK and FtsN, and partially bypasses the need for FtsA. These findings suggest that rather than serving simply as a protein scaffold within the divisome, FtsL may play a more active role in the activation of the machine. Our results support a model in which FtsL, along with its partners FtsB and FtsQ, function as part of a sensing mechanism that promotes the onset of cell wall remodeling processes needed for the initiation of cell constriction once assembly of the divisome complex is deemed complete.     

Ca2+‐independent sortase‐A exhibits high selective protein ligation activity in the cytoplasm of Escherichia coli

A Staphylococcus aureus transpeptidase, sortase A (SrtA), which catalyzes a peptide ligation with high substrate specificity, is a useful tool to site‐specifically attach proteinaceous/peptidic functional molecules to target proteins. However, its strong Ca²⁺ dependency makes SrtA difficult for use under low Ca²⁺ concentrations and in the presence of Ca²⁺‐binding substances. To overcome this problem, we designed a SrtA mutant that Ca²⁺‐independently demonstrates a high catalytic activity. The heptamutant (P94R/E105K/E108A/D160N/D165A/K190E/K196T), which resulted from a combination of known mutations at the Ca²⁺‐binding site and around the substrate‐binding site, successfully catalyzed a selective protein‐protein ligation in the cytoplasm of Escherichia coli. Selective protein modification in living cells is a promising approach for investigating cellular events and regulating cell functions. This SrtA mutant may prove to be a versatile tool for adding new functionalities to proteins of interest by incorporating functional proteins and chemically modified peptides in living cells, which usually retain low Ca²⁺ concentrations.     

A single‐component multidrug transporter of the major facilitator superfamily is part of a network that protects Escherichia coli from bile salt stress

Resistance to high concentrations of bile salts in the human intestinal tract is vital for the survival of enteric bacteria such as Escherichia coli. Although the tripartite AcrAB–TolC efflux system plays a significant role in this resistance, it is purported that other efflux pumps must also be involved. We provide evidence from a comprehensive suite of experiments performed at two different pH values (7.2 and 6.0) that reflect pH conditions that E. coli may encounter in human gut that MdtM, a single‐component multidrug resistance transporter of the major facilitator superfamily, functions in bile salt resistance in E. coli by catalysing secondary active transport of bile salts out of the cell cytoplasm. Furthermore, assays performed on a chromosomal ΔacrB mutant transformed with multicopy plasmid encoding MdtM suggested a functional synergism between the single‐component MdtM transporter and the tripartite AcrAB–TolC system that results in a multiplicative effect on resistance. Substrate binding experiments performed on purified MdtM demonstrated that the transporter binds to cholate and deoxycholate with micromolar affinity, and transport assays performed on inverted vesicles confirmed the capacity of MdtM to catalyse electrogenic bile salt/H⁺ antiport.