Fundamental Understanding and Material Challenges in Rechargeable Nonaqueous Li–O2 Batteries: Recent Progress and Perspective

Energy storage challenges have triggered growing interest in various battery technologies and electrocatalysis. As a particularly promising variety, the Li–O₂ battery with an extremely high energy density is of great significance, offering tremendous opportunities to improve cell performance via understanding catalytic mechanisms and the exploration of new materials. Furthermore, focus on nonaqueous electrolyte‐based Li–O₂ batteries has markedly intensified since there could be a higher probability of commercialization, compared to that of solid‐state or aqueous electrolytes. The recent advancements of the nonaqueous Li–O₂ battery in terms of fundamental understanding and material challenges, including electrolyte stability, water effect, and noncarbon cathode materials are summarized in this review. Further, the current status of water impact on discharge products, possible mechanisms, and parasitic reactions in nonaqueous electrolytes are reviewed for the first time. The key challenges of noncarbon oxygen electrode materials, such as noble metals and metal oxides‐based cathodes, transition metals, transition metal compounds (carbides, oxides) based cathodes as well as noncarbon supported catalysts are discussed. This review concludes with a perspective on future research directions for nonaqueous Li–O₂ batteries.     

Behavioural analyses of quinine processing in choice, feeding and learning of larval Drosophila

Gustatory stimuli can support both immediate reflexive behaviour, such as choice and feeding, and can drive internal reinforcement in associative learning. For larval Drosophila, we here provide a first systematic behavioural analysis of these functions with respect to quinine as a study case of a substance which humans report as "tasting bitter". We describe the dose-effect functions for these different kinds of behaviour and find that a half-maximal effect of quinine to suppress feeding needs substantially higher quinine concentrations (2.0 mM) than is the case for internal reinforcement (0.6 mM). Interestingly, in previous studies (Niewalda et al. 2008, Schipanski et al 2008) we had found the reverse for sodium chloride and fructose/sucrose, such that dose-effect functions for those tastants were shifted towards lower concentrations for feeding as compared to reinforcement, arguing that the differences in dose-effect function between these behaviours do not reflect artefacts of the types of assay used. The current results regarding quinine thus provide a starting point to investigate how the gustatory system is organized on the cellular and/or molecular level to result in different behavioural tuning curves towards a bitter tastant.     

Correlation of secondary structure with biological activity for a leader peptide: circular dichroism-derived structure and in vitro biological activities of preproparathyroid hormone peptide and its analogs

Leader or signal sequences are specialized domains within precursor proteins which serve an essential role in interacting with the cellular secretory apparatus to enable intracellular transport and secretion of proteins. Despite many differences in primary amino acid sequences, signal domains interact with a common set of intracellular components, presumably because the signal sequences share an overall conformational similarity. In a few instances, mutant signal peptides from prokaryotes have been studied and their structures correlated with function (export) in vivo. A series of analogs of the precursor-specific region of preproparathyroid hormone have been prepared which contain substitutions of either proline or a charged amino acid within the hydrophobic core. These synthetic "mutants" have previously been evaluated in several in vitro assays to determine their functionality with regard to protein secretion and suitability as substrates for signal peptidase. The secondary structural content of each peptide, as well as the native sequence and sulfur-free analog, was determined in aqueous and nonaqueous conditions by circular dichroism (CD) as a function of time. The structures obtained were correlated with in vitro bioactivities. Unlike the findings or previous CD studies, all the peptides examined here had low to undetectable alpha-helical content in both aqueous and nonaqueous buffers. The unsubstituted and sulfur-free analogs had high (80-85%) beta-structure in aqueous conditions which was reduced to approximately 30% in nonaqueous solvent. The proline- and charged-substituted peptides contained about half the beta-structure content (35-55%) in aqueous buffer; in nonaqueous solvent their structure was similar to the unsubstituted peptides. The structure-activity correlates found were as follows: a high degree of structure (aqueous conditions) correlated with interaction with signal recognition particle and substrate suitability for signal peptidase; a low degree of structure (nonaqueous environment) correlated with activity in the translocation assay.     

Action of phenolic antioxidants on various active oxygen species

The action of phenolic antioxidants, such as probucol, on various active oxygen species was investigated using luminol chemiluminescence and spin trapping with 5,5-dimethyl-1-pyrroline-N-oxide (DMPO). The various active oxygen species, including hydroxyl radicals (Fenton reaction), superoxide anions, singlet oxygen and hypochlorite ions were examined with phenolic antioxidants under aqueous and nonaqueous conditions. Probucol showed a quenching effect on both superoxide anions and hypochlorite ions in nonaqueous solution. However, it had no effect on hydroxyl radicals. α-Tocopherol, a natural phenolic antioxidant, showed a stronger quenching effect on superoxide anions and hypochlorite ions than probucol, and quenched hydroxyl radicals in nonaqueous solution. Furthermore, Trolox showed a quenching effect on all active oxygen species in both aqueous and nonaqueous solution. The antioxidants were studied under comparable conditions in a series of test systems and the reactivity profiles depicted as ‘radar charts’ which are helpful for characterizing antioxidant action.     

Deamidation of the asparaginyl-glycyl sequence

The deamidation of Ac-Asn-Gly-NHMe and Ac-Isn-Gly-NHMe has been studied as a model for the facile deamidation of the Asn-Gly sequence in proteins. At alkaline pH, the product in each case is an identical mixture of Ac-alpha-Asp-Gly-NHMe (approximately 22%) and Ac-beta-Asp-Gly-NHMe (approximately 78%) as determined by n.m.r. spectroscopy. Because this same ratio is obtained from both Ac-Asn-Gly-NHMe and Ac-Isn-Gly-NHMe, the postulated mechanism, that deamidation proceeds through a cyclic imide intermediate, is confirmed. Unlike peptides of aspartyl esters, cyclization does not occur under nonaqueous conditions or at low pH in aqueous solution.     

Differential accumulation of dimethylallyl diphosphate in leaves and needles of isoprene- and methylbutenol-emitting and nonemitting species

The biosynthesis and emission of volatile plant terpenoids, such as isoprene and methylbutenol (MBO), depend on the chloroplastic production of dimethylallyl diphosphate (DMAPP). To date, it has been difficult to study the relationship of cellular DMAPP levels to emission of these volatiles because of the lack of a sensitive assay for DMAPP in plant tissues. Using a recent DMAPP assay developed in our laboratories, we report that species with the highest potential for isoprene and MBO production also exhibit elevated light-dependent DMAPP production, ranging from 110% to 1,063%. Even species that do not produce significant amounts of volatile terpenoids, however, exhibit some potential for light-dependent production of DMAPP. We used a nonaqueous fractionation technique to determine the intracellular distribution of DMAPP in isoprene-emitting cottonwood (Populus deltoides) leaves; approximately 65% to 70% of the DMAPP recovered at midday occurred in the chloroplasts, indicating that most of the light-dependent production of DMAPP was chloroplastic in origin. The midday concentration of chloroplastic DMAPP in cottonwood leaves is estimated to be 0.13 to 3.0 mM, which is consistent with the relatively high K(m)s that have been reported for isoprene synthases (0.5-8 mM). The results provide support for the hypothesis that the light dependence of isoprene and MBO emissions is in part due to controls over DMAPP production.     

Enzymes in organic media. Forms, functions and applications.

Enzyme catalysis in low water containing organic solvents is finding an increasing number of applications in diverse areas. This review focuses on some aspects which have not been reviewed elsewhere. Different strategies for obtaining higher activity and stability in such media are described. In this context, the damaging role of lyophilization and the means of overcoming such effects are discussed. Ultrasonication and microwave assistance are two emerging approaches for enhancing reaction rates in low water media. Control of water activity and medium engineering are two crucial approaches in optimization of catalytic behaviour in nonaqueous enzymology. Organometallics and synthesis/modification of polymers are two areas where nonaqueous enzymology can play a greater role in the coming years. The greater understanding of enzyme behaviour in nonaqueous media is expected to lead to larger and even more diverse kinds of applications.     

Urease-catalyzed urea synthesis.

The equilibrium of hydrolytic reactions can be shifted toward condensation by carrying out the reaction at low water concentration. The rate and yield of urease-catalyzed urea synthesis from (NH₄)₂CO₃ or NH₄HCO₃ has been examined as a function of water concentration (in mixtures with organic solvents), substrate and H⁺ concentration, and polarity of the nonaqueous component of the solvent. Similar effects of organic solvents are observed on the reaction rate in both directions; the results suggest that at least in some conditions the reaction proceeds through nonenzymically formed carbamate. The equilibrium concentration of urea, in 50% ($\text{v}\text{v}$) water, varies over 10-fold, depending on the nature of the nonaqueous component of the solvent; nonhydroxylic solvents such as acetone given the highest yield. Solubility measurements suggest that the interactions of the solvent mixtures with (NH₄)₂CO₃ (or carbamate), rather than urea, are responsible for the variations in urea yield. Activities of water and the ionic components of the equilibrium are strongly influenced by the nature of the nonaqueous component of the solvent, as well as its concentration.     

The closed/open model for lipase activation. Addressing intermediate active forms of fungal enzymes by trapping of conformers in water-restricted environments

The behavior of prototypic fungal lipases in a water-restricted environment has been investigated by exploiting the reported experimental strategy that allows the trapping (freeze-drying) of the enzyme in the conformation present in aqueous solution and to subsequently assay it in nonaqueous media [Mingarro, I., Abad, C., and Braco, L. (1995) Proc. Natl. Acad. Sci. U.S.A. 92, 3308-3312]. We now report, using simple esterification as well as acidolysis (triglycerides as substrates) as nonaqueous model reactions, that the presence of a detergent (n-octyl-beta-glucopyranoside) in the freeze-drying buffer, at concentrations below the critical micellar concentration, generates different catalytically active (kinetically trapped) conformational states of the enzyme. These activated forms exquisitely discriminate between short- and long-chain fatty acids, suggesting that they can be correlated with intermediate conformations of the protein sufficiently open to permit the access of relatively small but not large substrates. Additional data obtained from aqueous solution activity measurements in the presence of detergent revealed that the fungal lipase retains an active conformation induced by high detergent concentration (30 mM) for a long period of time, a 'memory effect', which is stabilized in the absence of a well-defined interface by few detergent molecules. Together these results provide support to a model of lipase action involving several equilibrium states (closed, intermediate, and open), which can be modulated by the composition of the microenvironment, i.e., by the detergent concentration.     

Investigation of the chemical basis of nitroalkane toxicity: tautomerism and decomposition of propane 1- and 2-nitronate under physiological conditions

Unlike primary nitroalkanes, such as 1-nitropropane, the secondary nitroalkane 2-nitropropane is geno- and hepatotoxic. Nitroalkanes exist in equilibrium with alkane nitronates. In order to investigate the relationship between nitroalkane toxicity and generation and stability of nitronates, propane 1- or 2-nitronate (4-6 mM) were incubated in buffer (pH 3.8 -7.4) in the absence or presence of cysteine. Equilibrium formation and degradation were studied by 1H-NMR spectroscopy and ion pair HPLC chromatography. Propane 1-nitronate generated 1-nitropropane rapidly and almost quantitatively. In the case of propane 2-nitronate equilibrium at pH 7.4 was reached within 8 h, when 48% of initial nitronate had tautomerised to 2-nitropropane. The pKa of the reaction 2-nitropropane less than--greater than propane 2-nitronate measured by HPLC was 7.63. Equilibrium formation, hydrolysis and reduction of nitronates were pH-dependent and, in the case of propane 2-nitronate, yielded mainly acetone, nitrite and acetone oxime, apart from 2-nitropropane. Hydrolysis of propane 2-nitronate (4 mM) to nitrite was modulated by cysteine (4 mM) and p-methoxyphenol (0.4 mM). At pH 7.4 they increased nitrite generation by 300 and 28%, respectively, at pH 4.8 they decreased nitrite formation by 91 and 82%, respectively, probably by scavenging radical intermediates. Differences between nitroalkanes in terms of content of nitronate tautomer at equilibrium are probably an important chemical determinant of their toxic potential.     

A three-dimensional solubility parameter approach to nonaqueous enzymology

Widespread commercial application of enzymes as catalysts for specialty or commodity chemical synthesis will require their use in nonaqueous systems. While a number of non-aqueous enzyme applications have been demonstrated, the lack of useful rules for predicting enzyme-solvent interactions has hindered the development of this technology. Both Hildebrand and solvent hydrophobicity (octanol-water partition coefficient) parameters have been used previously to correlate and predict enzyme activity in nonaqueous systems, with some success, but any single-parameter approach is inherently limited in its ability to reflect the spectrum of possible enzyme-solvent interactions. Therefore, this study evaluates the three-dimensional solubility parameter space, as proposed by Hansen, to correlate and predict enzyme activity in microaqueous, miscible, and biphasic nonaqueous systems. Preliminary results suggest that Hansen parameters may be useful for correlating nonaqueous enzyme activity, and that the dispersive and polar parameters may be disproportionately important in single-phase microaqueous systems. The Hansen hydrogen-bonding parameter appears to be the only parameter yet evaluated capable of correlating the water requirement for enzyme activity in microaqueous systems, suggesting that water affects protein structure through enthalpic rather than entropic processes in nonaqueous systems. Insufficient data are available for miscible and biphasic systems, but it is proposed that enzyme activity may correlate with the average solubility parameters of miscible systems and of the aqueous phase in biphasic systems.     

Effect of Aqueous and Nonaqueous Fixatives on the Quantitative Estimation of Collagen-Proteoglycan Interaction in Tissue Sections

The present study was designed to assess the influence of aqueous and nonaqueous fixatives on the quantitative estimation of collagen-proteoglycan interaction in tissue sections. Tissues containing different collagen types and distinct sulfated proteoglycan classes were isolated from pig costal cartilage, human skin, and the inner muscular layer of dog small intestine and fixed using aqueous or nonaqueous methods. The results showed that the best fixation method was exposure to paraformaldehyde gas. When using aqueous fixatives, proteoglycans were lost to different degrees among the various tissues analyzed, reflecting differences in chemical properties of proteoglycan classes and/or in their interactions with other matrix components such as collagen.     

Asparagusate dehydrogenases and lipoyl dehydrogenase from asparagus mitochondria. Physical, chemical, and enzymatic properties.

Asparagusate dehydrogenases I and II and lipoyl dehydrogenase have been obtained in homogeneous state from asparagus mitochondria. They are flavin enzymes with 1 mol of FAD/mol of protein. Asparagusate dehydrogenases I and II and lipoyl dehydrogenase have s20,w of 6.22 S, 6.39 S, and 5.91 S, respectively, and molecular weights of 111,000, 110,000, and 95,000 (sedimentation equilibrium) or 112,000, 112,000, and 92,000 (gel filtration). They are slightly acidic proteins with isoelectric points of 6.75, 5.75, and 6.80. Both asparagusate dehydrogenases catalyzed the reaction Asg(SH)2 + NAD+ equilibrium AsgS2 + NADH + H+ and exhibit lipoyl dehydrogenase and diaphorase activities. Lipoyl dehydrogenase is specific for lipoate and has no asparagusate dehydrogenase activity. NADP cannot replace NAD in any case. Optimum pH for substrate reduction of the three enzymes are near 5.9. Asparagusate dehydrogenases I and II have Km values of 21.5 mM and 20.0 mM for asparagusate and 3.0 mM and 3.3 mM for lipoate, respectively. Lipoyl dehydrogenase activity of asparagusate dehydrogenases is enhanced by NAD and surfactants such as lecithin and Tween 80, but asparagusate dehydrogenase activity is not enhanced. Asparagusate dehydrogenases are strongly inhibited by mercuric ion, p-chloromercuribenzoic acid, and N-ethylmaleimide. Amino acid composition of the three enzymes is presented and discussed.     

Effect of K+- and kainate-mediated depolarization on survival and functional maturation of GABAergic and glutamatergic neurons in cultures of dissociated mouse cerebellum

The effect of the depolarizing agents, an elevated potassium concentration (25 mM) or kainic acid (50 μM) on neuronal survival and differentiation was investigated in cultures of dissociated neurons from cerebella of 7-day-old mice. When maintained in the presence of an antimitotic agent such cultures consist primarily of glutamatergic and GABAergic neurons. Cell survival was monitored by measurement of DNA, and differentiation by determining uptake and depolarization coupled release of glutamate (D-aspartate as label) and GABA. The depolarizing agents were added separately or together either from the start of the culture period (7–8 days) or at day 5 in culture. The main findings are that K⁺ depolarization is important for differentiation of glutamatergic neurons but not for GABAergic neurons. This depolarizing signal is important during the early phase of development in culture. For glutamatergic neurons, kainate may replace K⁺ as a depolarizing signal whereas in case of the GABAergic neurons, kainate was toxic particularly during the late phase of development. It was further observed that the glutamatergic neurons when maintained in a medium with 5 mM K⁺ during the first 5 days in culture became sensitive to kainate toxicity when this amino acid was added at day 5. This was not the case when the medium contained 25 mM K⁺ from the start of the culture period. Special issue dedicated to Dr. Kinya Kuriyama.     

Identification of glucose response proteins in two biological models of beta-cell adaptation to chronic high glucose exposure.

High resolution 2-dimensional sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) combined with computerized analysis of gel images was used to search for proteins whose biosynthesis was induced or repressed in pancreatic islet cells chronically exposed to high glucose in an in situ and a tissue culture model of islet cell adaptation to excessive fuel load. The in situ model involved a 4-day intravenous infusion of either 50% glucose or 0.45% saline solution, followed by islet isolation, [35S]methionine labeling at 3 and 18 mM glucose for both groups, and protein analysis by 2-dimensional SDS-PAGE. The tissue culture model involved a 7-day culture of isolated rat islets in RPMI 1640 with 10% fetal calf serum containing either 3 or 30 mM glucose, followed by radiolabeling and 2-dimensional PAGE of proteins as in the in situ model. A small fraction of about 1.5% of the approximately 2000 identifiable proteins can be characterized as adaptive proteins. Of these altogether 58 proteins in the two models, 5 proteins were demonstrable in both models and two of these (proteins 1526 and 7622) are particularly noteworthy. Protein 1526 (Mr 57,000; pI 5.09) showed the same response pattern in both models and its expression was most enhanced when islets from chronically glucose-infused animals or those cultured for 7 days at 30 mM were radiolabeled at 18 mM glucose. Protein 7622 (Mr 68,000; pI 6.50) (also known as GSP-65; Collins, H.W., Buettger, C., and Matschinsky, F.M. (1990) Proc. Natl. Acad. Sci. U.S.A. 87, 5494-5498) showed a different labeling pattern in the two models: stimulation of [35S]methionine incorporation by 18 mM glucose both in control and experimental islets from the infusion study, but lack of such stimulation of radiolabeling in islets cultured for 7 days at 30 mM glucose in contrast to islets cultured at 3 mM. The experimental strategy and the methodology are evaluated and the significance of the results is discussed. Potentials of the approach and plans for future experiments are considered.     

Factors affecting L-malate activation of mitochondrial malate dehydrogenase from chicken liver

Mitochondrial malate dehydrogenase is activated by high concentrations of L-malate. In this paper, several factors affecting this activation on chicken liver enzyme have been investigated. The results obtained show clearly that this phenomenon is an intrinsic property of this enzyme since it does not depend on pH or ionic strength of the reaction medium. However, L-malate activation decreases when NAD+ concentration diminishes (5mM----0.2 mM) in such a way that when NAD+ concentration is 0.2 mM, L-malate does not activate mitochondrial malate dehydrogenase. On the other hand, several activators of this enzymatic system, such as citrate or phosphate, also produce the elimination of this activation by L-malate; in this case, the phenomenon seems be due to a competitive binding to a regulatory site of the different metabolites implied.     

Study of the interaction of Na+,K+-ATPase protomers using the molecular target method

The radiation inactivation analysis of Na+, K+-ATPase, (EC 3.6.1.37) from two different sources was carried out using ATP, CTP, GTP and p-NPP as substrates. In the case of Na+, K+-ATPase from the bovine brain the relation between the logarithm of the residual activity and the radiation dose is strictly linear, which permits calculating 75-90 kDa (for 3 mM GTP and 10 mM p-NPP). Duck salt glands Na+, K+-ATPase reveals larger target sizes: 350 kDa for ATP hydrolysis in saturating concentrations and 145-190 kDa in the case of GTP and p-NPP or low concentration of ATP (30 microM). A conclusion is drawn that while hydrolyzing substrates with complex kinetics (ATP and CTP) the enzyme functions like oligomer. The interaction of nucleotide with substrate-binding site of low affinity induces the aggregation of monomers.     

Influence of glutathione on the reactivation of enzymes containing cysteine or cystine

Refolding of dimeric porcine cytosolic or mitochondrial malate dehydrogenases and of tetrameric pig heart and skeletal muscle lactate dehydrogenases (containing 5-7 cysteine residues), as well as reformation of the four cystine cross-bridges of bovine pancreatic ribonuclease, were studied in the presence of reduced and oxidized glutathione (GSH and GSSG). At the intracellular GSH level (5 mM) reduced ribonuclease can be reoxidized by 0.01-0.5 mM GSSG (pH 7.4) both at 20 degrees C and 37 degrees C. In this physiological range of GSSG concentrations and pH, the dehydrogenases show at least partial reactivation. With GSSG concentrations greater than 5 mM, reactivation is found to be completely inhibited for all the enzymes given. The results show that at the intracellular level of GSH and GSSG, thiol groups in reduced, unfolded ribonuclease are oxidized to form intramolecular cystine cross-bridges, while thiol groups of typical cysteine enzymes, such as lactate and malate dehydrogenase, remain in their reduced state during refolding. The rate of reactivation of lactate dehydrogenase (porcine muscle) is not affected by GSSG. In the case of ribonuclease, increasing concentrations of GSSG increase the rate of reactivation: At 20 degrees C, the halftime of the correct disulfide bond formation varies from approximately equal to 80 h in the presence of 0.01 mM GSSG to approximately equal to 10 h in the presence of 0.25 mM GSSG. A further increase in the rate of reactivation at higher GSSG concentrations is accompanied by a decrease in yield. Reactivation of ribonuclease is also observed at the low glutathione level found in blood plasma (5-25 microM GSH).     

Substitution of inosine for yeastolate in the culture medium forDrosophila cells

Summary The nutritional requirement ofDrosophila cells (GM₁ and GM₂) was studied. TC Yeastolate contained in the medium forDrosophila cell culture was found to be replaceable with adenosine or inosine without appreciable changes in the generation time of cells. The optimal concentration of either adenosine or inosine was 0.01 mM. Whereas adenosine manifested cell toxicity at concentrations higher than 0.1 mM, in the case of inosine, such an inhibitory effect was not observed up to and at the concentration of 1.0 mM. Further-more, the plating efficiency at cell densities as low as 2×10³ cells per cm² was raised from 0 to 10% by supplementing inosine (0.1 mM) for the TC Yeastolate. Therefore inosine is in practice more useful than adenosine. Experiments using radioactive nucleosides suggested that both adenosine and inosine were exclusively incorporated into RNA as adenosine-monophosphate.     

Partial release of AcPhe-Phe-tRNA from ribosomes during poly(U)-dependent poly(Phe) synthesis and the effects of chloramphenicol

Poly(U)-programmed 70S ribosomes can be shown to be 80% to 100% active in binding the peptidyl-tRNA analogue AcPhe-tRNA to their A or P sites, respectively. Despite this fact, only a fraction of such ribosomes primed with AcPhe-tRNA participate in poly(U)-directed poly(Phe) synthesis (up to 65%) at 14 mM Mg2+ and 160 mM NH4+. Here it is demonstrated that the apparently 'inactive' ribosomes (greater than or equal to 35%) are able to participate in peptide-bond formation, but lose their nascent peptidyl-tRNA at the stage of Ac(Phe)n-tRNA, with n greater than or equal to 2. The relative loss of early peptidyl-tRNAs is largely independent of the degree of initial saturation with AcPhe-tRNA and is observed in a poly(A) system as well. This observation resolves a current controversy concerning the active fraction of ribosomes. The loss of Ac(Phe)n-tRNA is reduced but still significant if more physiological conditions for Ac(Phe)n synthesis are applied (3 mM Mg2+, 150 mM NH4+, 2 mM spermidine, 0.05 mM spermine). Chloramphenicol (0.1 mM) blocks the puromycin reaction with AcPhe-tRNA as expected but, surprisingly, does not affect the puromycin reaction with Ac(Phe)2-tRNA nor peptide bond formation between AcPhe-tRNA and Phe-tRNA. The drug facilitates the release of Ac(Phe)2-4-tRNA from ribosomes at 14 mM Mg2+ while it hardly affects the overall synthesis of poly(Phe) or poly(Lys).