Calmodulin in the membrane transport of Ca++

The involvement of calmodulin in a Ca⁺⁺-transporting process was demonstrated for the first time by Jarrett and Penniston and by Gopinath and Vincenzi in 1977. They observed that the Ca⁺⁺-pumping ATPase of the erythrocyte membrane was specifically activated by a soluble protein factor which shared the properties of calmodulin, and was indeed found to be identical with it. This fundamental observation has triggered a considerable amount of activity in the various areas of membrane transport of Ca⁺⁺. As a result, it is now known that calmodulin is involved in many processes of Ca⁺⁺ transport located in various membranes, and it has also become known that it plays different roles in different transport systems. The fine details of the interaction(s) between calmodulin and the various transport systems are at the moment obscure. It has become obvious, however, that some Ca⁺⁺ transporting enzymes interact with calmodulin directly, whereas some do not, and are influenced by it via intermediate (modulating) proteins. At the present initial state of knowledge, this difference offers a convenient means to classify the type of calmodulin involvment in the various Ca⁺⁺ transporting processes. It will thus be used in the synthetic survey presented in this article.     

The Ca++ permeability of the apical membrane in neuromast hair cells

The mechanosensitivity of eel (Anguilla anguilla) neuromasts was measured by the impulse responses of single afferent nerve fibers to mechanical stimuli. It is dependent on the potential across the skin and on the ions in the water outside the apical membrane of the sensory cells. The mechanosensitivity decreases to zero when the skin is polarized by 10-100 mV cathodal DC (skin surface negative); it increases with increasing (10-60 mV) anodal DC and remains remarkably constant with higher polarization (Fig. 1). The mechanosensitivity increases with increasing concentrations of Ca++ outside the apical membrane of the sensory cells. Na+ and K+ have no influence. Addition of La , Co++, Mg++, D 600 and A-QA 39 inhibits the mechanosensitivity; the degree of inhibition varies with the inhibitor and the ratio [Ca++]/[inhibitor], indicating that the inhibition is competitive (Figs. 2, 3). We conclude that the apical membrane is specifically permeable to Ca++ ('late Ca channel') and that the inward receptor current through the apical membrane is carried by Ca++. Streptomycin also inhibits mechanosensitivity by competing with Ca++. With streptomycin, however, anodal polarization reduces, rather than increases, the mechanosensitivity (Fig. 4).(ABSTRACT TRUNCATED AT 250 WORDS)     

Targeting and stability of Na/Ca exchanger 1 in cardiomyocytes requires direct interaction with the membrane adaptor ankyrin-B

Na/Ca exchanger activity is important for calcium extrusion from the cardiomyocyte cytosol during repolarization. Animal models exhibiting altered Na/Ca exchanger expression display abnormal cardiac phenotypes. In humans, elevated Na/Ca exchanger expression/activity is linked with pathophysiological conditions including arrhythmia and heart failure. Whereas the molecular mechanisms underlying Na/Ca exchanger biophysical properties are widely studied and generally well characterized, the cellular pathways and molecular partners underlying the specialized membrane localization of Na/Ca exchanger in cardiac tissue are essentially unknown. In this report, we present the first direct evidence for a protein pathway required for Na/Ca exchanger localization and stability in primary cardiomyocytes. We define the minimal structural requirements on ankyrin-B for direct Na/Ca exchanger interactions. Moreover, using ankyrin-B mutants that lack Na/Ca exchanger binding activity, and primary cardiomyocytes with reduced ankyrin-B expression, we demonstrate that direct interaction with the membrane adaptor ankyrin-B is required for the localization and post-translational stability of Na/Ca exchanger 1 in neonatal mouse cardiomyocytes. These results raise exciting new questions regarding potentially dynamic roles for ankyrin proteins in the biogenesis and maintenance of specialized membrane domains in excitable cells.     

Ca++ fluxes in resealed synaptic plasma membrane vesicles

The effect of the monovalent cations Na⁺, Li⁺, and K⁺ on Ca⁺⁺ fluxes has been determined in resealed synaptic plasma membrane vesicle preparations from rat brain. Freshly isolated synaptic membranes, as well as synaptic membranes which were frozen (?80°C), rapidly thawed, and passively loaded with K₂/succinate and ⁴⁵CaCl₂, rapidly released approximately 60% of the intravesicular Ca⁺⁺ when exposed to NaCl or to the Ca⁺⁺ ionophore A 23187. Incubation of these vesicles with LiCl caused a lesser release of Ca⁺⁺. The EC₅₀ for Na⁺ activation of Ca⁺⁺ efflux from the vesicles was approximately 6.6mM. exposure of the Ca⁺⁺-loaded vesicles to 150 mM KCl produced a very rapid (?1 sec) loss of Ca⁺⁺ from the vesicles, but the Na⁺-induced efflux could still be detected above this K⁺ - sensitive effect. Vesicles pre-loaded with NaCl (150 mM) exhibited rapid ⁴⁵Ca uptake with an estimated EC₅₀ for Ca⁺⁺ of 7–10 μM. This Ca⁺⁺ uptake was blocked by dissipation of the Na⁺ gradient. These observations are suggestive of the preservation in these purified frozen synaptic membrane preparations of the basic properties of the Na⁺Ca⁺⁺ exchange process and of a K⁺ - sensitive Ca⁺⁺ flux across the membranes.     

The importance of the membrane interface as the reference state for membrane protein stability

The insertion of nascent polypeptide chains into lipid bilayer membranes and the stability of membrane proteins crucially depend on the equilibrium partitioning of polypeptides. For this, the transfer of full sequences of amino-acid residues into the bilayer, rather than individual amino acids, must be understood. Earlier studies have revealed that the most likely reference state for partitioning very hydrophobic sequences is the membrane interface. We have used μs-scale simulations to calculate the interface-to-transmembrane partitioning free energies ΔG_S→TM for two hydrophobic carrier sequences in order to estimate the insertion free energy for all 20 amino acid residues when bonded to the center of a partitioning hydrophobic peptide. Our results show that prior single-residue scales likely overestimate the partitioning free energies of polypeptides. The correlation of ΔG_S→TM with experimental full-peptide translocon insertion data is high, suggesting an important role for the membrane interface in translocon-based insertion. The choice of carrier sequence greatly modulates the contribution of each single-residue mutation to the overall partitioning free energy. Our results demonstrate the importance of quantifying the observed full-peptide partitioning equilibrium, which is between membrane interface and transmembrane inserted, rather than combining individual water-to-membrane amino acid transfer free energies.     

Role of Ca++ in virus-induced membrane fusion. Ca++ accumulation and ultrastructural changes induced by Sendai virus in chicken erythrocytes

Some of the ultrastructural (freeze-etching technique), morphological, and biochemical effects of Sendai virus interaction with chicken erythrocytes have been studied under fusogenic (in the presence of CaCl2) and nonfusogenic (in the presence of ethyleneglycol-bis-N,N'-tetraacetic acid, [EGTA]) conditions. The following phenomena occur, irrespective of the presence of CaCl2 or EGTA: (a) binding of iodinated virus particles to chicken erythrocytes at 4 degrees C and their partial release from the cells at 37 degrees C; (b) gradual incorporation of the viral envelope and viral M-protein into plasma membrane, as visualized in the protoplasmic and exoplasmic fracture (P and E, respectively) faces of the membrane; and (c) virus-dependent transient clustering of intramembrane particles at 4 degrees C, which is reversible after transferring the cells back to 37 degrees C. The following virus-induced phenomena occur only in the presence of CaCl2: (a) rounding of cells followed by their fusion; (b) transient decrease in the density of intramembrane particles; and (c) the virus induces uptake of 45CaCl2 by chicken erythrocytes. The uptake is specific as it is inhibited by LaCl3, and no accumulation of [14C]glucose-1-phosphate ([14C]G-1-P) could be observed under the 45 CaCl2 uptake conditions. The data show that fusion of virus with plasma membrane is a Ca++-independent process and, as such, it should be distinguished from the virus-induced membrane-membrane and cell fusion processes. The latter is absolutely dependent on the rise of intracellular Ca++, as reflected by the fact that Ca++-induced rounding of chicken erythrocytes always precedes fusion (Volsky, D. and A. Loyter. 1977.Biochim. Biophys. Acta 471:253--259).     

The importance of the amino acid in position 32 of cholecystokinin in determining its interaction with cholecystokinin receptors on pancreatic acini

In the C-terminal heptapeptide of cholecystokinin, replacement of the penultimate residue, aspartic acid, by beta-alanine caused a 300-fold decrease in the potency with which the peptide stimulated enzyme secretions, whereas replacement by glutamic acid caused a 1000-fold decrease in potency. The beta-alanine-substituted peptide was approximately ten times more potent when the n terminus was blocked with t-butyloxycarbonyl than when it was blocked with benzyloxycarbonyl, and the glutamic acid-substituted peptide was approximately twice as potent when the N terminus was blocked with t-butyloxycarbonyl than when it was blocked with benzyloxycarbonyl. Changes in the ability of the peptide to stimulate amylase secretion were accompanied by corresponding changes in the ability of the peptide to inhibit binding of 125I-labeled cholecystokinin. The magnitude of stimulation of enzyme secretion caused by a maximally effective peptide concentration was the same with each analogue as it was with the unaltered peptide. Replacing the aspartyl residue by beta-alanine or glutamic acid or replacing the N-terminal t-butyloxycarbonyl moiety by benzyloxycarbonyl caused an equivalent decrease in the ability of the peptide to stimulate enzyme secretion and its ability to cause residual stimulation of enzyme secretion. In contrast, the N-terminal desamino analogue of cholecystokinin heptapeptide was ten times less potent than the unaltered peptide in stimulating amylase secretion, but 100 times less potent than the unaltered peptide in causing residual stimulation of enzyme secretion.     

The importance of the amino acid in position 32 of cholecystokinin in determining its interaction with cholecystokinin receptors on pancreatic acini

In the C-terminal heptapeptide of cholecystokinin, replacement of the penultimate residue, aspartic acid, by β-alanine caused a 300-fold decrease in potency with which the peptide stimulated enzyme secretion, whereas replacement by glutamic acid caused a 1000-fold decrease in potency. The β-alanine-substituted peptide was approximately ten times more potent when the N terminus was blocked with t-butyloxycarbonyl than when it was blocked with benzyloxycarbonyl, and the glutamic acid-substituted peptide was approximately twice as potent when the N terminus was blocked with t-butyloxycarbonyl than when it was blocked with benzyloxycarbonyl. Changes in the ability of the peptide to stimulate amylase secretion were acompanied by corresponding changes in the ability of the peptide to inhibit binding of ¹²⁵I-labeled cholecystokinin. The magnitude of stimulation of enzyme secretion caused by a maximally effective peptide concentration was the same with each analogue as it was with the unaltered peptide. Rpelacing the aspartyl by β-alanine or glutamic acid or replacing of N-terminal t-butyloxycarbonyl moiety by benzyloxycarbonyl caused an equivalent decrease in the ability of the peptide to stimulate enzyme secretion and its ability to cause residual stimulation of enzyme secretion. In contrast, the N-terminal desamino analogue of cholecystokinin heptapeptide was ten times less potent than the unaltered peptide in stimulating amylase secretion, but 100 times less potent that the unaltered peptide in causing residual stimulation of enzyme secretion.     

Role of N-acetylneuraminic acid in rat renal brush-border membrane vesicle aggregation by aminoglycosides

Interaction between aminoglycosides (AGs) and rat renal brush-border membrane (BBM) vesicles was investigated by the aggregation technique. The order of aggregation was gentamicin greater than dibekacin not equal to netilmicin greater than amikacin, and this order corresponds to the strength of the nephrotoxicity of the aminoglycosides in vivo rather than the number of amino groups in the aminoglycosides. BBM vesicles were aggregated through ionic interaction, as evident from the finding that aggregation ceased to occur at alkaline pH. By addition of N-acetylneuraminic acid (NANA) to the incubation medium, the vesicle aggregation induced by gentamicin was significantly inhibited. To affect the liberation of the NANA residue from BBM vesicles, the vesicles were treated with neuraminidase, resulting in an about 60% release with a significant decrease in the uptake of gentamicin into the vesicles. The decrease in the degree of vesicle aggregation was in proportion to the amount of NANA liberated. It follows from the findings that the NANA residue may in some way be responsible for the accumulation of aminoglycosides in renal proximal tubular cells.     

Docosahexaenoic acid in the diet: its importance in maintenance and restoration of neural membrane function

The central nervous system has the second highest concentration of lipids after adipose tissue. Long chain fatty acids, particularly arachidonic acid and docosahexaenoic acid, are integral components of neural membrane phospholipids. Alterations in neural membrane phospholipid components cannot only influence crucial intracellular and intercellular signaling but also alter many membrane physical properties such as fluidity, phase transition temperature, bilayer thickness, and lateral domains. A deficiency of docosahexaenoic acid markedly affects neurotransmission, membrane-bound enzyme and ion channel activities, gene expression, intensity of inflammation, and immunity and synaptic plasticity. Docosahexaenoic acid deficiency is associated with normal aging, Alzheimer disease, hyperactivity, schizophrenia, and peroxisomal disorders. Although the molecular mechanism of docosahexaenoic acid involvement in the disorders remains unknown, the supplementation of docosahexaenoic acid in the diet restores gene expression and modulates neurotransmission. Also, improvements are seen in signal transduction processes associated with behavioral deficits, learning activity, peroxisomal disorders, and psychotic changes in schizophrenia, depression, hyperactivity, stroke, and Alzheimer disease.     

Active Uptake of Ca++ and Ca++-Activated Mg++ ATPase in Red Cell Membrane Fragments

Isolated human red blood cell membrane fragments (RBCMF) were found to take up Ca⁺⁺ in the presence of ATP.¹ This ATP-dependent Ca⁺⁺ uptake by RBCMF appears to be the manifestation of an active Ca⁺⁺ transport mechanism in the red cell membrane reported previously (Schatzmann, 1966; Lee and Shin, 1969). The influences of altering experimental conditions on Ca⁺⁺-stimulated Mg⁺⁺ ATPase (Ca⁺⁺ ATPase) and Ca⁺⁺ uptake of RBCMF were studied. It was found that pretreatment of RBCMF at 50°C abolished both Ca⁺⁺ ATPase and Ca⁺⁺ uptake. Pretreatment of RBCMF with phospholipases A and C decreased both Ca⁺⁺ ATPase and Ca⁺⁺ uptake, whereas pretreatment with phospholipase D did not significantly alter either Ca⁺⁺ ATPase or Ca⁺⁺ uptake. Both Ca⁺⁺ ATPase and Ca⁺⁺ uptake had ATP specificity, similar optimum pH's, and optimum incubation temperatures. From these results, it was concluded that Ca⁺⁺ uptake is intimately linked to Ca⁺⁺ ATPase.     

The interaction of ethanol with reconstituted synaptosomal plasma membrane Ca2+ -ATPase

The primary effect of ethanol is on the central nervous system. However, the molecular mechanisms responsible for the physiological symptoms of ethanol intoxication are still unknown. Low concentrations of ethanol were observed to stimulate the activity of the calcium pump from reconstituted synaptosomal plasma membrane Ca2+ -ATPase (PMCA), and ethanol inhibited Ca2+ -ATPase activity at concentrations above 5%. The greatest stimulating effect was obtained with 5% (v/v) ethanol and was lipid-dependent, being 74% when the protein had been reconstituted in phosphatidylcholine (PC) and less when the reconstituted protein had previously been activated by calmodulin or after removal of a 9-kDa autoinhibitory site by controlled trypsinization. Stimulation of the pump by ethanol was lower for the native or trypsin-digested protein in the presence of phosphatidylserine than in PC. These results suggest a direct ethanol-protein interaction, because the activating effect depended on the state of Ca2+ -ATPase (native or truncated, or in presence of calmodulin). The activating mechanism of ethanol may involve opening an autoinhibitory domain located close to the calmodulin binding domain.     

N-acetylneuraminic acid accumulation in a buoyant lysosomal fraction of cultured fibroblasts from patients with infantile generalized N-acetylneuraminic acid storage disease

Cultured fibroblasts from control individuals and two patients affected with the infantile variant of generalized N-acetylneuraminic acid (NeuAc) storage disease were disrupted by nitrogen cavitation, and the post-nuclear supernatant fractions were subjected to subcellular fractionation on Percoll gradients. Accumulating NeuAc in affected fibroblasts (approx. 150 nmol/mg protein) co-localized with the lysosomal marker N-acetyl-beta-hexosaminidase (Hex), in a fraction with a mean density of 1.035 g/ml. In contrast, more than 70% of the Hex activity of control cells sedimented in comparable gradients with a density of more than 1.07 g/ml. The lysosomal localization of NeuAc accumulation in affected fibroblasts was confirmed by treatment of post-nuclear supernatant fractions with 0.5 mM Gly-Phe-beta-naphthylamide (20 min, 37 degrees C) prior to centrifugation, which resulted in the simultaneous loss of latency of Hex and free NeuAc, and their association with the soluble fraction on Percoll gradients. The results provide direct evidence for the accumulation of free NeuAc in a unique buoyant lysosomal fraction of affected fibroblasts.