New mechanisms of biological effects of electromagnetic fields

ATP production in mitochondria depends on the nuclear spin and magnetic moment of Mg²⁺ ion in creatine kinase and ATPase. Consequently, the enzymatic synthesis of ATP is an ion-radical process and depends on the external magnetic field and microwave fields that control the spin states of ion-radical pairs and influence the ATP synthesis. The chemical mechanism of ATP synthesis and the origin of biological effects of electromagnetic (microwave) fields are discussed.     

The Influence of Low Magnetic Fields and Magnesium Isotopes on <Emphasis Type="Italic">E. coli</Emphasis> Bacteria

The combined effects of external low static magnetic fields at 0–22 mT and magnesium isotopes on the growth and development of E. coli bacteria has been studied. The magnetic field and ²⁵Mg magnetic isotope effects were obtained in two ranges: 0.8–3.0 and 8–13 mT. The experimental values of the growth rate, the number of CFUs and the ATP pool of bacteria enriched in magnetic magnesium isotope ²⁵Mg (nuclear spin, I = 5/2) in the range of 0.8–3.0 mT are significantly higher compared to bacteria enriched in nonmagnetic isotopes ²⁴Mg, ²⁶Mg, or natural magnesium. The increase in the growth rate, colony-forming ability, and intracellular ATP concentration in bacteria in all groups cultivated under exposure to an external static magnetic field in the range of 0.8 to 3.0 mT confirms the existence of magnetosensitive stages of enzymatic reactions that proceed via the ion-radical mechanism. The combined influence of the magnetic field in the range of 8 to 13 mT and the magnesium magnetic isotope ²⁵Mg on the colony forming ability of E. coli bacteria is associated with processes that are responsible for cell division. The above-mentioned effects of bacterial magnetosensitivity (to magnetic fields and magnetic isotopes) are in good agreement with theoretical predictions of the theory of spin-dependent enzymatic reactions.     

Magnesium magnetic isotope effect: a key towards mechanochemistry of phosphorylating enzymes as molecular machines

A discovery of the huge magnesium isotope effect in enzymatic ATP synthesis provides a new insight into mechanochemistry of enzymes as the molecular machines. It has been found that the catalytic activity values of ATPase, creatine kinase and phosphoglycerate kinase are 2 to 4-fold higher once their active sites contain magnetic (25Mg) not spinless, non-magnetic (24Mg, 26Mg), magnesium cation isotopes. This clearly proves that the ATP synthesis is a spin-selective process involving Mg2+ as the electron accepting reagent. The formation of ATP takes place in an ion-radical pair resulted by two partners, ATP oxyradical and Mg+. The magnesium bivalent cation is a key player in this process, this ion transforms the protein molecule mechanics into a mere chemistry. This ion is a most critical detail of structure of the magnesium dependent phosphorylation enzymes as the mechanochemical molecular machines.     

Mg spin determines adenosinetriphosphate energetics

The molecular dynamics method DFT:B3LYP (6-31G** basis set, T = 310 K) was used to study interactions between adenosinetriphosphate (ATP), ATP subsystem, and magnesium cofactor [Mg(H2O)6]2+, Mg subsystem, in water environment modeled with 78 water molecules in singlet (S) and triplet (T) states. The lowest in energy singlet (S) and triplet (T) potential energy surfaces, PESs, are remarkably separated in space and direct the Mg cofactor towards the gamma-beta-phosphate oxygens (O1-O2), S path, or towards the beta-alpha-phosphate oxygens (O2-O3), T path. Chelation of the gamma-beta-phosphates and beta2-alpha-phosphates ends, respectively, in the formation of stable, low-energy, ([Mg(H2O)4-(O1-O2)ATP]2-) and metastable, high-energy, ([Mg(H2O)2-(O2-O3)ATP]2-) chelates, differing in the number of water molecules around the Mg. Intersection between the two T PESs produces an unstable state, a result of spin redistribution between the Mg and ATP subsystems. This state, which is sensitive to a hyperfine interaction with the Mg nuclear spin, 25Mg, reveals an unpaired electron spin and initiates the ATP cleavage along the ion-radical path, yielding a highly reactive adenosinemonophosphate ion-radical, *AMP-, earlier observed in the CIDNP (Chemically Induced Dynamic Nuclear Polarization) experiment (A.A. Tulub, 2006). Biological consequences of the findings are discussed.     

Magnesium magnetic isotope effect: A key to the mechanochemistry of phosphorylating enzymes as molecular machines

The discovery of the powerful magnesium isotope effect on enzymatic ATP synthesis provides a new insight into the mechanochemistry of enzymes as molecular machines. The catalytic activities of ATPase, creatine kinase, and glycerophsphate kinase containing a Mg²⁺ ion with magnetic isotope nuclei (²⁵Mg) were found to be two to four times higher than those of the enzymes with spinless, nonmagnetic magnesium cation isotopes (²⁴Mg or ²⁶Mg). This demonstrates unambiguously that ATP synthesis is a spin-selective process involving Mg2+ as the electron-accepting reagent. ATP synthesis proceeds in an ion-radical pair consisting of an ADP oxyradical and Mg²⁺. In this process, the magnesium bivalent cation is the key agent that transforms the mechanics of a protein molecule into chemical processes. This ion is the crucial structural component of enzymes as mechanochemical molecular machines.     

Spin biochemistry

The rates of adenosine triphosphate (ATP) production by isolated mitochondria and mitochondrial creatime kinase incubated in isotopically pure media containing, separately, ²⁴Mg²⁺, ²⁵Mg²⁺, and ²⁶Mg²⁺ ions were shown to be strongly dependent on the magnesium nuclear spin and magnetic moment. The rate of adenosine 5′-diphosphate phosphorylation in mitochondria with magnetic nuclei²⁵Mg is about twice higher than that with the spinless, nonmagnetic nuclei^24.26Mg. When mitochondrial oxidative phosphorylation was selectively blocked by treatment with 1-methylnicotine amide, ²⁵Mg²⁺ ions were shown to be nearly four times more active in mitochondrial ATP synthesis than ^24,26Mg²⁺ ions. The rate of ATP production associated with creatine kinase is twice higher for ²⁵Mg²⁺ than for ^24.26Mg and does not depend on the blockade of oxidative phosphorylation. There is no difference between ²⁴Mg²⁺ and ²⁶Mg²⁺ effects in both oxidative and substrate phophorylation. These observations demonstrate that the enzymatic phosphorylation is a nuclear spin selective process controlled by magnetic isotope effect. The reaction mechanism proposed includes a participation of intermediate ion-radical pairs with Mg⁺ cation as a radical partner. Therefore, the key mitochondrial phosphotransferases work as a magnesium nuclear spin mediated molecular machines.     

Magnetic-dependent ATP pool in <Emphasis Type="Italic">Escherichia coli</Emphasis>

The ATP pool in Escherichia coli is a magnetic-dependent characteristic of microorganism vital activity. It depends on the values of the external static magnetic field and the existence of magnetic moment of magnesium isotopes nuclei added to the growth nutrient medium. The combined effects of the magnetic field 70–95 mT and magnesium magnetic isotope ²⁵Mg on E. coli bacteria leads to increase intracellular concentration of ATP. Magnetic-field effects in the range of 0.8–16 mT, registered for all bacteria regardless of the magnesium-isotopic enrichment of nutrient medium, evidence about the sensitivity of intracellular processes to weak magnetic fields.     

Comparison of DeltapH- and Delta***φ***-driven ATP synthesis catalyzed by the H(+)-ATPases from Escherichia coli or chloroplasts reconstituted into liposomes.

The H(+)-ATPases from Escherichia coli, EF(0)F(1), and from chloroplasts, CF(0)F(1), were reconstituted in liposomes from phosphatidylcholine/phosphatidic acid. The proteoliposomes were energized by an acid-base transition and a K(+)/valinomycin diffusion potential and the initial rate of ATP synthesis was measured as a function of the transmembrane pH difference, DeltapH, and the electric potential difference, Deltaφ. With EF(0)F(1), a rate of 80 s(-1) is observed at DeltapH=4.1 and Deltaφ approximately 140 mV. The rate decreases sigmoidally with Deltaφ and at Deltaφ approximately 0 mV, the rate is about 1 s(-1) although DeltapH is still 4.1. Under the same conditions with CF(0)F(1), a rate of 280 s(-1) is observed which decreases to 190 s(-1) when Deltaφ is abolished, i.e. ATP synthesis catalyzed by EF(0)F(1) and CF(0)F(1) depends in a different way on DeltapH and Deltaφ. EF(0)F(1)-catalyzed ATP synthesis was measured as a function of DeltapH at a constant Deltaφ. The rate depends sigmoidally on DeltapH reaching a maximal rate which cannot be further increased by increasing DeltapH. However, this maximal rate depends on Deltaφ, i.e. DeltapH and Deltaφ are not kinetically equivalent in driving ATP synthesis. We assume that EF(0)F(1) must be converted into a metastable, active state before it catalyzes proton transport-coupled ATP synthesis. For EF(0)F(1), this activation step depends only on Deltaφ, whereas for CF(0)F(1), the activation depends on DeltapH and Deltaφ.     

Magnesium spin state determines the energetics of an adenosinetriphosphate molecule

The molecular dynamics method (density functional theory) DFT:B3LYP (6-3IG** basis set, t = 310 K) was used to study interactions between a molecule of adenosinetriphosphate (ATP) (ATP subsystem) and the [Mg(H₂O)₆]²⁺ magnesium cofactor (Mg subsystem) in an aqueous medium simulated by 78 water molecules in the singlet (S) and triplet (T) states. Potential energy surfaces (PESs) for the S (lowest in energy) and T states (highest in energy) are significantly separated in space. Motion along them directs the Mg complex either to oxygen atoms of the γ-β-phosphate groups (O1–O2) (S state of PES) or to oxygen atoms of the β-α-phosphate groups (O2–O3) (T state of PES). Chelation of the γ-β- and β-α-phosphates leads to formation of a stable low-energy ([Mg(H₂O)₄-(OI-O2)ATP]^2?) complex or a metastable high-energy ([Mg(H₂O)₂-(O2–O3)ATP]^2?) complex, respectively, which differ in number of water molecules surrounding the Mg atom. Intersection of two T PESs is accompanied by formation of an unstable state characterized by redistribution of spins between the Mg and ATP subsystems. This state, being sensitive to interaction with the Mg nuclear spin (²⁵Mg), induces an unpaired electron spin, which initiates the ATP cleavage by the ion-radical mechanism, yielding a reactive ion radical of adenosinemonophosphate (·AMP^?), which was earlier found experimentally by the method of chemically induced dynamic nuclear polarization (CIDNP). Biological aspects of the results obtained are discussed.     

ATP synthesis in chromatophores driven by artificially induced ion gradients

An electrochemical potential difference for protons (delta mu H+) across the membrane of bacterial chromatophores was induced by an artificially generated pH difference (delta pH) and a K+/valinomycin diffusion potential, delta phi. The initial rate of ATP synthesis was measured with a rapid-mixing quenched-flow apparatus in the time range between 70 ms and 30 s after the acid-base transition. The rate of ATP synthesis depends exponentially on delta pH. Increasing diffusion potentials shift the delta pH dependency to lower delta pH values. Diffusion potentials were calculated from the Goldman equation. Using estimated permeability coefficients, the rate of ATP synthesis depends only on the electrochemical potential difference of protons irrespective of the relative contribution of delta pH and delta phi.     

Coreconstitution of bacterial ATP synthase with monomeric bacteriorhodopsin into liposomes. A comparison between the efficiency of monomeric bacteriorhodopsin and purple membrane patches in coreconstitution experiments

The conditions for coreconstitution of a bacterial ATP synthase and bacteriorhodopsin into lecithin liposomes and for light driven ATP synthesis have been optimized. A rate of maximally 280 nmol ATP min-1 mg ATP synthase-1 was achieved with monomerized bacteriorhodopsin compared with a rate of up to 45 nmol ATP min-1 mg-1 found for proteoliposomes containing bacteriorhodopsin in the form of purple membrane patches. The different rates are explained by the finding that monomeric bacteriorhodopsin is more homogeneously distributed among the liposomes than the purple membrane patches. The final activities depended on both the purification method for the two proteins and the coreconstitution procedure. Furthermore, the ratio (lipid to bacteriorhodopsin to ATP synthase) could be optimized. Light-driven ATP synthesis depends also on the type of detergent used. The best result was obtained by deoxycholate. Also the relationship between proton translocation (by bacteriorhodopsin) and ATP synthesis activity was measured. A constant H+/ATP ratio was found at higher light intensities. This ratio increased strongly at lower light intensities.     

Interaction of a membrane preparation of Na+, K+-ATPase with a spin-labeled analog of ATP]

Interaction of membrane Na+, K+-ATPase preparation from brain gray matter with spin-labelled ATP analogue, in which free iminoxyl radical is joined as a result of 2'(3')-OH ribose groups acylation, is studied. The rotatory mobility of spin-labelled ATP analogue in Na+,K+-ATPase preparation is found to change in non-linear manner during temperature variation (the break-point on the curve being at 20-23degrees C). It correlates with temperature dependence of Na+,K+-ATPase and temperature dependence of lipid viscosity in the membranes, determined by means of hydrophobic spin probes. Substitution of Mg2+ ions with paramagnetic Mn2+ ions resulted in an intense magnetic dipole-dipole interaction between a spin label and Mn2+ ion, which indicated the formation of triple complex enzyme--spin-labelled ATP--Mn2+.     

The rate of ATP-synthesis as a function of delta pH and delta psi catalyzed by the active, reduced H(+)-ATPase from chloroplasts.

The H(+)-ATPase from chloroplasts was brought into the active, reduced state. Then, an electrochemical potential difference of protons across the thylakoid membranes was generated by an acid-base transition, delta pH, combined with a K+/valinomycin diffusion potential, delta psi. The initial rate of ATP synthesis was measured with a rapid-mixing quenched-flow apparatus in the time-range between 20-150 ms. The rate of ATP synthesis depends in a sigmoidal way on delta pH. Increasing diffusion potentials shifts the delta pH-dependencies to lower delta pH values. Analysis of the data indicate that the rate of ATP synthesis depends on the electrochemical potential difference of protons irrespective of the relative contribution of delta pH and delta psi.     

NH2-terminal spin labeling of human hemoglobin--spin states and temperature dependence

In order to explore fully how ligand- and temperature-induced alterations in the spin states of heme iron are related to protein readjustments, the spin label 4-isothiocyanate (I) was covalently attached at beta-93 cysteines and at NH2-terminal valines of various heme-iron ligand forms of human hemoglobin. It was found that the mobility of NH2-terminally bound spin labels depends on the magnetic moment of the heme iron. There is a an approximately linear relationship between the magnetic moment of the heme iron and the mobility of NH2-terminally bound spin labels. In accordance with our previous results, the temperature dependence of ESR spectra of spin-labeled hemoglobin suggests the temperature-induced protein conformational change in those heme-iron ligand forms that are characterized by the equilibrium of the spin states of the heme iron. The conformational change was sensed at both spin-label-binding sites: at beta-93 cysteines and at NH2-terminal valines.     

Standard magnetic resonance-based measurements of the Pi→ATP rate do not index the rate of oxidative phosphorylation in cardiac and skeletal muscles

Magnetic resonance spectroscopy-based magnetization transfer techniques (MT) are commonly used to assess the rate of oxidative (i.e., mitochondrial) ATP synthesis in intact tissues. Physiologically appropriate interpretation of MT rate data depends on accurate appraisal of the biochemical events that contribute to a specific MT rate measurement. The relative contributions of the specific enzymatic reactions that can contribute to a MT P(i)→ATP rate measurement are tissue dependent; nonrecognition of this fact can bias the interpretation of MT P(i)→ATP rate data. The complexities of MT-based measurements of mitochondrial ATP synthesis rates made in striated muscle and other tissues are reviewed, following which, the adverse impacts of erroneous P(i)→ATP rate data analyses on the physiological inferences presented in selected published studies of cardiac and skeletal muscle are considered.     

Orientation of spin-labeled myosin heads in glycerinated muscle fibers.

We have used electron paramagnetic resonance (EPR) spectra to study spin labels selectively and rigidly attached to myosin heads in glycerinated rabbit psoas muscle fibers. Because the angle between the magnetic field and the principal axis of the probe determines the position of the EPR absorption line, spectra from labeled fibers oriented parallel to the magnetic field yielded directly the distribution of spin label orientations relative to the fiber axis. Two spin labels, having reactivities resembling iodoacetamide (IASL) and maleimide (MSL), were used. In rigor fibers with complete filament overlap, both labels displayed a narrow angular distribution, full width at half maximum approximately 15 degrees, centered at angles of 68 degrees (IASL) and 82 degrees (MSL). Myosin subfragments (heavy meromyosin and subfragment-1) were labeled and allowed to diffuse into fibers. The resulting spectra showed the same sharp angular distribution that was found for the labeled fibers. Thus is appears that virtually all myosin heads in a rigor fiber have the same orientation relative to the fiber axis, and this orientation is determined by the actomyosin bond. Experiments with stretched fibers indicated that the spin labels on the fraction of heads not interacting with actin filaments had a broad angular distribution. Addition of ATP to unstretched fibers under relaxing conditions produced orientational disorder, resulting in a spectrum almost indistinguishable from that of an isotropic distribution of probes. Addition of either an ATP analog (AMPPNP) or pyrophosphate produced partial disorder. That is a fraction of the probes remained sharply oriented as in rigor while a second fraction was in a disordered distribution similar to that of relaxed fibers.     

Conformational changes in glycogen phosphorylase studied with a spin-label probe.

Phosphorylase b and a were covalently modified on essentially one -- SH group per subunit by a spin label 4-(2-iodoacetamido)2,2,6,6-tetramethyl piperidinyloxyl. The labelled enzyme is fully active and exhibits all the characteristics of the native molecule. The electron spin resonance spectrum of the label depends on the nature of the ligand that is bound to the enzyme. This property of the spin label is used to study the interaction between the enzyme (both in the b and a forms) and activators (AMP, IMP, CMP), inhibitors (ADP, ATP, UDPG, glucose 6-phosphate), substrates (phosphate and glucose 1-phosphate) and other ligands (adenosine, beta-glycerol-2-phosphate). The interactions are analysed in terms of the apparent ligand dissociation constants and the multiplicity of conformations that this regulatory enzyme exhibits.     

Photosynthetic regeneration of ATP using a strain of thermophilic blue-green algae

Photosynthetic ATP accumulation was shown in the presence of exogenous ADP plus orthophosphate on illumination to the intact cells of a strain of thermophilic blue-green algae isolated from Matsue hot springs, Mastigocladus sp. Kinetic studies of various effectors on the ATP accumulation proved that the ATP synthesis depends mainly on the cyclic photophosphorylation system around photosystem I (PS-I) in the algal cells. The temperature and pH optima for the accumulation were found at 45 degrees C and pH 7.5. Maximum yield was obtained with light intensity higher than 15 mW/cm(2). Borate ion exerted pronounced enhancement on the ATP synthesis. With a continuous reactor at a flow rate of 1 ml/hr at 45 degrees C and pH 7.5, efficient photoconversion of ADP (2mM, at substrate reservoir) to ATP (1mM, at product outlet) has been maintained for a period of 2.5 days, though the efficiency has decreased in a further 2-day period to the level of 0.5mM ATP/9.5 h of residence time.     

The rate of ATP synthesis catalyzed by reconstituted CF0F1-liposomes: Dependence on ΔpH and Δψ

The kinetics of proton-transport coupled ATP synthesis in CF₀F₁ reconstituted into asolectin liposomes was investigated upon energization of the membrane by an artificially generated ΔpH and Δψ. With a rapid mixing system the rate of ATP synthesis was measured at short reaction times (under 200 ms) where all parameters (ΔpH, Δψ, substrate and product concentrations) remain practically constant at their initial values. The rate of ATP synthesis depends, in a sigmoidal way, on ΔpH, the maximal rate being 200 ATP per CF₀F₁ per s. At constant ΔpH, an additional diffusion potential increases the rate until the maximal rate is reached.     

MITOCHONDRIA: Investigation of in vivo muscle mitochondrial function by 31P magnetic resonance spectroscopy

The most important function of mitochondria is the production of energy in the form of ATP. The socio-economic impact of human diseases that affect skeletal muscle mitochondrial function is growing, and improving their clinical management critically depends on the development of non-invasive assays to assess mitochondrial function and monitor the effects of interventions. ³¹P magnetic resonance spectroscopy provides two approaches that have been used to assess in vivo ATP synthesis in skeletal muscle: measuring P_i ⟶ ATP exchange flux using saturation transfer in resting muscle, and measuring phosphocreatine recovery kinetics after exercise. However, P_i ⟶ ATP exchange does not represent net mitochondrial ATP synthesis flux and has no simple relationship with mitochondrial function. Post-exercise phosphocreatine recovery kinetics, on the other hand, yield reliable measures of muscle mitochondrial capacity in vivo, whose ability to define the site of functional defects is enhanced by combination with other non-invasive techniques.