Cooperative binding ensures the obligatory melibiose/Na+ cotransport in MelB

MelB catalyzes the obligatory cotransport of melibiose with Na⁺, Li⁺, or H⁺. Crystal structure determination of the Salmonella typhimurium MelB (MelB_St) has revealed a typical major facilitator superfamily (MFS) fold at a periplasmic open conformation. Cooperative binding of Na⁺ and melibiose has been previously established. To determine why cotranslocation of sugar solute and cation is obligatory, we analyzed each binding in the thermodynamic cycle using three independent methods, including the determination of melting temperature by circular dichroism spectroscopy, heat capacity change (ΔC_p), and regulatory phosphotransferase EIIA^Glc binding with isothermal titration calorimetry (ITC). We found that MelB_St thermostability is increased by either substrate (Na⁺ or melibiose) and observed a cooperative effect of both substrates. ITC measurements showed that either binary formation yields a positive sign in the ΔC_p, suggesting MelB_St hydration and a likely widening of the periplasmic cavity. Conversely, formation of a ternary complex yields negative values in ΔCp, suggesting MelB_St dehydration and cavity closure. Lastly, we observed that EIIA^Glc, which has been suggested to trap MelB_St at an outward-open state, readily binds to the MelB_St apo state at an affinity similar to MelB_St/Na⁺. However, it has a suboptimal binding to the ternary state, implying that MelB_St in the ternary complex may be conformationally distant from the EIIA^Glc-preferred outward-facing conformation. Our results consistently support the notion that binding of one substrate (Na⁺ or melibiose) favors MelB_St at open states, whereas the cooperative binding of both substrates triggers the alternating-access process, thus suggesting this conformational regulation could ensure the obligatory cotransport.     

Suppression of Conformation-Compromised Mutants of Salmonella enterica Serovar Typhimurium MelB

The crystal structure of the Na⁺-coupled melibiose permease of Salmonella enterica serovar Typhimurium (MelB_St) demonstrates that MelB is a member of the major facilitator superfamily of transporters. Arg residues at positions 295, 141, and 363 are involved in interdomain interactions at the cytoplasmic side by governing three clusters of electrostatic/polar interactions. Insertion of (one at a time) Glu, Leu, Gln, or Cys at positions R295, R141, and R363, or Lys at position R295, inhibits active transport of melibiose to a level of 2 to 20% of the value for wild-type (WT) MelB_St, with little effect on binding affinities for both sugar and Na⁺. Interestingly, a spontaneous suppressor, D35E (periplasmic end of helix I), was isolated from the R363Q MelB_St mutant. Introduction of the D35E mutation in each of the mutants at R295, R141 (except R141E), or R363 rescues melibiose transport to up to 91% of the WT value. Single-site mutations for the pair of D35 and R175 (periplasmic end of helix VI) were constructed by replacing Asp with Glu, Gln, or Cys and R175 with Gln, Asn, or Cys. All mutants with mutations at R175 are active, indicating that a positive charge at R175 is not necessary. Mutant D35E shows reduced transport; D35Q and D35C are nearly inactivated. Surprisingly, the D35Q mutation partially rescues both R141C and R295Q mutations. The data support the idea that Arg at position 295 and a positive charge at positions 141 and 363 are required for melibiose transport catalyzed by MelB_St, and their mutation inhibits conformational cycling, which is suppressed by a minor modification at the opposite side of the membrane.     

Complete cysteine-scanning mutagenesis of the Salmonella typhimurium melibiose permease

The melibiose permease of Salmonella typhimurium (MelB_St) catalyzes the stoichiometric symport of galactopyranoside with a cation (H⁺, Li⁺, or Na⁺) and is a prototype for Na⁺-coupled major facilitator superfamily (MFS) transporters presenting from bacteria to mammals. X-ray crystal structures of MelB_St have revealed the molecular recognition mechanism for sugar binding; however, understanding of the cation site and symport mechanism is still vague. To further investigate the transport mechanism and conformational dynamics of MelB_St, we generated a complete single-Cys library containing 476 unique mutants by placing a Cys at each position on a functional Cys-less background. Surprisingly, 105 mutants (22%) exhibit poor transport activities (<15% of Cys-less transport), although the expression levels of most mutants were comparable to that of the control. The affected positions are distributed throughout the protein. Helices I and X and transmembrane residues Asp and Tyr are most affected by cysteine replacement, while helix IX, the cytoplasmic middle-loop, and C-terminal tail are least affected. Single-Cys replacements at the major sugar-binding positions (K18, D19, D124, W128, R149, and W342) or at positions important for cation binding (D55, N58, D59, and T121) abolished the Na⁺-coupled active transport, as expected. We mapped 50 loss-of-function mutants outside of these substrate-binding sites that suffered from defects in protein expression/stability or conformational dynamics. This complete Cys-scanning mutagenesis study indicates that MelB_St is highly susceptible to single-Cys mutations, and this library will be a useful tool for further structural and functional studies to gain insights into the cation-coupled symport mechanism for Na⁺-coupled MFS transporters.     

Reduced Na+ Affinity Increases Turnover of Salmonella enterica Serovar Typhimurium MelB

The melibiose permease of Salmonella enterica serovar Typhimurium (MelB_St) catalyzes symport of melibiose with Na⁺, Li⁺, or H⁺. Bioinformatics and mutational analyses indicate that a conserved Gly117 (helix IV) is a component of the Na⁺-binding site. In this study, Gly117 was mutated to Ser, Asn, or Cys. All three mutations increase the maximum rate (V_max) for melibiose transport in Escherichia coli DW2 and greatly decrease Na⁺ affinity, indicating that intracellular release of Na⁺ is facilitated. Rapid melibiose transport, particularly by the G117N mutant, triggers osmotic lysis in the lag phase of growth. The findings support the previous conclusion that Gly117 plays an important role in cation binding and translocation. Furthermore, a spontaneous second-site mutation (P148L between loop_4-5 and helix V) in the G117C mutant prevents cell lysis. This mutation significantly decreases V_max with little effect on cosubstrate binding in G117C, G117S, and G117N mutants. Thus, the P148L mutation specifically inhibits transport velocity and thereby blocks the lethal effect of elevated melibiose transport in the Gly117 mutants.     

Phosphorylation and Functional Properties of the IIA Domain of the Lactose Transport Protein of Streptococcus thermophilus

The lactose-H⁺ symport protein (LacS) of Streptococcus thermophilus has a carboxyl-terminal regulatory domain (IIA^LacS) that is homologous to a family of proteins and protein domains of the phosphoenolpyruvate:carbohydrate phosphotransferase system (PTS) in various organisms, of which IIA^Glc of Escherichia coli is the best-characterized member. On the basis of these similarities, it was anticipated that IIA^LacS would be able to perform one or more functions associated with IIA^Glc, i.e., carry out phosphoryl transfer and/or affect other catabolic functions. The gene fragment encoding IIA^LacS was overexpressed in Escherichia coli, and the protein was purified in two steps by metal affinity and anion-exchange chromatography. IIA^LacS was unable to restore glucose uptake in a IIA^Glc-deficient strain, which is consistent with a very low rate of phosphorylation of IIA^LacS by phosphorylated HPr (HPr~P) from E. coli. With HPr~P from S. thermophilus, the rate was more than 10-fold higher, but the rate constants for the phosphorylation of IIA^LacS (k₁ = 4.3 × 10² M⁻¹ s⁻¹) and dephosphorylation of IIA^LacS~P by HPr (k₋₁ = 1.1 × 10³ M⁻¹ s⁻¹) are still at least 4 orders of magnitude lower than for the phosphoryltransfer between IIA^Glc and HPr from E. coli. This finding suggests that IIA^LacS has evolved into a protein domain whose main function is not to transfer phosphoryl groups rapidly. On the basis of sequence alignment of IIA proteins with and without putative phosphoryl transfer functions and the known structure of IIA^Glc, we constructed a double mutant [IIA^LacS(I548E/G556D)] that was predicted to have increased phosphoryl transfer activity. Indeed, the phosphorylation rate of IIA^LacS(I548E/G556D) by HPr~P increased (k₁ = 4.0 × 10³ M⁻¹ s⁻¹) and became nearly independent of the source of HPr~P (S. thermophilus, Bacillus subtilis, or E. coli). The increased phosphoryl transfer rate of IIA^LacS(I548E/G556D) was insufficient to complement IIA^Glc in PTS-mediated glucose transport in E. coli. Both IIA^LacS and IIA^LacS(I548E/G556D) could replace IIA^Glc, but in another function: they inhibited glycerol kinase (inducer exclusion) when present in the unphosphorylated form.     

Regulation of glycerol and maltose uptake by the IIAGlc-like domain of IINag of the phosphotransferase system inSalmonella typhimurium LT2

InEnterobacteriaceae the nonphosphorylated form of IIA^G1c of the phosphoenolpyruvate-dependent phosphotransferase system (PTS) can inhibit the uptake and subsequent metabolism of glycerol and maltose by binding to, and inhibiting, glycerol kinase and the Ma1K protein of the maltose transport system, respectively. In this report we show that the IIA^Glc-Iike domain of the membrane-bound II^{N-acetylglucosamine} (II^Nag) of the PTS can replace IIA^Glc in aSalmonella typhimurium crr mutant strain that lacks all soluble IIA^Glc. The inhibition was most severe in cells which were partially induced for the glycerol or maltose up take systems. TheStreptococcus thermophilus lactose transporter LacS, which also contains a IIA^Glc-like domain, could not replace IIA^Glc. Neither IINag nor LacS could replace IIA^Glc in activation of adenylate cyclase.     

Substrate-induced conformational changes of melibiose permease from Escherichia coli studied by infrared difference spectroscopy

Fourier transform infrared difference spectroscopy has been used to obtain information about substrate-induced structural changes of the melibiose permease (MelB) from Escherichia coli reconstituted into liposomes. Binding of the cosubstrate Na(+) gives rise to several peaks in the amide I and II regions of the difference spectrum Na(+).MelB minus H(+).MelB, that denote the presence of conformational changes in all types of secondary structures (alpha-helices, beta-sheets, loops). In addition, peaks around 1400 and at 1740-1720 cm(-1) are indicative of changes in protonation/deprotonation or in environment of carboxylic groups. Binding of the cosubstrate Li(+) produces a difference spectrum that is also indicative of conformational changes, but that is at variance as compared to that induced by Na(+) binding. To analyze the following transport steps, the melibiose permease with either H(+), Na(+), or Li(+) bound was incubated with melibiose. The difference spectra obtained by subtracting the spectrum cation.MelB from the respective complex cation.melibiose.MelB were roughly similar among them, but different from those induced by cation binding, and more intense. Therefore, major conformational changes that are induced during melibiose binding/substrate translocation, like those denoted by intense peaks at 1668 and 1645 cm(-)(1), are similar for the three cotransporting cations. Changes in the protonation state and/or in the environment of given carboxylic residues were also induced by melibiose-MelB interaction in the presence of cations.     

Alteration of Sugar-Induced Conformational Changes of the Melibiose Permease by Mutating Arg in Loop 4-5

The melibiose permease (MelB) from Escherichia coli couples the uptake of melibiose to that of Na⁺, Li⁺, or H⁺. In this work, we applied attenuated total reflection Fourier transform infrared (ATR-FTIR) difference spectroscopy to obtain information about the structural changes involved in substrate interaction with the R141C mutant and with the wild-type MelB reacted with N-ethylmaleimide (NEM). These modified permeases have the ability to bind the substrates but fail to transport them. It is shown that the sugar-induced ATR-FTIR difference spectra of the R141C mutant are different from those corresponding to the Cys-less permease from which it is derived. There are alterations of peaks assigned to turns and β-structures located most likely in loop 4-5. In addition, and quite notably, a peak at 1659 cm⁻¹, assigned to changes at the level of one α-helix subpopulation, disappears in the melibiose-induced difference spectrum in the presence of Na⁺, suggesting a reduction of the conformational change capacity of the mutated MelB. These helices may involve structural components that couple the cation- and sugar-binding sites. On the other hand, MelB-NEM difference spectra are proportionally less disrupted than the R141C ones. Hence, the transport cycle of these two permeases, modified at two different loops, is most likely impaired at a different stage. It is proposed that the R141C mutant leads to the generation of a partially defective ternary complex that is unable to catalyze the subsequent conformational change necessary for substrate translocation.     

Amino acid substitutions in the sugar kinase/hsp70/actin superfamily conserved ATPase core of E. coli glycerol kinase modulate allosteric ligand affinity but do not alter allosteric coupling

IIA^Glc, the glucose-specific phosphocarrier protein of the phosphoenolpyruvate:glycose phosphotransferase system, is an allosteric inhibitor of Escherichia coli glycerol kinase. A linked-functions initial-velocity enzyme kinetics approach is used to define the MgATP-IIA^Glc heterotropic allosteric interaction. The interaction is measured by the allosteric coupling constants Q and W, which describe the mutual effect of the ligands on binding affinity and the effect of the allosteric ligand on V_max, respectively. Allosteric interactions between these ligands display K-type activation and V-type inhibition. The allosteric coupling constant Q is about 3, showing cooperative coupling such that each ligand increases the affinity for binding of the other. The allosteric coupling constant W is about 0.1, showing that the allosteric inhibition is partial such that binding of IIA^Glc at saturation does not reduce V_max to zero. E. coli glycerol kinase is a member of the sugar kinase/heat shock protein 70/actin superfamily, and an element of the superfamily conserved ATPase catalytic core was identified as part of the IIA^Glc inhibition network because it is required to transplant IIA^Glc allosteric control into a non-allosteric glycerol kinase [A.C. Pawlyk, D.W. Pettigrew, Proc. Natl. Acad. Sci. USA 99 (2002) 11115-11120]. Two of the amino acids at this locus of E. coli glycerol kinase are replaced with those from the non-allosteric enzyme to enable determination of its contributions to MgATP-IIA^Glc allosteric coupling. The substitutions reduce the affinity for IIA^Glc by about 5-fold without changing significantly the allosteric coupling constants Q and W. The insensitivity of the allosteric coupling constants to the substitutions may indicate that the allosteric network is robust or the locus is not an element of that network. These possibilities may arise from differences of E. coli glycerol kinase relative to other superfamily members with respect to oligomeric structure and location of the allosteric site in a single domain far from the catalytic site.     

Bacterial transporters: Charge translocation and mechanism

A comparative review of the electrophysiological characterization of selected secondary active transporters from Escherichia coli is presented. In melibiose permease MelB and the Na⁺/proline carrier PutP pre-steady-state charge displacements can be assigned to an electrogenic conformational transition associated with the substrate release process. In both transporters cytoplasmic release of the sugar or the amino acid as well as release of the coupling cation are associated with a charge displacement. This suggests a common transport mechanism for both transporters. In the NhaA Na⁺/H⁺ exchanger charge translocation due to its steady-state transport activity is observed. A new model is proposed for pH regulation of NhaA that is based on coupled Na⁺ and H⁺ equilibrium binding.     

Kinesin-2 KIF3AB Exhibits Novel ATPase Characteristics

KIF3AB is an N-terminal processive kinesin-2 family member best known for its role in intraflagellar transport. There has been significant interest in KIF3AB in defining the key principles that underlie the processivity of KIF3AB in comparison with homodimeric processive kinesins. To define the ATPase mechanism and coordination of KIF3A and KIF3B stepping, a presteady-state kinetic analysis was pursued. For these studies, a truncated murine KIF3AB was generated. The results presented show that microtubule association was fast at 5.7 μm⁻¹ s⁻¹, followed by rate-limiting ADP release at 12.8 s⁻¹. ATP binding at 7.5 μm⁻¹ s⁻¹ was followed by an ATP-promoted isomerization at 84 s⁻¹ to form the intermediate poised for ATP hydrolysis, which then occurred at 33 s⁻¹. ATP hydrolysis was required for dissociation of the microtubule·KIF3AB complex, which was observed at 22 s⁻¹. The dissociation step showed an apparent affinity for ATP that was very weak (K_½,ATP at 133 μm). Moreover, the linear fit of the initial ATP concentration dependence of the dissociation kinetics revealed an apparent second-order rate constant at 0.09 μm⁻¹ s⁻¹, which is inconsistent with fast ATP binding at 7.5 μm⁻¹ s⁻¹ and a K_d,ATP at 6.1 μm. These results suggest that ATP binding per se cannot account for the apparent weak K_½,ATP at 133 μm. The steady-state ATPase K_m,ATP, as well as the dissociation kinetics, reveal an unusual property of KIF3AB that is not yet well understood and also suggests that the mechanochemistry of KIF3AB is tuned somewhat differently from homodimeric processive kinesins.     

Human DNA Polymerase ν Catalyzes Correct and Incorrect DNA Synthesis with High Catalytic Efficiency

DNA polymerase ν (pol ν) is a low fidelity A-family polymerase with a putative role in interstrand cross-link repair and homologous recombination. We carried out pre-steady-state kinetic analysis to elucidate the kinetic mechanism of this enzyme. We found that the mechanism consists of seven steps, similar that of other A-family polymerases. pol ν binds to DNA with a K_d for DNA of 9.2 nm, with an off-rate constant of 0.013 s⁻¹and an on-rate constant of 14 μm⁻¹ s⁻¹. dNTP binding is rapid with K_d values of 20 and 476 μm for the correct and incorrect dNTP, respectively. Pyrophosphorylation occurs with a K_d value for PP_i of 3.7 mm and a maximal rate constant of 11 s⁻¹. Pre-steady-state kinetics, examination of the elemental effect using dNTPαS, and pulse-chase experiments indicate that a rapid phosphodiester bond formation step is flanked by slow conformational changes for both correct and incorrect base pair formation. These experiments in combination with computer simulations indicate that the first conformational change occurs with rate constants of 75 and 20 s⁻¹; rapid phosphodiester bond formation occurs with a K_eq of 2.2 and 1.7, and the second conformational change occurs with rate constants of 2.1 and 0.5 s⁻¹, for correct and incorrect base pair formation, respectively. The presence of a mispair does not induce the polymerase to adopt a low catalytic conformation. pol ν catalyzes both correct and mispair formation with high catalytic efficiency.     

Calcium Regulates Molecular Interactions of Otoferlin with Soluble NSF Attachment Protein Receptor (SNARE) Proteins Required for Hair Cell Exocytosis

Mutations in otoferlin, a C2 domain-containing ferlin family protein, cause non-syndromic hearing loss in humans (DFNB9 deafness). Furthermore, transmitter secretion of cochlear inner hair cells is compromised in mice lacking otoferlin. In the present study, we show that the C2F domain of otoferlin directly binds calcium (K_D = 267 μm) with diminished binding in a pachanga (D1767G) C2F mouse mutation. Calcium was found to differentially regulate binding of otoferlin C2 domains to target SNARE (t-SNARE) proteins and phospholipids. C2D–F domains interact with the syntaxin-1 t-SNARE motif with maximum binding within the range of 20–50 μm Ca²⁺. At 20 μm Ca²⁺, the dissociation rate was substantially lower, indicating increased binding (K_D = ∼10⁻⁹) compared with 0 μm Ca²⁺ (K_D = ∼10⁻⁸), suggesting a calcium-mediated stabilization of the C2 domain·t-SNARE complex. C2A and C2B interactions with t-SNAREs were insensitive to calcium. The C2F domain directly binds the t-SNARE SNAP-25 maximally at 100 μm and with reduction at 0 μm Ca²⁺, a pattern repeated for C2F domain interactions with phosphatidylinositol 4,5-bisphosphate. In contrast, C2F did not bind the vesicle SNARE protein synaptobrevin-1 (VAMP-1). Moreover, an antibody targeting otoferlin immunoprecipitated syntaxin-1 and SNAP-25 but not synaptobrevin-1. As opposed to an increase in binding with increased calcium, interactions between otoferlin C2F domain and intramolecular C2 domains occurred in the absence of calcium, consistent with intra-C2 domain interactions forming a “closed” tertiary structure at low calcium that “opens” as calcium increases. These results suggest a direct role for otoferlin in exocytosis and modulation of calcium-dependent membrane fusion.     

Regulation of glycerol and maltose uptake by the IIAGlc-like domain of IINag of the phosphotransferase system inSalmonella typhimurium LT2

InEnterobacteriaceae the nonphosphorylated form of IIA^G1c of the phosphoenolpyruvate-dependent phosphotransferase system (PTS) can inhibit the uptake and subsequent metabolism of glycerol and maltose by binding to, and inhibiting, glycerol kinase and the Ma1K protein of the maltose transport system, respectively. In this report we show that the IIA^Glc-Iike domain of the membrane-bound II^{N-acetylglucosamine} (II^Nag) of the PTS can replace IIA^Glc in aSalmonella typhimurium crr mutant strain that lacks all soluble IIA^Glc. The inhibition was most severe in cells which were partially induced for the glycerol or maltose up take systems. TheStreptococcus thermophilus lactose transporter LacS, which also contains a IIA^Glc-like domain, could not replace IIA^Glc. Neither IINag nor LacS could replace IIA^Glc in activation of adenylate cyclase.     

Sugar binding induced charge translocation in the melibiose permease from Escherichia coli

Electrogenic events associated with the activity of the melibiose permease (MelB), a transporter from Escherichia coli, were investigated. Proteoliposomes containing purified MelB were adsorbed to a solid supported lipid membrane, activated by a substrate concentration jump, and transient currents were measured. When the transporter was preincubated with Na(+) at saturating concentrations, a charge translocation in the protein upon melibiose binding could still be observed. This result demonstrates that binding of the uncharged substrate melibiose triggers a charge displacement in the protein. Further analysis showed that the charge displacement is neither related to extra Na(+) binding to the transporter, nor to the displacement of already bound Na(+) within the transporter. The electrogenic melibiose binding process is explained by a conformational change with concomitant displacement of charged amino acid side chains and/or a reorientation of helix dipoles. A kinetic model is suggested, in which Na(+) and melibiose binding are distinct electrogenic processes associated with approximately the same charge displacement. These binding reactions are fast in the presence of the respective cosubstrate (k > 50 s(-1)).     

Investigation of sugar binding kinetics of the E. coli sugar/H+ symporter XylE using solid-supported membrane-based electrophysiology

Bacterial transporters are difficult to study using conventional electrophysiology because of their low transport rates and the small size of bacterial cells. Here, we applied solid-supported membrane–based electrophysiology to derive kinetic parameters of sugar translocation by the Escherichia coli xylose permease (XylE), including functionally relevant mutants. Many aspects of the fucose permease (FucP) and lactose permease (LacY) have also been investigated, which allow for more comprehensive conclusions regarding the mechanism of sugar translocation by transporters of the major facilitator superfamily. In all three of these symporters, we observed sugar binding and transport in real time to determine K_M, V_max, K_D, and k_obs values for different sugar substrates. K_D and k_obs values were attainable because of a conserved sugar-induced electrogenic conformational transition within these transporters. We also analyzed interactions between the residues in the available X-ray sugar/H⁺ symporter structures obtained with different bound sugars. We found that different sugars induce different conformational states, possibly correlating with different charge displacements in the electrophysiological assay upon sugar binding. Finally, we found that mutations in XylE altered the kinetics of glucose binding and transport, as Q175 and L297 are necessary for uncoupling H⁺ and d-glucose translocation. Based on the rates for the electrogenic conformational transition upon sugar binding (>300 s⁻¹) and for sugar translocation (2 s⁻¹ − 30 s⁻¹ for different substrates), we propose a multiple-step mechanism and postulate an energy profile for sugar translocation. We also suggest a mechanism by which d-glucose can act as an inhibitor for XylE.     

Sucrose Octasulfate Selectively Accelerates Thrombin Inactivation by Heparin Cofactor II

Inactivation of thrombin (T) by the serpins heparin cofactor II (HCII) and antithrombin (AT) is accelerated by a heparin template between the serpin and thrombin exosite II. Unlike AT, HCII also uses an allosteric interaction of its NH₂-terminal segment with exosite I. Sucrose octasulfate (SOS) accelerated thrombin inactivation by HCII but not AT by 2000-fold. SOS bound to two sites on thrombin, with dissociation constants (K_D) of 10 ± 4 μm and 400 ± 300 μm that were not kinetically resolvable, as evidenced by single hyperbolic SOS concentration dependences of the inactivation rate (k_obs). SOS bound HCII with K_D 1.45 ± 0.30 mm, and this binding was tightened in the T·SOS·HCII complex, characterized by K_complex of ∼0.20 μm. Inactivation data were incompatible with a model solely depending on HCII·SOS but fit an equilibrium linkage model employing T·SOS binding in the pathway to higher order complex formation. Hirudin-(54–65)(SO₃⁻) caused a hyperbolic decrease of the inactivation rates, suggesting partial competitive binding of hirudin-(54–65)(SO₃⁻) and HCII to exosite I. Meizothrombin(des-fragment 1), binding SOS with K_D = 1600 ± 300 μm, and thrombin were inactivated at comparable rates, and an exosite II aptamer had no effect on the inactivation, suggesting limited exosite II involvement. SOS accelerated inactivation of meizothrombin 1000-fold, reflecting the contribution of direct exosite I interaction with HCII. Thrombin generation in plasma was suppressed by SOS, both in HCII-dependent and -independent processes. The ex vivo HCII-dependent process may utilize the proposed model and suggests a potential for oversulfated disaccharides in controlling HCII-regulated thrombin generation.     

Characterization of an Electron Transport Pathway Associated with Glucose and Fructose Respiration in the Intact Chloroplasts of Chlamydomonas reinhardtii and Spinach

The role of an electron transport pathway associated with aerobic carbohydrate degradation in isolated, intact chloroplasts was evaluated. This was accomplished by monitoring the evolution of ¹⁴CO₂ from darkened spinach (Spinacia oleracea) and Chlamydomonas reinhardtii chloroplasts externally supplied with [¹⁴C]fructose and [¹⁴C]glucose, respectively, in the presence of nitrite, oxaloacetate, and conventional electron transport inhibitors. Addition of nitrite or oxaloacetate increased the release of ¹⁴CO₂, but it was shown that O₂ continued to function as a terminal electron acceptor. ¹⁴CO₂ evolution was inhibited up to 30 and 15% in Chlamydomonas and spinach, respectively, by 50 μm rotenone and by amytal, but at 500- to 1000-fold higher concentrations, indicating the involvement of a reduced nicotinamide adenine dinucleotide phosphate-plastoquinone oxidoreductase. ¹⁴CO₂ release from the spinach chloroplast was inhibited 80% by 25 μm 2,5-dibromo-3-methyl-6-isopropyl-p-benzoquinone. ¹⁴CO₂ release was sensitive to propylgallate, exhibiting approximately 50% inhibition in Chlamydomonas and in spinach chloroplasts of 100 and 250 μm concentrations, respectively. These concentrations were 20- to 50-fold lower than the concentrations of salicylhydroxamic acid (SHAM) required to produce an equivalent sensitivity. Antimycin A (100 μm) inhibited approximately 80 to 90% of ¹⁴CO₂ release from both types of chloroplast. At 75 μm, sodium azide inhibited ¹⁴CO₂ evolution about 50% in Chlamydomonas and 30% in spinach. Sodium azide (100 mm) combined with antimycin A (100 μm) inhibited ¹⁴CO₂ evolution more than 90%. ¹⁴CO₂ release was unaffected by uncouplers. These results are interpreted as evidence for a respiratory electron transport pathway functioning in the darkened, isolated chloroplast. Chloroplast respiration defined as ¹⁴CO₂ release from externally supplied [1-¹⁴C]glucose can account for at least 10% of the total respiratory capacity (endogenous release of CO₂) of the Chlamydomonas reinhardtii cell.     

Modulation of Escherichia coli Adenylyl Cyclase Activity by Catalytic-Site Mutants of Protein IIAGlc of the Phosphoenolpyruvate:Sugar Phosphotransferase System

It is demonstrated here that in Escherichia coli, the phosphorylated form of the glucose-specific phosphocarrier protein IIA^Glc of the phosphoenolpyruvate:sugar phosphotransferase system is an activator of adenylyl cyclase and that unphosphorylated IIA^Glc has no effect on the basal activity of adenylyl cyclase. To elucidate the specific role of IIA^Glc phosphorylation in the regulation of adenylyl cyclase activity, both the phosphorylatable histidine (H90) and the interactive histidine (H75) of IIA^Glc were mutated by site-directed mutagenesis to glutamine and glutamate. Wild-type IIA^Glc and the H75Q mutant, in which the histidine in position 75 has been replaced by glutamine, were phosphorylated by the phosphohistidine-containing phosphocarrier protein (HPr~P) and were equally potent activators of adenylyl cyclase. Neither the H90Q nor the H90E mutant of IIA^Glc was phosphorylated by HPr~P, and both failed to activate adenylyl cyclase. Furthermore, replacement of H75 by glutamate inhibited the appearance of a steady-state level of phosphorylation of H90 of this mutant protein by HPr~P, yet the H75E mutant of IIA^Glc was a partial activator of adenylyl cyclase. The H75E H90A double mutant, which cannot be phosphorylated, did not activate adenylyl cyclase. This suggests that the H75E mutant was transiently phosphorylated by HPr~P but the steady-state level of the phosphorylated form of the mutant protein was decreased due to the repulsive forces of the negatively charged glutamate at position 75 in the catalytic pocket. These results are discussed in the context of the proximity of H75 and H90 in the IIA^Glc structure and the disposition of the negative charge in the modeled glutamate mutants.