Form of aluminium for uptake and translocation in buckwheat (Fagopyrum esculentum Moench)

 The forms of Al for uptake by the roots and translocation from the root to the shoot were investigated in a buckwheat (Fagopyrum esculentum Moench, cv. Jianxi) that accumulates Al in its leaves. The Al concentration in the xylem sap was 15-fold higher in the plants exposed to AlCl₃ than in those exposed to an Al-oxalate (1:3) complex, suggesting that the roots take up Al in the ionic form. The Al concentration in the xylem sap was 4-fold higher than that in the external solution after a 1-h exposure to AlCl₃ solution and 10-fold higher after a 2-h exposure. The Al concentration in the xylem sap increased with increasing Al concentration in the external solution. The Al uptake was not affected by a respiratory inhibitor, hydroxylamine, but significantly inhibited by the addition of La. These results suggest that Al uptake by the root is a passive process, and La³⁺ competes for the binding sites for Al³⁺ on the plasma membrane. The form of Al in the xylem sap was identified by ²⁷Al-nuclear magnetic resonance analysis. The chemical shift of ²⁷Al in the xylem sap was around 10.9 ppm, which is consistent with that of the Al-citrate complex. Furthermore, the dominant organic acid in the xylem sap was citric acid, indicating that Al was translocated in the form of Al-citrate complex. Because Al is present as Al-oxalate (1:3) in the root, the present data show that ligand exchange from oxalate to citrate occurs before Al is released to xylem. Received: 10 December 1999 / Accepted: 3 February 2000     

Mechanism for the detoxification of aluminum in roots of tea plant (Camellia sinensis (L.) Kuntze)

To determine the mechanism of aluminum (Al) detoxification in the roots of tea plants (Camellia sinensis (L.) Kuntze), the amounts of Al and Al-chelating compounds (fluoride (F), organic acids and catechins) were measured and the chemical forms of Al in root cell extracts were identified by the application of 27Al-nuclear magnetic resonance (NMR) spectroscopy. Tea plants were cultivated in nutrient solutions containing 0, 4, 1.0 and 4.0 mM of Al at pH 4.2 for approximately 10 weeks. The levels of soluble Al, water-soluble oxalate and citrate, but not F, malate or catechins in young roots increased with an increase in the concentration of Al in the treatment solution. The 27Al NMR spectra of root tips and cell sap extracted from root tips that had been treated with Al were almost identical and had four signals, with two (11 and 16 ppm) apparently corresponding to the known chemical shifts of Al-oxalate complexes. In the spectra of cell sap, the resonances at 11 and 16 ppm increased with an increase in the Al contents. These results suggest that the levels of Al-oxalate complexes increased in response to an increase in the Al level, implying that oxalate is a key Al-chelating compound in the mechanism of Al detoxification in the tea root.     

Estimating the chemical compositions of soil solutions by obtaining saturation extracts or specific 1:2 by volume extracts

The aluminium tolerance of several tree species was studied in a cloud forest in Northern Venezuela, growing on a very acid soil and rich in soluble Al. The Al-accumulator species (>1000 ppm in leaves) were compared to non-accumulator ones in relation to total Al concentration in xylem sap, pH and Al concentration in vacuoles, and rhizosphere alkalinization capacity. The Al³⁺ concentration in the soil solution and the xylem sap were also measured. The results show that in the Al-accumulator plant Richeria grandis, xylem sap is relatively rich in Al and about 35% of it is present in ionic form. In the non-accumulator plant studied (Guapira olfersiana) there is no Al detectable in xylem sap. The pH of vacuolar sap of several Al-accumulator species studied was very acidic and ranged between 2.6–4.8, but the presence of Al in vacuoles was not correlated with the acidity of the vacuolar sap. Both Al-accumulator and non accumulator plants had the capacity to reduce acidity of the rhizosphere and increased the pH of the nutrient solution by one unit within the first 24 hours. Trees growing in natural, high acidity-high Al³⁺ environment show a series of tolerance mechanisms, such as deposition of Al in vacuoles, Al chelation and rhizosphere alkalinization. These partially ameliorate the toxic effects of this element, but they probably impose a high ecological cost in terms of photosynthate allocation and growth rate.     

Influence of aluminum and phosphorus on growth and xylem sap composition in Melastoma malabathricum L.

Melastoma (Melastoma malabathricum L.) is an aluminum-accumulating woody plant that accumulates more than 10 000 mg kg^–1 of aluminum (Al) in mature leaves. The influence of Al and phosphorus (P) applications on plant growth and xylem sap was examined in the present study in order to elucidate the interaction between Al-induced growth enhancement and P nutrition, and to determine the form of Al for translocation from roots to shoots. Although the Al application significantly increased the growth of Melastomaseedlings with the high P pre-treatment, and P concentrations in the leaves and Pi concentrations in the xylem sap regardless of the P pre-treatment, we could not come to the conclusion that a primary cause of the Al-induced growth enhancement in Melastoma is the stimulation of P uptake. The degree of Al-induced growth enhancement corresponded not with the P concentrations but with the Al concentrations in the plant tissue, suggesting that the Al-induced growth enhancement in Melastoma is primarily caused by Al itself in the plant tissue rather than by the stimulation of P uptake. Through the analysis of organic acids and Al in the xylem sap and plant tissue, the form of Al for translocation from roots to shoots was shown to be an Al-citrate complex that was transformed into Al-oxalate complex for Al storage in the leaves. In addition, the xylem sap of Melastoma seedlings grown in the absence of Al contained higher concentrations of malate. In the presence of Al, however, higher concentrations of citrate were found, indicating that Melastoma changes its organic acid metabolism in the presence or absence of Al; more specifically, it increases the synthesis of citrate.     

Form of Al changes with Al concentration in leaves of buckwheat

Buckwheat (Fagopyrum esculentum Moench. cv. Jianxi) is known as an Al-accumulating plant. The process leading to the accumulation of Al in the leaves was investigated, focusing on the chemical form of Al using 27Al-nuclear magnetic resonance. Leaves with different Al concentrations were prepared by growing buckwheat on a very acidic soil (Andosol) amended with or without CaCO3 (1 or 3 g x kg-1 soil). When the Al concentration of the leaves was lower, only one major signal was observed at a chemical shift of 16.1 ppm, which was assigned to an Al-oxalate complex at a 1:3 ratio. However, when the Al concentration of the leaves increased to a high level (e.g. 12 g Al kg-1), an additional signal at a chemical shift of 11.2 ppm was observed. This signal was assigned to an Al-citrate complex at a 1:1 ratio. In the leaf with a high Al concentration, both Al-oxalate (1:3) and Al-citrate (1:1) were detected in marginal and middle parts, while only Al-oxalate was detected in the basal part. The oxalate concentration did not differ very much between leaves with low and high Al concentrations at the same position, while citrate concentration significantly increased with increasing Al concentration when the oxalate/Al ratio became lower than 3.0. As the Al-citrate complex has been demonstrated to be the form of transport in the xylem, the results suggest that when internal oxalate is enough to form a complex with Al at a 3:1 ratio in the leaves with a low Al concentration, Al-citrate converts to Al-oxalate. However, this conversion does not occur in the leaves with a very high Al concentration, resulting in the coexistence of both Al-oxalate and Al-citrate complexes.     

A quantitative method to assess muscle tissue oxygenation in vivo by monitoring H nuclear magnetic resonance myoglobin resonances

A nuclear magnetic resonance (NMR) method was implemented to assess in vivo oxygenation levels by a quantitative determination of the ¹H NMR myoglobin (Mb) resonances. The proximal His-F8 N_δH at 70-90 ppm and Val-E11 γCH₃ resonance at -2.8 ppm, reflecting deoxygenated (deoxy-Mb) and oxygenated (met-Mb) states, were alternately recorded. The method was developed in vitro choosing a couple of NMR sequences that could each maximize the signal-to-noise ratio (SNR) while avoiding baseline rolling and suppressing the water signal. Two quantitative calibration methods were implemented for deoxy- and met-Mb samples (0.1-1 mM), respectively. The respective limit of detection (LOD) and limit of quantification (LOQ) were 0.015 and 0.05 mM for met-Mb and 0.013 and 0.042 mM for deoxy-Mb. Sequences and calibration curves were employed in vivo in Arenicola marina to obtain, for the first time, an accurate measurement of oxy- and deoxy-Mb actual concentrations. In Arenicola, the peaks at approximately 87 and -2.7 ppm, reflecting the deoxy- and oxy-Mb states, respectively, were alternately recorded during increasing hypoxia. The deoxy-Mb concentrations were obtained from the calibration curve. The oxy-Mb concentrations were calculated from the calibration of met-Mb because it was proved that oxy- and met-Mb gave the same NMR molar response. From oxy- and deoxy-Mb concentrations, the intracellular oxygen partial pressure (P_iO₂) trend was determined.     

Identification of the form of Cd in the leaves of a superior Cd-accumulating ecotype of Thlaspi caerulescens using 113Cd-NMR

Thlaspi caerulescens (Ganges ecotype) is a known Cd hyperaccumulator, however, the ligands which coordinate to Cd ions in the leaves have not been identified. In the present study, the chemical form of Cd was investigated by using ¹¹³Cd-nuclear magnetic resonance (NMR) spectroscopy. Plants were grown hydroponically with a highly enriched ¹¹³Cd stable isotope. Measurements of ¹¹³Cd-NMR with intact leaves showed a signal at the chemical shift of around –16 ppm. Crude leaf sap also gave a similar chemical shift. Purification by gel filtration (Sephadex G-10), followed by cationic and anionic exchange chromatography, showed that Cd occurred only in the anionic fraction, which gave the same chemical shift as intact leaves. Further purification of the anionic fraction, combined with ¹¹³Cd- and ¹H-NMR studies, revealed that only the fraction containing malate showed a chemical shift similar to the intact leaves. These results indicate that Cd was coordinated mainly with malate in the leaves of T. caerulescens. The malate concentration in the leaves was not affected by increasing Cd concentration in the solution, suggesting that malate synthesis is not induced by Cd. Because the Cd-malate complex is relatively weak, we suggest that the complex forms inside the vacuoles as a result of an efficient tonoplast transport of Cd and a constitutively high concentration of malate in the vacuoles, and that the formation of the Cd-malate complex may lead to a decrease of subsequent Cd efflux to the cytoplasm.     

High Aluminum Resistance in Buckwheat : II. Oxalic Acid Detoxifies Aluminum Internally

Buckwheat (Fagopyrum esculentum Moench. cv Jianxi), which shows high Al resistance, accumulates Al in the leaves. The internal detoxification mechanism was studied by purifying and identifying Al complexes in the leaves and roots. About 90% of Al accumulated in the leaves was found in the cell sap, in which the dominant organic acid was oxalic acid. Purification of the Al complex in the cell sap of leaves by molecular-sieve chromatography resulted in a complex with a ratio of Al to oxalic acid of 1:3. A ¹³C-nuclear magnetic resonance study of the purified cell sap revealed only one signal at a chemical shift 164.4 ppm, which was assigned to the Al-chelated carboxylic group of oxalic acid. A ²⁷Al-nuclear magnetic resonance analysis revealed one major signal at the chemical shift of 16.0 to 17.0 ppm, with a minor signal at the chemical shift of 11.0 to 12 ppm in both the intact roots and their cell sap, which is consistent with the Al-oxalate complexes at 1:3 and 1:2 ratios, respectively. The purified cell sap was not phytotoxic to root elongation in corn (Zea mays). All of these results indicate that Al tolerance in the roots and leaves of buckwheat is achieved by the formation of a nonphytotoxic Al-oxalate (1:3) complex.     

H2O2 reactivity of a dinuclear copper(II) complex incorporating a constrained binucleating polyaminopyridyl ligand and a phosphodiester coligand

A dinuclear copper(II) complex [Cu₂(PD)(DPP⁻)₂](ClO₄)₂ (1) incorporating a constrained binucleating hexadenate ligand, PD (1,3-bis{bis[(2-pyridyl)ethyl]amino}benzene), and coligand, DPP⁻ (diphenylphosphate) was synthesized and characterized, with a specific outlook towards evaluating spectroscopic and H₂O₂ reactivity relevant to the active-sites of noncoupled dinuclear copper enzymes, DβM and PHM. In solution, complex 1 exhibits a broad ¹H NMR in the range −25 to +60 ppm and has a solution magnetic moment (μ) of ∼2.0 B.M./Cu(II), typical of a noninteracting dicopper(II) center. The room temperature H₂O₂ reactivity of 1 monitored by UV-Vis spectroscopy reveals the formation of a copper(II)-dioxygen intermediate 1a, which in turn leading to a arene ligand hydroxylation (PD-O⁻) and thus provide a new doubly-bridged dicopper(II) complex, [Cu₂(PD-O⁻)(DPP⁻)](ClO₄)₂ (2). The dioxygen intermediate produces OPPh₃ on treatment with PPh₃ revealing it is an electrophilic hydroperoxide oxidant. Solution magnetic moment of 1.61 B.M./Cu(II) indicates the product complex 2 is a moderately interacting dicopper(II) center and its ¹H NMR spans between −20 and +180 ppm. A comparison of the optical absorption features of complex 1a with related dinuclear hydroperoxo-copper(II) complexes is discussed.     

Multinuclear NMR and molecular modelling investigations on the structure and equilibria of complexes that form in aqueous solutions of Ca and gluconate

Complexation of d-gluconate (Gluc⁻) with Ca²⁺ has been investigated via ¹H, ¹³C and ⁴³Ca NMR spectroscopy in aqueous solutions in the presence of high concentration background electrolytes (1 M ? I ? 4 M (NaCl) ionic strength). From the ionic strength dependence of its formation constant, the stability constant at 6 ? pH ? 11 and at I → 0 M has been derived (). The protonation constant of Gluc⁻ at I = 1 M (NaCl) ionic strength was also determined and was found to be log K_a = 3.24 ± 0.01 (¹³C NMR) and log K_a = 3.23 ± 0.01 (¹H NMR). It was found that ¹H and ¹³C NMR chemical shifts upon complexation (both with H⁺ and with Ca²⁺) do not vary in an unchanging way with the distance from the Ca²⁺/H⁺ binding site. From 2D ¹H-⁴³Ca NMR spectra, simultaneous binding of Ca²⁺ to the alcoholic OH on C2 and C3 was deduced. Molecular modelling results modulated this picture by revealing structures in which the Gluc⁻ behaves as a multidentate ligand. The five-membered chelated initial structure was found to be thermodynamically more stable than that derived from a six-membered chelated initial structure.     

Deuterium isotope effects in carbohydrates revisited. Cryoprobe studies of the anomerization and NH to ND deuterium isotope induced 13C NMR chemical shifts of acetamidodeoxy and aminodeoxy sugars

Complete ¹H and ¹³C NMR chemical shift assignments have been generated from a series of acetamidodeoxy and aminodeoxy sugar derivatives. For free sugars, the enhanced sensitivity of an NMR cryoprobe allowed simple 1D and 2D NMR spectra to be obtained from essentially single anomers, before significant mutarotation had occurred. The NMR assignments have been used to characterize deuterium isotope effects on ¹³C chemical shifts measured under conditions of slow NH to ND exchange in single solutions. Within a range of 0 to −0.138 ppm, β, γ, δ, and ζ deuterium isotope effects have been observed, thus providing additional reference data for assignment of the ¹³C NMR spectra of nitrogenous saccharides.     

Involvement of Long-Distance Na<Superscript>+</Superscript> Transport in Maintaining Water Potential Gradient in the Medium-Root-Leaf System of a Halophyte <Emphasis Type="Italic">Suaeda altissima</Emphasis>

The aim of this study was to determine the range of NaCl concentrations in the nutrient solution that allow Suaeda altissima (L.) Pall., a salt-accumulating halophyte, to maintain the upward gradient of water potential in the “medium-root-leaf” system. We evaluated the contribution of Na⁺ ions in the formation of water potential gradient and demonstrated that Na⁺ loading into the xylem is involved in this process. Plants were grown in water culture at NaCl concentrations ranging from zero to 1 M. The water potential of leaf and root cells was measured with the method of isopiestic thermocouple psychrometry. When NaCl concentration in the growth medium was raised in the range of 0–500 mM (the medium water potential was lowered accordingly), the root and leaf cells of S. altissima decreased their water potential, thus promoting the maintenance of the upward water potential gradient in the medium-root-leaf system. Growing S. altissima at NaCl concentrations f 750 mM and 1 M disordered water homeostasis and abolished the upward gradient of water potential between roots and leaves. At NaCl concentrations of 0–250 mM, the detached roots of S. altissima were capable of producing the xylem exudate. The concentration of Na⁺ in the exudate was 1.3 to 1.6 times higher than in the nutrient medium; the exudate pH was acidic and was lowered from 5.5 to 4.5 with the rise in the salt concentration. The results indicate that the long-distance Na⁺ transport and, especially, the mechanism of Na⁺ loading into the xylem play a substantial role in the formation of water potential gradient in S. altissima. The accumulation of Na⁺ in the xylem and acidic pH values of the xylem sap suggest that Na⁺ loading into the xylem is carried out by the Na⁺/H⁺ antiporter of the plasma membrane in parenchymal cells of the root stele.__________Translated from Fiziologiya Rastenii, Vol. 52, No. 4, 2005, pp. 549–557.Original Russian Text Copyright © 2005 by Balnokin, Kotov, Myasoedov, Khailova, Kurkova, Lun’kov, Kotova.     

Recovery of nitrogen fixation after short-term flooding of the nodulated root system of soybean

Nitrogen fixation of terrestrial legumes is strongly and rapidly diminished under flooding. Although recovery is possible with the formation of aerenchyma, information is scarce regarding recovery after draining following short-term flooding, before the appearance of morphological adaptations. This study used soybean (Glycine max) plants nodulated with Bradyrhizobium elkanii to determine xylem sap glutamine as an indication of nitrogen fixation activity during recovery from different periods of flooding. Xylem glutamine levels showed rapid recovery (within 90 min) following periods of flooding up to 4 h. Recovery was progressively slower after longer periods of flooding. After 48 h flooding very little recovery could be observed within the first 120 min after draining but recovery was possible within 48 h. Consistent with the changes in xylem glutamine, direct measurements of apparent nitrogenase activity carried out immediately on draining revealed rapid recovery after flooding for 1 h and slow recovery following 48 h of flooding. In the latter case, nitrogenase activity largely recovered 24 h after draining. Experiments with ¹⁵N₂ incorporation into amino acids exported in the xylem sap revealed that glutamine was by far the most highly labelled amino acid in sap collected over the first 30 min of exposure to the isotope. This is conclusive evidence that xylem sap glutamine is an immediate product of N₂ fixation and export. The changes in xylem sap glutamine seen on flooding (decline) and after draining (recovery) can therefore be attributed to changes in nitrogenase activity. The data show that xylem sap glutamine is a useful means for assessing changes in nitrogenase activity, especially when the root system is submersed in water and activity cannot be measured directly.     

Proteomic analysis of hybrid poplar xylem sap

Xylem sap collected from Populus trichocarpa × Populus deltoides using root pressure was estimated to contain more than 100 proteins. Ninety-seven of these proteins were identified using liquid chromatography-tandem mass spectrometry (LC-MS/MS). These proteins were classified into 10 functional categories including metabolism, signaling, stress response and cell wall functions. The majority of xylem sap proteins were metabolic enzymes involved in processes including translation, proteolysis, and glycolysis. Stress-related proteins were also prevalent. In contrast to xylem sap proteins collected from annual plants, the majority of poplar xylem sap proteins do not appear to be classically secreted since only 33 proteins were predicted to have an N-terminal signal peptide targeting them to the secretory pathway. Of the remaining 64 proteins, 27 were predicted to be secreted non-classically. While a number of proteins identified here have been previously reported in xylem sap proteomes of annual plants, many xylem sap proteins were identified in poplar which may reflect functions specific to perennial plants.     

Nickel speciation in the xylem sap of the hyperaccumulator Alyssum serpyllifolium ssp. lusitanicum growing on serpentine soils of northeast Portugal

Nickel speciation was studied in the xylem sap of Alyssum serpyllifolium ssp. lusitanicum, a Ni-hyperaccumulator endemic to the serpentine soils of northeast Portugal. The xylem sap was collected from plants growing in its native habitat and characterized in terms of carboxylic and amino acids content. The speciation of nickel was studied in model and real solutions of xylem sap by voltammetric titrations using Square Wave Voltammetry (SWV). The results showed that Ni transport in the xylem sap occurs mainly as a free hydrated cation (about 70%) and complexed with carboxylic acids, mainly citric acid (18%). Altogether, oxalic acid, malic acid, malonic acid and aspartic acid complexed less than 13% of total Ni. A negligible amount bounded to the amino acids, like glutamic acid and glutamine (<1%). Histidine did not play a role in Ni translocation in the xylem sap of A. serpyllifolium under field conditions. Amino acids are one of the main forms of N transport in the xylem sap, and under field conditions, N is usually a limited nutrient. We hypothesize that the translocation of Ni in the xylem sap as a free ion or chelated with carboxylic acids is ‘cheaper’ in terms of N resources.     

Nitrilotris(methylenephosphonates) in aqueous solution and solid state - dilatometric, potentiometric and NMR investigations

Dissociation and alkali complex formation equilibria of nitrilotris(methylenephosphonic acid) (NTMP, H₆L) have been studied by dilatometric, potentiometric and ³¹P NMR-controlled titrations. Dilatometry indicated the formation of alkali complexes ML (M=Li, Na, K, Rb, Cs) at high pH with a stability decreasing from Li to Cs. An efficient combination of potentiometric and NMR methods confirmed two types of alkali metal complexes MHL and ML. Stability constants for the equilibria following M⁺ + HL⁵⁻ ? MHL⁴⁻ and M⁺ + L⁶⁻ ? ML⁵⁻, respectively, were determined: logK_NaHL=1.08(0.07), logK_KHL=0.86(0.08), logK_NaL=2.24(0.03). Systematic errors are introduced by using alkali metal hydroxides as titrants for routine potentiometric determinations of dissociation constants pK_a5^app and pK_a6^app. Correction formulae were derived to convert actual dissociation constants pK_a into apparent dissociation constants pK_a^app (or vice versa). The actual dissociation constants were found: pK_a5(H₂L⁴⁻ ? H⁺ + HL⁵⁻)=7.47(0.03) and pK_a6(HL⁵⁻ ? H⁺ + L⁶⁻)=14.1(0.1). The anisotropy of ³¹P chemical shifts of salts M_nH_6 − nL (M=Li, Na, n=0-5) is more sensitive towards titration (n) than isotropic solution state chemical shifts.     

C, N CP MAS and high resolution multinuclear NMR study of methyl

Fluorine atoms are often incorporated into drug molecules as part of the lead optimization process in order to improve affinity or modify undesirable metabolic and pharmacokinetic profiles. From an NMR perspective, the abundance of fluorinated drug leads provides an exploitable niche for structural studies using ¹⁹F NMR in the drug discovery process. As ¹⁹F has no interfering background signal from biological sources, ¹⁹F NMR studies of fluorinated drugs bound to their protein receptors can yield easily interpretable and unambiguous structural constraints. ¹⁹F can also be selectively incorporated into proteins to obtain additional constraints for structural studies. Despite these advantages, ¹⁹F NMR has rarely been exploited for structural studies due to its broad lines in macromolecules and their ligand complexes, leading to weak signals in ¹H/¹⁹F heteronuclear NOE experiments. Here we demonstrate several different experimental strategies that use ¹⁹F NMR to obtain ligand–protein structural constraints for ligands bound to the anti-apoptotic protein Bcl-xL, a drug target for anti-cancer therapy. These examples indicate the applicability of these methods to typical structural problems encountered in the drug development process.     

Structural Studies of Bcl-xL/ligand Complexes using 19F NMR

Fluorine atoms are often incorporated into drug molecules as part of the lead optimization process in order to improve affinity or modify undesirable metabolic and pharmacokinetic profiles. From an NMR perspective, the abundance of fluorinated drug leads provides an exploitable niche for structural studies using ¹⁹F NMR in the drug discovery process. As ¹⁹F has no interfering background signal from biological sources, ¹⁹F NMR studies of fluorinated drugs bound to their protein receptors can yield easily interpretable and unambiguous structural constraints. ¹⁹F can also be selectively incorporated into proteins to obtain additional constraints for structural studies. Despite these advantages, ¹⁹F NMR has rarely been exploited for structural studies due to its broad lines in macromolecules and their ligand complexes, leading to weak signals in ¹H/¹⁹F heteronuclear NOE experiments. Here we demonstrate several different experimental strategies that use ¹⁹F NMR to obtain ligand–protein structural constraints for ligands bound to the anti-apoptotic protein Bcl-xL, a drug target for anti-cancer therapy. These examples indicate the applicability of these methods to typical structural problems encountered in the drug development process.     

pH-responsive switching of near-infrared absorption of a diradical complex of Pt and 3,4-diaminobenzoate formed in aqueous solutions

In alkaline aqueous solutions, 3,4-diaminobenzoate (H₂(²L^PDA)⁻) reacts with Pt^II to form a 1:2 (Pt:L) complex that intensely absorbs near-infrared (NIR) light at 713 nm (ε = 8.0 × 10⁴ M⁻¹ cm⁻¹). The absorption disappeared at pH < 3 (in DMSO), showing pH-responsive switching of the NIR absorption. By comparing the NIR-absorbing behavior of this complex to that of a complex, [Pt^II(¹L^ISQ)₂]²⁻, containing the analogous phenylenediamine ligand [(¹L^ISQ)²⁻ = o-diiminobenzosemiquinonate radical], the complex can be formulated as [Pt^II(²L^ISQ)₂]²⁻. The assignment of the entity was consistent with the redox and spectroelectrochemical behaviors and electronic spin resonance (ESR) spectroscopy. First, one-electron oxidation of [Pt^II(²L^ISQ)₂]²⁻ formed an ESR-silent complex assignable to the dimeric complex [{Pt^II(²L^ISQ)(²L^IBQ)}₂]²⁻ [(²L^IBQ) = o-iminobenzoquinone form] in which the two radical centers at were antiferromagnetically coupled. Second, the one-electron reduced complex of [Pt^II(²L^ISQ)₂]²⁻ exhibited an ESR signal attributed to [Pt^II(²L^ISQ)(²L^PDA)]³⁻; 34% of the electronic spin was located at the Pt^II center rather than on the moiety. The pH-responsive switching-off of the NIR absorption was thus rationally explained by oxidation of [Pt^II(²L^ISQ)₂]²⁻ to [{Pt^II(²L^ISQ)(²L^IBQ)}₂]²⁻ by the increase of the rest potential of the solution in the lower pH region.     

Facile pyramidal inversion at phosphorus in [R3EP7W(CO)3] type complexes: An EXSY NMR study

A series of [R₃EP₇W(CO)₃]²⁻ complexes where (E = Si, Ge, Sn, Pb; R = alkyl, phenyl) were prepared from [P₇W(CO)₃]³⁻ and R₃EX reagents (X = Cl, Br) in dmf or CH₃CN solutions. The Pb derivatives were prepared at −50 °C and are not thermally stable. The compounds were characterized by ³¹P NMR spectroscopy and selected ESI-MS studies. All compounds undergo rapid inversion at the ER₃-bound phosphorus atom. The barriers to inversion were measured by way of 2D ³¹P EXSY experiments at various temperatures. The analysis showed very low barriers to pyramidal inversion (ΔG^‡ 10.3-13.5 kcal/mol) that were essentially enthalpic in origin. The activation barriers generally increased with increasing electronegativity of the E atom and the steric bulk of the ER₃ substituents. The latter was interpreted by way of a non-linear transition state.