ATP synthesis kinetics and mitochondrial function in the postischemic myocardium as studied by 31P NMR

The effects of ischemia on mitochondrial function and the unidirectional rate of ATP synthesis (Pi----ATP rate) were studied using a Langendorff-perfused heart preparation and 31P NMR spectroscopy. There was significant postischemic depression of mechanical function assessed as the heart rate pressure product, and the myocardial oxygen consumption rate at a given rate pressure product was elevated. Experiments performed on glucose- and pyruvate-perfused hearts demonstrated the presence of a large contribution to the unidirectional Pi----ATP rate catalyzed by glyceraldehyde-3-phosphate dehydrogenase and phosphoglycerate kinase. This rate was much greater than the maximal glucose utilization rate in the myocardium, demonstrating that the glyceraldehyde-3-phosphate dehydrogenase/phosphoglycerate kinase reactions are near equilibrium both before and after ischemia. In the pyruvate-perfused postischemic hearts, the glycolytic contribution was eliminated and the net rate of ATP synthesis by oxidative phosphorylation was measurable. Despite the reduced mechanical function and increased myocardial oxygen consumption rate, the ratio of the net rate of ATP synthesis by oxidative phosphorylation to oxygen consumption rate (the P:O ratio) was not altered subsequent to ischemia (2.34 +/- 0.12 and 2.36 +/- 0.09 in normal and postischemic hearts, respectively). Therefore, mitochondrial uncoupling cannot be the cause of postischemic depression in mechanical function; instead, the data suggest the existence of ischemia-induced inefficiency in ATP utilization.     

3'-Phosphoadenosine 5'-phosphosulfate binding site of flavonol 3-sulfotransferase studied by affinity chromatography and 31P NMR

The function of Lys-59, Arg-141, and Arg-277 in PAPS binding and catalysis of the flavonol 3-sulfotransferase was investigated. Affinity chromatography of conservative mutants with PAPS analogues allowed us to determine that Lys-59 interacts with the 5' portion of the nucleotide, while Arg-141 interacts with the 3' portion, confirming assignments deduced from the crystal structure of mouse estrogen sulfotransferase [Kakuta, Y., Pedersen, L. G., Carter, C. W. , Negishi, M., and Pedersen, L. C. (1997) Nat. Struct. Biol. 4, 904-908]. The affinity chromatography method could be used to characterize site-directed mutants for other types of enzymes that bind nucleoside 3',5'- or 2',5'-diphosphates. 31P NMR spectra of enzyme-PAP complexes were recorded for the wild-type enzyme and K59R and K59A mutants. The results of these experiments suggest that Lys-59 is involved in the determination of the proper orientation of the phosphosulfate group for catalysis.     

Rice plants take up iron as an Fe3+-phytosiderophore and as Fe2+

Only graminaceous monocots possess the Strategy II iron (Fe)-uptake system in which Fe is absorbed by roots as an Fe3+-phytosiderophore. In spite of being a Strategy II plant, however, rice (Oryza sativa) contains the previously identified Fe2+ transporter OsIRT1. In this study, we isolated the OsIRT2 gene from rice, which is highly homologous to OsIRT1. Real-time PCR analysis revealed that OsIRT1 and OsIRT2 are expressed predominantly in roots, and these transporters are induced by low-Fe conditions. When expressed in yeast (Saccharomyces cerevisiae) cells, OsIRT2 cDNA reversed the growth defects of a yeast Fe-uptake mutant. This was similar to the effect of OsIRT1 cDNA. OsIRT1- and OsIRT2-green fluorescent protein fusion proteins localized to the plasma membrane when transiently expressed in onion (Allium cepa L.) epidermal cells. OsIRT1 promoter-GUS analysis revealed that OsIRT1 is expressed in the epidermis and exodermis of the elongating zone and in the inner layer of the cortex of the mature zone of Fe-deficient roots. OsIRT1 expression was also detected in the ccompanion cells. Analysis using the positron-emitting tracer imaging system showed that rice plants are able to take up both an Fe3+-phytosiderophore and Fe2+. This result indicates that, in addition to absorbing an Fe3+-phytosiderophore, rice possesses a novel Fe-uptake system that directly absorbs the Fe2+, a strategy that is advantageous for growth in submerged conditions.     

Internal motions of apo-neocarzinostatin as studied by 13C NMR methine relaxation at natural abundance

Summary Dynamics of the backbone and some side chains of apo-neocarzinostatin, a 10.7 kDa carrier protein, have been studied from ¹³C relaxation rates R1, R2 and steady-state ¹³C-{¹H} NOEs, measured at natural abundance. Relaxation data were obtained for 79 nonoverlapping C resonances and for 11 threonine C single resonances. Except for three C relaxation rates, all data were analysed from a simple two-parameter spectral density function using the model-free approach of Lipari and Szabo. The corresponding C–H fragments exhibit fast (_e < 40 ps) restricted libration motions (S²=0.73 to 0.95). Global examination of the microdynamical parameters S² and _e along the amino acid sequence gives no immediate correlation with structural elements. However, different trends for the three loops involved in the binding site are revealed. The -ribbon comprising residues 37 to 47 is spatially restricted, with relatively large _e values in its hairpin region. The other -ribbon (residues 72 to 87) and the large disordered loop ranging between residues 97–107 experience small-amplitude motions on a much faster (picosecond) time scale. The two N-terminal residues, Ala¹ and Ala², and the C-terminal residue Asn¹¹³, exhibit an additional slow motion on a subnanosecond time scale (400–500 ps). Similarly, the relaxation data for eight threonine side-chain C must be interpreted in terms of a three-parameter spectral density function. They exhibit slower motions, on the nanosecond time scale (500–3000 ps). Three threonine (Thr⁶⁵, Thr⁶⁸, Thr⁸¹) side chains do not display a slow component, but an exchange contribution to the observed transverse relaxation rate R2 could not be excluded at these sites. The microdynamical parameters (S², _e and R2_ex) or (S _infslow ^sup2 , S _inffast ^sup2 and _slow) were obtained from a straightforward solution of the equations describing the relaxation data. They were calculated assuming an overall isotropic rotational correlation time _e for the protein of 5.7 ns, determined using standard procedures from R2/R1 ratios. However, it is shown that the product (1–S²)× _e is nearly independent of _e for residues not exhibiting slow motions on the nanosecond time scale. In addition, this parameter very closely follows the heteronuclear NOEs, which therefore could be good indices for local fast motions on the picosecond time scale.     

The orientation effect of gramicidin A on bicelles and Eu3+ -doped bicelles as studied by solid-state NMR and FT-IR spectroscopy

We have explored the effect of gramicidin A (gA) on bicelle (Bic) orientation in the absence and presence of Eu(3+) by (31)P and (2)H NMR at different DMPC/gA ratios. FT-IR spectroscopy was used to assess the lipid chain ordering and verify the transmembrane peptide conformation. Our results show a time-dependent flipping of the bilayer normal alignment at high temperatures and high proportion of gA. The results are explained by both the diamagnetic susceptibility anisotropy of the beta(6.3) helical peptides and viscosity of the lipid mixture. The concentration effect of gramicidin on Bic/Eu(3+) is compared to that on Eu(3+)-doped DMPC liposomes. The Bic/Eu(3+) system is no longer oriented in the presence of gA and adopts a vesicular morphology while the peptide incorporation induces the formation of ellipsoidal DMPC/Eu(3+) assemblies aligned with their normal parallel to the magnetic field. The difference is explained in terms of lipid chain disorder and size of the bilayers.     

Active site contacts in the purine nucleoside phosphorylase--hypoxanthine complex by NMR and ab initio calculations

Hypoxanthine (Hx) with specific (15)N labels has been used to probe hydrogen-bonding interactions with purine nucleoside phosphorylase (PNP) by NMR spectroscopy. Hx binds to human PNP as the N-7H tautomer, and the N-7H (1)H and (15)N chemical shifts are located at 13.9 and 156.5 ppm, respectively, similar to the solution values. In contrast, the (1)H and (15)N chemical shifts of N-1H in the PNP.Hx complex are shifted downfield by 3.5 and 7.5 ppm to 15.9 and 178.8 ppm, respectively, upon binding. Thus, hydrogen bonding at N-1H is stronger than at N-7H in the complex. Ab initio chemical shift calculations on model systems that simulate Hx in solution and bound to PNP are used to interpret the NMR data. The experimental N-7H chemical shift changes are caused by competing effects of two active site contacts. Hydrogen bonding of Glu201 to N-1H causes upfield shifts of the N-7H group, while the local hydrogen bond (C=O to N-7H from Asn243) causes downfield shifts. The observed N-7H chemical shift can be reproduced by a hydrogen bond distance approximately 0.13 A shorter (but within experimental error) of the experimental value found in the X-ray crystal structure of the bovine PNP.Hx complex. The combined use of NMR and ab initio chemical shift computational analysis provides a novel approach to understand enzyme-ligand interactions in PNP, a target for anticancer agents. This approach has the potential to become a high-resolution tool for structural determination.     

Dynamical structure of the antibody combining site as studied by 1H-15N shift correlation NMR spectroscopy.

The Fv fragment, which is a smallest antigen-binding unit of immunoglobulin, has been used for a 1H-15N shift correlation NMR study of the dynamical structure of the antibody combining site. Fv has been prepared by clostripain digestion of a mouse anti-dansyl IgG2a monoclonal antibody that lacks the entire CH1 domain. We have previously reported that of the six hypervariable regions, three each from the heavy chain (H1, H2, and H3) and the light chain (L1, L2, and L3), H3 is primarily responsible for the antigen binding in the anti-dansyl Fv fragment. The backbone amide nitrogens of all non-proline amino acid residues in H3 have been multiply labeled with 15N. [15N]T2 relaxation times and hydrogen-deuterium exchange rates of the amide groups of the main chain were measured in the absence and presence of epsilon-dansyl-L-lysine (DNS-Lys). It has been shown that (1) in the absence of DNS-Lys H3 displays a significant degree of internal motion and (2) antigen binding induces a significant change in the dynamical structure of H3.     

The state of water in muscle as studied by pulsed NMR

Spin-lattice relaxation times for the water protons in rat gastronemius muscle are reported over the temperature range +37 to −70°C at six resonance frequencies ranging from 4.5 to 60.0 MHz. From −8 to −70°C, the bulk of the muscle water is frozen. The unfrozen part is termed the hydrated layer and amounts to 7–12% of the total water content. Its correlation time takes teh form of a log-Gaussaian distribution function. From +37 to −8°C, the spin-lattice relaxation time is explained by the exchange of water between the hydration layer and the rest of the water, which behaves like ordinary liquid water. The fact that the observed T₂ values are smaller than the calculated values is attributed to the inner field inhomogeneity of the heterogenous system and/or the modification of T₂ due to non-zero dipolar interaction.In the presence of perdeuterated dimethylsulfoxide, the freezing point of water decreases and the amount of non-freezable water increases. T₁ of water protons for muscle containing 10, 20, and 40% dimethylsulfoxide was calculated.     

Temperature-dependence of protein hydrogen bond properties as studied by high-resolution NMR

The temperature-dependence of a large number of NMR parameters describing hydrogen bond properties in the protein ubiquitin was followed over a range from 5 to 65 degrees C. The parameters comprise hydrogen bond (H-bond) scalar couplings, h3JNC', chemical shifts, amide proton exchange rates, 15N relaxation parameters as well as covalent 1JNC' and 1JNH couplings. A global weakening of the h3JNC' coupling with increasing temperature is accompanied by a global upfield shift of the amide protons and a decrease of the sequential 1JNC' couplings. If interpreted as a linear increase of the N...O distance, the change in h3JNC' corresponds to an average linear thermal expansion coefficient for the NH-->O hydrogen bonds of 1.7 x 10(-4)/K, which is in good agreement with overall volume expansion coefficients observed for proteins. A residue-specific analysis reveals that not all hydrogen bonds are affected to the same extent by the thermal expansion. The end of beta-sheet beta1/beta5 at hydrogen bond E64-->Q2 appears as the most thermolabile, whereas the adjacent hydrogen bond I3-->L15 connecting beta-strands beta1 and beta2 is even stabilized slightly at higher temperatures. Additional evidence for the stabilization of the beta1/beta2 beta-hairpin at higher temperatures is found in reduced hydrogen exchange rates for strand end residue V17. This reduction corresponds to a stabilizing change in free energy of 9.7 kJ/mol for the beta1/beta2 hairpin. The result can be linked to the finding that the beta1/beta2 hairpin behaves as an autonomously folding unit in the A-state of ubiquitin under changed solvent conditions. For several amide groups the temperature-dependencies of the amide exchange rates and H-bond scalar couplings are uncorrelated. Therefore, amide exchange rates are not a sole function of the hydrogen bond "strength" as given by the electronic overlap of donors and acceptors, but are clearly dependent on other blocking mechanisms.     

Protein dynamics studied by NMR

The results of NMR studies using several nuclei indicate that proteins have considerable internal mobility. The most obvious is the mobility of side-chains. This mobility is general on the exterior surfaces but extends internally in a differential way. The functional value of surface mobility concerns both on and off rates of ligand binding (e.g. metal ions and parts of substrates) and protein/protein interactions. The mobility, which indicates that recognition is more in the hand-in-glove class than in the lock-in-key class, makes for a modified view of the specificity of protein interactions. Thus, fast on/off systems cannot be as selective as slower systems. Segmental mobility of proteins is considered in the context of protein secondary structure. The least mobile segments are the -sheet and the tight -turn. Mobility is always possible for, but not within, rod-like helices and in loose turns. Many examples are given and the importance of mobility in molecular machines is described. Finally, examples are given of virtually random-coil proteins, segments, and linker regions between domains and the functional value of such extremely dynamic regions of proteins is discussed.This work is based on a lecture at the EBSA Symposium, organised by the Italian Biophysical Society (S.I.B.P.A.), Tabiano Terme, September 1992     

The nature of bile salt micelles as studied by deuterium NMR

Deuterium NMR of 3α,12α-dihydroxy-7,7-dideutero-5β-cholanoic acid was studied. Molecular sizes obtained from deuterium spin-lattice relaxation time (T₁) data of 3α,12α-dihydroxy-7,7-dideutero-5β-cholanoic acid in methanol and in water are in accordance with monomeric and tetrameric structures in the two media, respectively. The deuterium T₁ and intensity of 3α,12α-dihydroxy-7,7-dideutero-5β-cholanoic acid in aqueous solution at pH 8.0–8.8 were studied as functions of NaCl and lecithin concentrations. The results indicated that tetramers are in equilibrium with larger aggregates when secondary micelles are formed in the precense of NaCl, and that 3α, 12α-dihydroxy-7,7-dideutero-5β-cholanoic acid forms mixed micelles with lecithin with a molecular ratio of 2 : 3.     

Binding ability of a HHP-tagged protein towards Ni2+ studied by paramagnetic NMR relaxation: The possibility of obtaining long-range structure information

The binding ability of a protein with a metal binding tag towards Ni(2+) was investigated by longitudinal paramagnetic NMR relaxation, and the possibility of obtaining long-range structure information from the paramagnetic relaxation was explored. A protein with a well-defined solution structure (Escherichia coli thioredoxin) was used as the model system, and the peptide His-His-Pro (HHP) fused to the N-terminus of the protein was used as the metal binding tag. It was found that the tag forms a stable dimer complex with the paramagnetic Ni(2+) ion, where each metal ion binds two HHP-tagged protein molecules. However, it was also found that additional sites in the protein compete with the HHP-tag for the binding of the metal ion. These binding sites were identified as the side chain carboxylate groups of the aspartic and glutamic acid residues. Yet, the carboxylate groups bind the Ni(2+) ions considerably weaker than the HHP-tag, and only protons spatially close to the carboxylate sites are affected by the Ni(2+) ions bound to these groups. As for the protons that are unaffected by the carboxylate-bound Ni(2+) ions, it was found that the long-range distances derived from the paramagnetic relaxation enhancements are in good agreement with the solution structure of thioredoxin. Specifically, the obtained long-range paramagnetic distance constraints revealed that the dimer complex is asymmetric with different orientations of the two protein molecules relative to the Ni(2+) ion.     

Binding interactions in a kinase active site modulate background ATP hydrolysis

Kinases play central roles in many cellular processes, transferring the terminal phosphate groups of nucleoside triphosphates (NTPs) onto substrates. In the absence of substrates, kinases can also hydrolyse NTPs producing NDPs and inorganic phosphate. Hydrolysis is usually much less efficient than the native phosphoryl transfer reaction. This may be related to the fact that NTP hydrolysis is metabolically unfavorable as it unproductively consumes the cell's energy stores. It has been suggested that substrate interactions could drive changes in NTP binding pocket, activating catalysis only when substrates are present. Structural data show substrate-induced conformational rearrangements, however there is a lack of corresponding functional information. To better understand this phenomenon, we developed a suite of isothermal titration calorimetry (ITC) kinetics methods to characterize ATP hydrolysis by the antibiotic resistance enzyme aminoglycoside-3′-phosphotransferase-IIIa (APH(3′)-IIIa). We measured K_m, k_cat, and product inhibition constants and single-turnover kinetics in the presence and absence of non-substrate aminoglycosides (nsAmgs) that are structurally similar to the native substrates. We found that the presence of an nsAmg increased the chemical step of cleaving the ATP γ-phosphate by at least 10- to 20-fold under single-turnover conditions, supporting the existence of interactions that link substrate binding to substantially enhanced catalytic rates. Our detailed kinetic data on the association and dissociation rates of nsAmgs and ADP shed light on the biophysical processes underlying the enzyme's Theorell-Chance reaction mechanism. Furthermore, they provide clues on how to design small-molecule effectors that could trigger efficient ATP hydrolysis and generate selective pressure against bacteria harboring the APH(3′)-IIIa.     

Binding of ATP to Brain Glutamate Decarboxylase as Studied by Affinity Chromatography

Abstract: The interactions of two forms of porcine brain glutamate decarboxylase (β-GAD and γ-GAD) with the effector ATP were studied by affinity chromatography. A third form, γk-GAD, was only slightly retarded by the affinity matrix and was eluted in the buffer wash. The interaction of GAD with the ATP affinity matrix was qualitatively similar to its interaction with free ATP as reported in previous kinetic studies. The rank order of adenine nucleotides as eluting agents and affinity ligands was ATP > ADP > AMP. GAD was also eluted by its cofactor, pyridoxal 5'-phosphate, and this was enhanced by 1 mM P_i In contrast, a high concentration (140 mM) of P_i by itself was required to elute the enzyme. GAD remained active while bound to the affinity column and was eluted in the holoenzyme form by ATP, indicating that the affinity ligand did not bind in the active site and did not displace catalytically active cofactor from the enzyme.     

Active site dynamics in NADH oxidase from Thermus thermophilus studied by NMR spin relaxation

We have characterized the backbone dynamics of NADH oxidase from Thermus thermophilus (NOX) using a recently-developed suite of NMR experiments designed to isolate exchange broadening, together with (15)N R (1), R (1ρ ), and {(1)H}-(15)N steady-state NOE relaxation measurements performed at 11.7 and 18.8 T. NOX is a 54?kDa homodimeric enzyme that belongs to a family of structurally homologous flavin reductases and nitroreductases with many potential biotechnology applications. Prior studies have suggested that flexibility is involved in the catalytic mechanism of the enzyme. The active site residue W47 was previously identified as being particularly important, as its level of solvent exposure correlates with enzyme activity, and it was observed to undergo "gating" motions in computer simulations. The NMR data are consistent with these findings. Signals from W47 are dynamically broadened beyond detection and several other residues in the active site have significant R ( ex ) contributions to transverse relaxation rates. In addition, the backbone of S193, whose side chain hydroxyl proton hydrogen bonds directly with the FMN cofactor, exhibits extensive mobility on the ns-ps timescale. We hypothesize that these motions may facilitate structural rearrangements of the active site that allow NOX to accept both FMN and FAD as cofactors.     

Effect of Fe3+ on Na,K-ATPase: Unexpected activation of ATP hydrolysis

Iron is a key element in cell function; however, its excess in iron overload conditions can be harmful through the generation of reactive oxygen species (ROS) and cell oxidative stress. Activity of Na,K-ATPase has been shown to be implicated in cellular iron uptake and iron modulates the Na,K-ATPase function from different tissues. In this study, we determined the effect of iron overload on Na,K-ATPase activity and established the role that isoforms and conformational states of this enzyme has on this effect. Total blood and membrane preparations from erythrocytes (ghost cells), as well as pig kidney and rat brain cortex, and enterocytes cells (Caco-2) were used. In E1-related subconformations, an enzyme activation effect by iron was observed, and in the E2-related subconformations enzyme inhibition was observed. The enzyme's kinetic parameters were significantly changed only in the Na⁺ curve in ghost cells. In contrast to Na,K-ATPase α2 and α3 isoforms, activation was not observed for the α1 isoform. In Caco-2 cells, which only contain Na,K-ATPase α1 isoform, the FeCl₃ increased the intracellular storage of iron, catalase activity, the production of H₂O₂ and the expression levels of the α1 isoform. In contrast, iron did not affect lipid peroxidation, GSH content, superoxide dismutase and Na,K-ATPase activities. These results suggest that iron itself modulates Na,K-ATPase and that one or more E1-related subconformations seems to be determinant for the sensitivity of iron modulation through a mechanism in which the involvement of the Na, K-ATPase α3 isoform needs to be further investigated.