The binding of barium and calcium ions by the antibiotic beauvericin

The ion-transporting antibiotic beauvericin has been shown to have a high affinity for calcium and barium ions in addition to the more usual affinity for monovalent cations. As judged by crystallization, extraction into organic solvent, and U-tube transport the cation selectivity is Rb>Ba>K>Na?Ca?Li. For these studies an improved method for the synthesis of beauvericin has been developed.     

The binding of hemoglobin to membranes of normal and sickle erythrocytes

The binding of hemoglobins A, S, and A₂ to red cell membranes prepared by hypotonic lysis from normal blood and blood from persons with sickle cell anemia was quantified under a variety of conditions using hemoglobin labelled by alkylation with ¹⁴C-labelled Nitrogen Mustard. Membrane morphology was examined by electron microscopy. Normal membranes were found capable of binding native hemoglobin A and hemoglobin S in similar amounts when incubated at low hemoglobin: membrane ratios, but at high ratios hemoglobin saturation levels of the membranes increased progressively for hemoglobin A, hemoglobin S and hemoglobin A₂, respectively, in order of increasing electropositivity. Binding was unaffected by variations in temperature (4–22 °C) and altered little by the presence of sulfhydryl reagents, but was inhibited at pH levels above 7.35; disrupted at high ionic strength; and dependent on the ionic composition of the media. These findings suggest that electrostatic, but not hydrophobic or sulfhydryl bonds are important in membrane binding of the hemoglobin under the conditions studied.An increased retention of hemoglobin in preparations of membranes from red cells of patients with sickle cell anemia (homozygote S) was attributable to the dense fraction of homozygote S red cells rich in irreversibly sickled cells, and the latter membranes had a smaller residual binding capacity for new hemoglobin. This suggests that in homozygote S cells which have become irreversibly sickled cells in vivo, there are membrane changes which involve alteration and/or blockade of hemoglobin binding sites.These findings support the notion that hemoglobin participates in the dynamic structure of the red cell membrane in a manner which differs in normal and pathological states.     

The influx of calcium ions into human erythrocytes during cold storage

1. When human erythrocytes, suspended in iso-osmotic sucrose containing CaCl(2), are stored at 3 degrees C, Ca(2+) influx into the cells occurs. Simultaneously, efflux of K(+), Na(+), Cl(-) and water takes place and cell volume diminishes. 2. The extent of Ca(2+) influx increases with duration of cold storage and with increasing concentration of Ca(2+) in the suspending medium. 3. Erythrocytes that have been thus loaded with Ca(2+) exhibit Ca(2+) efflux against a concentration gradient when subsequently incubated at 37 degrees C. 4. Ca(2+) influx likewise occurs when the sucrose of the medium is replaced by iso-osmotic solutions of other non-ionized compounds. 5. Replacement of sucrose by iso-osmotic KCl or NaCl greatly diminishes the rate of Ca(2+) influx during cold storage; however, in iso-osmotic choline chloride, Ca(2+) influx is as rapid as in sucrose. 6. Preincubation of erythrocytes in iso-osmotic sucrose at 37 degrees C causes rapid efflux of K(+) and Na(+) and renders the cell membranes highly permeable to Ca(2+) during subsequent cold storage. 7. Preincubation of erythrocytes in iso-osmotic NaCl at 37 degrees C with trypsin or neuraminidase is without effect on the permeability of the membrane towards Ca(2+). 8. The experimental results lead to the conclusion that the main prerequisite for Ca(2+) influx into erythrocytes is the partial depletion of the cells of their univalent cations.     

The binding of hemoglobin to membranes of normal and sickle erythrocytes.

The binding of hemoglobins A, S, and A2 to red cell membranes prepared by hypotonic lysis from normal blood and blood from persons with sickle cell anemia was quantified under a variety of conditions using hemoglobin labelled by alkylation with 14C-labelled Nitrogen Mustard. Membrane morphology was examined by electron microscopy. Normal membranes were found capable of binding native hemoglobin A and hemoglobin S in similar amounts when incubated at low hemoglobin: membrane ratios, but at high ratios hemoglobin saturation levels of the membranes increased progressively for hemoglobin A, hemoglobin S and hemoglobin A2, respectively, in order of increasing electropositivity. Binding was unaffected by variations in temperature (4-22 degrees C) and altered little by the presence of sulfhydryl reagents, but was inhibited at pH levels above 7.35; disrupted at high ionic strength; and dependent on the ionic composition of the media. These findings suggest that electrostatic, but not hydrophobic or sulfhydryl bonds are important in membrane binding of the hemoglobin under the conditions studied. An increased retention of hemoglobin in preparations of membranes from red cells of patients with sickle cell anemia (homozygote S) was attributable to the dense fraction of homozygote S red cells rich in irreversibly sickled cells, and the latter membranes had a smaller residual binding capacity for new hemoglobin. This suggests that in homozygote S cells which have become irreversibly sickled cells in vivo, there are membrane changes which involve alteration and/or blockade of hemoglobin binding sites. These findings support the notion that hemoglobin participates in the dynamic structure of the red cell membrane in a manner which differs in normal and pathological states.     

The permeability of thymocyte plasma membranes for calcium ions]

The passive calcium transport through the plasmatic membranes of thymocytes of cattle has been investigated. It has been found that this process is a reaction of the first order. The kinetic values of the reaction have been calculated.     

Ultrastructural alteration of plant plasma membranes induced by auxin and calcium ions

Ultrastructural changes in isolated and in situ plasma membranes of etiolated soybean hypocotyls (Glycine max L. cv. Wayne) were induced by indole-3-acetic acid (IAA), other auxins, and calcium chloride. Fixed and embedded preparations were stained by a phosphotungstate-chromate procedure to identify and accentuate plasma membrane. Measurements were on micrographs obtained with an electron optical system calibrated and corrected for reproducible and accurate size measurements. Plasma membranes treated for 20 minutes with 1 mum IAA were 10 to 15% thinner than controls. The response to IAA was rapid, reproducible, auxin-specific, temperature-dependent, and reversible. Comparable responses were obtained with isolated and in situ membranes. Membranes treated with 0.5 m calcium chloride for 20 minutes were 15 to 20% thicker than controls. Multiple cycles of alternating calcium and IAA treatments yielded membranes with dimensions that reflected the last treatment of the series. The findings show a direct response of plasma membranes to growth regulating agents and provide evidence for a cell-free response of isolated plasma membranes to a hormone.     

Modulation of E-cadherin monomer folding by cooperative binding of calcium ions

Classical cadherins are transmembrane glycoproteins involved in calcium-dependent cell-cell adhesion. Calcium ions are coordinated at the interface between successive modules of the cadherin ectodomain and are thought to regulate the adhesive interactions of cadherins when present at millimolar concentrations. It is widely accepted that calcium plays a critical role in cadherin-mediated cell-cell adhesion, but the nature of cadherin-calcium binding remains a matter of debate. We investigated the parameters of noncovalent cadherin-calcium binding, using the two N-terminal modules of E-cadherin (E/EC12) with a native N-terminal end and nondenaturing electrospray ionization mass spectrometry. By directly visualizing the molecular complexes, we demonstrated that E/EC12 binds three calcium ions, with an average KD of 20 +/- 0.7 microM. These calcium ions bound cooperatively to E/EC12 in its monomeric state, and these properties were not modified by an N-terminal extension consisting of a single methionine residue. This binding induced specific structural changes, as shown by assessments of protease sensitivity, circular dichroism, and mass spectrometry. Furthermore, the D103A mutation (a residue involved in E-cadherin adhesive function) modified calcium binding and led to a loss of cooperativity and the absence of structural changes, despite calcium binding. As the amino acids involved in calcium binding are found within the cadherin consensus motif, our findings may be relevant to other members of the cadherin family.     

Marked stereoselectivity in the binding of copper ions by heparin. Contrasts with the binding of gadolinium and calcium ions

Heparin forms a complex with cupric ion (Cu2+) at a level of less than or equal to 10(-3) mol of the metal ion per dimeric unit of the polymer, as evidenced by paramagnetic relaxation effects on its 1H- and 13C-n.m.r. spectra. No interaction occurred with heparin derivatives modified either by desulfation of the residues of alpha-L-iduronic acid 2-sulfate, or by hydrolysis of the sulfamino group of the residues of 2-deoxy-2-sulfamino-alpha-D-glucose 6-sulfate, although binding was induced by N-acetylation of the latter derivative. Under the same experimental conditions, no alternative type of glycosyluronic acid structure tested, including the other glycosaminoglycans, showed significant relaxation enhancement by Cu2+. These results are in contrast to those obtained with gadolinium ion (Gd3+), another paramagnetic probe, or with calcium ion (Ca2+), which promotes chemical-shift displacements. The binding selectivities of those two cations are much broader than that of Cu2%, although they also differ notably in their relationship to the structure of heparin.     

Alteration of UV-sensitivity of mice peritoneal macrophage plasma membranes by calcium ions

Effect of Ca2+ ions on UV-induced mice peritoneal macrophage plasma membrane damage has been studied. Drop of the extracellular Ca2+ concentration has been found to result in a reduced expression of this damage. On the contrary, a raised intra- and extra-cellular Ca2+ level is associated with a higher number of cells with damaged plasma membranes. These findings make it possible to suggest that this change in the plasma membrane photosensitivity might be a result of alterations in the membrane lipid matrix electrical stability owing to UV-induced lipid photo-peroxidation. This study has also shown that free radical peroxidation of membrane lipids plays a significant part in UV-induced cell damage.     

Regulation of cyclic GMP binding to retinal rod membranes by calcium

The apparently cooperative binding of 8-(5-thioacetamidofluorescein)-cGMP (SAF-cGMP) to cGMP-binding sites of the rod outer segments is regulated by Ca2+ in the 0.1-1 microM activity range. High Ca2+ reduces, and low Ca2+ increases the affinity of SAF-cGMP binding. This regulation involves only intrinsic membrane components. It is proposed that an allosteric regulation of cGMP binding by Ca2+ can contribute to photoreceptor potential adaptation.     

Effect of calcium ions on neutral red binding by skeletal muscle plasma membranes and the mechanism of Ca2+ sorption]

Evidence on the influence of Ca2+ on the binding of neutral red by plasma membranes of skeletal muscle is dealt with. It is suggested that the binding of Ca2+ occurs according to the principle of bimolecular binding. It is suggested that the Ca2+-binding sites with high affinity may control the process of calcium transport by plasma membranes.     

Effects of calcium ions on pyruvate kinase from human erythrocytes.

Ca2+ ions have a biphasic effect on the allosteric pyruvate kinase (EC 2.7.1.40) from human erythrocytes: Ca2+ is an activator at low phosphoenolpyruvate (PEP) concentrations: at increased PEP concentrations Ca2+ behaves as an inhibitor. In the presence of ATP the same effect was observed and at low PEP concentrations Ca2+ ions can completely abolish the ATP inhibitory effect. At high Ca2+ concentrations there is a loss of the cooperativity towards PEP. The enzyme activated by fructose-1,6-diphosphate (FDP) is inhibited by Ca2+ ions at all concentrations of PEP tested. Mg2+ ions are not able to counteract the activation by Ca2+ ions at low PEP concentrations. The results are interpreted on the basis of the model of Monod.     

The effects of calcium and magnesium ions on the secondary structure of calcium binding component of troponin

A 40% increase of the α-helicity of calcium binding component of troponin was observed upon addition of micromolar concentrations of calcium ions. Magnesium ions cause also a significan increase of the helical content of this protein but at much higher concentrations than calcium. In the presence of 1mM MgCl₂ micromolar concentrations of calcium ions do not affect the secondary structure of the troponin calcium binding component.