The influence of calcium ions on fibrin polymerization

The influence of calcium ions on the polymerization induced in fibrinogen solutions by thrombin and by Reptilase has been investigated by meansof static and dynamic light scattering in combination with measurements of the release of the fibrinopeptide A. The calcium concentration was varied in the range between 0.3 and 103 calcium ions per fibrinogen molecule. The enzyme concentration was chosen sufficiently low so that it was possible to make quantitative observations as a function of time, in particular, beforethe onset of gelation. Likewise, the influence of calcium ions on the enzymatically induced polymerization of fragment X was studied. The results indicate that there are at least three mechanisms by which calcium can influence the evolution of the polymer system on the path to gelation and clotting. Which mechanism dominates depends upon the calcium concentration.     

The effects of pH and calcium concentrations on gill potentials in the Brown Trout,Salmo trutta

Summary Measurements of the transepithelial potential (V_int-V_ext) across the gills of Brown Trout,Salmo trutta, were made in solutions of a range of pH and calcium concentrations. The potential was strongly dependent on external pH, being negative in neutral solutions but positive in acid solutions. The addition of calcium to the external medium produced a positive shift in potential in all but very acid media (pH 4.0–3.5), where very little change was seen. The gill membrane appears to act as a hydrogen electrode having a very high permeability to H⁺ ions, and the potential behaves as a diffusion potential. The presence of calcium reduced the permeability to both H⁺ and Na⁺ ions but even at a calcium concentration of 8.0 mM/l the permeability ratio H⁺/Na⁺ was still more than 900. The transepithelial potential is shown to be diffusional in origin and is discussed in terms of the relative permeability of the gill to H⁺, Na⁺ and Cl^– ions. Sodium fluxes across the gills were measured and provide the basis for a theoretical consideration of Na⁺, Cl^– and H⁺ fluxes across the gills in neutral and acid solutions. The positive potential at low pH largely accounts for the increased loss of sodium from fish in these conditions.     

Development of electrochemical calcium sensors by using silicon nanowires modified with phosphotyrosine

This paper reports the electrical detection of calcium ions by using silicon nanowires (SiNWs) as channels in a chemically gated field-effect-transistor (FET) configuration. To obtain a selective and sensitive layer for calcium sensing, the SiNWs are modified with a biologically relevant amino acid phosphotyrosine (p-Tyr), which is able to complex calcium ions with high affinity. It is found that when the p-Tyr modified SiNWs are exposed to aqueous solutions containing calcium ions, their conductances increase with the increasing of calcium concentration up to 10microM. In contrast, when the SiNWs are exposed to sodium or potassium, or when they are modified with tyrosine (Tyr), no significant increase in the conductance is observed. This finding suggests that the calcium ions complexed with the phosphate group of p-Tyr can act as a positive gate voltage on the FET device comprising of n-type SiNWs, and leads to an increase in their conductances. The FET device is also sensitive to magnesium ions. However, the response is 10 times lower than that of calcium at the same concentration. The study reported here may pave the way for designing an intracellular calcium sensor which permits the monitoring of calcium concentration in real time.     

On the formation of calcium(II) taurocholate aggregate species in aqueous solution

Abstract

The influence of the presence of calcium(II) ions in solutions containing sodium and taurocholate ions at 25°C and in 0.5 mol dm^?3 N(CH₃)₄Cl as the constant ionic medium was studied. The composition and existence range of aggregates formed by taurocholate sodium and calcium(II) were investigated by means of two different procedures. First, the increasing calcium oxalate solubility due to the presence of taurocholate ions was studied as a function of the taurocholate, sodium and hydrogen ions. The free concentration of sodium and hydrogen ions was determined in solutions equilibrated with solid calcium(II) oxalate. After filtration, the concentration of calcium(II) (by atomic absorption spectro-photometry) and that of oxalate were also determined. In the second approach, electromotive force measurements carried out in solutions containing taurocholate, sodium and calcium(II) ions provided hydrogen and sodium ions free concentrations. The results from both procedures could be explained by assuming the presence of aggregates of different composition with the participation of sodium, calcium(II) and taurocholate ions, depending on the concentration of the reagents. No protonated species were present in appreciable concentrations. All the species found have even anion aggregation numbers. A strong analogy with the composition of sodium taurocholate and glycocholate is observed, while a comparison with sodium deoxycholate, glycodeoxycholate and taurodeoxycholate shows wide differences.     

Factors controlling the intracellular concentration of calcium and the spontaneous activity of the ureter

The role of the electrogenic Na(+)-Ca(2+)-exchange mechanism in regulating the spike activity of the ureter was studied. The ureter cells were shown to be capable of generating action potentials (AP) in sodium-free Krebs solution. The time during which the spikes are generated is in exponential dependence on the concentration of calcium ions in the medium, [Ca2+]o within 2.5 to 15 mmol/l. Simultaneously with the generation of the spikes, accumulation of calcium in the muscles is observed, proportional to the increase of [Ca2+]o. The addition of as little as 20 mmol/l Na+ or Li+ ions into the solution restores the prolonged electrical activity of the ureter. Under these conditions, the decrease of intracellular Ca2+ within 5 min was more than two times larger as compared with that in sodium-free medium. Upon substituting Ba2+ ions for Ca2+ ions in Krebs solution AP are generated within an interval which was the longer the higher the Ba2+ concentration in the medium. Li+ ions can replace Na+ ions in maintaining AP and in extruding calcium from the cell. It is supposed that the generation of the stable spike activity of the ureter depends on the functioning of Na(+)-Ca(2+)-exchange mechanism.     

An investigation on calcium taurodeoxycholate micellar aggregates

Abstract

The formation of micellar aggregates in the presence of calcium(II) ions in solutions containing sodium and taurodeoxycholate ions and their composition at 25°C and in 0.5 mol dm^?3 N(CH₃)₄Cl as constant ionic medium was studied. The study was carried out by means of two different procedures. In the first one, solid calcium oxalate was equilibrated with taurodeoxycholate, sodium and hydrogen ions and the free concentration of sodium and hydrogen ions was determined. After filtration, the calcium(II) (by atomic absorption spectrophotometry) and oxalate concentration were also determined. In the second approach, hydrogen and sodium ions free concentrations were obtained by electromotive force measurements carried out in solutions containing taurodeoxycholate. The results of both procedures could be explained by assuming the presence of aggregates of different composition with the participation of sodium, calcium(II) and taurodeoxycholate ions, depending on the concentration of the reagents. Protonated species were even present in appreciable concentrations. All the found species have taurodeoxycholate aggregation numbers in multiples of three. A mechanism for the micellar aggregates containing calcium and sodium is proposed. Sodium taurodeoxycholate in the presence of calcium(II) forms larger aggregates than does taurocholate in the presence of calcium(II); the building block of the former is a trimer whereas the latter system has lower aggregation numbers and its building block is a dimer or an octamer.     

Activation of skinned muscle fibers by calcium and strontium ions

Intact and mechanically skinned skeletal muscle fibers of the crab Carcinus maenas have been used. The aim of the experiments was to determine the origin of the mechanical activity recorded in intact crab muscle fibers exhibiting an inward strontium current in strontium solution without calcium. To do so, the effect of strontium ions in inducing activation of contractile proteins and calcium release from the sarcoplasmic reticulum has been studied. The properties of the sarcoplasmic reticulum membrane towards strontium ions, i.e., the efficiency of the calcium ATPase towards strontium ions and the capability to release strontium ions have been investigated. Results show that the contractile proteins have a lower affinity for strontium than for calcium ions. However, the maximum bound strontium is identical to the maximum bound calcium. As for the sarcoplasmic reticulum, strontium ions can induce a calcium release and also can be taken up by the calcium ATPase and be released. We concluded that the mechanical activity in intact fibers bathed in a strontium medium has two origins: first, a direct and partial activation of the contractile proteins by strontium ions flowing through the calcium channel; second, a contractile proteins activation of calcium ions released by the sarcoplasmic reticulum by a "strontium-induced calcium release" mechanism.     

Effect of pH and calcium of the surrounding medium on electrical activity of the isolated muscle spindle

The effect of pH and the calcium ions of the surrounding medium on the receptor potential and unit activity of the isolated frog muscle spindle was investigated. With a decrease in pH of the medium the amplitude and duration of the hyperpolarization phase of the receptor potential increased and the amplitude of its depolarization phase decreased. The frequencies of the spontaneous and evoked activity were reversibly reduced under these conditions. A change in pH of the surrounding medium toward the alkaline side led to a decrease in the amplitude and duration of the hyperpolarization phase of the receptor potential. The firing rate initially increased and then decreased to 30–50% of normal. An increase in the calcium concentration in an alkaline medium led to an increase, but in an acid and normal medium to a decrease, in firing rate. The observed changes in electrical activity of the muscle spindle in solutions can be explained by changes in the velocity of active (electrogenic) and passive transport of sodium and calcium ions.     

Zinc and calcium ions cooperatively modulate ADAMTS13 activity

ADAMTS13 is a metalloproteinase that cleaves von Willebrand factor (VWF) multimers. The metal ion dependence of ADAMTS13 activity was examined with multimeric VWF and a fluorescent peptide substrate based on Asp(1596)-Arg(1668) of the VWF A2 domain, FRETS-VWF73. ADAMTS13 activity in citrate-anticoagulated plasma was enhanced approximately 2-fold by zinc ions, approximately 3-fold by calcium ions, and approximately 6-fold by both ions, suggesting cooperative activation. Cleavage of VWF by recombinant ADAMTS13 was activated up to approximately 200-fold by zinc ions (K(D) (app) approximately 0.5 microM), calcium ions (K(D) (app) approximately 4.8 microM), and barium ions (K(D) (app) approximately 1.7 mM). Barium ions stimulated ADAMTS13 activity in citrated plasma but not in citrate-free plasma. Therefore, the stimulation by barium ions of ADAMTS13 in citrated plasma appears to reflect the release of chelated calcium and zinc ions from complexes with citrate. At optimal zinc and calcium concentrations, ADAMTS13 cleaved VWF with a K(m) (app) of 3.7 +/- 1.4 microg/ml (approximately 15 nM for VWF subunits), which is comparable with the plasma VWF concentration of 5-10 microg/ml. ADAMTS13 could cleave approximately 14% of VWF pretreated with guanidine HCl, suggesting that this substrate is heterogeneous in susceptibility to proteolysis. ADAMTS13 cleaved FRETS-VWF73 with a K(m) (app) of 3.2 +/- 1.1 microM, consistent with an approximately 200-fold decrease in affinity compared with VWF. ADAMTS13 cleaved VWF and FRETS-VWF73 with roughly comparable catalytic efficiency of 55 microM(-1) min(-1) and 18 microM(-1) min(-1), respectively. The striking preference of ADAMTS13 for VWF suggests that substrate recognition depends on structural features or exosites on multimeric VWF that are missing from FRETS-VWF73.     

Effects of calcium ions on electrical responses of gastric gland cells to histamine and pentagastrin

The effect of Ca ions on electrical responses of gastric gland cells on histamine and pentagastrin was investigated using intracellular glass microelectrodes. It was established that in low-calcium solutions hyperpolarization induced by these secretagogues was diminished. In calcium-free solutions and in solutions with blockers of the calcium current hyperpolarization induced by histamine and pentagastrin was not observed. It was suggested that external calcium ions are necessary for hyperpolarization responses to histamine and pentagastrin actions on gastric gland cells to occur.     

Irreversible effects of calcium ions on the plasma membrane calcium pump

The calcium pump of human red cells can be irreversibly activated by preincubation of the membranes in the presence of calcium ions, with a pattern reminiscent of that produced by controlled trypsin attack. With 1 mm Ca²⁺, the activity of the basal enzyme increases three to fourfold over 30 to 60 min, to levels about half those obtained in the presence of calmodulin. On the whole, the effect occurs slowly, with a very low Ca²⁺ affinity at 37°C and is unaffected by serine-protease inhibitors. The activation caused by 1 mm Ca²⁺ is little affected by leupeptin (a thiol-protease inhibitor) and that obtained at 10 m Ca²⁺ is not inhibited. Preincubations at 0°C also lead to activation, to a level up to half that seen at 37°C, and the effect is not affected by leupeptin or antipain. No activation is observed by preincubating soluble purified Ca,Mg-ATPase in Ca²⁺-containing solutions at 37°C. Instead, calcium ions protect the detergent-solubilized enzyme from thermal inactivation, the effect being half-maximal between 10 and 20 m Ca²⁺. We conclude that the activation of the membrane-bound Ca,Mg-ATPase by Ca²⁺ should result from an irreversible conformational change in the enzyme and not from attack by a membrane-bound protease, and that this change presumably arises from the release of inhibitory particles existing in the original membrane preparations.We thank The Wellcome Trust for a research grant, the Medical Research Council for an equipment grant and the Regional Transfusion Service (Sheffield) for bank blood supplies.     

Interactions of mono- and divalent counterions with alkali- and enzyme-deesterified pectins in salt-free solutions

The free fractions of monovalent and divalent counterions were determined on salt-free solutions of pectins. The effects of charge density, distribution of the carboxyl groups, polymer concentration, and the nature of the counterion were investigated by determinating the calcium and sodium activity coefficients (with specific electrodes) and by measuring the transport parameters (by conductimetry). Poor agreement for calcium ions was found with the Manning theory. The strong binding of these ions to highly charged polymers, which is ascribed to a dimerization process was demonstrated in very dilute solutions.     

Interaction of sodium with the sarcolemmal calcium system.

Sarcolemma isolated from guinea pig heart binds calcium in an ATP-dependent manner. Sodium ions decrease the total amount of calcium bound by the membranes. ATP-dependent calcium binding is more sensitive to sodium than the non-ATP-dependent calcium binding. The ATPase active during calcium binding is affected by sodium ions to the same extent as the ATP-dependent calcium binding process. The inhibition of the calcium binding process and of ATPase activity by sodium was more pronounced when the membranes were preincubated with sodium. The effect of sodium on calcium binding is dependent on both the time of contact between sodium and the membranes and the concentration of sodium. It is suggested that the effect of sodium on the calcium binding system in the sarcolemma may be a link between the inhibition of Na+K+-ATPase (EC 3.6.1.3) by cardiac glycosides and the subsequent increase in intracellular calcium.     

Calcium-ion-induced stabilization of the protease from Bacillus cereus WQ9-2 in aqueous hydrophilic solvents: effect of calcium ion binding on the hydration shell and intramolecular interactions

The neutral protease WQ from Bacillus cereus is stable in various aqueous organic mixtures, with the exception of those containing acetonitrile (ACN) and dimethylformamide (DMF). The stability of the enzyme in aqueous hydrophilic solvents was dramatically enhanced with the addition of calcium ions, with the degree of improvement in the half-life relative to different solutions ranging from fourfold to more than 70-fold. Studies of the kinetic constants showed that calcium ions induced slight conformational changes in the active site of the enzyme in aqueous ACN. We investigated the molecular mechanisms underlying this stabilizing effect by employing a combination of biophysical techniques and molecular dynamics simulation. In aqueous ACN, the intrinsic fluorescence and circular dichroism analysis demonstrated that the addition of calcium ions induced a relatively compact conformation and maintained both the native-like microenvironment near the tryptophan residues and the secondary structure. Alternatively, homology modeling confirmed the location of four calcium-ion-binding sites in the enzyme, and molecular dynamics simulation revealed that three other calcium ions were bound to the surface of the enzyme. Calcium ions, known as a type of kosmotrope, can strongly bond with water molecules, thus aiding in the formation of the regional hydration shell required for the maintenance of enzyme activity. In addition, the introduction of calcium ions resulted in the formation of additional ionic interactions, providing propitious means for protein stabilization. Thus, the stronger intramolecular interactions were also expected to contribute partially to the enhanced stability of the enzyme in an aqueous organic solvent.     

'Calcium-activated' intracellular calcium elevation: a novel mechanism of osteoclast regulation

The osteoclast is unique in its capacity to resorb bone. An unbalanced increase in this activity causes osteoporosis, a crippling bone disease that poses a major public health problem. Despite this, our understanding of osteoclast regulation is very limited. Calcitonin is the only known physiological inhibitor of osteoclast function. We demonstrate here for the first time that the concentration of calcium ions at the resorptive site directly regulates osteoclast function by modulating the intracellular free calcium concentration. This represents an important feedback mechanism of osteoclast control.     

A role for calcium in auxin transport

The basipetal transport of the auxin, indoleacetic acid, in sunflower stem sections is markedly suppressed by washing the tissue in ethylenediaminetetraacetate, and transport is restored by subsequent application of calcium solutions. The ethylenediaminetetraacetate treatment is shown to result in the removal of substantial amounts of calcium from the tissue, and the restoration of transport is distinctive for calcium solutions, lesser effects being observed for magnesium and lanthanum, and little effect for monovalent cations. The calcium effects are interpreted as indicating that the auxin transport system depends upon structural or functional features of cellular membranes which involve calcium in a manner analogous to the transport of inorganic ions.     

Circadian rhythm leaf movement of Phaseolus vulgaris and the role of calcium ions

Legume plants, due to their distinctive botanical characteristics, such as leaf movements, physiological characteristics, such as nitrogen fixation, and their abilities to endure environmental stresses, have important roles in sustainable pastures development. Leaf movement of legume plants is turgor regulated and osmotically active fluxes of ions between extensor and flexor of pulvinus cause this movement. To determine the role of calcium ions in circadian leaf movements of Phaseolus vulgaris L., a radiotracer technique experiment using ⁴⁵Ca ions were employed. Measurements were taken during circadian leaf movements, and samples were taken from different parts of the leaflet. The ⁴⁵Ca β-particle activity reduced from leaflet base pulvinus to leaf tip. The pulvinus had the highest activity, while the leaf tip had the lowest. By increase of the ratio of ⁴⁵Ca β-particle activity within flexor to extensor (Fl/Ex) the midrib-petiole angle, as an indicator of leaf movement, increased linearly during circadian leaf movement (r = 0.86). The ⁴⁵Ca β-particle activity of Flex/Ext ratio reduced linearly (r = −0.88) toward midnight. In conclusion, it was found that calcium ions accumulation is opposite to the fluxes of osmatically active ions and water movement. Calcium ions accumulate at less negative water potential side of the pulivnus.Key words: pulvinus, extensor, flexor, leaf movement, rhythm, circadian, calcium, Phaseolus vulgaris, radioactive     

Superoxide release and intracellular free calcium of calcium-depleted human neutrophils stimulated by N-formyl-methionyl-leucyl-phenylalanine

The superoxide release and the change in the intracellular free calcium ions on stimulation with N-formyl-methionyl-leucyl-phenylalanine were studied in human neutrophils deprived of divalent cations by treatment of the cells with ionophore A23187 in the presence of EGTA. The depleted cells showed no release of superoxide on stimulation with the chemotactic peptide when calcium ions were absent in the medium, but the activity was completely recovered when the cells were preincubated with calcium for at least 3 min before the stimulation. The cells pretreated with Cd2+ showed slight activity of the release, but no recovery was observed with other divalent cations such as Mg2+, Sr2+, Co2+, Ba2+ and Zn2+. The recovery with calcium ions was dependent on the time of the addition relative to the time of the stimulation with the chemotactic peptide: a simultaneous addition of both calcium and the peptide elicited about half of the full activity, while no release was observed when calcium was added later than 2 min after the stimulation with the peptide, though a marked elevation of the intracellular free calcium monitored by quin-2 fluorescence was found. Comparison of the time-courses of the superoxide release and the change in the fluorescence suggest that, besides the elevation of intracellular free calcium, a transient reaction which is also dependent on calcium is required for the full induction of the superoxide-producing activity.     

Disease causing mutations of calcium channels

Calcium ions play an important role in the electrical excitability of nerve and muscle, as well as serving as a critical second messenger for diverse cellular functions. As a result, mutations of genes encoding calcium channels may have subtle affects on channel function yet strongly perturb cellular behavior. This review discusses the effects of calcium channel mutations on channel function, the pathological consequences for cellular physiology, and possible links between altered channel function and disease. Many cellular functions are directly or indirectly regulated by the free cytosolic calcium concentration. Thus, calcium levels must be very tightly regulated in time and space. Intracellular calcium ions are essential second messengers and play a role in many functions including, action potential generation, neurotransmitter and hormone release, muscle contraction, neurite outgrowth, synaptogenesis, calcium-dependent gene expression, synaptic plasticity and cell death. Calcium ions that control cell activity can be supplied to the cell cytosol from two major sources: the extracellular space or intracellular stores. Voltage-gated and ligand-gated channels are the primary way in which Ca(2+) ions enter from the extracellular space. The sarcoplasm reticulum (SR) in muscle and the endoplasmic reticulum in non-muscle cells are the main intracellular Ca(2+) stores: the ryanodine receptor (RyR) and inositol-triphosphate receptor channels are the major contributors of calcium release from internal stores.     

Fluorescence studies of the sarcoplasmic reticulum calcium pump.

Intrinsic Tryptophan fluorescence has been used to reveal conformational changes of the Sarcoplasmic Reticulum Calcium pump. It is shown that upon binding of calcium ions the fluorescence is enhanced. The effect being reversed after removal of dependence calcium ions by EGTA. The calcium concentration dependence of this fluorescence change and the effect of inhibitors is compared with the activation of calcium dependent ATPase. We conclude that calcium ions induces a conformational change of the calcium pump and that this change is responsible for the activation of the ATPase activity.