Dietary magnesium intake influences circulating pro-inflammatory neuropeptide levels and loss of myocardial tolerance to postischemic stress

Severe dietary Mg restriction (Mg(9), 9% of recommended daily allowance [RDA], plasma Mg = 0.25 mM) induces a pro-inflammatory neurogenic response in rats (substance P [SP]), and the associated increases in oxidative stress in vivo and cardiac susceptibility to ischemia/reperfusion (I/R) injury were previously shown to be attenuated by SP receptor blockade and antioxidant treatment. The present study assessed if less severe dietary Mg restriction modulates the extent of both the neurogenic/oxidative responses in vivo and I/R injury in vitro. Male Sprague-Dawley rats maintained on Mg(40) (40% RDA, plasma Mg = 0.6 mM) or Mg(100) (100% RDA, plasma Mg = 0.8 mM) diets were assessed for plasma SP levels (CHEM-ELISA) during the first 3 weeks and were compared with the Mg(9) group; red blood cell (RBC) glutathione and plasma malondialdehyde levels were compared at 3 weeks in Mg(9), Mg(20) (plasma Mg = 0.4 mM), Mg(40), and Mg(100) rats; and 40-min global ischemia/30-min reperfusion hearts from 7-week-old Mg(20), Mg(40), and Mg(100) rats were compared with respect to functional recovery (cardiac work, and diastolic, systolic, and developed pressures), tissue LDH release, and free radical production (ESR spectroscopy and alpha-phenyl-N-tert butylnitrone [PBN; 3 mM] spin trapping). The Mg(40) diet induced smaller elevations in plasma SP (50% lower) compared with Mg(9), but with a nearly identical time course. RBC glutathione and plasma malondialdehyde levels revealed a direct relationship between the severity of oxidative stress and hypomagnesemia. The dominant lipid free radical species detected in all I/R groups was the alkoxyl radical (PBN/alkoxyl: alpha(H) = 1.93 G, alpha(N) = 13.63 G); however, Mg(40) and Mg(20) hearts exhibited 2.7- and 3.9-fold higher alkoxyl levels, 40% and 65% greater LDH release, and lower functional recovery (Mg(20) < Mg(40)) compared with Mg(100). Our data suggest that varying dietary Mg intake directly influences the magnitude of the neurogenic/oxidative responses in vivo and the resultant myocardial tolerance to I/R stress.     

Effect of Mg nutriture on the dynamics of administered 25Mg exchange in vivo in the rat

The effect of Mg nutriture on Mg exchange and interorgan distribution was studied in adult rats ten days after a single I.P. dose of (25)Mg ( approximately 5 mg). First the effects of level of Mg intake (0.25, 0.05, or 0.01% Mg) on standard measures of Mg nutriture were studied for 62d to fully document the Mg status of the adult rats. The Mg-deficient diet led to a reduction in plasma, erythrocyte and urine Mg concentration but the only tissues affected were kidney and bone; no outward signs of deficiency were observed. At this point, the 4 remaining rats from each diet group received a single dose of (25)Mg and were killed 10d later. Unlike measures of total Mg content, Mg restriction was observed to significantly alter the distribution of isotope within the soft tissue compartment. The proportion of retained isotope accumulated by soft tissues other than skeletal muscle increased. Because this was not true for skeletal muscle, exogenous (25)Mg label was diverted to more metabolically active tissues during Mg restriction. The apparent Mg exchangeable pool (MgEP) size, determined by in vivo stable isotope dilution, reflected this difference in skeletal muscle (25)Mg accumulation; MgEP size was 39% lower in Mg restricted (0.01% Mg) compared to control (0.05% Mg) rats. The pool of exchangeable Mg in bone was also reduced by Mg restriction but, unlike the soft tissue compartment, the reduction in bone exchangeable Mg was quantitatively similar to the reduction in total Mg content.     

Modulation of Mg2+ efflux from rat ventricular myocytes studied with the fluorescent indicator furaptra

The fluorescent Mg(2+) indicator furaptra (mag-fura-2) was introduced into single ventricular myocytes by incubation with its acetoxy-methyl ester form. The ratio of furaptra's fluorescence intensity at 382 and 350 nm was used to estimate the apparent cytoplasmic [Mg(2+)] ([Mg(2+)](i)). In Ca(2+)-free extracellular conditions (0.1 mM EGTA) at 25 degrees C, [Mg(2+)](i) averaged 0.842 +/- 0.019 mM. After the cells were loaded with Mg(2+) by exposure to high extracellular [Mg(2+)] ([Mg(2+)](o)), reduction of [Mg(2+)](o) to 1 mM (in the presence of extracellular Na(+)) induced a decrease in [Mg(2+)](i). The rate of decrease in [Mg(2+)](i) was higher at higher [Mg(2+)](i), whereas raising [Mg(2+)](o) slowed the decrease in [Mg(2+)](i) with 50% reduction of the rate at approximately 10 mM [Mg(2+)](o). Because a part of the furaptra molecules were likely trapped inside intracellular organelles, we assessed possible contribution of the indicator fluorescence emitted from the organelles. When the cell membranes of furaptra-loaded myocytes were permeabilized with saponin (25 microg/ml for 5 min), furaptra fluorescence intensity at 350-nm excitation decreased to 22%; thus approximately 78% of furaptra fluorescence appeared to represent cytoplasmic [Mg(2+)] ([Mg(2+)](c)), whereas the residual 22% likely represented [Mg(2+)] in organelles (primarily mitochondria as revealed by fluorescence imaging). [Mg(2+)] calibrated from the residual furaptra fluorescence ([Mg(2+)](r)) was 0.6-0.7 mM in bathing solution [Mg(2+)] (i.e., [Mg(2+)](c) of the skinned myocytes) of either 0.8 mM or 4.0 mM, suggesting that [Mg(2+)](r) was lower than and virtually insensitive to [Mg(2+)](c). We therefore corrected furaptra fluorescence signals measured in intact myocytes for this insensitive fraction of fluorescence to estimate [Mg(2+)](c). In addition, by utilizing concentration and dissociation constant values of known cytoplasmic Mg(2+) buffers, we calculated changes in total Mg concentration to obtain quantitative information on Mg(2+) flux across the cell membrane. The calculations indicate that, in the presence of extracellular Na(+), Mg(2+) efflux is markedly activated by [Mg(2+)](c) above the normal basal level (approximately 0.9 mM), with a half-maximal activation of approximately 1.9 mM [Mg(2+)](c). We conclude that [Mg(2+)](c) is tightly regulated by an Mg(2+) efflux that is dependent on extracellular [Na(+)].     

Characterization of Mg(2+) efflux from rat erythrocytes non-loaded with Mg(2+).

Non-Mg(2+)-loaded rat erythrocytes with a physiological level of Mg(2+)(i) exhibited Mg(2+) efflux when incubated in nominally Mg(2+)-free media. Two types of Mg(2+) efflux were shown: (1) An Na(+)-dependent Mg(2+) efflux in NaCl and Na gluconate medium, which was inhibited by amiloride and quinidine, as was Na(2+)/Mg(2+) antiport in Mg(2+)-loaded rat erythrocytes; and (2) an Na(+)-independent Mg(2+) efflux in sucrose medium and choline Cl medium, which may be differentiated into SITS-sensitive Mg(2+) efflux at low Cl(-)(o) (in sucrose) and into SITS-insensitive Mg(2+) efflux at high Cl(-)(o) (in 150 mmol/l choline Cl).     

深圳市森林植被碳储量特征及其空间分布

基于2005年深圳市森林资源二类调查资料数据,采用材积源生物量法,计测深圳市森林植被碳储量和碳密度,分析了深圳市森林植被碳储量空间分布格局.结果表明,2005年深圳市森林植被总碳储量为225.04×10⁴Mg,平均碳密度为25.63MgC·hm^-2.深圳市各区的森林植被碳储量空间分布上有显著差异.表现为龙岗区(123.13×10⁴Mg)>宝安区(46.70×10⁴Mg)>盐田区(20.49×10⁴Mg)>罗湖区(14.75×10⁴Mg)>南山区(12.79×10⁴Mg)>福田区(5.63×10⁴Mg)>保护区(1.57×10⁴Mg).各区碳密度分布为盐田区(46.18MgC·hm^-2)>福田区(37.63 MgC·hm^-2)>罗湖区(36.78MgC·hm^-2)>龙岗区(26.60MgC·hm^-2)>保护区>(24.19 MgC·hm^-2)>宝安区(19.53MgC·hm^-2),与碳储量大小分布无明显相关.深圳市乔木林碳储量为146.11×10⁴Mg,以中幼龄林为主,占73.2%,平均碳密度为30.76MgC·hm^-2.根据森林植被碳储量与碳密度的空间差异性对深圳市森林进行了区划,并分区提出了提高深圳市森林碳吸存能力的有效措施.     

Magnesium deposition and depletion in magnesium supplemented rats during and after hypokinesia and vivarium control

Hypokinesia (diminished movement) induces significant magnesium (Mg) changes; however, little is known about Mg deposition and Mg depletion during HK. Measuring the Mg level in some tissues during HK and post-HK and Mg supplement, we aimed to establish Mg deposition and Mg depletion during prolonged HK. Studies were done on 408, 13-wk-old male Wistar rats (370-390 g) for a 15-d pre-HK period, a 98-d HK period, and a 15-d post-HK period. Rats were equally divided into four groups: unsupplemented vivarium control rats (UVCR), unsupplemented hypokinetic rats (UHKR), supplemented vivarium control rats (SVCR), and supplemented hypokinetic rats (SHKR). Both UHKR and SHKR were kept in small individual cages. The SVCR and SHKR took 53 mg Mg/d. During the HK period, plasma, urinary, and fecal Mg levels increased significantly (p < or = 0.05), whereas during the post-HK period Mg deposition, muscle and bone Mg content decreased significantly (p < or = 0.05) in UHKR and SHKR when compared with their pre-HK values and their respective vivarium controls (UVCR and SVCR). During the initial days of the post-HK period, plasma, urinary, and fecal Mg levels decreased significantly (p < or = 0.05), whereas during the post-HK period Mg deposition, muscle and bone Mg content remained significantly (p < or = 0.05) depressed in UHKR and SHKR when compared with UVCR and SVCR, respectively. However, during the HK period and post-HK period Mg deposition, bone, muscle, plasma, urinary, and fecal Mg levels changed significantly (p < or = 0.05) more in SHKR than UHKR. By contrast, during the HK period and post-HK period. Mg deposition, muscle, bone, plasma, urinary, and fecal Mg values change insignificantly (p > 0.05) in UVCR and SVCR when compared with their pre-HK values. It was concluded that reduced muscle, bone, plasma, urinary, and fecal Mg during post-HK and Mg supplement may demonstrate Mg depletion, whereas higher Mg loss during HK despite reduced muscle and bone Mg and Mg depletion might demonstrate Mg deposition incapacity during HK.     

An ATP-dependent Na+/Mg2+ countertransport is the only mechanism for Mg extrusion in squid axons

The components of magnesium efflux in squid axons have been studied under internal dialysis and voltage clamp conditions. The present report rules out the existence of an ATP-dependent, Nao- and Mgo-independent Mg2+ efflux (ATP-dependent Mg2+ pump) leaving the Mg2+-Na+ exchange system as the only mechanism for Mg2+ extrusion. The main features of the Mg2+ efflux are: (1) The efflux is completely dependent on ATP. (2) The efflux can be activated either by external Na+ (forward Mg2+-Na+ exchange) or external Mg2+ (Mg2+-Mg2+ exchange). (3) The mobility of the Mg2+ exchanger in the Na+o-loaded form is greater than that in the Mg2+-loaded one. (4) In variance with the Na+-Ca2+ exchange mechanism, Mg2+-Mg2+ exchange is not activated by external monovalent cations. (5) ATP gamma S replaces ATP in activating Mg2+-Na+ exchange suggesting that a phosphorylation/dephosphorylation process regulates this transport mechanism.     

Effect of magnesium supplementation and training on magnesium tissue distribution in rats

The aim of this work is to study the effect of training and Mg supplementation on body pools of Mg and on Mg tissue distribution. Forty male Wistar rats were divided into four groups (n=10): control group (C); trained group (T); Mg-supplemented group (+Mg); and trained and Mg-supplemented group (+MgT). The Mg supplement (100 ppm of Mg) was given in the drinking water for 21 d. The training consisted of swimming during 60% of maximal swimming time obtained in the first session to exhaustion, during 3 wk (5 d a week). The variables measured were: erythrocytes (RBC), hemoglobin (Hb), hematocrit (Hto), total proteins (TP), and Mg in serum, RBC, liver, muscle, bone, and kidney. There was less Mg in liver, muscle, and erythrocyte in trained animals than in control or supplemented animals (T vs C, +MgT vs C and +MgT vs +Mg) (p < 0.01). Trained antimals (T and +MgT) showed higher Mg kidney rates than the untrained ones (p<0.01). There was less bone Mg in control (C) and in supplemented and trained (+MgT) groups than in trained (T) and in supplemented (+Mg) animals (p<0.01). Serum Mg showed a decreasing concentration profile in the following order: +Mg, +MgT, T, C (p<0.01). We conclude that Mg supplementation improves bone and serum Mg levels, but this does not affect Mg status in soft tissues. Maintained exercise leads to a diminution of Mg in the aforementioned soft tissues that is not noticeable in serum, probably provoked by an increase of renal excretion.     

Na+/Mg2+ transporter acts as a Mg2+ buffering mechanism in PC12 cells

Mg(2+) buffering mechanisms in PC12 cells were demonstrated with particular focus on the role of the Na(+)/Mg(2+) transporter by using a newly developed Mg(2+) indicator, KMG-20, and also a Na(+) indicator, Sodium Green. Carbonyl cyanide p-(trifluoromethoxy) phenylhydrazone (FCCP), a protonophore, induced a transient increase in the intracellular Mg(2+) concentration ([Mg(2+)](i)). The rate of decrease of [Mg(2+)](i) was slower in a Na(+)-free extracellular medium, suggesting the coupling of Na(+) influx and Mg(2+) efflux. Na(+) influxes were different for normal and imipramine- (a putative inhibitor of the Na(+)/Mg(2+) transporter) containing solutions. FCCP induced a rapid increase in [Na(+)](i) in the normal solution, while the increase was gradual in the imipramine-containing solution. The rate of decrease of [Mg(2+)](i) in the imipramine-containing solution was also slower than that in the normal solution. From these results, we show that the main buffering mechanism for excess Mg(2+) depends on the Na(+)/Mg(2+) transporter in PC12 cells.     

Phosphorylation-dependent modulation of cardiac calcium current by intracellular free magnesium

We compared the effects of cytosolic free magnesium (Mg(2+)(i)) on L-type Ca(2+) current (I(Ca,L)) in patch-clamped guinea pig ventricular cardiomyocytes under basal conditions, after inhibition of protein phosphorylation, and after stimulation of cAMP-mediated phosphorylation. Basal I(Ca,L) density displayed a bimodal dependence on the concentration of Mg(2+)(i) ([Mg(2+)](i); 10(-6)-10(-2) M), which changed significantly as cell dialysis progressed due to a pronounced and long-lasting rundown of I(Ca,L) in low-Mg(2+) dialysates. Ten minutes after patch breakthrough, I(Ca,L) density (at +10 mV) in Mg(2+)(i)-depleted cells ([Mg(2+)](i) approximately 1 microM) was elevated, increased to a maximum at approximately 20 microM [Mg(2+)](i), and declined steeply at higher [Mg(2+)](i). Treatment with the broad-spectrum protein kinase inhibitor K252a (10 microM) reduced I(Ca,L) density and abolished these effects of Mg(2+)(i) except for a negative shift of I(Ca,L)-voltage relations with increasing [Mg(2+)](i). Maximal stimulation of cAMP-mediated phosphorylation occluded the Mg(2+)(i)-induced stimulation of I(Ca,L) and prevented inhibitory effects of the ion at [Mg(2+)](i) <1 mM but not at higher concentrations. These results show that the modulation of I(Ca,L) by Mg(2+)(i) requires protein kinase activity and likely originates from interactions of the ion with proteins involved in the regulation of protein phosphorylation/dephosphorylation. Stimulatory effects of Mg(2+)(i) on I(Ca,L) seem to increase the cAMP-mediated phosphorylation of Ca(2+) channels, whereas inhibitory effects of Mg(2+)(i) appear to curtail and/or reverse cAMP-mediated phosphorylation.     

Characterization of furosemide-sensitive Mg2+ influx in Yoshida ascites tumor cells

Partially Mg2+-depleted Yoshida ascites tumor cells took up Mg2+ after reincubation in Mg2+- and HCO3(-)-containing media. Mg2+ influx was insensitive to ouabain, amiloride and disulfonic stilbenes, but was noncompetitively inhibited by furosemide (Ki = 0.4 mM) and bumetanide. Mg2+ influx obeyed Michaelis-Menten kinetics with respect to Mg2+ concentration (Km = 1.1 mM) and was sigmoidal with respect to HCO3- concentration. Electroneutral Mg2+, HCO3- cotransport was supposed to be the mechanism of Mg2+ influx.     

Cytosolic free magnesium in cardiac myocytes: identification of a Mg2+ influx pathway

Regulation of intracellular Mg2+ activity in the heart is not well characterized. Cardiac myocytes were prepared as primary cultures from 7 day old chick embryo hearts and intracellular Mg2+ concentration [( Mg2+]i) was determined in single ventricular cells with mag-fura-2. Basal [Mg2+]i was 0.48 +/- 0.03 mM in normal culture medium. There was no correlation of basal [Mg2+]i with cellular contraction or intracellular [Ca2+]i (determined with fura-2). Cardiocytes cultured (16 hr) in low Mg (0.16 mM) media contained 0.21 +/- 0.05 mM Mg2+ which returned to normal levels when placed in Mg media with a refill time of 20 min. Basal [Ca2+]i (121 +/- 11 nM) and stimulated [Ca2+]i (231 +/- 41 nM) was similar to control cells. Verapamil, 25 microM, reversibly blocked Mg2+ refill. In conclusion, the basal [Mg2+]i of isolated cardiomyocytes is considerably below the Mg2+ electrochemical equilibrium allowing passive Mg2+ influx. The influx pathway for Mg2+ is inhibited by verapamil and appears to be independent of Ca2+ as assessed by fura-2.     

Anion-dependent Mg2+ influx and a role for a vacuolar H+-ATPase in sheep ruminal epithelial cells

The K+-insensitive component of Mg2+ influx in primary culture of ruminal epithelial cells (REC) was examined by means of fluorescence techniques. The effects of extracellular anions, ruminal fermentation products, and transport inhibitors on the intracellular free Mg2+ concentration ([Mg2+]i), Mg2+ uptake, and intracellular pH were determined. Under control conditions (HEPES-buffered high-NaCl medium), the [Mg2+]i of REC increased from 0.56 +/- 0.14 to 0.76 +/- 0.06 mM, corresponding to a Mg2+ uptake rate of 15 microM/min. Exposure to butyrate did not affect Mg2+ uptake, but it was stimulated (by 84 +/- 19%) in the presence of CO2/HCO(-)3. In contrast, Mg2+ uptake was strongly diminished if REC were suspended in HCO(-)3-buffered high-KCl medium (22.3 +/- 4 microM/min) rather than in HEPES-buffered KCl medium (37.5 +/- 6 microM/min). After switching from high- to low-Cl- solution, [Mg2+]i was reduced from 0.64 +/- 0.09 to 0.32 +/- 0.16 mM and the CO2/HCO(-)3-stimulated Mg2+ uptake was completely inhibited. Bumetanide and furosemide blocked the rate of Mg2+ uptake by 64 and 40%, respectively. Specific blockers of vacuolar H+-ATPase reduced the [Mg2+]i (36%) and Mg2+ influx (38%) into REC. We interpret this data to mean that the K+-insensitive Mg2+ influx into REC is mediated by a cotransport of Mg2+ and Cl- and is energized by an H+-ATPase. The stimulation of Mg2+ transport by ruminal fermentation products may result from a modulation of the H+-ATPase activity.     

Quantification of Mg2+ extrusion and cytosolic Mg2+-buffering in Xenopus oocytes

Intracellular Mg(2+) buffering and Mg(2+) extrusion were investigated in Xenopus laevis oocytes. Mg(2+) or EDTA were pressure injected and the resulting changes in the intracellular Mg(2+) concentration were measured simultaneously with Mg(2+)-selective microelectrodes. In the presence of extracellular Na(+), injected Mg(2+) was extruded from the oocytes with an estimated v(max) and K(M) of 74 pmol cm(-2)s(-1) and 1.28 mM, respectively. To investigate genuine cytosolic Mg(2+) buffering, measurements were carried out in the nominal absence of extracellular Na(+) to block Mg(2+) extrusion, and during the application of CCCP (inhibiting mitochondrial uptake). Under these conditions, Mg(2+) buffering calculated after both MgCl(2) and EDTA injections could be described by a buffer equivalent with a concentration of 9.8mM and an apparent dissociation constant, K(d-app), of 0.6mM together with an [ATP](i) of 0.9 mM with a K(d-app) 0.12 mM. Xenopus oocytes thus possess highly efficient mechanisms to maintain their intracellular Mg(2+) concentration.     

Relationship between low magnesium status and TRPM6 expression in the kidney and large intestine

The body maintains Mg(2+) homeostasis by renal and intestinal (re)absorption. However, the molecular mechanisms that mediate transepithelial Mg(2+) transport are largely unknown. Transient receptor potential melastatin 6 (TRPM6) was recently identified and shown to function in active epithelial Mg(2+) transport in intestine and kidney. To define the relationship between Mg(2+) status and TRPM6 expression, we used two models of hypomagnesemia: 1) C57BL/6J mice fed a mildly or severely Mg(2+)-deficient diet, and 2) mice selected for either low (MgL) or high (MgH) erythrocyte and plasma Mg(2+) status. In addition, the mice were subjected to a severely Mg(2+)-deficient diet. Our results show that C57BL/6J mice fed a severely Mg(2+)-deficient diet developed hypomagnesemia and hypomagnesuria and showed increased TRPM6 expression in kidney and intestine. When fed a Mg(2+)-adequate diet, MgL mice presented hypomagnesemia and hypermagnesuria, and lower kidney and intestinal TRPM6 expression, compared with MgH mice. A severely Mg(2+)-deficient diet led to hypomagnesemia and hypomagnesuria in both strains. Furthermore, this diet induced kidney TRPM6 expression in MgL mice, but not in MgH mice. In conclusion, as shown in C57BL/6J mice, dietary Mg(2+)-restriction results in increased Mg(2+) (re)absorption, which is correlated with increased TRPM6 expression. In MgL and MgH mice, the inherited Mg(2+) status is linked to different TRPM6 expression. The MgL and MgH mice respond differently to a low-Mg(2+) diet with regard to TRPM6 expression in the kidney, consistent with genetic factors contributing to the regulation of cellular Mg(2+) levels. Further studies of these mice strains could improve our understanding of the genetics of Mg(2+) homeostasis.     

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.     

Divergent effects of the malignant hyperthermia-susceptible Arg(615)-->Cys mutation on the Ca(2+) and Mg(2+) dependence of the RyR1

The sarcoplasmic reticulum (SR) Ca(2+) release channel (RyR1) from malignant hyperthermia-susceptible (MHS) porcine skeletal muscle has a decreased sensitivity to inhibition by Mg(2+). This diminished Mg(2+) inhibition has been attributed to a lower Mg(2+) affinity of the inhibition (I) site. To determine whether alterations in the Ca(2+) and Mg(2+) affinity of the activation (A) site contribute to the altered Mg(2+) inhibition, we estimated the Ca(2+) and Mg(2+) affinities of the A- and I-sites of normal and MHS RyR1. Compared with normal SR, MHS SR required less Ca(2+) to half-maximally activate [(3)H]ryanodine binding (K(A,Ca): MHS = 0.17 +/- 0.01 microM; normal = 0.29 +/- 0.02 microM) and more Ca(2+) to half-maximally inhibit ryanodine binding (K(I,Ca): MHS = 519.3 +/- 48.7 microM; normal = 293.3 +/- 24.2 microM). The apparent Mg(2+) affinity constants of the MHS RyR1 A- and I-sites were approximately twice those of the A- and I-sites of the normal RyR1 (K(A,Mg): MHS = 44.36 +/- 4.54 microM; normal = 21.59 +/- 1.66 microM; K(I,Mg): MHS = 660.8 +/- 53.0 microM; normal = 299.2 +/- 24.5 microM). Thus, the reduced Mg(2+) inhibition of the MHS RyR1 compared with the normal RyR1 is due to both an enhanced selectivity of the MHS RyR1 A-site for Ca(2+) over Mg(2+) and a reduced Mg(2+) affinity of the I-site.     

Tissue magnesium loss during prolonged hypokinesia in magnesium supplemented and unsupplemented rats

This study aims at showing that during hypokinesia (HK) tissue magnesium (Mg2+) content decreases more with higher Mg2+ intake than with lower Mg2+ intake and that Mg2+ loss increases more with higher than lower tissue Mg2+ depletion due to inability of the body to use Mg2+ during HK. Studies were conducted on male Wistar rats during a pre-HK period and a HK period. Rats were equally divided into four groups: unsupplemented vivarium control rats (UVCR), unsupplemented hypokinetic rats (UHKR), supplemented vivarium control rats (SVCR) and supplemented hypokinetic rats (SHKR). SVCR and SHKR consumed 42 mEq Mg2+ per day. The gastrocnemius muscle and right femur bone Mg2+ content decreased significantly, while plasma Mg2+ level and urine and fecal Mg2+ loss increased significantly in SHKR and UHKR compared with their pre-HK values and their respective vivarium controls (SVCR and UVCR). However, muscle and bone Mg2+ content decreased more significantly and plasma Mg2+ level, and urine and fecal Mg2+ loss increased more significantly in SHKR than in UHKR. The greater tissue Mg2+ loss with higher Mg2+ intake and the lower tissue Mg2+ loss with lower Mg2+ intake shows that the risk of higher tissue Mg2+ depletion is directly related to the magnitude of Mg2+ intake. The higher Mg2+ loss with higher tissue Mg2+ depletion and the lower Mg2+ loss with lower Mg2+ tissue depletion shows that the risk of greater Mg2+ loss is directly related to the magnitude of tissue Mg2+ depletion. It was concluded that tissue Mg2+ depletion increases more when the Mg2+ intake is higher and that Mg2+ loss increases more with higher than lower tissue Mg2+ depletion indicating that during prolonged HK the tissue Mg2+ depletion is not due to the Mg2+ shortage in food but to the inability of the body to use Mg2+.