Ion‐specific modulation of protein interactions: Anion‐induced,reversible oligomerization of a fusion protein

Ions can significantly modulate the solution interactions of proteins. We aim to demonstrate that the salt-dependent reversible heptamerization of a fusion protein called peptibody A or PbA is governed by anion-specific interactions with key arginyl and lysyl residues on its peptide arms. Peptibody A, an E. coli expressed, basic (pI = 8.8), homodimer (65.2 kDa), consisted of an IgG1-Fc with two, C-terminal peptide arms linked via penta-glycine linkers. Each peptide arm was composed of two, tandem, active sequences (SEYQGLPPQGWK) separated by a spacer (GSGSATGGSGGGASSGSGSATG). PbA was monomeric in 10 mM acetate, pH 5.0 but exhibited reversible self-association upon salt addition. The sedimentation coefficient (s_w) and hydrodynamic diameter (D_H) versus PbA concentration isotherms in the presence of 140 mM NaCl (A5N) displayed sharp increases in s_w and D_H, reaching plateau values of 9 s and 16 nm by 10 mg/mL PbA. The D_H and sedimentation equilibrium data in the plateau region (>12 mg/mL) indicated the oligomeric ensemble to be monodisperse (PdI = 0.05) with a z-average molecular weight (M_z) of 433 kDa (stoichiometry = 7). There was no evidence of reversible self-association for an IgG1-Fc molecule in A5N by itself or in a mixture containing fluorescently labeled IgG1-Fc and PbA, indicative of PbA self-assembly being mediated through its peptide arms. Self-association increased with pH, NaCl concentration, and anion size (I⁻ > Br⁻ > Cl⁻ > F⁻) but could be inhibited using soluble Trp-, Phe-, and Leu-amide salts (Trp > Phe > Leu). We propose that in the presence of salt (i) anion binding renders PbA self-association competent by neutralizing the peptidyl arginyl and lysyl amines, (ii) self-association occurs via aromatic and hydrophobic interactions between the..xx..xxx..xx.. motifs, and (iii) at >10 mg/mL, PbA predominantly exists as heptameric clusters.     

Potential-dependent anion transport in tonoplast vesicles from oat roots

Potential-dependent anion movement into tonoplast vesicles from oat roots (Avena sativa L. var Lang) was monitored as dissipation of membrane potentials (Δψ) using the fluorescence probe Oxonol V. The potentials (positive inside) were generated with the H⁺-pumping pyrophosphatase, which is K⁺ stimulated and anion insensitive. The relative rate of ΔΨ dissipation by anions was used to estimate the relative permeabilities of the anions. In decreasing order they were: SCN⁻ (100) > NO₃⁻ (72) = Cl⁻ (70) > Br⁻ (62) > SO₄²⁻ (5) = H₂PO₄⁻ (5) > malate (3) = acetate (3) > iminodiacetate (2). Kinetic studies showed that the rate of Δψ dissipation by Cl⁻ and NO₃⁻, but not by SCN⁻, was saturable. The K_m values for Cl⁻ and NO₃⁻ uptake were about 2.3 and 5 millimolar, respectively, suggesting these anions move into the vacuole through proteinaceous porters. In contrast to a H⁺-coupled Cl⁻ transporter on the same vesicles, the potential-dependent Cl⁻ transport was insensitive to 4,4′-diisothiocyano-2,2′-stilbene disulfonate. These results suggest the existence of at least two different mechanisms for Cl⁻ transport in these vesicles. The potentials generated by the H⁺-translocating ATPase and H⁺-pyrophosphatase were nonadditive, giving support to the model that both pumps are on tonoplast vesicles. No evidence for a putative Cl⁻ conductance on the anion-sensitive H⁺-ATPase was found.     

The Effect of Ionic Strength and Specific Anions on Substrate Binding and Hydrolytic Activities of Na,K-ATPase

The physiological ligands for Na,K-ATPase (the Na,K-pump) are ions, and electrostatic forces, that could be revealed by their ionic strength dependence, are therefore expected to be important for their reaction with the enzyme. We found that the affinities for ADP³⁻, eosin²⁻, p-nitrophenylphosphate, and V_max for Na,K-ATPase and K⁺-activated p-nitrophenylphosphatase activity, were all decreased by increasing salt concentration and by specific anions. Equilibrium binding of ADP was measured at 0–0.5 M of NaCl, Na₂SO₄, and NaNO₃ and in 0.1 M Na-acetate, NaSCN, and NaClO₄. The apparent affinity for ADP decreased up to 30 times. At equal ionic strength, I, the ranking of the salt effect was NaCl ≈ Na₂SO₄ ≈ Na-acetate < NaNO₃ < NaSCN < NaClO₄. We treated the influence of NaCl and Na₂SO₄ on K _diss for E·ADP as a “pure” ionic strength effect. It is quantitatively simulated by a model where the binding site and ADP are point charges, and where their activity coefficients are related to I by the limiting law of Debye and Hückel. The estimated net charge at the binding site of the enzyme was about +1. Eosin binding followed the same model. The NO₃ ⁻ effect was compatible with competitive binding of NO₃ ⁻ and ADP in addition to the general I-effect. K _diss for E·NO₃ was ∼32 mM. Analysis of V_max/K _m for Na,K-ATPase and K⁺-p-nitrophenylphosphatase activity shows that electrostatic forces are important for the binding of p-nitrophenylphosphate but not for the catalytic effect of ATP on the low affinity site. The net charge at the p-nitrophenylphosphate-binding site was also about +1. The results reported here indicate that the reversible interactions between ions and Na,K-ATPase can be grouped according to either simple Debye-Hückel behavior or to specific anion or cation interactions with the enzyme.     

The Disastrous Effects of Salt Dust Deposition on Cotton Leaf Photosynthesis and the Cell Physiological Properties in the Ebinur Basin in Northwest China

Salt dust in rump lake areas in arid regions has long been considered an extreme stressor for both native plants and crops. In recent years, research on the harmful effects of salt dust on native plants has been published by many scholars, but the effect on crops has been little studied. In this work, in order to determine the impact of salt dust storms on cotton, we simulated salt dust exposure of cotton leaves in Ebinur Basin in Northwest China, and measured the particle sizes and salt ions in the dust, and the photosynthesis, the structure and the cell physiological properties of the cotton leaves. (1) Analysis found that the salt ions and particle sizes in the salt dust used in the experiments were consistent with the natural salt dust and modeled the salt dust deposition on cotton leaves in this region. (2) The main salt cations on the surface and inside the cotton leaves were Na⁺, Ca²⁺, Cl^- and SO₄^2-, while the amounts of CO₃^- and HCO₃^- were low. From the analysis, we can order the quantity of the salt cations and anions ions present on the surface and inside the cotton leaves as Na⁺>Ca²⁺>Mg²⁺>K⁺ and Cl^->SO₄^2->HCO₃^->CO₃^-, respectively. Furthermore, the five salt dust treatment groups in terms of the total salt ions on both the surface and inside the cotton leaves were A(500g.m^-2)>B(400g.m^-2)>C(300g.m^-2)>D(200g.m^-2)>E(100g.m^-2)>F(0g.m^-2). (3)The salt dust that landed on the surface of the cotton leaves can significantly influence the photosynthetic traits of P_n, PE, C_i, T_i, G_s, T_r, WUE, L_s, φ, A_max, k and R_ady of the cotton leaves. (4)Salt dust can significantly damage the physiological functions of the cotton leaves, resulting in a decrease in leaf chlorophyll and carotenoid content, and increasing cytoplasmic membrane permeability and malondialdehyde (MDA) content by increasing the soluble sugar and proline to adjust for the loss of the cell cytosol. This increases the activity of antioxidant enzymes to eliminate harmful materials, such as the intracellular reactive oxygen and MDA, thus reducing the damage caused by the salt dust and maintaining normal physiological functioning. Overall, this work found that the salt dust deposition was a problem for the crop and the salt dust could significantly influence the physiological and biochemical processes of the cotton leaves. This will eventually damage the leaves and reduce the cotton production, leading to agricultural economic loss. Therefore, attention should be paid to salt dust storms in the Ebinur Basin and efficient measures should be undertaken to protect the environment.     

Anion conductance of frog muscle membranes: one channel, two kinds of pH dependence

Anion conductance and permeability sequences were obtained for frog skeletal muscle membranes from the changes in characteristic resistance and transmembrane potential after the replacement of one anion by another in the bathing solution. Permeability and conductance sequences are the same. The conductance sequence at pH = 7.4 is Cl^- Br^- > NO₃ ^- > I^- > trichloroacetate ≥ benzoate > valerate > butyrate > proprionate > formate > acetate ≥ lactate > benzenesulfonate ≥ isethionate > methylsulfonate > glutamate ≥ cysteate. The anions are divided into two classes: (a) Chloride-like anions (Cl^- through trichloroacetate) have membrane conductances that decrease as pH decreases. The last six members of the complete sequence are also chloride like. (b) Benzoate-like anions (benzoate through acetate) have conductances that increase as pH decreases. At pH = 6.7 zinc ions block Cl^- and benzoate conductances with inhibitory dissociation constants of 0.12 and 0.16 mM, respectively. Chloride-like and benzoate-like anions probably use the same channels. The minimum size of the channel aperture is estimated as 5.5 x 6.5 Å from the dimensions of the largest permeating anions. A simple model of the channel qualitatively explains chloride-like and benzoate-like conductance sequences and their dependence on pH.     

Characterization of nigericin-stimulated ATPase from sealed microsomal vesicles of tobacco callus

To understand the function and membrane origin of ionophore-stimulated ATPases, the activity of nigericin-stimulated ATPase was characterized from a low-density microsomal fraction containing sealed vesicles of autonomous tobacco (Nicotiana tabacum Linnaeous cv. Wisconsin no. 38) callus. The properties of KCl-stimulated, Mg-requiring ATPases (KCl-Mg,ATPase) were similar in the absence or presence of nigericin. Nigericin (or gramicidin) stimulation of a KCl-Mg,ATPase activity was optimum at pH 6.5 to 7.0. The enzyme was inhibited completely by N,N′-dicyclohexylcarbodiimide (10 μm), tributyltin (5 μm), and partially by vanadate (200 μm), but it was insensitive to fusicoccin and mitochondrial ATPase inhibitors, such as azide (1 mm) and oligomycin (5 μg/ml). The ATPase was more sensitive to anions than cations. Cations stimulated ATPase activity with a selectivity sequence of NH₄⁺ > K⁺, Rb⁺, Cs⁺, Na⁺, Li⁺ > Tris⁺. Anions stimulated Mg, ATPase activity with a decreasing sequence of Cl⁻ = acetate > SO₄²⁻ > benzene sulfonate > NO₃⁻. The anion stimulation was caused partly by dissipation of the electrical potential (interior positive) by permeant anions and partly by a specific ionic effect. Plant membranes had at least two classes of nigericin-stimulated ATPases: one sensitive and one insensitive to vanadate. Many of the properties of the nigericin-sensitive, salt-stimulated Mg,ATPase were similar to a vanadate-sensitive plasma membrane ATPase of plant tissues, yet other properties (anion stimulation and vanadate insensitivity) resembled those of a tonoplast ATPase. These results support the idea that nigericin-stimulated ATPases are mainly electrogenic H⁺ pumps originated in part from the plasma membrane and in part from other nonmitochondrial membranes, such as the tonoplast.     

Permeation and Block of the Skeletal Muscle Chloride Channel,ClC-1, by Foreign Anions

A distinctive feature of the voltage-dependent chloride channels ClC-0 (the Torpedo electroplaque chloride channel) and ClC-1 (the major skeletal muscle chloride channel) is that chloride acts as a ligand to its own channel, regulating channel opening and so controlling the permeation of its own species. We have now studied the permeation of a number of foreign anions through ClC-1 using voltage-clamp techniques on Xenopus oocytes and Sf9 cells expressing human (hClC-1) or rat (rClC-1) isoforms, respectively. From their effect on channel gating, the anions presented in this paper can be divided into three groups: impermeant or poorly permeant anions that can not replace Cl⁻ as a channel opener and do not block the channel appreciably (glutamate, gluconate, HCO₃ ⁻, BrO₃ ⁻); impermeant anions that can open the channel and show significant block (methanesulfonate, cyclamate); and permeant anions that replace Cl⁻ at the regulatory binding site but impair Cl⁻ passage through the channel pore (Br⁻, NO₃ ⁻, ClO₃ ⁻, I⁻, ClO₄ ⁻, SCN⁻). The permeability sequence for rClC-1, SCN⁻ ∼ ClO₄ ⁻ > Cl⁻ > Br⁻ > NO₃ ⁻ ∼ ClO₃ ⁻ > I⁻ >> BrO₃ ⁻ > HCO₃ ⁻ >> methanesulfonate ∼ cyclamate ∼ glutamate, was different from the sequence determined for blocking potency and ability to shift the P _open curve, SCN⁻ ∼ ClO₄ ⁻ > I⁻ > NO₃ ⁻ ∼ ClO₃ ⁻ ∼ methanesulfonate > Br⁻ > cyclamate > BrO₃ ⁻ > HCO₃ ⁻ > glutamate, implying that the regulatory binding site that opens the channel is different from the selectivity center and situated closer to the external side. Channel block by foreign anions is voltage dependent and can be entirely accounted for by reduction in single channel conductance. Minimum pore diameter was estimated to be ∼4.5 Å. Anomalous mole-fraction effects found for permeability ratios and conductance in mixtures of Cl⁻ and SCN⁻ or ClO₄ ⁻ suggest a multi-ion pore. Hydrophobic interactions with the wall of the channel pore may explain discrepancies between the measured permeabilities of some anions and their size.     

Interactions between permeation and gating in the TMEM16B/anoctamin2 calcium-activated chloride channel

At least two members of the TMEM16/anoctamin family, TMEM16A (also known as anoctamin1) and TMEM16B (also known as anoctamin2), encode Ca²⁺-activated Cl⁻ channels (CaCCs), which are found in various cell types and mediate numerous physiological functions. Here, we used whole-cell and excised inside-out patch-clamp to investigate the relationship between anion permeation and gating, two processes typically viewed as independent, in TMEM16B expressed in HEK 293T cells. The permeability ratio sequence determined by substituting Cl⁻ with other anions (P_X/P_Cl) was SCN⁻ > I⁻ > NO₃⁻ > Br⁻ > Cl⁻ > F⁻ > gluconate. When external Cl⁻ was substituted with other anions, TMEM16B activation and deactivation kinetics at 0.5 µM Ca²⁺ were modified according to the sequence of permeability ratios, with anions more permeant than Cl⁻ slowing both activation and deactivation and anions less permeant than Cl⁻ accelerating them. Moreover, replacement of external Cl⁻ with gluconate, or sucrose, shifted the voltage dependence of steady-state activation (G-V relation) to more positive potentials, whereas substitution of extracellular or intracellular Cl⁻ with SCN⁻ shifted G-V to more negative potentials. Dose–response relationships for Ca²⁺ in the presence of different extracellular anions indicated that the apparent affinity for Ca²⁺ at +100 mV increased with increasing permeability ratio. The apparent affinity for Ca²⁺ in the presence of intracellular SCN⁻ also increased compared with that in Cl⁻. Our results provide the first evidence that TMEM16B gating is modulated by permeant anions and provide the basis for future studies aimed at identifying the molecular determinants of TMEM16B ion selectivity and gating.     

Influence of Nitrate and Ammonium Nutrition on the Uptake, Assimilation, and Distribution of Nutrients in Ricinus communis

Ricinus communis L. plants were grown in nutrient solutions in which N was supplied as NO₃⁻ or NH₄⁺, the solutions being maintained at pH 5.5. In NO₃⁻-fed plants excess nutrient anion over cation uptake was equivalent to net OH⁻ efflux, and the total charge from NO₃⁻ and SO₄²⁻ reduction equated to the sum of organic anion accumulation plus net OH⁻ efflux. In NH₄⁺-fed plants a large H⁺ efflux was recorded in close agreement with excess cation over anion uptake. This H⁺ efflux equated to the sum of net cation (NH₄⁺ minus SO₄²⁻) assimilation plus organic anion accumulation. In vivo nitrate reductase assays revealed that the roots may have the capacity to reduce just under half of the total NO₃⁻ that is taken up and reduced in NO₃⁻-fed plants. Organic anion concentration in these plants was much higher in the shoots than in the roots. In NH₄⁺-fed plants absorbed NH₄⁺ was almost exclusively assimilated in the roots. These plants were considerably lower in organic anions than NO₃⁻-fed plants, but had equal concentrations in shoots and roots. Xylem and phloem saps were collected from plants exposed to both N sources and analyzed for all major contributing ionic and nitrogenous compounds. The results obtained were used to assist in interpreting the ion uptake, assimilation, and accumulation data in terms of shoot/root pH regulation and cycling of nutrients.     

Studies of the Uptake of Nitrate in Barley : IV. Electrophysiology

Transmembrane electrical potential differences (Δψ) of epidermal and cortical cells were measured in intact roots of barley (Hordeum vulgare L. cv Klondike). The effects of exogenous NO₃⁻ on Δψ (in the concentration range from 100 micromolar to 20 millimolar) were investigated to probe the mechanisms of nitrate uptake by the high-affinity (HATS) and low-affinity (LATS) transport systems for NO₃⁻ uptake. Both transport systems caused depolarization of Δψ, demonstrating that the LATS (like the HATS) for NO₃⁻ uptake is probably mediated by an electrogenic cation (H⁺?) cotransport system. Membrane depolarization by the HATS was “inducible” by NO₃⁻, and saturable with respect to exogenous [NO₃⁻]. By contrast, depolarization by the LATS was constitutive, and first-order in response to external [NO₃⁻]. H⁺ fluxes, measured in 200 micromolar and in 5 millimolar Ca(NO₃)₂ solutions, failed to alkalinize external media as anticipated for a 2 H⁺:1 NO₃⁻ symport. However, switching from K₂SO₄ solutions (which were strongly acidifying) to KNO₃ solutions at the same K⁺ concentration caused marked reductions in H⁺ efflux. These observations are consistent with NO₃⁻ uptake by the HATS and the LATS via 2 H⁺:1 NO₃⁻ symports. These observations establish that the HATS for nitrate uptake by barley roots is essentially similar to those reported for Lemna and Zea mays by earlier workers. There are, nevertheless, distinct differences between barley and corn in their quantitative responses to external NO₃⁻.     

Influence of the level of nitrate nutrition on ion uptake and assimilation, organic Acid accumulation, and cation-anion balance in whole tomato plants

Tomato plants (Lycopersicon esculentum L. var. Ailsa Craig) were grown in water culture in nutrient solution in a series of 10 increasing levels of nitrate nutrition. Using whole plant data derived from analytical and yield data of individual plant parts, the fate of anion charge arising from increased NO₃ assimilation was followed in its distribution between organic anion accumulation in the plant and OH⁻ efflux into the nutrient solution as calculated by excess anion over cation uptake. With increasing NO₃ nutrition the bulk of the anion charge appeared as organic anion accumulation in the plants. OH⁻ efflux at a maximum accounted for only 20% of the anion charge shift. The major organic anion accumulated in response to nitrate assimilation was malate. The increase in organic anion accumulation was paralleled by an increase in cation concentration (K⁺, Ca²⁺, Mg²⁺, Na⁺). Total inorganic anion levels (NO₃⁻, SO₄²⁻, H₂PO₄⁻, Cl⁻) were relatively constant. The effect of increasing NO₃ nutrition in stimulating organic anion accumulation was much more pronounced in the tops than in the roots.     

Anion-Sensitive, H-Pumping ATPase of Oat Roots : Direct Effects of Cl, NO(3), and a Disulfonic Stilbene

To understand the mechanism and molecular properties of the tonoplast-type H⁺-translocating ATPase, we have studied the effect of Cl⁻, NO₃⁻, and 4,4′-diisothiocyano-2,2′-stilbene disulfonic acid (DIDS) on the activity of the electrogenic H⁺-ATPase associated with low-density microsomal vesicles from oat roots (Avena sativa cv Lang). The H⁺-pumping ATPase generates a membrane potential (Δψ) and a pH gradient (ΔpH) that make up two interconvertible components of the proton electrochemical gradient (μh⁺). A permeant anion (e.g. Cl⁻), unlike an impermeant anion (e.g. iminodiacetate), dissipated the membrane potential ([¹⁴C]thiocyanate distribution) and stimulated formation of a pH gradient ([¹⁴C]methylamine distribution). However, Cl⁻-stimulated ATPase activity was about 75% caused by a direct stimulation of the ATPase by Cl⁻ independent of the proton electrochemical gradient. Unlike the plasma membrane H⁺-ATPase, the Cl⁻-stimulated ATPase was inhibited by NO₃⁻ (a permeant anion) and by DIDS. In the absence of Cl⁻, NO₃⁻ decreased membrane potential formation and did not stimulate pH gradient formation. The inhibition by NO₃⁻ of Cl⁻-stimulated pH gradient formation and Cl⁻-stimulated ATPase activity was noncompetitive. In the absence of Cl⁻, DIDS inhibited the basal Mg,ATPase activity and membrane potential formation. DIDS also inhibited the Cl⁻-stimulated ATPase activity and pH gradient formation. Direct inhibition of the electrogenic H⁺-ATPase by NO₃⁻ or DIDS suggest that the vanadate-insensitive H⁺-pumping ATPase has anion-sensitive site(s) that regulate the catalytic and vectorial activity. Whether the anion-sensitive H⁺-ATPase has channels that conduct anions is yet to be established.     

HMGB‐1 induces c‐kit+ cell microvascular rolling and adhesion via both toll‐like receptor‐2 and toll‐like receptor‐4 of endothelial cells

High-mobility group box 1 (HMGB-1) is a strong chemo-attractive signal for both inflammatory and stem cells. The aim of this study is to evaluate the mechanisms regulating HMGB-1–mediated adhesion and rolling of c-kit⁺ cells and assess whether toll-like receptor-2 (TLR-2) and toll-like receptor-4 (TLR-4) of endothelial cells or c-kit⁺ cells are implicated in the activation of downstream migration signals to peripheral c-kit⁺ cells. Effects of HMGB-1 on the c-kit⁺ cells/endothelial interaction were evaluated by a cremaster muscle model in wild-type (WT), TLR-2 (−/−) and Tlr4 (LPS-del) mice. The mRNA and protein expression levels of endothelial nitric oxide synthase were determined by quantitative real-time PCR and immunofluorescence staining. Induction of crucial adhesion molecules for rolling and adhesion of stem cells and leukocytes were monitored in vivo and in vitro. Following local HMGB-1 administration, a significant increase in cell rolling was detected (32.4 ± 7.1% in ‘WT’ versus 9.9 ± 3.2% in ‘control’, P < 0.05). The number of firmly adherent c-kit⁺ cells was more than 13-fold higher than that of the control group (14.6 ± 5.1 cells/mm² in ‘WT’ versus 1.1 ± 1.0 cells/mm² in ‘control’, P < 0.05). In knockout animals, the fraction of rolling cells did not differ significantly from control levels. Firm endothelial adhesion was significantly reduced in TLR-2 (−/−) and Tlr4 (LPS-del) mice compared to WT mice (1.5 ± 1.4 cells/mm² in ‘TLR-2 (−/−)’ and 2.4 ± 1.4 cells/mm² in ‘Tlr4 (LPS-del)’ versus 14.6 ± 5.1 cells/mm² in ‘WT’, P < 0.05). TLR-2 (−/−) and Tlr4 (LPS-del) stem cells in WT mice did not show significant reduction in rolling and adhesion compared to WT cells. HMGB-1 mediates c-kit⁺ cell recruitment via endothelial TLR-2 and TLR-4.     

Extracellular Chloride Regulates the Epithelial Sodium Channel

The extracellular domain of the epithelial sodium channel ENaC is exposed to a wide range of Cl⁻ concentrations in the kidney and in other epithelia. We tested whether Cl⁻ alters ENaC activity. In Xenopus oocytes expressing human ENaC, replacement of Cl⁻ with SO₄²⁻, H₂PO₄⁻, or SCN⁻ produced a large increase in ENaC current, indicating that extracellular Cl⁻ inhibits ENaC. Extracellular Cl⁻ also inhibited ENaC in Na⁺-transporting epithelia. The anion selectivity sequence was SCN⁻ < SO₄²⁻ < H₂PO₄⁻ < F⁻ < I⁻ < Cl⁻ < Br⁻. Crystallization of ASIC1a revealed a Cl⁻ binding site in the extracellular domain. We found that mutation of corresponding residues in ENaC (α_H418A and β_R388A) disrupted the response to Cl⁻, suggesting that Cl⁻ might regulate ENaC through an analogous binding site. Maneuvers that lock ENaC in an open state (a DEG mutation and trypsin) abolished ENaC regulation by Cl⁻. The response to Cl⁻ was also modulated by changes in extracellular pH; acidic pH increased and alkaline pH reduced ENaC inhibition by Cl⁻. Cl⁻ regulated ENaC activity in part through enhanced Na⁺ self-inhibition, a process by which extracellular Na⁺ inhibits ENaC. Together, the data indicate that extracellular Cl⁻ regulates ENaC activity, providing a potential mechanism by which changes in extracellular Cl⁻ might modulate epithelial Na⁺ absorption.The epithelial Na⁺ channel ENaC² is a heterotrimer of homologous α, β, and γ subunits (1, 2). ENaC functions as a pathway for Na⁺ absorption across epithelial cells in the kidney collecting duct, lung, distal colon, and sweat duct (reviewed in Refs. 3 and 4). Na⁺ transport is critical for the maintenance of Na⁺ homeostasis and for the control of the composition and quantity of the fluid on the apical membrane of these epithelia. ENaC mutations and defects in its regulation cause inherited forms of hypertension and hypotension (5) and may contribute to the pathogenesis of lung disease in cystic fibrosis (6).ENaC is a member of the DEG/ENaC family of ion channels. A common structural feature of these channels is a large extracellular domain that plays a critical role in channel gating. For example, in ASICs, the extracellular domain functions as a receptor for protons, which transiently activate the channel by titrating residues that form an acidic pocket (7). FaNaCh is a ligand-gated family member in Helix aspersa, activated by the peptide FMRFamide (8). In Caenorhabditis elegans MEC family members, the extracellular domain is thought to respond to mechanical signals (9).ENaC differs from other family members because it is constitutively active in the absence of a ligand/stimulus. However, a convergence of data indicate that ENaC gating is modulated by a variety of molecules that bind to or modify its extracellular domains, including proteases (10–12), Na⁺ (13–15), protons (16), and the divalent cations Zn²⁺ and Ni²⁺ (17, 18). These findings suggest that the ENaC extracellular domain might regulate epithelial Na⁺ transport by sensing and integrating diverse signals in the extracellular environment.In the current study, we tested the hypothesis that ENaC activity is regulated by changes in the extracellular Cl⁻ concentration. Several observations suggested that Cl⁻ might be a strong candidate to regulate the channel. First, transport of Na⁺ and Cl⁻ are often coupled to maintain electroneutrality. Second, ENaC is exposed to large changes in extracellular Cl⁻ concentration. For example, in the kidney collecting duct, the urine Cl⁻ concentration varies widely (19). As the predominant anion, its concentration parallels that of Na⁺ in most clinical states. However, under conditions of metabolic alkalosis and metabolic acidosis, the Na⁺ and Cl⁻ concentrations can become dissociated as a result of increased urinary bicarbonate (alkalosis) or ammonium (acidosis) (19). Thus, ENaC is well positioned to respond to changes in Cl⁻ concentration. Third, crystallization of ASIC1a revealed a binding site for a Cl⁻ ion at the base of the thumb domain (7). The Cl⁻ is coordinated by Arg-310 and Glu-314 from one subunit and Lys-212 from an adjacent subunit. Although the functional role of Cl⁻ binding to ASIC1a is unknown, it supports the hypothesis that extracellular Cl⁻ might regulate the activity of DEG/ENaC ion channels.     

Structural Effects of Cl and Other Anions on the Water Oxidizing Complex of Chloroplast Photosystem II

To further our understanding of the role of Cl⁻ and certain other monovalent anions in the oxygen evolving photosystem II of chloroplasts, dissociating and stabilizing anion effects on the extrinsic 17 and 23 kilodalton polypeptides of the photosynthetic water oxidizing complex were investigated. It was found that (a) the dissociation of the two polypeptides in Cl⁻ free media of pH ≈ 7 was enhanced by millimolar concentrations of the divalent anion SO₄²⁻ and also by divalent cations like Mg²⁺ and Ca²⁺; (b) the dissociation was opposed by relatively low concentrations of monovalent anions with an order of effectiveness Cl⁻ = Br⁻ > NO₃⁻ > F⁻ > ClO₄⁻; (c) at molar concentrations, SO₄²⁻ stabilized the binding of the 23 kilodalton polypeptide, while Cl⁻ and Br⁻ became dissociating agents, in agreement with studies by Blough and Sauer (1984 Biochim Biophys Acta 767: 377-381); (d) the binding of the polypeptides was strengthened at room temperature relative to 0°C, indicating an involvement of hydrophobic forces. It is suggested that a specific binding of Cl⁻, or certain substitutes, organizes the protein surfaces and/or the adjacent water layers in the water oxidizing complex in a way that not only stabilizes its assembly, but is essential for the catalytic mechanism as well. Binding of, or charge screening by, divalent ions interferes with this process. At high salt concentrations, all these effects are overridden by “lyotropic” actions of the solutes that affect the integrity of the water oxidizing protein complex by stabilizing or disrupting critical hydrophobic domains.     

Noncovalent Intermolecular Forces in Phycobilisomes of Porphyridium cruentum

Using sensitized fluorescence as a measure of intactness of phycobilisomes isolated from Porphyridium cruentum, the effects of various environmental perturbations on phycobilisome integrity were investigated. The rate of phycobilisome dissociation in 0.75 ionic strength sodium salts proceeds in the order: SCN⁻ > NO₃⁻ > Cl⁻ > C₆H₅O₇³⁻ > SO₄²⁻ > PO₄³⁻, as predicted from the lyotropic series of anions and their effects on hydrophobic interactions in proteins. Similarly, increasing temperature (to 30 C) and pH values approaching the isoelectric points of the biliproteins stabilize phycobilisomes. Deuterium substitution at exchangeable sites on the phycobiliproteins decreases the rate of phycobilisome dissociation, while substitution at nonexchangeable sites increases rates of dissociation. It is concluded that hydrophobic intermolecular interactions are the most important forces in maintaining the phycobilisome structure. Dispersion forces also seem to contribute to phycobilisome stabilization. The adverse effects of electrostatic repulsion must not be ignored; however, it seems that the requirement of phycobilisomes of high salt concentrations is not simply countershielding of charges on the proteins.     

Anion-sensitive, h-pumping ATPase in membrane vesicles from oat roots

H⁺-pumping ATPases were detected in microsomal vesicles of oat (Avena sativa L. var Lang) roots using [¹⁴C]methylamine distribution or quinacrine fluorescent quenching. Methylamine (MeA) accumulation into vesicles and quinacrine quench were specifically dependent on Mg,ATP. Both activities reflected formation of a proton gradient (ΔpH) (acid inside) as carbonyl cyanide m-chlorophenylhydrazone, nigericin (in the presence of K⁺), or gramicidin decreased MeA uptake or increased quinacrine fluorescence. The properties of H⁺ pumping as measured by MeA uptake were characterized. The K_mapp for ATP was about 0.1 millimolar. Mg,GTP and Mg, pyrophosphate were 19% and 30% as effective as Mg,ATP. MeA uptake was inhibited by N,N′-dicyclohexylcarbodiimide and was mostly insensitive to oligomycin, vanadate, or copper. ATP-dependent MeA was stimulated by anions with decreasing order of potency of Cl⁻ > Br⁻ > NO₃⁻ > SO₄²⁻, iminodiacetate, benzene sulfonate. Anion stimulation of H⁺ pumping was caused in part by the ability of permeant anions to dissipate the electrical potential and in part by a specific requirement of Cl⁻ by a H⁺ -pumping ATPase. A pH gradient, probably caused by a Donnan potential, could be dissipated by K⁺ in the presence or absence of ATP. MeA uptake was enriched in vesicles of relatively low density and showed a parallel distribution with vanadate-insensitive ATPase activity on a continuous dextran gradient. ΔpH as measured by quinacrine quench was partially vanadate-sensitive. These results show that plant membranes have at least two types of H⁺ -pumping ATPases. One is vanadate-sensitive and probably enriched in the plasma membrane. One is vanadate-resistant, anion-sensitive and has many properties characteristic of a vacuolar ATPase. These results are consistent with the presence of electrogenic H⁺ pumps at the plasma membrane and tonoplast of higher plant cells.     

Relationship of Cell Sap pH to Organic Acid Change During Ion Uptake

Excised roots of barley (Hordeum vulgare, var. Campana) were incubated in KCl, K₂SO₄, CaCl₂, and NaCl solutions at concentrations of 10⁻⁵ to 10⁻² n. Changes in substrate solution pH, cell sap pH, and organic acid content of the roots were related to differences in cation and anion absorption. The pH of expressed sap of roots increased when cations were absorbed in excess of anions and decreased when anions were absorbed in excess of cations. The pH of the cell sap shifted in response to imbalances in cation and anion uptake in salt solutions as dilute as 10⁻⁵ n. Changes in cell sap pH were detectable within 15 minutes after the roots were placed in 10⁻³ n K₂SO₄. Organic acid changes in the roots were proportional to expressed sap pH changes induced by unbalanced ion uptake. Changes in organic acid content in response to differential cation and anion uptake appear to be associated with the low-salt component of ion uptake.     

Differences in SOM Decomposition and Temperature Sensitivity among Soil Aggregate Size Classes in a Temperate Grasslands

The principle of enzyme kinetics suggests that the temperature sensitivity (Q₁₀) of soil organic matter (SOM) decomposition is inversely related to organic carbon (C) quality, i.e., the C quality-temperature (CQT) hypothesis. We tested this hypothesis by performing laboratory incubation experiments with bulk soil, macroaggregates (MA, 250–2000 μm), microaggregates (MI, 53–250 μm), and mineral fractions (MF, <53 μm) collected from an Inner Mongolian temperate grassland. The results showed that temperature and aggregate size significantly affected on SOM decomposition, with notable interactive effects (P<0.0001). For 2 weeks, the decomposition rates of bulk soil and soil aggregates increased with increasing incubation temperature in the following order: MA>MF>bulk soil >MI(P <0.05). The Q₁₀ values were highest for MA, followed (in decreasing order) by bulk soil, MF, and MI. Similarly, the activation energies (E_a) for MA, bulk soil, MF, and MI were 48.47, 33.26, 27.01, and 23.18 KJ mol⁻¹, respectively. The observed significant negative correlations between Q₁₀ and C quality index in bulk soil and soil aggregates (P<0.05) suggested that the CQT hypothesis is applicable to soil aggregates. Cumulative C emission differed significantly among aggregate size classes (P <0.0001), with the largest values occurring in MA (1101 μg g⁻¹), followed by MF (976 μg g⁻¹) and MI (879 μg g⁻¹). These findings suggest that feedback from SOM decomposition in response to changing temperature is closely associated withsoil aggregation and highlights the complex responses of ecosystem C budgets to future warming scenarios.     

Probing the Binding Sites of Antibiotic Drugs Doxorubicin and N-(trifluoroacetyl) Doxorubicin with Human and Bovine Serum Albumins

We located the binding sites of doxorubicin (DOX) and N-(trifluoroacetyl) doxorubicin (FDOX) with bovine serum albumin (BSA) and human serum albumins (HSA) at physiological conditions, using constant protein concentration and various drug contents. FTIR, CD and fluorescence spectroscopic methods as well as molecular modeling were used to analyse drug binding sites, the binding constant and the effect of drug complexation on BSA and HSA stability and conformations. Structural analysis showed that doxorubicin and N-(trifluoroacetyl) doxorubicin bind strongly to BSA and HSA via hydrophilic and hydrophobic contacts with overall binding constants of K _DOX-BSA = 7.8 (±0.7)×10³ M⁻¹, K _FDOX-BSA = 4.8 (±0.5)×10³ M⁻¹ and K _DOX-HSA = 1.1 (±0.3)×10⁴ M⁻¹, K _FDOX-HSA = 8.3 (±0.6)×10³ M⁻¹. The number of bound drug molecules per protein is 1.5 (DOX-BSA), 1.3 (FDOX-BSA) 1.5 (DOX-HSA), 0.9 (FDOX-HSA) in these drug-protein complexes. Docking studies showed the participation of several amino acids in drug-protein complexation, which stabilized by H-bonding systems. The order of drug-protein binding is DOX-HSA > FDOX-HSA > DOX-BSA > FDOX>BSA. Drug complexation alters protein conformation by a major reduction of α-helix from 63% (free BSA) to 47–44% (drug-complex) and 57% (free HSA) to 51–40% (drug-complex) inducing a partial protein destabilization. Doxorubicin and its derivative can be transported by BSA and HSA in vitro.