4-oxo-4H-quinolizine-3-carboxylic acids as Mg2+ selective, fluorescent indicators

In this paper, we present the synthesis of a new series of substituted 4-oxo-4H-quinolizine-3-carboxylic acids and the evaluation of their fluorescent response upon complexation with Mg2+ and Ca2+. This has led to the development of the first Mg2+-selective, ratioable fluorescent indicators. We found that 4-oxo-4H-quinolizine-3-carboxylates are excellent fluorophores which show a strong fluorescent response to Mg2+ but not to Ca2; the latter metal ion often causing interference during Mg2+ measurements with previously described indicators. The dissociation constants of the studied fluorophores-around 1.0 mM-are of the same order of magnitude as is usually observed for intracellular Mg2+.     

Role of magnesium in nucleotide exchange on the small G protein rac investigated using novel fluorescent Guanine nucleotide analogues

Novel guanine nucleotide analogues have been used to investigate the role of Mg(2+) in nucleotide release and binding with the small G protein rac. The fluorescent analogues have 7-(ethylamino)-8-bromocoumarin-3-carboxylic acid attached to the 3'-position of the ribose via an ethylenediamine linker. This modification has only small effects on the interaction with rac. There are large fluorescence changes on binding of the triphosphate to rac, on hydrolysis, and then on release of the diphosphate. Furthermore, the fluorescence is sensitive to the presence of Mg(2+) in the active site. Using this signal, it was shown that, for a variety of conditions, the nucleotides dissociate by a two-step mechanism. Mg(2+) is released first followed by the nucleotide. With the diphosphate, Mg(2+) is fast and nucleotide release slow. For the fluorescent GMPPNP analogue, the rate of dissociation is limited by Mg(2+) release. In the latter case, Mg(2+) binds tightly with a K(d) of 61 nM, whereas for the diphosphate the K(d) is 11 microM (30 degrees C, pH 7.6).     

Light-induced increase in free Mg2+ concentration in spinach chloroplasts: measurement of free Mg2+ by using a fluorescent probe and necessity of stromal alkalinization

Free Mg(2+) in chloroplasts may contribute to the regulation of photosynthetic enzymes, but adequate methodology for the determination of free Mg(2+) concentration ([Mg(2+)]) in chloroplasts has been lacking. We measured internal chloroplast [Mg(2+)] by using a Mg-sensitive fluorescent indicator, mag-fura-2. In intact, dark-kept spinach chloroplasts, internal [Mg(2+)] was estimated to be 0.50 mM, and illumination caused an increase in [Mg(2+)] to 2.0mM in the stroma. The light-induced increase in [Mg(2+)] was inhibited by a blocker of driven electron transport and uncouplers. The K(+)-specific ionophore valinomycin inhibited the [Mg(2+)] increase in the absence of external K(+), and addition of KCl restored the [Mg(2+)] increase. NH(4)Cl, which induces stromal alkalinization, enhanced the [Mg(2+)] increase. A Ca(2+)-channel blocker, ruthenium red, inhibited the [Mg(2+)] increase, but LaCl(3) had no effect. These results indicate that stromal alkalinization is essential for light-induced increase in [Mg(2+)]. This system for measuring internal chloroplast [Mg(2+)] might provide a suitable system for assay of Mg(2+) transport activity of chloroplast membranes.     

Ion-induced conformational and stability changes in Nereis sarcoplasmic calcium binding protein: evidence that the APO state is a molten globule

Nereis sarcoplasmic Ca(2+)-binding protein (NSCP) is a calcium buffer protein that binds Ca(2+) ions with high affinity but is also able to bind Mg(2+) ions with high positive cooperativity. We investigated the conformational and stability changes induced by the two metal ions. The thermal reversible unfolding, monitored by circular dichroism spectroscopy, shows that the thermal stability is maximum at neutral pH and increases in the order apo < Mg(2+) < Ca(2+). The stability against chemical denaturation (urea, guanidinium chloride) studied by circular dichroism or intrinsic fluorescence was found to have a similar ion dependence. To explore in more detail the structural basis of stability, we used the fluorescent probes to evaluate the hydrophobic surface exposure in the different ligation states. The apo-NSCP exhibits accessible hydrophobic surfaces, able to bind fluorescent probes, in clear contrast with denatured or Ca(2+)/Mg(2+)-bound states. Gel filtration experiments showed that, although the metal-bound NSCP has a hydrodynamic volume in agreement with the molecular mass, the volume of the apo form is considerably larger. The present results demonstrate that the apo state has many properties in common with the molten globule. The possible factors of the metal-dependent structural changes and stability are discussed.     

Ca(2+) measurements in skinned cardiac fibers: effects of Mg(2+) on Ca(2+) activation of force and fiber ATPase.

In contrast to previous studies, a new fluorescent method was used to accurately determine the Ca(2+) concentration in test solutions used to activate skinned rat cardiac cells. This method used the calcium green-2 fluorescent indicator, which is shown to change its fluorescence over the Ca(2+) range responsible for Ca(2+) activation of force and ATPase. The dissociation constant (K(d)) of calcium green-2 for Ca(2+) was determined for three different Mg(2+) concentrations in solutions similar to those used in the experiment. Increasing Mg(2+) concentration from 1.0 to 8.0 mM had no significant effect on the Ca(2+) sensitivity of either force or actomyosin ATPase activity, in contrast to previous reported studies on force. The ATPase activity was activated at lower Ca(2+) concentration than the force. The ratio (ATPase/force) is proportional to the dissociation rate of force-generating myosin cross bridges and decreased during Ca(2+) activation. These findings are consistent with the hypothesis that cardiac muscle contraction is activated by a single Ca(2+)-specific binding site on troponin C.     

Mechanisms of Mg(2+) transport in cultured ruminal epithelial cells

Net Mg(2+) absorption from the rumen is mainly mediated by a transcellular pathway, with the greater part (62%) being electrically silent. To investigate this component of Mg(2+) transport, experiments were performed with isolated ruminal epithelial cells (REC). Using the fluorescent indicators mag-fura 2, sodium-binding benzofuran isophthalate, and 2', 7'-bis(2-carboxyethyl)-5(6)-carboxyfluorescein, we measured the intracellular free Mg(2+) concentration ([Mg(2+)](i)), the intracellular Na(+) concentration ([Na(+)](i)), and the intracellular pH (pH(i)) of REC under basal conditions, after stimulation with butyrate and HCO(-)(3), and after changing the transmembrane chemical gradients for Mg(2+), H(+), and Na(+). REC had a mean resting pH(i) of 6.83 +/- 0.1, [Mg(2+)](i) was 0.56 +/- 0. 14 mM, and [Na(+)](i) was 18.95 +/- 3.9 mM. Exposure to both HCO(-)(3) and HCO(-)(3)/butyrate led to a stimulation of Mg(2+) influx that amounted to 27.7 +/- 5 and 29 +/- 10.6 microM/min, respectively, compared with 15 +/- 1 microM/min in control solution. The increase of [Mg(2+)](i) was dependent on extracellular Mg(2+) concentration ([Mg(2+)](e)). Regulation of pH(i) has been demonstrated to be Na(+) dependent and is performed, for the most part, by a Na(+)/H(+) exchanger. The recovery of pH(i) was fully blocked in nominally Na(+)-free media, even if [Mg(2+)](e) was stepwise increased from 0 to 7.5 mM. However, an increase of [Mg(2+)](i) was observed after reversing the transmembrane Na(+) gradient. This rise in [Mg(2+)](i) was pH independent, K(+) insensitive, dependent on [Mg(2+)](e), imipramine and quinidine sensitive, and accompanied by a decrease of [Na(+)](i). The results are consistent with the existence of a Na(+)/Mg(2+) exchanger in the cell membrane of REC. The coupling between butyrate, CO(2)/HCO(-)(3), and Mg(2+) transport may be mediated by another mechanism, perhaps by cotransport of Mg(2+) and HCO(-)(3).     

Polyvalent cation-sensing mechanism increased Na(+)-independent Mg(2+) transport in renal epithelial cells

Extracellular Ca(2+)/polyvalent cation-sensing receptor (CaSR) is capable of monitoring changes in extracellular polyvalent cation concentrations. In the present study, we investigated whether CaSR agonists reinforce the decrease of intracellular free Mg(2+) concentration ([Mg(2+)](i)) induced by extracellular Mg(2+) plus Na(+) removal. Interestingly, exposure of NRK-52E renal epithelial cells to increasing extracellular Mg(2+) concentrations from 0.8 to 15 mM for 1-2 days resulted in a twofold increase in the levels of CaSR mRNA and protein. By fluorophotometer (with mag-fura 2 fluorescent dye) and atomic absorption spectrophotometer, we confirmed that activation of CaSR by neomycin (0.5 mM) or gadolinium (1 mM) reinforced the decrease of [Mg(2+)](i) induced by Mg(2+) removal in the cells cultured in 10 mM Mg(2+)-containing medium. The neomycin-induced [Mg(2+)](i) decrease was inhibited by nicardipine (50 microM), but not by verapamil (50 microM) or amiloride (0.1 mM). These results indicate that CaSR monitors extracellular Mg(2+) concentration, and probably cause activation of Na(+)-independent Mg(2+)-transport system.     

Newly developed Mg2+-selective fluorescent probe enables visualization of Mg2+ dynamics in mitochondria

Mg(2+) plays important roles in numerous cellular functions. Mitochondria take part in intracellular Mg(2+) regulation and the Mg(2+) concentration in mitochondria affects the synthesis of ATP. However, there are few methods to observe Mg(2+) in mitochondria in intact cells. Here, we have developed a novel Mg(2+)-selective fluorescent probe, KMG-301, that is functional in mitochondria. This probe changes its fluorescence properties solely depending on the Mg(2+) concentration in mitochondria under physiologically normal conditions. Simultaneous measurements using this probe together with a probe for cytosolic Mg(2+), KMG-104, enabled us to compare the dynamics of Mg(2+) in the cytosol and in mitochondria. With this method, carbonyl cyanide p-(trifluoromethoxy) phenylhydrazone (FCCP)-induced Mg(2+) mobilization from mitochondria to the cytosol was visualized. Although a FCCP-induced decrease in the Mg(2+) concentration in mitochondria and an increase in the cytosol were observed both in differentiated PC12 cells and in hippocampal neurons, the time-courses of concentration changes varied with cell type. Moreover, the relationship between mitochondrial Mg(2+) and Parkinson's disease was analyzed in a cellular model of Parkinson's disease by using the 1-methyl-4-phenylpyridinium ion (MPP(+)). A gradual decrease in the Mg(2+) concentration in mitochondria was observed in response to MPP(+) in differentiated PC12 cells. These results indicate that KMG-301 is useful for investigating Mg(2+) dynamics in mitochondria. All animal procedures to obtain neurons from Wistar rats were approved by the ethical committee of Keio University (permit number is 09106-(1)).     

Human gene SLC41A1 encodes for the Na+/Mg²+ exchanger

Magnesium (Mg(2+)), the second most abundant divalent intracellular cation, is involved in the vast majority of intracellular processes, including the synthesis of nucleic acids, proteins, and energy metabolism. The concentration of intracellular free Mg(2+) ([Mg(2+)](i)) in mammalian cells is therefore tightly regulated to its optimum, mainly by an exchange of intracellular Mg(2+) for extracellular Na(+). Despite the importance of this process for cellular Mg(2+) homeostasis, the gene(s) encoding for the functional Na(+)/Mg(2+) exchanger is (are) still unknown. Here, using the fluorescent probe mag-fura 2 to measure [Mg(2+)](i) changes, we examine Mg(2+) extrusion from hSLC41A1-overexpressing human embryonic kidney (HEK)-293 cells. A three- to fourfold elevation of [Mg(2+)](i) was accompanied by a five- to ninefold increase of Mg(2+) efflux. The latter was strictly dependent on extracellular Na(+) and reduced by 91% after complete replacement of Na(+) with N-methyl-d-glucamine. Imipramine and quinidine, known unspecific Na(+)/Mg(2+) exchanger inhibitors, led to a strong 88% to 100% inhibition of hSLC41A1-related Mg(2+) extrusion. In addition, our data show regulation of the transport activity via phosphorylation by cAMP-dependent protein kinase A. As these are the typical characteristics of a Na(+)/Mg(2+) exchanger, we conclude that the human SLC41A1 gene encodes for the Na(+)/Mg(2+) exchanger, the predominant Mg(2+) efflux system. Based on this finding, the analysis of Na(+)/Mg(2+) exchanger regulation and its involvement in the pathogenesis of diseases such as Parkinson's disease and hypertension at the molecular level should now be possible.     

Mg2+-induced tRNA folding

Mg(2+)-induced folding of yeast tRNA(Phe) was examined at low ionic strength in steady-state and kinetic experiments. By using fluorescent labels attached to tRNA, four conformational transitions were revealed when the Mg(2+) concentration was gradually increased. The last two transitions were not accompanied by changes in the number of base pairs. The observed transitions were attributed to Mg(2+) binding to four distinct types of sites. The first two types are strong sites with K(diss) of 4 and 16 microM. The sites of the third and fourth types are weak with a K(diss) of 2 and 20 mM. Accordingly, the Mg(2+)-binding sites previously classified as "strong" and "weak" can be further subdivided into two subtypes each. Fluorescent transition I is likely to correspond to Mg(2+) binding to a unique strong site selective for Mg(2+); binding to this site causes only minor A(260) change. The transition at 2 mM Mg(2+) is accompanied by substantial conformational changes revealed by probing with ribonucleases T1 and V1 and likely enhances stacking of the tRNA bases. Fast and slow kinetic phases of tRNA refolding were observed. Time-resolved monitoring of Mg(2+) binding to tRNA suggested that the slow kinetic phase was caused by a misfolded tRNA structure formed in the absence of Mg(2+). Our results suggest that, similarly to large RNAs, Mg(2+)-induced tRNA folding exhibits parallel folding pathways and the existence of kinetically trapped intermediates stabilized by Mg(2+). A multistep scheme for Mg(2+)-induced tRNA folding is discussed.     

Battle for the EF-hands: magnesium-calcium interference in calmodulin.

The ubiquitous Ca(2+)-regulatory protein calmodulin activates target enzymes as a response to submicromolar Ca(2+) increases in a background of millimolar Mg(2+). The potential influence of Mg(2+)/Ca(2+) competition is especially intriguing for the N-terminal domain of the protein which possesses the sites with the lowest Ca(2+) specificity. The interdependence of Ca(2+) and Mg(2+) binding in the N-terminal domain of calmodulin was therefore studied using (43)Ca NMR, (1)H-(15)N NMR, and fluorescent Ca(2+) chelator techniques. The apparent affinity for Ca(2+) was found to be significantly decreased at physiological Mg(2+) levels. At Ca(2+) concentrations of an activated cell the (Ca(2+))(2) state of the N-terminal domain is therefore only weakly populated, indicating that for this domain Ca(2+) binding is intimately associated with binding of target molecules. The data are in good agreement with a two-site model in which each site can bind either Ca(2+) or Mg(2+). The Mg(2+)-Ca(2+) binding interaction is slightly positively allosteric, resulting in a significantly populated (Mg(2+))(1)(Ca(2+))(1) state. The Ca(2+) off-rate from this state is determined to be at least one order of magnitude faster than from the (Ca(2+))(2) state. These two findings indicate that the (Mg(2+))(1)(Ca(2+))(1) state is structurally and/or dynamically different from the (Ca(2+))(2) state. The (43)Ca quadrupolar coupling constant and the (1)H and (15)N chemical shifts of the (Mg(2+))(1)(Ca(2+))(1) state were calculated from titration data. The values of both parameters suggest that the (Mg(2+))(1)(Ca(2+))(1) state has a conformation more similar to the "closed" apo and (Mg(2+))(2) states than to the "open" (Ca(2+))(2) state.     

Extracellular Mg2+ induces an intracellular Ca2+ wave during oocyte activation in the marine shrimp Sicyonia ingentis.

In contrast to most systems in which oocyte activation is triggered by the fertilizing sperm, Sicyonia ingentis oocytes are activated by seawater Mg2+ during spawning. S. ingentis oocytes were spawned into Mg(2+)-free seawater and microinjected with the fluorescent Ca2+ indicator Fluo-3 to study the effects of added Mg2+ on intracellular Ca2+ levels. The Mg2+ induced a wave of fluorescence across the oocyte that traveled at a speed of 13 +/- 3 microns/sec. Extracellular Ca2+ was not required for induction of the wave. Treatment with Ca2+ ionophore in Mg(2+)-free medium or a localized injection (0.3% oocyte volume) of 3-5 microM Ca2+ also initiated the wave; injection of 250 mM Mg2+ (up to 1.5% oocyte volume) had no effect. Microinjection of 750 microM EGTA (final) suppressed the Mg(2+)-induced wave, while an identical concentration of EDTA had no inhibitory effect. Subsequent to the initial Mg(2+)-induced intracellular Ca2+ increase, a second Ca2+ increase was observed at approximately 15 min postspawning; the timing of this second increase appeared to be independent of when the Mg(2+)-induced wave was initiated, thus an event associated with spawning may be involved. While oocytes in normal seawater were monospermic, those in Mg(2+)-free seawater were polyspermic, suggesting a role for the Mg(2+)-induced Ca2+ wave in regulating sperm entry into the oocyte.     

A charge reversal differentiates (p)ppGpp synthesis by monofunctional and bifunctional Rel proteins

A major regulatory mechanism evolved by microorganisms to combat stress is the regulation mediated by (p)ppGpp (the stringent response molecule), synthesized and hydrolyzed by Rel proteins. These are divided into bifunctional and monofunctional proteins based on the presence or absence of the hydrolysis activity. Although these proteins require Mg(2+) for (p)ppGpp synthesis, high Mg(2+) was shown to inhibit this reaction in bifunctional Rel proteins from Mycobacterium tuberculosis and Streptococcus equisimilis. This is not a characteristic feature in enzymes that use a dual metal ion mechanism, such as DNA polymerases that are known to carry out a similar pyrophosphate transfer reaction. Comparison of polymerase Polbeta and Rel(Seq) structures that share a common fold led to the proposal that the latter would follow a single metal ion mechanism. Surprisingly, in contrast to bifunctional Rel, we did not find inhibition of guanosine 5'-triphosphate, 3'-diphosphate (pppGpp) synthesis at higher Mg(2+) in the monofunctional RelA from Escherichia coli. We show that a charge reversal in a conserved motif in the synthesis domains explains this contrast; an RXKD motif in the bifunctional proteins is reversed to an EXDD motif. The differential response of these proteins to Mg(2+) could also be noticed in fluorescent nucleotide binding and circular dichroism experiments. In mutants where the motifs were reversed, the differential effect could also be reversed. We infer that although a catalytic Mg(2+) is common to both bifunctional and monofunctional proteins, the latter would utilize an additional metal binding site formed by EXDD. This work, for the first time, brings out differences in (p)ppGpp synthesis by the two classes of Rel proteins.     

Luminal Ca2+-regulated Mg2+ inhibition of skeletal RyRs reconstituted as isolated channels or coupled clusters

In resting muscle, cytoplasmic Mg(2+) is a potent inhibitor of Ca(2+) release from the sarcoplasmic reticulum (SR). It is thought to inhibit calcium release channels (RyRs) by binding both to low affinity, low specificity sites (I-sites) and to high affinity Ca(2+) sites (A-sites) thus preventing Ca(2+) activation. We investigate the effects of luminal and cytoplasmic Ca(2+) on Mg(2+) inhibition at the A-sites of skeletal RyRs (RyR1) in lipid bilayers, in the presence of ATP or modified by ryanodine or DIDS. Mg(2+) inhibits RyRs at the A-site in the absence of Ca(2+), indicating that Mg(2+) is an antagonist and does not simply prevent Ca(2+) activation. Cytoplasmic Ca(2+) and Cs(+) decreased Mg(2+) affinity by a competitive mechanism. We describe a novel mechanism for luminal Ca(2+) regulation of Ca(2+) release whereby increasing luminal [Ca(2+)] decreases the A-site affinity for cytoplasmic Mg(2+) by a noncompetitive, allosteric mechanism that is independent of Ca(2+) flow. Ryanodine increases the Ca(2+) sensitivity of the A-sites by 10-fold, which is insufficient to explain the level of activation seen in ryanodine-modified RyRs at nM Ca(2+), indicating that ryanodine activates independently of Ca(2+). We describe a model for ion binding at the A-sites that predicts that modulation of Mg(2+) inhibition by luminal Ca(2+) is a significant regulator of Ca(2+) release from the SR. We detected coupled gating of RyRs due to luminal Ca(2+) permeating one channel and activating neighboring channels. This indicated that the RyRs existed in stable close-packed rafts within the bilayer. We found that luminal Ca(2+) and cytoplasmic Mg(2+) did not compete at the A-sites of single open RyRs but did compete during multiple channel openings in rafts. Also, luminal Ca(2+) was a stronger activator of multiple openings than single openings. Thus it appears that RyRs are effectively "immune" to Ca(2+) emanating from their own pore but sensitive to Ca(2+) from neighboring channels.     

Spatial distribution of cytoplasmic domains of the Mg(2+)-transporter MgtE, in a solution lacking Mg(2+), revealed by paramagnetic relaxation enhancement

MgtE is a prokaryotic Mg(2+) transporter that controls cellular Mg(2+) concentrations. We previously reported crystal structures of the cytoplasmic region of MgtE, consisting of 2 domains, that is, N and CBS, in the Mg(2+)-free and Mg(2+)-bound forms. The Mg(2+)-binding sites lay at the interface of the 2 domains, making the Mg(2+)-bound form compact and globular. In the Mg(2+)-free structure, however, the domains are far apart, and the Mg(2+)-binding sites are destroyed. Therefore, it is unclear how Mg(2+)-free MgtE changes its conformation to accommodate Mg(2+) ions. Here, we used paramagnetic relaxation enhancement (PRE) to characterize the relative orientation of the N and CBS domains in the absence of Mg(2+) in solution. When the residues on the surface of the CBS domain were labeled with nitroxide tags, significant PRE effects were observed for the residues in the N domain. No single structure satisfied the PRE profiles, suggesting that the N and CBS domains are not fixed in a particular orientation in solution. We then conducted ensemble simulated annealing calculations in order to obtain the atomic probability density and visualize the spatial distribution of the N domain in solution. The results indicate that the N domain tends to occupy the space near its position in the Mg(2+)-bound crystal structure, facilitating efficient capture of Mg(2+) with increased intracellular Mg(2+) concentration, which is necessary to close the gate.     

Relationship between total and free cellular Mg(2+) during metabolic stimulation of rat cardiac myocytes and perfused hearts

The changes in total Mg were compared with changes in cytosolic free Mg(2+) during metabolic stimulation of collagenase-dispersed rat cardiac myocytes or Langendorff-perfused rat hearts. In myocytes the addition of agents leading to cAMP increase or protein kinase C activation results in a loss or gain of more than 5% of total Mg content within 3 min (i.e., 3-4 nmol Mg/mg protein). Under the same conditions, changes in cytosolic free Mg(2+) measured with fluorescent indicator are small and result in changes of cytosolic free Mg(2+) equivalent to 90-140 microM. In perfused hearts, beta-adrenergic stimulation results in a loss of total Mg larger than 0.5 micromol per gram of heart corresponding to 9% loss of total Mg content of the heart (estimated to be 5.8 micromol). Under these conditions there is no change in cytosolic free Mg(2+) or the major buffer of cytosolic Mg(2+), ATP, as measured by (31)P NMR. These data suggest that a major redistribution of total Mg occurs in intracellular organelles or in cytosolic buffers in order to maintain cytosolic free Mg(2+) relatively unchanged during the observed cellular massive translocation of total Mg. Hence, Mg(2+) may regulate metabolic functions not within the cytosol but in locations where its concentration oscillates, such as extracellular fluid and intracellular compartments.     

Enhanced dynamic range in a genetically encoded Ca2+ sensor

Genetically encoded fluorescence resonance energy transfer (FRET) indicators are powerful tools for real-time detection of second messenger molecules and activation of signal proteins. However, these fluorescent protein-based sensors typically display marginal FRET efficiency. To improve their FRET efficiency for optical imaging and screening, we developed a number of fluorescent protein mutants based on cyan fluorescent protein (CFP) and yellow fluorescent protein (YFP). To improve FRET ratios, which were initially within a narrow dynamic range, we used DNA shuffling to develop a new FRET pair called 3xCFP/Venus. The optimized 3xCFP/Venus pair exhibited higher FRET ratios than CyPet/YPet, which has one of the greatest dynamic ranges of protein-based FRET pairs. We converted this FRET pair to a Ca(2+) FRET indicators using circular permutation Venus (cpVenus) linked with 3xCFP to form 3xCFP/cpVenus, which displayed an ～11-fold change in dynamic range in response to Ca(2+) binding. The enhanced dynamic range for Ca(2+) concentration detection using 3xCFP/cpVenus was confirmed in PC12 cells using previously established indicators (TN-XXL, ECFP/cpCitrine). To our knowledge, this FRET pair displays the largest dynamic range so far among genetically-encoded sensors, and can be used for sensitive FRET detection.     

Mrs2p is an essential component of the major electrophoretic Mg2+ influx system in mitochondria

Steady-state concentrations of mitochondrial Mg(2+) previously have been shown to vary with the expression of Mrs2p, a component of the inner mitochondrial membrane with two transmembrane domains. While its structural and functional similarity to the bacterial Mg(2+) transport protein CorA suggested a role for Mrs2p in Mg(2+) influx into the organelle, other functions in cation homeostasis could not be excluded. Making use of the fluorescent dye mag-fura 2 to measure free Mg(2+) concentrations continuously, we describe here a high capacity, rapid Mg(2+) influx system in isolated yeast mitochondria, driven by the mitochondrial membrane potential Deltapsi and inhibited by cobalt(III)hexaammine. Overexpression of Mrs2p increases influx rates 5-fold, while the deletion of the MRS2 gene abolishes this high capacity Mg(2+) influx. Mg(2+) efflux from isolated mitochondria, observed with low Deltapsi only, also requires the presence of Mrs2p. Cross-linking experiments revealed the presence of Mrs2p-containing complexes in the mitochondrial membrane, probably constituting Mrs2p homo- oligomers. Taken together, these findings characterize Mrs2p as the first molecularly identified metal ion channel protein in the inner mitochondrial membrane.     

Alterations of ionized Mg2+ in human blood after exercise

Magnesium (Mg) is the second most abundant intracellular cation with modulating properties in a number of metabolic processes, e.g. in glycolysis, and intracellular signalling processes, e.g. regulation of ion channels and transporters. There are conflicting data available about the regulation of Mg in blood cells during exercise. Moreover, there are no data available about changes of the metabolic important fraction of ionized Mg(2+) both in blood and in blood cells during exercise. The present study investigated the changes of ionized Mg(2+) and total Mg concentration in different compartments after a stepwise treadmill ergometer test. Intracellular ionized Mg(2+) of thrombocytes and erythrocytes was determined by the magnesium sensitive fluorescent dyes mag-fura-2 and Mag-Green using fluorescence spectroscopy and flow cytometry, respectively. Ionized Mg(2+) in blood/serum was measured by an ion-sensitive microelectrode. Total cellular and serum Mg concentration were investigated using atomic absorbance spectroscopy and photometry, respectively. The present results shown that at the end of the ergometer test, ionized Mg(2+) in both blood and serum and total serum Mg decreased. In contrast, intracellular concentration of ionized Mg increased in both thrombocytes and erythrocytes. Total intracellular Mg was unchanged making a Mg(2+) shift between the intra- and extracellular compartment unlikely. The present study therefore demonstrated opposite changes of the ratio [ionized Mg(2+)]/[total Mg] in the intracellular and the extracellular compartment after anaerobic exercise. In in vitro experiments, similar changes of ionized Mg(2+) in both compartments could be mimicked by application of weak acids like propionic and lactic acid. It is concluded changes in the fraction of ionized Mg(2+) should be high enough to influence intracellular signalling and metabolic processes.