Inhibition of calcium-calmodulin complex formation by vasorelaxant basic dipeptides demonstrated by in vitro and in silico analyses

Background

Tryptophan-histidine (Trp-His) was found to suppress the activity of the Ca^2 +/calmodulin (CaM)-dependent protein kinases II (CaMKII), which requires the Ca^2 +-CaM complex for an initial activation. In this study, we attempted to clarify whether Trp-His inhibits Ca^2 +-CaM complex formation, a CaMKII activator.

Methods

The ability of Trp-His and other peptides to inhibit Ca^2 +-CaM complex formation was investigated by a Ca^2 +-encapsulation fluorescence assay. The peptide-CaM interactions were illustrated by molecular dynamic simulation.

Results

We showed that Trp-His inhibited Ca^2 +-CaM complex formation with a 1:1 binding stoichiometry of the peptide to CaM, considering that Trp-His reduced Hill coefficient of Ca^2 +-CaM binding from 2.81 to 1.92. His-Trp also showed inhibitory activity, whereas Trp + His, 3-methyl His-Trp, and Phe-His did not show significant inhibitory activity, suggesting that the inhibitory activity was due to a peptide skeleton (irrespective of the sequence), a basic amino acid, a His residue, the N hydrogen atom of its imidazole ring, and Trp residue. In silico studies suggested the possibility that Trp-His and His-Trp interacted with the Ca^2 +-binding site of CaM by forming hydrogen bonds with key Ca^2 +-binding residues of CaM, with a binding free energy of − 49.1 and − 68.0 kJ/mol, respectively.

Conclusions

This is the first study demonstrating that the vasoactive dipeptide Trp-His possesses inhibitory activity against Ca^2 +-CaM complex formation, which may elucidate how Trp-His inhibited CaMKII in a previous study.

General significance

The results provide a basic idea that could lead to the development of small peptides binding with high affinity to CaM and inhibiting Ca^2 +-CaM complex formation in the future.     

Structural and stoichiometric determinants of Ca release-activated Ca (CRAC) channel Ca-dependent inactivation

Depletion of intracellular Ca^2 + stores in mammalian cells results in Ca^2 + entry across the plasma membrane mediated primarily by Ca^2 + release-activated Ca^2 + (CRAC) channels. Ca^2 + influx through these channels is required for the maintenance of homeostasis and Ca^2 + signaling in most cell types. One of the main features of native CRAC channels is fast Ca^2 +-dependent inactivation (FCDI), where Ca^2 + entering through the channel binds to a site near its intracellular mouth and causes a conformational change, closing the channel and limiting further Ca^2 + entry. Early studies suggested that FCDI of CRAC channels was mediated by calmodulin. However, since the discovery of STIM1 and Orai1 proteins as the basic molecular components of the CRAC channel, it has become apparent that FCDI is a more complex phenomenon. Data obtained using heterologous overexpression of STIM1 and Orai1 suggest that, in addition to calmodulin, several cytoplasmic domains of STIM1 and Orai1 and the selectivity filter within the channel pore are required for FCDI. The stoichiometry of STIM1 binding to Orai1 also has emerged as an important determinant of FCDI. Consequently, STIM1 protein expression levels have the potential to be an endogenous regulator of CRAC channel Ca^2 + influx. This review discusses the current understanding of the molecular mechanisms governing the FCDI of CRAC channels, including an evaluation of further experiments that may delineate whether STIM1 and/or Orai1 protein expression is endogenously regulated to modulate CRAC channel function, or may be dysregulated in some pathophysiological states.     

Coupled gating modifies the regulation of cardiac ryanodine receptors by luminal Ca

Cardiac ryanodine receptors (RYR2s) infrequently exhibit coupled gating that is manifested by synchronous opening and closing. To better characterize this phenomenon, we investigated the regulation of coupled RYR2 channels by luminal Ca^2 + focusing on effects that are likely mediated by the true luminal activation mechanism. By reconstituting an ion channel into a planar lipid bilayer and using substantially lower concentration of luminal Ba^2 + (8 mM, the virtual absence of Ca^2 +) and luminal Ca^2 + (8 mM), we show that response of coupled RYR2 channels to caffeine at a diastolic cytosolic Ca^2 + (90 nM) was affected by luminal Ca^2 + in a similar manner as for the single RYR2 channel except the gating behavior. Whereas, the single RYR2 channel responded to luminal Ca^2 + by prolongation in open and closed times, coupled RYR2 channels seemed to be resistant in this respect. In summary, we conclude that the class of Ca^2 + sites located on the luminal face of coupled RYR2 channels that is responsible for the channel potentiation by luminal Ca^2 + is functional and not structurally hindered by the channel coupling. Thus, the idea about non-functional luminal Ca^2 + sites as a source of the apparent gating resistance of coupled RYR2 channels to luminal Ca^2 + appears to be ruled out.     

Intrinsic Disorder Mediates Cooperative Signal Transduction in STIM1

Intrinsically disordered domains have been reported to play important roles in signal transduction networks by introducing cooperativity into protein–protein interactions. Unlike intrinsically disordered domains that become ordered upon binding, the EF-SAM domain in the stromal interaction molecule (STIM) 1 is distinct in that it is ordered in the monomeric state and partially unfolded in its oligomeric state, with the population of the two states depending on the local Ca^2 + concentration. The oligomerization of STIM1, which triggers extracellular Ca^2 + influx, exhibits cooperativity with respect to the local endoplasmic reticulum Ca^2 + concentration. Although the physiological importance of the oligomerization reaction is well established, the mechanism of the observed cooperativity is not known. Here, we examine the response of the STIM1 EF-SAM domain to changes in Ca^2 + concentration using mathematical modeling based on in vitro experiments. We find that the EF-SAM domain partially unfolds and dimerizes cooperatively with respect to Ca^2 + concentration, with Hill coefficients and half-maximal activation concentrations very close to the values observed in vivo for STIM1 redistribution and extracellular Ca^2 + influx. Our mathematical model of the dimerization reaction agrees quantitatively with our analytical ultracentrifugation-based measurements and previously published free energies of unfolding. A simple interpretation of these results is that Ca^2 + loss effectively acts as a denaturant, enabling cooperative dimerization and robust signal transduction. We present a structural model of the Ca^2 +-unbound EF-SAM domain that is consistent with a wide range of evidence, including resistance to proteolytic cleavage of the putative dimerization portion.     

Sleep deprivation impairs calcium signaling in mouse splenocytes and leads to a decreased immune response

Background

Sleep is a physiological event that directly influences health by affecting the immune system, in which calcium (Ca^2 +) plays a critical signaling role. We performed live cell measurements of cytosolic Ca^2 + mobilization to understand the changes in Ca^2 + signaling that occur in splenic immune cells after various periods of sleep deprivation (SD).

Methods

Adult male mice were subjected to sleep deprivation by platform technique for different periods (from 12 to 72 h) and Ca^2 + intracellular fluctuations were evaluated in splenocytes by confocal microscopy. We also performed spleen cell evaluation by flow cytometry and analyzed intracellular Ca^2 + mobilization in endoplasmic reticulum and mitochondria. Additionally, Ca^2 + channel gene expression was evaluated

Results

Splenocytes showed a progressive loss of intracellular Ca^2 + maintenance from endoplasmic reticulum (ER) stores. Transient Ca^2 + buffering by the mitochondria was further compromised. These findings were confirmed by changes in mitochondrial integrity and in the performance of the store operated calcium entry (SOCE) and stromal interaction molecule 1 (STIM1) Ca^2 + channels.

Conclusions and general significance

These novel data suggest that SD impairs Ca^2 + signaling, most likely as a result of ER stress, leading to an insufficient Ca^2 + supply for signaling events. Our results support the previously described immunosuppressive effects of sleep loss and provide additional information on the cellular and molecular mechanisms involved in sleep function.     

Aequorin-based genetic approaches to visualize Ca signaling in developing animal systems

Background

In recent years, as our understanding of the various roles played by Ca^2 + signaling in development and differentiation has expanded, the challenge of imaging Ca^2 + dynamics within living cells, tissues, and whole animal systems has been extended to include specific signaling activity in organelles and non-membrane bound sub-cellular domains.

Scope of review

In this review we outline how recent advances in genetics and molecular biology have contributed to improving and developing current bioluminescence-based Ca^2 + imaging techniques. Reporters can now be targeted to specific cell types, or indeed organelles or domains within a particular cell.

Major conclusions

These advances have contributed to our current understanding of the specificity and heterogeneity of developmental Ca^2 + signaling. The improvement in the spatial resolution that results from specifically targeting a Ca^2 + reporter has helped to reveal how a ubiquitous signaling messenger like Ca^2 + can regulate coincidental but different signaling events within an individual cell; a Ca^2 + signaling paradox that until now has been hard to explain.

General significance

Techniques used to target specific reporters via genetic means will have applications beyond those of the Ca^2 + signaling field, and these will, therefore, make a significant contribution in extending our understanding of the signaling networks that regulate animal development. This article is part of a Special Issue entitled Biochemical, biophysical and genetic approaches to intracellular calcium signalling.     

Hydrogen atom abstraction from HOOOCl by chlorine atom and OH radical

Gas-phase reactions of HOOOCl with both Cl atom and OH radical are investigated using ab initio methods. The structures of all reactants, products, intermediates, and transition states have been optimized and characterized with the quadratic configuration interaction (QCISD) method. The overall mechanism for the Cl + HOOOCl and OH + HOOOCl reaction is the formation of HCl + O₂ + ClO and H₂O + O₂ + ClO, respectively. The rate-limiting step in each reaction is the abstraction of hydrogen from HOOOCl by either Cl or OH radicals and the barrier height is predicted to be 1.9 kcal mol⁻¹ and 8.1 kcal mol⁻¹ for abstraction by Cl atom and OH radical, respectively. Since both barriers for hydrogen abstraction are high, the reaction is suggested to be slow. These results also suggest that an atmospheric removal mechanism for HOOOCl may result from reaction with Cl atoms rather than with OH radicals, and that photolysis of HOOOCl may be the major removal mechanism for the intermediate.     

The C-terminus of human Cav2.3 voltage-gated calcium channel interacts with alternatively spliced calmodulin-2 expressed in two human cell lines

Ca_v2.3 containing voltage-activated Ca^2 + channels are expressed in excitable cells and trigger neurotransmitter and peptide-hormone release. Their expression remote from the fast release sites leads to the accumulation of presynaptic Ca^2 + which can both, facilitate and inhibit the influx of Ca^2 + ions through Ca_v2.3. The facilitated Ca^2 + influx was recently related to hippocampal postsynaptic facilitation and long term potentiation. To analyze Ca^2 + mediated modulation of cellular processes more in detail, protein partners of the carboxy terminal tail of Ca_v2.3 were identified by yeast-2-hybrid screening, leading in two human cell lines to the detection of a novel, extended and rarely occurring splice variant of calmodulin-2 (CaM-2), called CaM-2-extended (CaM-2-ext). CaM-2-ext interacts biochemically with the C-terminus of Ca_v2.3 similar to the classical CaM-2 as shown by co-immunoprecipitation. Functionally, only CaM-2-ext reduces whole cell inward currents significantly. The insertion of the novel 46 nts long exon and the consecutive expression of CaM-2-ext must be dependent on a new upstream translation initiation site which is only rarely used in the tested human cell lines. The structure of the N-terminal extension is predicted to be more hydrophobic than the remaining CaM-2-ext protein, suggesting that it may help to dock it to the lipophilic membrane surrounding.     

Multi-step formation of a hemifusion diaphragm for vesicle fusion revealed by all-atom molecular dynamics simulations

Membrane fusion is essential for intracellular trafficking and virus infection, but the molecular mechanisms underlying the fusion process remain poorly understood. In this study, we employed all-atom molecular dynamics simulations to investigate the membrane fusion mechanism using vesicle models which were pre-bound by inter-vesicle Ca^2 +-lipid clusters to approximate Ca^2 +-catalyzed fusion. Our results show that the formation of the hemifusion diaphragm for vesicle fusion is a multi-step event. This result contrasts with the assumptions made in most continuum models. The neighboring hemifused states are separated by an energy barrier on the energy landscape. The hemifusion diaphragm is much thinner than the planar lipid bilayers. The thinning of the hemifusion diaphragm during its formation results in the opening of a fusion pore for vesicle fusion. This work provides new insights into the formation of the hemifusion diaphragm and thus increases understanding of the molecular mechanism of membrane fusion. This article is part of a Special Issue entitled: Membrane Structure and Function: Relevance in the Cell's Physiology, Pathology and Therapy.     

Induction of TRPV5 expression by small activating RNA targeting gene promoter as a novel approach to regulate cellular calcium transportation

Aim

Promoter-targeted small activating RNAs (saRNAs) have been shown to be able to induce target gene expression, a mechanism known as RNA activation (RNAa). The present study tested whether saRNA can induce the overexpression of TRPV5 in human cells derived from the kidney and subsequently manipulate cell calcium uptake.

Main methods

Three saRNAs complementary to the TRPV5 promoter were synthesized and transfected into cells. TRPV5 expression at the RNA and protein levels was analyzed by quantitative real-time PCR and Western blotting respectively. For functional study, transcellular Ca^2 + transportation was tested by fura-2 analysis. Dihydrotestosterone (DHT), a suppressor of cellular calcium transportation, was administered to challenge the activating effect of selected saRNA.

Key findings

One of these synthesized saRNAs, ds-2939, significantly induced the expression of TRPV5 at both mRNA and protein levels. Fura-2 analysis revealed that the intracellular Ca^2 + concentration was elevated by ds-2939. DHT treatment reduced transmembrane Ca^2 + transport, which was partially antagonized by ds-2939.

Significance

Our results suggest that a saRNA targeting TRPV5 promoter can be utilized to manipulate the transmembrane Ca^2 + transport by upregulating the expression of TRPV5 and may serve as an alternative for the treatment of Ca^2 + balance-related diseases.     

MD simulations of the central pore of ryanodine receptors and sequence comparison with 2B protein from coxsackie virus

The regulation of intracellular Ca^2 + triggers a multitude of vital processes in biological cells. Ca^2 + permeable ryanodine receptors (RyRs) are the biggest known ion channels and play a key role in the regulation of intracellular calcium concentrations, particularly in muscle cells. In this study, we construct a computational model of the pore region of the skeletal RyR and perform molecular dynamics (MD) simulations. The dynamics and distribution of Ca^2 + around the luminal pore entry of the RyR suggest that Ca^2 + ions are channeled to the pore entry due to the arrangement of (acidic) amino acids at the extramembrane surface of the protein. This efficient mechanism of Ca^2 + supply is thought to be part of the mechanism of Ca^2 + conductance of RyRs. Viral myocarditis is predominantly caused by coxsackie viruses that induce the expression of the protein 2B which is known to affect intracellular Ca^2 + homeostasis in infected cells. From our sequence comparison, it is hypothesized, that modulation of RyR could be due to replacement of its transmembrane domains (TMDs) by those domains of the viral channel forming protein 2B of coxsackie virus. This article is part of a Special Issue entitled: Viral Membrane Proteins — Channels for Cellular Networking.     

In vivo effects of propyl gallate,a novel Ca sensitizer,in a mouse model of dilated cardiomyopathy caused by cardiac troponin T mutation

Aims

We have previously demonstrated that propyl gallate has a Ca^2 + sensitizing effect on the force generation in membrane-permeabilized (skinned) cardiac muscle fibers. However, in vivo beneficial effects of propyl gallate as a novel Ca^2 + sensitizer remain uncertain. In the present study, we aim to explore in vivo effects of propyl gallate.

Main methods

We compared effects of propyl gallate on ex vivo intact cardiac muscle fibers and in vivo hearts in healthy mice with those of pimobendan, a clinically used Ca^2 + sensitizer. The therapeutic effect of propyl gallate was investigated using a mouse model of dilated cardiomyopathy (DCM) with reduced myofilament Ca^2 + sensitivity due to a deletion mutation ΔK210 in cardiac troponin T.

Key findings

Propyl gallate, as well as pimobendan, showed a positive inotropic effect. Propyl gallate slightly increased the blood pressure without changing the heart rate in healthy mice, whereas pimobendan decreased the blood pressure probably through vasodilation via inhibition of phosphodiesterase and increased the heart rate. Propyl gallate prevented cardiac remodeling and systolic dysfunction and significantly improved the life-expectancy of knock-in mouse model of DCM with reduced myofilament Ca^2 + sensitivity due to a mutation in cardiac troponin T. On the other hand, gallate, a similarly strong antioxidant polyphenol lacking Ca^2 + sensitizing action, had no beneficial effects on the DCM mice.

Significance

These results suggest that propyl gallate might be useful for the treatment of inherited DCM caused by a reduction in the myofilament Ca^2 + sensitivity.     

Stimulation of cytosolic and mitochondrial calcium mobilization by indomethacin in Caco-2 cells: Modulation by the polyphenols quercetin,resveratrol and rutin

Background

The effect of indomethacin (INDO) on Ca^2 + mobilization, cytotoxicity, apoptosis and caspase activation and the potential protective effect of quercetin (QUE), resveratrol (RES) and rutin (RUT) were determined in Caco-2 cells.

Methods

Caco-2 cells were incubated with INDO in the presence or absence of QUE, RES or RUT. The concentrations of Ca^2 + in the cytosol (Fluo-3 AM) and mitochondria (Rhod-2 AM) were determined as well as the cytotoxicity (MTT reduction and LDH leakage), apoptosis (TUNEL) and caspase-3 and 9 activities.

Results

INDO promoted Ca^2 + efflux from the endoplasmic reticulum (ER), resulting in an early, but transient, increment of cytosolic Ca^2 + at 3.5 min, followed by a subsequent increment of intra-mitochondrial Ca^2 + at 24 min. INDO also induced cytotoxicity, apoptosis, and increased caspase activities and cytochrome c release. All these alterations were prevented by the inhibitors of the IP3R and RyR receptors, 2-Aminoethoxydiphenyl borate (2-APB) and dantrolene. QUE was the most efficient polyphenol in preventing Ca^2 + mobilization induced by INDO and all of its consequences including cytotoxicity and apoptosis.

Conclusions

In Caco-2 cells, INDO stimulates ER Ca^2 + mobilization, probably through the activation of IP3R and RyR receptors, and the subsequent entry of Ca^2 + into the mitochondria. Polyphenols protected the cells against the Ca^2 + mobilization induced by INDO and its consequences on cytotoxicity and apoptosis.

General significance

These results confirm the possibility of using polyphenols and particularly QUE for the protection of the gastroduodenal mucosa in subjects consuming NSAIDs.     

Crystal-structure and biochemical characterization of recombinant human calcyphosine delineates a novel EF-hand-containing protein family

Calcyphosine is an EF-hand protein involved in both Ca^2 +-phosphatidylinositol and cyclic AMP signal cascades, as well as in other cellular functions. The crystal structure of Ca^2 +-loaded calcyphosine was determined up to 2.65 Å resolution and reveals a protein containing two pairs of Ca^2 +-binding EF-hand motifs. Calcyphosine shares a highly similar overall topology with calmodulin. However, there are striking differences between EF-hand 4, both N-terminal and C-terminal regions, and interdomain linkers. The C-terminal domain of calcyphosine possesses a large hydrophobic pocket in the presence of calcium ions that might be implicated in ligand binding, while its N-terminal hydrophobic pocket is almost shielded by an additional terminal helix. Calcyphosine is largely monomeric, regardless of the presence of Ca^2 +. Differences in structure, oligomeric state in the presence and in the absence of Ca^2 +, a highly conserved sequence with low similarity to other proteins, and phylogeny define a new EF-hand-containing family of calcyphosine proteins that extends from arthropods to humans.     

Inhibitors of the 5-lipoxygenase arachidonic acid pathway induce ATP release and ATP-dependent organic cation transport in macrophages

We have previously described that arachidonic acid (AA)-5-lipoxygenase (5-LO) metabolism inhibitors such as NDGA and MK886, inhibit cell death by apoptosis, but not by necrosis, induced by extracellular ATP (ATPe) binding to P2X7 receptors in macrophages. ATPe binding to P2X7 also induces large cationic and anionic organic molecules uptake in these cells, a process that involves at least two distinct transport mechanisms: one for cations and another for anions. Here we show that inhibitors of the AA-5-LO pathway do not inhibit P2X7 receptors, as judged by the maintenance of the ATPe-induced uptake of fluorescent anionic dyes. In addition, we describe two new transport phenomena induced by these inhibitors in macrophages: a cation-selective uptake of fluorescent dyes and the release of ATP. The cation uptake requires secreted ATPe, but, differently from the P2X7/ATPe-induced phenomena, it is also present in macrophages derived from mice deficient in the P2X7 gene. Inhibitors of phospholipase A2 and of the AA-cyclooxygenase pathway did not induce the cation uptake. The uptake of non-organic cations was investigated by measuring the free intracellular Ca^2 + concentration ([Ca^2 +]_i) by Fura-2 fluorescence. NDGA, but not MK886, induced an increase in [Ca^2 +]_i. Chelating Ca^2 + ions in the extracellular medium suppressed the intracellular Ca^2 + signal without interfering in the uptake of cationic dyes. We conclude that inhibitors of the AA-5-LO pathway do not block P2X7 receptors, trigger the release of ATP, and induce an ATP-dependent uptake of organic cations by a Ca^2 +- and P2X7-independent transport mechanism in macrophages.     

Fluvoxamine rescues mitochondrial Ca transport and ATP production through σ1-receptor in hypertrophic cardiomyocytes

Aims

We previously reported that fluvoxamine, a selective serotonin reuptake inhibitor with high affinity for the σ₁-receptor (σ₁R), ameliorates cardiac hypertrophy and dysfunction via σ₁R stimulation. Although σ₁R on non-cardiomyocytes interacts with the IP₃ receptor (IP₃R) to promote mitochondrial Ca^2 + transport, little is known about its physiological and pathological relevance in cardiomyocytes.

Main methods

Here we performed Ca^2 + imaging and measured ATP production to define the role of σ₁Rs in regulating sarcoplasmic reticulum (SR)-mitochondrial Ca^2 + transport in neonatal rat ventricular cardiomyocytes treated with angiotensin II to promote hypertrophy.

Key finding

These cardiomyocytes exhibited imbalances in expression levels of σ₁R and IP₃R and impairments in both phenylephrine-induced mitochondrial Ca^2 + mobilization from the SR and ATP production. Interestingly, σ₁R stimulation with fluvoxamine rescued impaired mitochondrial Ca^2 + mobilization and ATP production, an effect abolished by treatment of cells with the σ₁R antagonist, NE-100. Under physiological conditions, fluvoxamine stimulation of σ₁Rs suppressed intracellular Ca^2 + mobilization through IP₃Rs and ryanodine receptors (RyRs). In vivo, chronic administration of fluvoxamine to TAC mice also rescued impaired ATP production.

Significance

These results suggest that σ₁R stimulation with fluvoxamine promotes SR-mitochondrial Ca^2 + transport and mitochondrial ATP production, whereas σ₁R stimulation suppresses intracellular Ca^2 + overload through IP₃Rs and RyRs. These mechanisms likely underlie in part the anti-hypertrophic and cardioprotective action of the σ₁R agonists including fluvoxamine.     

Organic bioelectronics for electronic-to-chemical translation in modulation of neuronal signaling and machine-to-brain interfacing

Background

A major challenge when creating interfaces for the nervous system is to translate between the signal carriers of the nervous system (ions and neurotransmitters) and those of conventional electronics (electrons).

Scope of review

Organic conjugated polymers represent a unique class of materials that utilizes both electrons and ions as charge carriers. Based on these materials, we have established a series of novel communication interfaces between electronic components and biological systems. The organic electronic ion pump (OEIP) presented in this review is made of the polymer–polyelectrolyte system poly(3,4-ethylenedioxythiophene):poly(styrenesulfonate) (PEDOT:PSS). The OEIP translates electronic signals into electrophoretic migration of ions and neurotransmitters.

Major conclusions

We demonstrate how spatio-temporally controlled delivery of ions and neurotransmitters can be used to modulate intracellular Ca^2 + signaling in neuronal cells in the absence of convective disturbances. The electronic control of delivery enables strict control of dynamic parameters, such as amplitude and frequency of Ca^2 + responses, and can be used to generate temporal patterns mimicking naturally occurring Ca^2 + oscillations. To enable further control of the ionic signals we developed the electrophoretic chemical transistor, an analog of the traditional transistor used to amplify and/or switch electronic signals. Finally, we demonstrate the use of the OEIP in a new “machine-to-brain” interface by modulating brainstem responses in vivo.

General significance

This review highlights the potential of communication interfaces based on conjugated polymers in generating complex, high-resolution, signal patterns to control cell physiology. We foresee widespread applications for these devices in biomedical research and in future medical devices within multiple therapeutic areas. This article is part of a Special Issue entitled Organic Bioelectronics—Novel Applications in Biomedicine.     

Ca modulating α-synuclein membrane transient interactions revealed by solution NMR spectroscopy

α-Synuclein is involved in Parkinson's disease and its interaction with cell membrane is crucial to its pathological and physiological functions. Membrane properties, such as curvature and lipid composition, have been shown to affect the interactions by various techniques, but ion effects on α-synuclein membrane interactions remain elusive. Ca^2 + dynamic fluctuation in neurons plays important roles in the onset of Parkinson's disease and its influx is considered as one of the reasons to cause cell death. Using solution Nuclear Magnetic Resonance (NMR) spectroscopy, here we show that Ca^2 + can modulate α-synuclein membrane interactions through competitive binding to anionic lipids, resulting in dissociation of α-synuclein from membranes. These results suggest a negative modulatory effect of Ca^2 + on membrane mediated normal function of α-synuclein, which may provide a clue, to their dysfunction in neurodegenerative disease.