Voltammetry of tobacco mosaic virus and its isolated protein at the graphite electrode

The electrochemical behaviour of tobacco mosaic virus (TMV) and its isolated protein was studied using differential pulse (DP) voltammetry at a graphite electrode and by direct current (DC) polarography in Brdicka solution. TMV and its isolated protein were found to be electrooxidized at the graphite electrode in the adsorbed state. Both species yielded two oxidation peaks on DP voltammograms. The first, more negative peak, corresponded to electrooxidation of tyrosine residues, whereas the other, more positive, peak corresponded to electrooxidation of tryptophan residues. DC polarography was used to detect degradation of TMV and denaturation of TMV-protein induced by an increased pH and by the addition of urea, respectively. These structural transformations resulted in increased DP voltammetric oxidation currents as recorded using a graphite working electrode. It has been suggested that the higher oxidation currents were due to an increase in the number of tyrosine and tryptophan residues accessible to the reaction at the graphite electrode. The results of these electrochemical investigations were in a good agreement with the estimation of the accessibility of tyrosine and tryptophan residues based on the well-explored three-dimensional structure of TMV and its isolated protein.     

Adsorption of single-stranded and double-helical polynucleotides on the mercury electrode

The adsorption of single-stranded polynucleotides and double-helical DNA on the dropping mercury electrode has been studied with the aid of Breyer's alternating current (a.c.) polarography. Our results indicate that all three constituents of polynucleotides (residues of bases, sugar, and phosphoric acid) are involved in the adsorption. At neutral pH their participation in adsorption depends on the ionic strength, the potential of the electrode, and the conformation of the polynucleotide in the solution. At an ionic strength of about 0.1, double-helical DNA is adsorbed electrostatically on a positively charged electrode surface by inadequately masked negative charges of the phosphate groups. At a higher ionic srength (about 0.5), this electrostatic adsorption is no longer detectable by using a.c. polarography; under these conditions it is probable that native DNA is adsorbed around the potential of the electrocapillary maximum with the aid of sugar residues and a few bases. Single-stranded polynucleotides, on the other hand, are primarily adsorbed by means of the bases. Desorption of double-helical DNA occurs around a potential of ?1.2 V against SCE. At this potential, the helical regions of single-stranded polynucleotides are also desorbed. Desorption of the disordered regions of single-stranded polynucleotides occurs at more negative potentials. Adsorption and desorption of a small number of bases released from double-helical DNA was evident in the a.c. polarograms only at elevated temperature, or at room temperature after degradation of DNA by sonication.     

Structural transitions of polyadenylic acid due to protonation: the influence of the length of single strands on the polarographic behaviour of the double-helical form

Transition of single-stranded poly(A) into its double-helical protonated form was followed by means of derivative pulse polarography, spectrophotometry, and other methods. It was found that properties of protonated poly(A) depended on the length of single strands from which the protonated double helix was formed. In contrary to longer poly(A) transition of short single-stranded molecules (s₂₀,w lower than about 3) caused practically no decrease in the pulse-polarographic current. It was concluded that the formation of the protonated double helix of poly(A) did not result in the inaccesibility of the reduction sites (located in the vicinity of the surface of the molecule) for the electrode process, as it was in DNA-like double-helical polynucleotides. The current changes observed in the course of transition of longer poly(A) were explained as due to slower transport of long double-stranded molecules to the electrode.     

Hydrogen bonds between protein side chains and phosphates and their role in biological calcification

Poly(L-histidine)-phosphate (H2PO4-, HPO4(2-)) and poly(L-glutamate)-phosphate systems (residue/phosphate, 1:1) in the presence of Ca2+ are studied by infrared spectroscopy. In the poly(L-histidine)-phosphate systems N...HOP in equilibrium NH+...O-P hydrogen bonds are formed where most phosphate protons are found at the histidine ring. With an increase in the degree of hydration the proportion of the proton limiting structure NH+...O-P increases. In the poly(L-glutamate)-dihydrogen phosphate system most phosphate protons are found at the carboxylate groups. Different behavior is observed for poly(L-glutamate)-hydrogen phosphate mixtures, where the residence time of the phosphate proton at the hydrogen acceptor carboxylate group is very short. This residence time increases, however, with increasing humidity. All these results support the triphasic theory of biological calcification involving a tripartite protein-calcium-phosphate complex where these hydrogen bonds can be present. The behavior of these hydrogen bonds can also explain the formation of a nidus of calcium phosphate salts in calcium oxalate-containing urinary calculi.     

The influence of salts andpH on polarographic currents produced by denatured DNA

Summary The behaviour of denatured DNA was studied with the aid of classical (dc) polarography, alternating current polarography, oscillopolarography and pulse-polarography. The dependences of limiting dc polarographic currents of denatured DNA onpH had S-shaped courses. The curves of S-shaped dependences shifted to variouspH according to the concentration and to the type of salts of background electrolyte. In the regions ofpH, where the height of dc polarographic step almost did not change withpH, the limiting current had the character of diffusion controlled currents. At higherpH, when the drop of current occurred, the dc polarographic curves had a maximum form. The decrease of current and the appearance of the maximum-like curve is probably connected with adsorption/desorption processes which take place on the electrode at negative potentials. S-shaped course had even the dependence of the height of pulse-polarographic curves and the depths of an indentation on the oscillopolarograms dE/dt againstE on pH. In difference to the dc polarography, it was possible by using these methods to work with lower DNA concentrations and to measure at lower pH.     

Polarography of polynucleotides. IV. Effect of the molecular weight of poly(U) on its adsorption at a charged surface

Effects of molecular size on the adsorption properties of poly(U) were studied using alternating current polarography as a technique and a dropping mercury electrode (d.m.e.) as a model interface. The measurements were carried out on fractions (by molecular weight) of poly(U) characterized by sedimentation and viscosity measurements. The data indicate that the rate of poly(U) adsorption is controlled by diffusion. The adsorption equilibrium can be established during the drop-life at higher concentrations of poly(U) where the electrode is fully covered, while at low concentrations corresponding to the linearized isotherm, the time τ for the establishment of the adsorption equilibrium is much longer than can be obtained with d.m.e. The time τ increases with increasing chain length, n (in monomeric units). From the concentration dependence of the course of current time, I ～t, curves, or of the current values at the end of the drop life, a constant K was calculated which depends on n. In the range of molecular weights studied (25 × 10³ to 564 × 10³) the data obeys the relationship log n = a + b log K (where a and b are constants). Area, A, occupied by the monomer of an adsorbed poly(U) molecule was calculated from experimental values of K and D (diffusion coefficient). The decrease of A with increasing n was explained in terms of the looping of longer poly(U) chains out from the electrode surface.     

Effect of lipid monolayers on diffusion of oxygen through the air/water interface

The dependence of the diffusion current on the depth of immersion of the electrode was studied by polarography using an open platinum electrode. As the electrode was brought from the depth of the liquid phase to its surface, an increase in the current under aerobic conditions was observed, due to diffusion of oxygen through the interface. The formation of lipid monolayers of phosphatidylcholine, stearic acid, hexadecanol, octadecanol, eicosanol, and docosanol on the water surface led to a decrease in diffusion current; the effect being most pronounced at a minimal depth of immersion of the electrode. The maximum value of the relative decrease in diffusion current R was obtained for docosanol monolaers. It was shown that the R value increases with increasing surface pressure in monolayers of phosphatidylcholine and stearic acid. It is assumed that the decrease in diffusion flow of O2 in the presence of monolayers is caused by the formation of an energy barrier that prevents the sorption of O2, which is related to the presence of hydrocarbon chains weakly interacting with oxygen.     

Interaction of nucleic acids with electrically charged surfaces. VII. The effect of ionic strength of neutral medium on the conformation of dna adsorbed on the mercury electrode

Triangular-wave direct current (d.c.) voltammetry at a hanging mercury drop electrode and phase-selective alternating current (a.c.) polarography at a dropping mercury electrode were used for the investigation of adsorption of double-helical (ds) DNA at mercury electrode surfaces from neutral solutions of 0.05-0.4 M HCOONH4. It was found for the potential region T (from -0.1 V up to ca. -1.0 V) that the height of voltammetric peaks of ds DNA is markedly influenced by the initial potential only at relatively low ionic strength (mu) (from 0.05 up to ca. 0.3). Also a decrease of differential capacity (measured by means of a.c. polarography) in the region T depended markedly on the electrode potential only at relatively low ionic strength. The following conclusions were made concerning the interaction of ds DNA with a mercury electrode charged to potentials of the region T in neutral medium of relatively low ionic strength mu < 0.3). (i) When ds DNA is adsorbed, a significantly higher number of DNA segments is anchored in the positively charged electrode surface than in the surface bearing a negative charge, (ii) In the region T, especially adsorbed labile regions of ds DNA are opened in the electrode surface, which are present in ds DNA already in the bulk of the solution, (iii) In the narrow region of potentials in the Vicinity of the zero charge potential a higher number of ds DNA segments can be opened, probably as a consequence of the strain which could act on the ds DNA molecule in the course of the segmental adsorption/desorption process.     

Interaction of nucleic acids with electrically charged surfaces: II. Conformational changes in double-helical polynucleotides

The influence of adsorption of double-stranded (ds) DNA, ds RNA and homopolymeric pairs at a mercury electrode on conformation of these polynucleotides was studied. Changes in the polarographic reducibility of polynucleotides, which were followed by means of normal pulse polarography and linear sweep peak voltammetry at the dropping mercury electrode were exploited to indicate conformational changes. It was found that, as a consequence of adsorption of ds polynucleotides on the negatively charged electrode conformational changes similar to denaturation take place in a narrow potential region around ?1.2 V (the region U). After sufficiently long time of the contact with the electrode (under our conditions about 10 s) these changes reach limiting values, which can approach total denaturation. Upon adsorption of ds polynucleotides on the electrode charged to more positive potentials than the region U either (1) no conformational changes occur or (2) only a small part of the polynucleotide (probably labile regions of the ds molecule) is very quickly denatured - the remainder of the molecule preserves its ds structure. Conformational changes of adsorbed ds polynucleotides are influenced by factors which change the stability of ds polynucleotides in solution. It is supposed that denaturation of ds polynucleotides in the region U might result from the strains connected with the repulsion of certain segments of the molecule anchored on the electrode from the negatively charged surface.     

Relation between differential pulse voltammetric oxidation of polyriboinosinic acid and its structure

Electrooxidation of poly (I) at a paraffin wax-impregnated spectroscopic graphite electrode was studied by means of differential pulse voltammetry. It was found that the transition of single-stranded poly (I) to its multistranded form, induced by increasing the ionic strength of neutral medium, is accompanied by a lowering of the oxidation current of poly (I). The marked lowering of the oxidation current is also observable as a consequence of the formation of double-stranded complex of poly (I). poly (C). The voltammetry at carbon electrodes provides for the study of poly(I) structure in principle identical information as optical methods.     

Interaction of red blood cells with a polarized electrode: evidence of long-range intermolecular forces.

We have investigated the electrostatic interaction of glutaraldehyde-fixed human red cells with a polarizable electrode carrying a defined surface charge density which can be varied continuously through a wide range. Cells in a dilute salt solution are unable to adhere to the electrode at high negative charge, but at lower negative charge densities they are reversibly adherent and can be forced off by increasing the negative polarization. Near zero electrode charge they become irreversibly stuck to the electrode and cannot be evicted even at maximum electrode polarization. Calculation of the electrostatic repulsive force using measured charge densities indicates the existence of an attractive force which may be acting over several hundred angstroms.     

Poly(I:C) induce bone marrow precursor cells into myeloid-derived suppressor cells

Dendritic cells (DC) and myeloid-derived suppressor cells (MDSC) are important cells involved in immune response. DC can be generated from mouse bone marrow (BM) in the presence of granulocyte-macrophage colony-stimulating factor (GM-CSF) and IL-4. Recent studies have revealed that combined treatment of bone marrow MDSC with LPS plus IFN-γ inhibited the DC development but enhanced MDSC functions, such as NO release and T cell suppression. In our study, bone marrow precursor cells cultures in GM-CSF and IL-4 were treated with poly(I:C) through the culture, Gr1(+)CD11b(+) cells with MDSC functions, such as NO release and T cell suppression were accumulated in the culture system. Then the similar phenomenon was observed in the vesicular stomatitis virus infection in vivo. In conclusion, we demonstrated that the bone marrow precursor cells in the presence of GM-CSF and IL-4 can differentiate into MDSC, which is dependent on the dynamic of interaction with poly(I:C).     

Analysis of nerve conduction block induced by direct current

The mechanisms of nerve conduction block induced by direct current (DC) were investigated using a lumped circuit model of the myelinated axon based on Frankenhaeuser–Huxley (FH) model. Four types of nerve conduction block were observed including anodal DC block, cathodal DC block, virtual anodal DC block, and virtual cathodal DC block. The concept of activating function was used to explain the blocking locations and relation between these different types of nerve block. Anodal/cathodal DC blocks occurred at the axonal nodes under the block electrode, while virtual anodal/cathodal DC blocks occurred at the nodes several millimeters away from the block electrode. Anodal or virtual anodal DC block was caused by hyperpolarization of the axon membrane resulting in the failure of activating sodium channels by the arriving action potential. Cathodal or virtual cathodal DC block was caused by depolarization of the axon membrane resulting in inactivation of the sodium channel. The threshold of cathodal DC block was lower than anodal DC block in most conditions. The threshold of virtual anodal/cathodal blocks was about three to five times higher than the threshold of anodal/cathodal blocks. The blocking threshold was decreased with an increase of axonal diameter, a decrease of electrode distance to axon, or an increase of temperature. This simulation study, which revealed four possible mechanisms of nerve conduction block in myelinated axons induced by DC current, can guide future animal experiments as well as optimize the design of electrodes to block nerve conduction in neuroprosthetic applications.     

Potentiometric characterization of ethidium bromide and of its reactions with nucleic acids

A liquid membrane electrode that allows the concentration of ethidium ion (Ed(+)) to be measured selectively and accurately in the range of 0.1 microM to 5 mM is made. For Ed(+) concentrations less than 1 microM or more than 0.1 mM, the trend is no longer linear, and the causes of this behavior are discussed. The mean activity coefficient of ethidium bromide exhibits deviations from the Debye-Huckel limiting law that are interpreted in terms of aggregate formation. The stability constants for Ed(2)(2+) and Ed(2)Br(+) are 230 kg mol(-1) and 3.0 x 10(4) kg(2) mol(-2), respectively. In NaCl solutions, clusters involving up to 4 Ed(+) units are detected and their stability constants are evaluated. The intercalation of ethidium into poly(A).poly(U) in 1M NaCl is investigated by the above electrode, and the results are compared with those obtained by spectrophotometry. The data are analyzed in terms of Scatchard plots. The potentiometric method is more accurate than the spectrophotometric one at low values of the binding degree (r) where negative deviations from linearity are observed. The deviations are ascribed to a cooperative behavior rather than to artifacts caused by minor systematic errors.     

尿酸在聚6-甲基香豆素修饰的玻碳电极上的电化学行为

制备了聚6-甲基香豆素修饰玻碳电极,研究了尿酸(UA)在该修饰电极上的电化学行为。实验结果表明:在pH=5.0的磷酸盐缓冲溶液中,扫描速率为50mV/s时,尿酸在修饰电极上于0.352V处产生一个灵敏的氧化峰,在0.278V处有一弱的还原峰。经线性扫描伏安法测定,氧化峰电流与尿酸浓度在2.5×10-6～1.0×10-5mol/L范围内表现出良好的线性关系,检出限为1.0×10-6mol/L。将修饰电极在常温下放置50d及将体系温度升高到75℃时,修饰电极对尿酸的响应电流大体不变,结果满意。     

Immobilization of rat brain acetylcholinesterase on ZnS and poly(indole-5-carboxylic acid) modified Au electrode for detection of organophosphorus insecticides

A novel, highly sensitive amperometric biosensor for detection of organophosphorus (OP) compounds has been constructed, based on rat brain acetylcholinesterase (AChE) immobilized onto nanocomposite of ZnS-nanoparticles (ZnSNPs) and poly(indole-5-carboxylic acid) electrodeposited on Au electrode. In the presence of acetylthiocholine chloride (ATCl) as a substrate, ZnSNPs promoted electron transfer reactions at a lower potential and catalyzed electrochemical oxidation of enzymatically formed thiocholine, thus increasing detection sensitivity. Under optimum conditions (phosphate buffer, pH 7.5 and 30°C), the inhibition of AChE by malathion and chlorpyrifos was proportional to their concentrations in the range, 0.1-50nM and 1.5-40nM, respectively. The biosensor determined malathion and chlorpyrifos in spiked tap water samples with a acceptable accuracy (95-100%). The enzyme electrode had long-storage stability (50% retention of initial activity within 2 months, when stored at 4°C).     

Copper-psychoactive drug complexes: a voltammetric approach to complexation by 1,4-benzodiazepines

Copper complexation by the 1,4-benzodiazepines medazepam, diazepam, flurazepam, nitrazepam, and clonazepam was investigated using differential pulse polarography and cyclic voltammetry at a mercury electrode in 0.10 M KNO3 and pH 7.0 +/- 0.1. Because the 1,4-benzodiazepines are easily reduced at a mercury electrode through the two-electron reduction of the 4,5-azomethine functional group, copper reduction, as well as that of the ligands, was analyzed under varying experimental conditions. In most situations adsorption phenomena occurred and their influence on voltammetric signals had to be carefully analyzed. The voltammetric behavior was then interpreted in terms of complex formation. The results showed that all benzodiazepines can act as ligands toward copper(II) ions, forming 1:1 and 1:2 complexes with similar stabilities. The stoichiometric acidity constants of the benzodiazepines under study were also determined by potentiometric titration in water-ethanol medium and 0.10 M KNO3 and then extrapolated to 0% concentration of ethanol.     

Direct‐Current Triboelectric Nanogenerator Realized by Air Breakdown Induced Ionized Air Channel

The air breakdown phenomenon is generally considered as a negative effect in previous research on triboelectric nanogenerators (TENGs), which is always accompanied by air ionization. Here, by utilizing the air breakdown induced ionized air channel, a direct‐current triboelectric nanogenerator (DC‐TENG) is designed for harvesting contact‐separation mechanical energy. During working process, the charges first transfer from bottom to top electrodes through an external circuit in contact state, then flow back via the ionized air channel created by air breakdown in the separation process. So a unidirectional flow of electrical charges can be observed in the external circuit. With repeating contact‐separation cycles, continuous pulsed DC output through the external circuit can be realized. This working mechanism was verified by real‐time electrode potential monitoring, photocurrent signal detection, and controllable discharging observation. The DC‐TENG can be used for directly and continuously charging an energy storage unit and/or driving electronic devices without using a bridge rectifier. Owing to its simplicity in structure, the mechanism is further applied to fabricate the first flexible DC‐TENG. This research provides a significant fundamental study for DC‐TENG technology and may expand its application in flexible electronics and flexible self‐charging power systems.     

A highly sensitive biosensor with (Con A/HRP)n multilayer films based on layer-by-layer technique for the detection of reduced thiols

The bilayer of Con A/HRP through the biospecific affinity of concanavalin A (Con A) and glycoprotein horseradish peroxidase (HRP) was prepared on the surface of an Au electrode modified by the precursor film consisted of poly(allylamine hydrochloride) poly(sodium-p-styrene-sulfonate). Atomic force microscopy and electrochemical impedance spectroscopy were adopted to monitor the uniform layer-by-layer assembly of the Con A/HRP bilayers. The amperometric measurement was based on the inhibition of reduced thiols and performed in the presence of the electron mediator hydroquinone in 0.2 M phosphate buffer of pH 6.5 at an applied potential of −0.15 V versus Ag/AgCl. Under the optimal conditions, the biosensor presented a linear response for cysteine from 0.1 to 23.5 μM, with a detection limit of 0.02 μM. The biosensor demonstrated high stability and repeatability. A series of reduced thiols were detected by this inhibition biosensor and oxidized thiols showed no effect on the current response of the biosensor.     

Electrochemical performance of 8-hydroxy-2'-deoxyguanosine and its detection at poly(3-methylthiophene) modified glassy carbon electrode

8-Hydroxy-2'-deoxyguanosine (8-OH-dG) has attracted enormous attention in recent years because it has been acknowledged as a typical biomarker of oxidative DNA damage. In this paper, the electrochemical performance of 8-OH-dG at the poly(3-methylthiophene) (P3MT) modified glassy carbon electrode (GCE) was investigated by cyclic voltammetry (CV) and linear sweep voltammetry (LSV). The conducting polymer P3MT can effectively decrease the oxidation peak potential of 8-OH-dG and greatly enhance its peak current. In 0.1 M pH 7.0 phosphate buffer solution (PBS), the anodic peak currents of cyclic voltammograms are linear with the 8-OH-dG concentration in two intervals, viz. 0.700-35.0 microM and 35.0-70.0 microM, with the correlative coefficients of 0.9992 and 0.9995, respectively. The detection limit of 8-OH-dG can be estimated to be 0.100 microM (S/N=3). This modified electrode can be used to detect the amount of 8-OH-dG in human urine. Furthermore, the effects of scan rate, pH, and interference of uric acid (UA) for the voltammetric behavior and detection of 8-OH-dG are also discussed. This proposed modified electrode also shows excellent reproducibility and stability that makes it an ideal candidate for amperometric detection of 8-OH-dG in flow injection analysis (FIA) and high performance liquid chromatography (HPLC).