A unique mechanism of curcumin inhibition on F1 ATPase

ATP synthase (F-ATPase) function depends upon catalytic and rotation cycles of the F₁ sector. Previously, we found that F₁ ATPase activity is inhibited by the dietary polyphenols, curcumin, quercetin, and piceatannol, but that the inhibitory kinetics of curcumin differs from that of the other two polyphenols (Sekiya et al., 2012, 2014). In the present study, we analyzed Escherichia coli F₁ ATPase rotational catalysis to identify differences in the inhibitory mechanism of curcumin versus quercetin and piceatannol. These compounds did not affect the 120° rotation step for ATP binding and ADP release, though they significantly increased the catalytic dwell duration for ATP hydrolysis. Analysis of wild-type F₁ and a mutant lacking part of the piceatannol binding site (γΔ277–286) indicates that curcumin binds to F₁ differently from piceatannol and quercetin. The unique inhibitory mechanism of curcumin is also suggested from its effect on F₁ mutants with defective β–γ subunit interactions (γMet23 to Lys) or β conformational changes (βSer174 to Phe). These results confirm that smooth interaction between each β subunit and entire γ subunit in F₁ is pertinent for rotational catalysis.     

Acceleration of the ATP-binding rate of F1-ATPase by forcible forward rotation

F₁-ATPase (F₁) is a reversible ATP-driven rotary motor protein. When its rotary shaft is reversely rotated, F₁ produces ATP against the chemical potential of ATP hydrolysis, suggesting that F₁ modulates the rate constants and equilibriums of catalytic reaction steps depending on the rotary angle of the shaft. Although the chemomechanical coupling scheme of F₁ has been determined, it is unclear how individual catalytic reaction steps depend on its rotary angle. Here, we report direct evidence that the ATP-binding rate of F₁ increases upon the forward rotation of the rotor, and its binding affinity to ATP is enhanced by rotation.     

Duplex unwinding and ATPase activities of the DEAD-box helicase eIF4A are coupled by eIF4G and eIF4B

Eukaryotic initiation factor (eIF) 4A is a DEAD-box helicase that stimulates translation initiation by unwinding mRNA secondary structure. The accessory proteins eIF4G, eIF4B, and eIF4H enhance the duplex unwinding activity of eIF4A, but the extent to which they modulate eIF4A activity is poorly understood. Here, we use real-time fluorescence assays to determine the kinetic parameters of duplex unwinding and ATP hydrolysis by these initiation factors. To ensure efficient duplex unwinding, eIF4B and eIF4G cooperatively activate the duplex unwinding activity of eIF4A. Our data reveal that eIF4H is much less efficient at stimulating eIF4A unwinding activity than eIF4B, implying that eIF4H is not able to completely substitute for eIF4B in duplex unwinding. By monitoring unwinding and ATPase assays under identical conditions, we demonstrate that eIF4B couples the ATP hydrolysis cycle of eIF4A with strand separation, thereby minimizing nonproductive unwinding events. Using duplex substrates with altered GC contents but similar predicted thermal stabilities, we further show that the rate of formation of productive unwinding complexes is strongly influenced by the local stability per base pair, in addition to the stability of the entire duplex. This finding explains how a change in the GC content of a hairpin is able to influence translation initiation while maintaining the overall predicted thermal stability.     

Expression patterns and adaptive functional diversity of vertebrate myoglobins

Recent years have witnessed a new round of research on one of the most studied proteins - myoglobin (Mb), the oxygen (O₂) carrier of skeletal and heart muscle. Two major discoveries have stimulated research in this field: 1) that Mb has additional protecting functions, such as the regulation of in vivo levels of the signaling molecule nitric oxide (NO) by scavenging and generating NO during normoxia and hypoxia, respectively; and 2) that Mb in vertebrates (particularly fish) is expressed as tissue-specific isoforms in other tissues than heart and skeletal muscle, such as vessel endothelium, liver and brain, as found in cyprinid fish. Furthermore, Mb has also been found to protect against oxidative stress after hypoxia and reoxygenation and to undergo allosteric, O₂-linked S-nitrosation, as in rainbow trout. Overall, the emerging evidence, particularly from fish species, indicates that Mb fulfills a broader array of physiological functions in a wider range of different tissues than hitherto appreciated. This new knowledge helps to better understand how variations in Mb structure and function may correlate with differences in animals' lifestyles and hypoxia-tolerance. This review integrates old and new results on Mb expression patterns and functional properties amongst vertebrates and discusses how these may relate to adaptive variations in different species. This article is part of a special issue entitled: Oxygen Binding and Sensing Proteins.     

The metal-binding sites of the zinc-transporting P-type ATPase of Escherichia coli. Lys and Asp in the seventh and eighth transmembrane segments of ZntA contribute to the coupling of metal binding and ATPase activity

ZntA is a P-type ATPase which transports Zn²⁺, Pb²⁺ and Cd²⁺ out of the cell. Two cysteine-containing motifs, CAAC near the N-terminus and CPC in transmembrane helix 6, are involved in binding of the translocated metal. We have studied these motifs by mutating the cysteines to serines. The roles of two other possible metal-binding residues, K⁶⁹³ and D⁷¹⁴, in transmembrane helices 7 and 8, were also addressed. The mutation CAAC → SAAS reduces the ATPase activity by 50%. The SAAS mutant is phosphorylated with ATP almost as efficiently as the wild type. However, its phosphorylation with P_i is poorer than that of the wild type and its dephosphorylation rate is faster than that of the wild type ATPase. The CPC → SPS mutant is inactive but residual phosphorylation with ATP could still be observed. The most important findings of this work deal with the prospective metal-binding residues K⁶⁹³ and D⁷¹⁴: the substitution K693N eliminates the Zn²⁺-stimulated ATPase activity completely, although significant Zn²⁺-dependent phosphorylation by ATP remains. The K693N ATPase is hyperphosphorylated by P_i. ZntA carrying the change D714M has strong metal-independent ATPase activity and is very weakly phosphorylated both by ATP and P_i. In conclusion, K⁶⁹³ and D⁷¹⁴ are functionally essential and appear to contribute to the metal specificity of ZntA, most probably by being parts of the metal-binding site made up by the CPC motif.     

Muscle proteins — their actions and interactions

Muscle contracts by the myosin cross-bridges ‘rowing’ the actin filaments past the myosin filaments. In the past year many structural details of this mechanism have become clear. Structural studies indicate distinct states for myosin S1 in the rigor, ATP or ‘down’ conformation and in the products complex (ADP·P_i) or ‘up’ state. Crystallographic studies substantiate this classification and yield details of the transformation. The isomerization ‘up’ to ‘down’ is the power stroke of muscle. This consists in the main of large changes of angle of the ‘lever arm’ (at the distal part of the myosin head) which can account for an 11 nm power stroke.     

Structure and Dynamics of the Actin Filament

We used all-atom molecular dynamics simulations to investigate the structure and properties of the actin filament, starting with either the recent Oda model or the older Holmes model. Simulations of monomeric and polymerized actin show that polymerization changes the nucleotide-binding cleft, bringing together the Q137 side chain and bound ATP in a way that may enhance the ATP hydrolysis rate in the filament. Simulations with different bound nucleotides and conformations of the DNase I binding loop show that the persistence length of the filament depends only on loop conformation. Computational modeling reveals how bound phalloidin stiffens actin filaments and inhibits the release of γ-phosphate from ADP-P_i actin.     

Active Cage Mechanism of Chaperonin-Assisted Protein Folding Demonstrated at Single-Molecule Level

The cylindrical chaperonin GroEL and its lid-shaped cofactor GroES of Escherichia coli have an essential role in assisting protein folding by transiently encapsulating non-native substrate in an ATP-regulated mechanism. It remains controversial whether the chaperonin system functions solely as an infinite dilution chamber, preventing off-pathway aggregation, or actively enhances folding kinetics by modulating the folding energy landscape. Here we developed single-molecule approaches to distinguish between passive and active chaperonin mechanisms. Using low protein concentrations (100 pM) to exclude aggregation, we measured the spontaneous and GroEL/ES-assisted folding of double-mutant maltose binding protein (DM-MBP) by single-pair fluorescence resonance energy transfer and fluorescence correlation spectroscopy. We find that GroEL/ES accelerates folding of DM-MBP up to 8-fold over the spontaneous folding rate. Accelerated folding is achieved by encapsulation of folding intermediate in the GroEL/ES cage, independent of repetitive cycles of protein binding and release from GroEL. Moreover, photoinduced electron transfer experiments provided direct physical evidence that the confining environment of the chaperonin restricts polypeptide chain dynamics. This effect is mediated by the net-negatively charged wall of the GroEL/ES cavity, as shown using the GroEL mutant EL(KKK2) in which the net-negative charge is removed. EL(KKK2)/ES functions as a passive cage in which folding occurs at the slow spontaneous rate. Taken together our findings suggest that protein encapsulation can accelerate folding by entropically destabilizing folding intermediates, in strong support of an active chaperonin mechanism in the folding of some proteins. Accelerated folding is biologically significant as it adjusts folding rates relative to the speed of protein synthesis.     

Endopolyphosphatase in Saccharomyces cerevisiae undergoes post-translational activations to produce short-chain polyphosphates

Endopolyphosphatase (Ppn), responsible for cleavage of long chain inorganic polyphosphate (poly P) of several hundred residues to generate progressively shorter chains, has been identified in mammalian cells and purified from Saccharomyces cerevisiae. Disruption of the encoding gene, PHM5, in S. cerevisiae resulted in a mutant that showed limited growth and failure to survive in a minimal medium. The limited digestion products of the yeast enzyme Ppn1 judged to be P(3) and P(60) have now, with the homogeneous enzyme and improved separation methods, been demonstrated to be P(i) and P(3). Ppn1, a homotetramer of a 35-kDa subunit, is of vacuolar origin and requires protease activation of a 78 kDa (674-aa) precursor polypeptide (prePpn1). The protease-processed Ppn1 has been purified 3800-fold to homogeneity and the protease cleavage sites determined. Both termini of prePpn1 and the post-translational modification of N-glycosylations are essential for the protease-mediated maturation of Ppn1.     

The growth and phosphorus utilisation of plants in sterile media when supplied with inositol hexaphosphate, glucose 1-phosphate or inorganic phosphate

Seedlings of six temperate pasture species, three grasses and three legumes, were grown for 19–24 days in sterile agar or sand-vermiculite media, in the presence of inorganic phosphate (P_i), glucose 1-phosphate (G1P) or inositol hexaphosphate (IHP). Agar (pH 5.0) had a low IHP-sorbing capacity while IHP was almost completely sorbed in sand-vermiculite. P_i and G1P were relatively available in both media. Growth of each species was measured in relation to phosphorus (P) supply and levels of P_i supply at which shoot yields reached 90% of maximum yield (P_crit) were determined. P_crit values were generally higher for the legume species than for the grasses, and were six-fold higher for Trifolium subterraneum L. seedlings when grown in sand-vermiculite relative to agar. When supplied with G1P, seedlings of the six species grew as well as plants supplied with P_i. By contrast, IHP was a poor source of P for plant growth, even when supplied in agar at levels up to 40-fold greater than P_crit. Using the growth of T. subterraneum in the presence of IHP, it was calculated that roots released approximately 0.09 nkat phytase g^-1 root dry wt per day, over 20 days of growth. By supplementing agar containing IHP with phytase from Aspergillus niger (E.C. 3.1.3.8; 0.012 nkat plant^-1, or _∼1.3 nkat g^-1 root dry wt), sufficient P became available to enable T. subterraneum seedlings to grow as well as P_i-supplied plants. These results indicate that while pasture plants can quite effectively use P from some organic P sources (e.g. G1P), the acquisition of phytate-P is limited both by availability of substrate and the capacity of plant roots to hydrolyse available IHP. This revised version was published online in June 2006 with corrections to the Cover Date.     

Locked 5Zs-biliverdin blocks the Meta-RA to Meta-RC transition in the functional cycle of bacteriophytochrome Agp1

The bacteriophytochrome Agp1 was reconstituted with a locked 5Zs-biliverdin in which the C(4)=C(5) and C(5)-C(6) bonds of the methine bridge between rings A and B are fixed in the Z and syn configuration/conformation, respectively. In Agp1-5Zs the photoconversion proceeds via the Lumi-R intermediate to Meta-R(A), but the following millisecond-transition to Meta-R(C) is blocked. Consistently, no transient proton release was detected. The photoconversion of Agp1-5Zs is apparently arrested in a Meta-R(A)-like intermediate, since the subsequent syn to anti rotation around the C(5)-C(6) bond is prevented by the lock. The Meta-R(A)-like photoproduct was characterized by its distinctive CD spectrum suggesting a reorientation of ring D.     

Insight into catalysis of a unique GTPase reaction by a combined biochemical and FTIR approach

Rap1 and Rap2 are the only small guanine nucleotide-binding proteins of the Ras superfamily that do not use glutamine for GTP hydrolysis. Moreover, Rap1GAP, which stimulates the GTPase reaction of Rap1 10(5)-fold, does not have the classical "arginine finger" like RasGAP but presumably, introduces an asparagine residue into the active site. Here, we address the requirements of this unique reaction in detail by combining various biochemical methods, such as fluorescence spectroscopy, stopped-flow and time-resolved Fourier transform infrared spectroscopy (FTIR). The fluorescence spectroscopic assay monitors primarily protein-protein interaction steps, while FTIR resolves simultaneously the elementary steps of functional groups labor-free, but it is less sensitive and needs higher concentrations. Combining both methods allows us to distinguish weather mechanistic defects caused by mutation are due to affinity or due to functionality. We show that several mutations of Asn290 block catalysis. Some of the mutants, however, still form a complex with Rap1*GDP in the presence of BeF(x) but not AlF(x), supporting the notion that fluoride complexes are indicators of the ground versus transition state. Mutational analysis also shows that Thr61 is not required for catalysis. While replacement of Thr61 of Rap1 by Leu eliminates GTPase activation by Rap1GAP, the T61A and T61Q mutants have only a minor effect on catalysis, but change the relative rates of cleavage and (P(i)(-)) release. While Rap1GAP(N290A) is completely inactive on wild-type Rap1, it can act on Rap1(T61Q), arguing that Asn290 in trans has a role in catalysis similar to that of the intrinsic Gln in Ras and Rho. Finally, since FTIR works at high, and thus mostly saturating, concentrations, it can clearly separate effects on affinity from purely catalytic modifications, showing that Arg388, conserved between RapGAPs and mutated in the homologous RheBGAP Tuberin, affects binding affinity severely but has no effect on the cleavage reaction itself.     

High-throughput genetic identification of functionally important regions of the yeast DEAD-box protein Mss116p

The Saccharomyces cerevisiae DEAD-box protein Mss116p is a general RNA chaperone that functions in splicing mitochondrial group I and group II introns. Recent X-ray crystal structures of Mss116p in complex with ATP analogs and single-stranded RNA show that the helicase core induces a bend in the bound RNA, as in other DEAD-box proteins, while a C-terminal extension (CTE) induces a second bend, resulting in RNA crimping. Here, we illuminate these structures by using high-throughput genetic selections, unigenic evolution, and analyses of in vivo splicing activity to comprehensively identify functionally important regions and permissible amino acid substitutions throughout Mss116p. The functionally important regions include those containing conserved sequence motifs involved in ATP and RNA binding or interdomain interactions, as well as previously unidentified regions, including surface loops that may function in protein-protein interactions. The genetic selections recapitulate major features of the conserved helicase motifs seen in other DEAD-box proteins but also show surprising variations, including multiple novel variants of motif III (SAT). Patterns of amino acid substitutions indicate that the RNA bend induced by the helicase core depends on ionic and hydrogen-bonding interactions with the bound RNA; identify a subset of critically interacting residues; and indicate that the bend induced by the CTE results primarily from a steric block. Finally, we identified two conserved regions—one the previously noted post II region in the helicase core and the other in the CTE—that may help displace or sequester the opposite RNA strand during RNA unwinding.     

Metabolite profiling of mycorrhizal roots of Medicago truncatula

Metabolite profiling of soluble primary and secondary metabolites, as well as cell wall-bound phenolic compounds from roots of barrel medic (Medicago truncatula) was carried out by GC-MS, HPLC and LC-MS. These analyses revealed a number of metabolic characteristics over 56 days of symbiotic interaction with the arbuscular mycorrhizal (AM) fungus Glomus intraradices, when compared to the controls, i.e. nonmycorrhizal roots supplied with low and high amounts of phosphate. During the most active stages of overall root mycorrhization, elevated levels of certain amino acids (Glu, Asp, Asn) were observed accompanied by increases in amounts of some fatty acids (palmitic and oleic acids), indicating a mycorrhiza-specific activation of plastidial metabolism. In addition, some accumulating fungus-specific fatty acids (palmitvaccenic and vaccenic acids) were assigned that may be used as markers of fungal root colonization. Stimulation of the biosynthesis of some constitutive isoflavonoids (daidzein, ononin and malonylononin) occurred, however, only at late stages of root mycorrhization. Increase of the levels of saponins correlated AM-independently with plant growth. Only in AM roots was the accumulation of apocarotenoids (cyclohexenone and mycorradicin derivatives) observed. The structures of the unknown cyclohexenone derivatives were identified by spectroscopic methods as glucosides of blumenol C and 13-hydroxyblumenol C and their corresponding malonyl conjugates. During mycorrhization, the levels of typical cell wall-bound phenolics (e.g. 4-hydroxybenzaldehyde, vanillin, ferulic acid) did not change; however, high amounts of cell wall-bound tyrosol were exclusively detected in AM roots. Principal component analyses of nonpolar primary and secondary metabolites clearly separated AM roots from those of the controls, which was confirmed by an hierarchical cluster analysis. Circular networks of primary nonpolar metabolites showed stronger and more frequent correlations between metabolites in the mycorrhizal roots. The same trend, but to a lesser extent, was observed in nonmycorrhizal roots supplied with high amounts of phosphate. These results indicate a tighter control of primary metabolism in AM roots compared to control plants. Network correlation analyses revealed distinct clusters of amino acids and sugars/aliphatic acids with strong metabolic correlations among one another in all plants analyzed; however, mycorrhizal symbiosis reduced the cluster separation and enlarged the sugar cluster size. The amino acid clusters represent groups of metabolites with strong correlations among one another (cliques) that are differently composed in mycorrhizal and nonmycorrhizal roots. In conclusion, the present work shows for the first time that there are clear differences in development- and symbiosis-dependent primary and secondary metabolism of M. truncatula roots.     

Ca binding to sarcoplasmic reticulum ATPase phosphorylated by Pi reveals four thapsigargin-sensitive Ca sites in the presence of ADP

Sarcoplasmic reticulum (SR) Ca²⁺-ATPase was phosphorylated by P_i at pH 8.0 in the presence of dimethyl sulfoxide (Me₂SO). Under these conditions, it was possible to measure transient ⁴⁵Ca²⁺ binding to the phosphoenzyme. Binding reached 1.2 Ca²⁺ per phosphoenzyme (E-PCa_x) within 10 min in 30% Me₂SO, 20 mM MgCl₂ and 0.1 mM P_i and the phosphoenzyme only decreased by 23% during this period. This Ca²⁺ binding was abolished by thapsigargin, showing that it is associated with functional sites of the Ca²⁺-ATPase. At 40% Me₂SO, simultaneous addition of Ca²⁺ and ADP increased Ca²⁺ binding up to almost four Ca²⁺ per phosphoenzyme (ADPE-PCa_y), revealing a species bearing simultaneously four Ca²⁺ sites. Both E-PCa_x and ADPE-PCa_y were further identified as distinct species by (2′,3′-O-2(2,4,6-trinitrophenyl)adenosine 5′-triphosphate) fluorescence, which revealed long-range modifications in the Ca²⁺-transport sites induced by ADP binding to E-P. In addition, E-PCa_x was shown to be a functional intermediate of the cycle leading to ATP synthesis provided that Me₂SO was diluted. These findings indicate that more than two functional Ca²⁺-sites exist on the functional Ca²⁺-ATPase unit, and that the additional sites become accessible upon ADP addition. This is compatible with a four-site model of the SR Ca²⁺-ATPase allowing simultaneous binding of Ca²⁺ at lumenal and cytosolic sites. The stoichiometries for Ca²⁺ binding found here could either be interpreted as binding of four Ca²⁺ on a Ca²⁺-ATPase monomer considered as the functional unit or as binding of two Ca²⁺ per monomer of a functional dimer.     

Mechanism and regulation of the mitochondrial ATP-Mg/Pi carrier

The mitochondrial ATP-Mg/P_i carrier functions to modulate the matrix adenine nucleotide pool size (ATP + ADP + AMP). Micromolar Ca²⁺ is required to activate the carrier. Net adenine nucleotide transport occurs as an electroneutral divalent exchange of ATP-Mg^2– for HPO ₄ ^2– . A steady-state adenine nucleotide pool size is attained when the HPO ₄ ^2– and ATP-Mg^2– matrix/cytoplasm concentration ratios are the same. This means that ATP-Mg^2– can be accumulated against a concentration gradient in proportion to the [HPO ₄ ^2– ] gradient that is normally maintained by the P_i/OH^– carrier. In liver, changes in matrix adenine nucleotide concentrations that are brought about by the ATP-Mg/P_i carrier can affect the activity of adenine nucleotide-dependent enzymes that are in the mitochondrial compartment. These enzymes in turn contribute to the overall regulation of bioenergetic function, flux through the gluconeogenesis and urea synthesis pathways, and organelle biogenesis. The ATP-Mg/P_i carrier is distinct from other mitochondrial transport systems with respect to kinetics and to substrate and inhibitor sensitivity. It is the only carrier regulated by Ca²⁺. This carrier is present in kidney and liver mitochondria, but not in heart.     

Modulation of the packaging reaction of bacteriophage t4 terminase by DNA structure

Bacteriophage terminases package DNA through the portal ring of a procapsid during phage maturation. We have probed the mechanism of the phage T4 large terminase subunit gp17 by analyzing linear DNAs that are translocated in vitro. Duplex DNAs of random sequence from 20 to 500 bp were efficiently packaged. Dye and short, single-stranded end extensions were tolerated, whereas 20-base extensions, hairpin ends, 20-bp DNA-RNA hybrid, and 4-kb dsRNA substrates were not packaged. Molecules 60 bp long with 10 mismatched bases were translocated; substrates with 20 mismatched bases, a related D-loop structure, or ones with 20-base single-strand regions were not. A single nick in 100- or 200-bp duplexes, irrespective of location, reduced translocation efficiency, but a singly nicked 500-bp molecule was packaged as effectively as an unnicked control. A fluorescence-correlation-spectroscopy-based assay further showed that a 100-bp nicked substrate did not remain stably bound by the terminase-prohead. Taken together, two unbroken DNA strands seem important for packaging, consistent with a proposed torsional compression translocation mechanism.     

Polymeric Structures and Dynamic Properties of the Bacterial Actin AlfA

AlfA is a recently discovered DNA segregation protein from Bacillus subtilis that is distantly related to actin and the bacterial actin homologues ParM and MreB. Here we show that AlfA mostly forms helical 7/3 filaments, with a repeat of about 180 Å, that are arranged in three-dimensional bundles. Other polymorphic structures in the form of two-dimensional rafts or paracrystalline nets were also observed. Here AlfA adopted a 16/7 helical symmetry, with a repeat of about 387 Å. Thin polymers consisting of several intertwining filaments also formed. Observed helical symmetries of AlfA filaments differed from those of other members of the actin family: F-actin, ParM, or MreB. Both ATP and guanosine 5′-triphosphate are able to promote rapid AlfA filament formation with almost equal efficiencies. The helical structure is only preserved under physiological salt concentrations and at a pH between 6.4 and 7.4, the physiological range of the cytoplasm of B. subtilis. Polymerization kinetics are extremely rapid and compatible with a cooperative assembly mechanism requiring only two steps: monomer activation followed by elongation, making AlfA one of the most efficient polymerizing motors within the actin family. Phosphate release lags behind polymerization, and time-lapse total internal reflection fluorescence images of AlfA bundles are consistent with treadmilling rather than dynamic microtubule-like instability. High-pressure small angle X-ray scattering experiments reveal that the stability of AlfA filaments is intermediate between the stability of ParM and the stability of F-actin. These results emphasize that actin-like polymerizing machineries have diverged to produce a variety of filament geometries with diverse properties that are tailored for specific biological processes.     

Transport function of the renal type IIa Na+/P(i) cotransporter is codetermined by residues in two opposing linker regions

Two highly similar regions in the predicted first intracellular (ICL-1) and third extracellular loop (ECL-3) of the type IIa Na+/P(i) cotransporter (NaPi-IIa) have been shown previously to contain functionally important sites by applying the substituted cysteine accessibility method (SCAM). Incubation in methanethiosulfonate (MTS) reagents of mutants that contain novel cysteines in both loops led to full inhibition of cotransport activity. To elucidate further the role these regions play in defining the transport mechanism, a double mutant (A203C-S460C) was constructed with novel cysteines in each region. The effect of cysteine modification by different MTS reagents on two electrogenic transport modes (leak and cotransport) was investigated. MTSEA (2-aminoethyl MTS hydrobromide) and MTSES (MTS ethylsulfonate) led to full inhibition of cotransport and increased the leak, whereas incubation in MTSET (2-[trimethylammonium]ethyl MTS bromide) inhibited only cotransport. The behavior of other double mutants with a cysteine retained at one site and hydrophobic or hydrophilic residues substituted at the other site, indicated that most likely only Cys-460 was modifiable, but the residue at Ala-203 was critical for conferring the leak and cotransport mode behavior. Substrate interaction with the double mutant was unaffected by MTS exposure as the apparent P(i) and Na+ affinities for P(i)-induced currents and respective activation functions were unchanged after cysteine modification. This suggested that the modified site did not interfere with substrate recognition/binding, but prevents translocation of the fully loaded carrier. The time-dependency of cotransport loss and leak growth during modification of the double cysteine mutant was reciprocal, which suggested that the modified site is a kinetic codeterminant of both transport modes. The behavior is consistent with a kinetic model for NaPi-IIa that predicts mutual exclusiveness of both transport modes. Together, these findings suggest that parts of the opposing linker regions are associated with the NaPi-IIa transport pathway.     

High-resolution nuclear magnetic resonance spectroscopy studies of polysaccharides crosslinked by sodium trimetaphosphate: a proposal for the reaction mechanism

An NMR spectroscopy study ((31)P, (1)H, (13)C) of the postulated crosslinking mechanism of sodium trimetaphosphate (STMP) on polysaccharides is reported using methyl alpha-D-glucopyranoside as a model. In a first step, reaction of STMP with Glc-OMe gives grafted sodium tripolyphosphate (STPP(g)). On the one hand, STTP(g) can react with a second alcohol functionality to give a crosslinked monophosphate. On the other hand, a monophosphate (grafted phosphate) could be obtained by alkaline degradation of STPP(g). NMR spectroscopy allows to detect the various species formed and to obtain the crosslinking density of STMP-polysaccharides hydrogels.