EFFECT OF ACTIVE ACCUMULATION OF CALCIUM AND PHOSPHATE IONS ON THE STRUCTURE OF RAT LIVER MITOCHONDRIA

Rat liver mitochondria allowed to accumulate maximal amounts of Ca⁺⁺ and HPO₄⁼ ions from the suspending medium in vitro during respiration have a considerably higher specific gravity than normal mitochondria and may be easily separated from the latter by isopycnic centrifugation in density gradients of sucrose or cesium chloride. When the mitochondria are allowed to accumulate less than maximal amounts of Ca⁺⁺ and HPO₄⁼ from the medium, they have intermediate specific gravities which are roughly proportional to their content of calcium phosphate. Maximally "loaded" mitochondria are relatively homogeneous with respect to specific gravity. Correlated biochemical and electron microscopic studies show that Ca⁺⁺-loaded mitochondria contain numerous dense granules, of which some 85 per cent are over 500 A in diameter. These granules are electron-opaque not only following fixation and staining with heavy metal reagents, but also following fixation with formaldehyde, demonstrating that the characteristic granules in Ca⁺⁺-loaded mitochondria have intrinsic electron-opacity. The dense granules are almost always located within the inner compartment of the mitochondria and not in the space between the inner and outer membranes. They are frequently located at or near the cristae and they often show electron-transparent "cores." Such granules appear to be made up of clusters of smaller dense particles, but preliminary x-ray diffraction analysis and electron diffraction studies have revealed no evidence of crystallinity in the deposits. The electron-opaque granules decrease in number when the Ca⁺⁺-loaded mitochondria are incubated with 2,4-dinitrophenol; simultaneously there is discharge of Ca⁺⁺ and phosphate from the mitochondria into the medium.     

OSMOTICALLY LYSED RAT LIVER MITOCONDRIA : Biochemical and Ultrastructural Properties in Relation to Massive Ion Accumulation

Osmotically lysed rat liver mitochondria have been utilized for a study of the biochemical and ultrastructural properties in relation to divalent ion accumulation. Osmotic lysis of mitochondria by suspension and washing in cold, distilled water results in the extraction of about 50% of the mitochondrial protein, the loss of the outer mitochondrial membrane, an increase in respiration, and a marked decrease in the ability to catalyze oxidative phosphorylation. Nevertheless, except for a decrease in the ability to accumulate Sr²⁺ by an ATP-supported process, these lysed mitochondria retain full capacity to accumulate massive amounts of divalent cations by respiration-dependent and ATP-supported mechanisms. The decreased ability of osmotically lysed mitochondria to accumulate Sr²⁺ by an ATP-energized process does not appear to be due to a loss or inactivation of a specific Sr²⁺-activated ATPase. The energy-dependent accumulation processes in lysed mitochondria show an increased sensitivity to inhibition by monovalent cations. Extraction of cytochrome c from osmotically lysed mitochondria results in a complete loss of phosphorylation and the respiration-dependent accumulation of Ca²⁺; a lesser, but significant, decrease in the ATP-supported accumulation of Ca²⁺ also was observed. The addition of cytochrome c fully restores the respiration-dependent accumulation of Ca²⁺ to the level present in unextracted, osmotically lysed mitochondria. The ATP-supported process is not affected by the addition of cytochrome c to extracted mitochondria, indicating that cytochrome c is not involved in ion transport energized by ATP. The osmotically lysed mitochondria are devoid of outer membranes and contain relatively little matrix substance. The accumulation of Ca²⁺ and P_i by lysed mitochondria under massive loading conditions is accompanied by the formation of electron-opaque deposits within the lysed mitochondria associated with the inner membranes. This finding suggests that the inner membrane plays a role in the deposition of divalent ions within intact rat liver mitochondria. The relevance of these observations to those of other investigators is discussed.     

MICROINCINERATION, ELECTRON MICROSCOPY, AND ELECTRON DIFFRACTION OF CALCIUM PHOSPHATE-LOADED MITOCHONDRIA

Isolated rat liver mitochondria were incubated in vitro under conditions supporting the massive accumulation of calcium and phosphate. Samples were embedded, thin sectioned, and examined in the electron microscope. The intramitochondrial distribution of insoluble or structure-bound mineral substances was studied by electron microscopy coupled with recently developed techniques of high resolution microincineration. As shown previously, the ion-loaded mitochondria acquire large, internal granules which have inherent electron opacity indicative of high mineral content. Study of ash patterns in preselected areas of sections directly confirmed the high mineral content of the granules, and the appearance of the residues was consistent with the copresence in the granules of some organic material. Other mitochondrial structures were almost devoid of mineral. Thin sections of unincubated control mitochondria also were incinerated. They were found to contain appreciable amounts of intrinsic mineral, seemingly associated with membranes. The normal, dense matrix granules commonly seen in unaltered mitochondria could be seen in intact sections of these control preparations, but after burning no definite correspondence of any ash to the granules could be demonstrated. The normal granules perhaps do not contain mineral. Heating experiments on ash patterns of all the preparations demonstrated the thermal stability and crystallizability of the ash. The crystallized ash of the in vitro-produced dense granules was tentatively shown by electron diffraction to be β-tricalcium phosphate (whitlockite). This, together with evidence from the literature, suggests that the original, noncrystalline mineral may be a colloidal, subcrystalline precursor of calcium-deficient hydroxyapatite. Experiments were performed on synthetic calcium phosphates for comparison. Other possible applications of the microincineration techniques are briefly discussed.     

In Vivo Effect of Uncoupling Agents on the Incorporation of Calcium and Strontium into Mitochondria and Other Subcellular Fractions of Rat Liver

After injection of ⁴⁵Ca⁺⁺ or ⁸⁹Sr⁺⁺ into rats, the largest part of the radioactivity in the liver cell is associated with the subcellular structures, only negligible amounts of it being found in the soluble hyaloplasm. 50 % or more of the ⁴⁵Ca⁺⁺ and ⁸⁹Sr⁺⁺ in the liver cell is recovered in the mitochondrial fraction. The specific activity of Ca⁺⁺ after injection of ⁴⁵Ca⁺⁺ is far greater in mitochondria than in microsomes. Pretreatment of the rats with uncouplers of oxidative phosphorylation markedly decreases the amount of radioactivity associated with the mitochondrial fraction. The amount of radioactivity recovered in the microsomes and in the final supernatant on the contrary increases. These effects are present only when mitochondrial oxidative phosphorylation is completely uncoupled. The Ca⁺⁺ content of mitochondria from the livers of rats pretreated with uncouplers is sharply decreased with respect to the controls. It is concluded that in the liver cells of the intact animal energy-linked movements of Ca⁺⁺ and Sr⁺⁺ take place in mitochondria.     

Calcium binding to intestinal membranes

Flame photometry reveals that glutaraldehyde and buffer solutions in routine use for electron microscopy contain varying amounts of calcium. The presence of electron-opaque deposits adjacent to membranes in a variety of tissues can be correlated with the presence of calcium in the fixative. In insect intestine (midgut), deposits occur adjacent to apical and lateral plasma membranes. The deposits are particularly evident in tissues fixed in glutaraldehyde without postosmication. They are also observed in osmicated tissue if calcium is added to wash and osmium solutions. Deposits are absent when calcium-free fixatives are used, but are present when traces of CaCl₂ (as low as 5 x 10^-5 M) are added. The deposits occur at regular intervals along junctional membranes, providing images strikingly similar to those obtained by other workers who have used pyroantimonate in an effort to localize sodium. Other divalent cations (Mg⁺⁺, Sr⁺⁺, Ba⁺⁺, Mn⁺⁺, Fe⁺⁺) appear to substitute for calcium, while sodium, potassium, lanthanum, and mercury do not. After postfixing with osmium with calcium added, the deposits can be resolved as patches along the inner leaflet of apical and lateral plasma membranes. The dense regions may thus localize membrane constituents that bind calcium. The results are discussed in relation to the role of calcium in control of cell-to-cell communication, intestinal calcium uptake, and the pyroantimonate technique for ion localization.     

Sensitivity of mitochondrial Mg++ flux to reagents which affect K+ flux

Effects on Mg⁺⁺ transport in rat liver mitochondria of three reagents earlier shown to affect mitochondrial K⁺ transport have been examined. The sulfhydryl reactive reagent phenylarsine oxide, which activates K⁺ flux into respiring mitochondria, also stimulates Mg⁺⁺ influx. The K⁺ analog Ba⁺⁺, when taken up into the mitochondrial matrix, inhibits influx of both K⁺ and Mg⁺⁺. The effect on Mg⁺⁺ influx is seen only if Mg⁺⁺, which blocks Ba⁺⁺ accumulation, is added after a preincubation with Ba⁺⁺. Thus the inhibition of Mg⁺⁺ influx appears to require interaction of Ba⁺⁺ at the matrix side of the inner mitochondrial membrane. Added Ba⁺⁺ also diminishes observed rates of Mg⁺⁺ efflux but not K⁺ efflux. This difference may relate to a higher concentration of Ba⁺⁺ remaining in the medium in the presence of Mg⁺⁺ under the conditions of our experiments. Pretreatment of mitochondria with dicyclohexylcarbodiimide (DCCD), under conditions which result in an increase in the apparentK _m for K⁺ of the K⁺ influx mechanism, results in inhibition of Mg⁺⁺ influx from media containing approximately 0.2 mM Mg⁺⁺. The inhibitory effect of DCCD on Mg⁺⁺ influx is not seen at higher external Mg⁺⁺ (0.8 mM). This dependence on cation concentration is similar to the dependence on K⁺ concentration of the inhibitory effect of DCCD on K⁺ influx. Although mitochondrial Mg⁺⁺ and K⁺ transport mechanisms exhibit similar reagent sensitivities, whether Mg⁺⁺ and K⁺ share common transport catalysts remains to be established.Abbreviations used: DCCD, dicyclohexylcarbodiimide; PheAsO, phenylarsine oxide.     

X-ray microanalysis of the mineral components in the scales of an amoeba,Cochliopodium sp. (Testacea)

Summary Mineral components of the scales in an amoeba, Cochliopodium sp., were examined by energy-dispersive X-ray microanalysis. The precipitates in potassium antimonate-treated material detected calcium in the scales. Calcium was also clearly detected in freeze-substituted thin sections. Similar deposits of calcium antimonate were detected in scales in formation within vacuoles, and also in Golgi cisternae, Golgi vesicles and special granules near the nucleus. There were only minute amounts of magnesium and potassium. This suggests that calcium is the main mineral component of the scales and that it is added in the Golgi complex during scale formation.     

Biochemical and ultrastructural properties of osmotically lysed rat-liver mitochondria

Isolated rat-liver mitochondria were osmotically lysed by suspension and washing 3 times in cold, distilled water. Pellets obtained by centrifugation at 105,000 g for 30 min were resuspended, fixed with glutaraldehyde and OsO₄, and embedded in Epon 812. Thin sections show the presence of two distinct membranous populations, each of which is relatively homogeneous in size and appearance. Swollen mitochondria (∼1.5 µ in diameter), which have been stripped of their outer membranes, are largely devoid of matrix and normal matrix granules and are referred to as "ghosts." The smaller (0.2 to 0.4 µ in diameter), empty appearing, vesicular elements, derived primarily from the outer mitochondrial membrane, can be differentiated from the ghosts on the basis of their smaller size and complete absence of internal structures, especially cristae. Each membranous element is enclosed by a single, continuous membrane; the "double membrane" organization typical of intact mitochondria is not observed. These findings indicate that the outer membrane of rat-liver mitochondria is spatially dissociated from the inner mitochondrial membrane by osmotic lysis of the mitochondria in distilled water. Three parameters of structural and functional significance in freshly isolated rat-liver mitochondria have been correlated with the structural alterations observed: (a) chemical composition (total protein, lipid phosphate and total phosphate), (b) specific and total activities of marker enzymes for mitochondrial matrix and membranes (malate dehydrogenase (MDH), D-β-hydroxybutyrate dehydrogenase (BDH) and cytochromes), and (c) integrated multienzyme functions (respiration, phosphorylation, and contraction). The data presented indicate that all mitochondrial membranes are completely conserved in the crude ghost preparation and that, in addition, about ⅓ of the matrix proteins (estimated by assays for MDH activity and protein) are retained. The study of integrated mitochondrial functions shows that a number of physiologically important multienzyme activities also are preserved in the water-washed preparation. The respiratory rate of ghosts per milligram of protein is 1.5 to 2.0 times that of intact mitochondria, which shows that the respiratory chain in the ghosts is functionally intact. The rate of phosphorylation is reduced, however, to about 25% of that measured in freshly isolated mitochondria and accounts for lowered P:O ratios using succinate as substrate (P:O ranges from 0.4 to 0.9). The phosphorylation of ADP to ATP is the only biochemical function, so far investigated, that is greatly affected by osmotic lysis. In addition, two lines of evidence suggest that the ghosts undergo an energy-dependent transformation resulting in contraction: (a) suspensions of the crude ghost preparation in 0.02 M Tris-0.125 M KCl medium show a marked increase in optical density upon the addition of ATP, and (b) ghost preparations incubated in ion-uptake medium in the absence of added calcium but in the presence of added ATP contain a large number of highly condensed ghosts (about 50% of the total profiles) when viewed as thin sections in the electron microscope. The correlated biochemical and morphological study presented here shows that the outer membrane of rat-liver mitochondria can be removed by controlled osmotic lysis without greatly impairing a number of integrated biochemical functions associated with the inner membrane.     

Mechanisms for Intracellular Calcium Regulation in Heart : I. Stopped-Flow Measurements of Ca++ Uptake by Cardiac Mitochondria

Initial velocities of energy-dependent Ca⁺⁺ uptake were measured by stopped-flow and dual-wavelength techniques in mitochondria isolated from hearts of rats, guinea pigs, squirrels, pigeons, and frogs. The rate of Ca⁺⁺ uptake by rat heart mitochondria was 0.05 nmol/mg/s at 5 µM Ca⁺⁺ and increased sigmoidally to 8 nmol/mg/s at 200 µM Ca⁺⁺. A Hill plot of the data yields a straight line with slope n of 2, indicating a cooperativity for Ca⁺⁺ transport in cardiac mitochondria. Comparable rates of Ca⁺⁺ uptake and sigmoidal plots were obtained with mitochondria from other mammalian hearts. On the other hand, the rates of Ca⁺⁺ uptake by frog heart mitochondria were higher at any Ca⁺⁺ concentrations. The half-maximal rate of Ca⁺⁺ transport was observed at 30, 60, 72, 87, 92 µM Ca⁺⁺ for cardiac mitochondria from frog, squirrel, pigeon, guinea pig, and rat, respectively. The sigmoidicity and the high apparent K_m render mitochondrial Ca⁺⁺ uptake slow below 10 µM. At these concentrations the rate of Ca⁺⁺ uptake by cardiac mitochondria in vitro and the amount of mitochondria present in the heart are not consistent with the amount of Ca⁺⁺ to be sequestered in vivo during heart relaxation. Therefore, it appears that, at least in mammalian hearts, the energy-linked transport of Ca⁺⁺ by mitochondria is inadequate for regulating the beat-to-beat Ca⁺⁺ cycle. The results obtained and the proposed cooperativity for mitochondrial Ca⁺⁺ uptake are discussed in terms of physiological regulation of intracellular Ca⁺⁺ homeostasis in cardiac cells.     

BIOCHEMICAL AND ULTRASTRUCTURAL ASPECTS OF CA2+ TRANSPORT BY MITOCHONDRIA OF THE HEPATOPANCREAS OF THE BLUE CRAB CALLINECTES SAPIDUS

Mitochondria isolated from the hepatopancreas of the blue crab Callinectes sapidus show up to 12-fold stimulation of respiration on addition of Ca²⁺, which is accompanied by Ca²⁺ accumulation (Ca²⁺:site = 1.9) and H⁺ ejection (H⁺:Ca²⁺ = 0.85). Sr²⁺ and Mn²⁺ are also accumulated; Mg²⁺ is not. A strongly hypertonic medium (383 mosM), Mg²⁺, and phosphate are required for maximal Ca²⁺ uptake. Ca²⁺ uptake takes precedence over oxidative phosphorylation of ADP for respiratory energy. Once Ca²⁺ is accumulated by the crab mitochondria, it is stable and only very slowly released, even by uncoupling agents. ATP hydrolysis also supports Ca²⁺ uptake. Respiration-inhibited crab hepatopancreas mitochondria show both high-affinity and low-affinity Ca²⁺-binding sites, which are inactive in the presence of uncoupling agents. Crab hepatopancreas mitochondria have an enormous capacity for accumulation of Ca²⁺, up to 5,500 ng-atoms Ca²⁺ per mg protein, with an equivalent amount of phosphate. Freshly isolated mitochondria contain very large amounts of Ca²⁺, Mg²⁺, phosphate, K⁺, and Na⁺; their high Ca²⁺ content is a reflection of the vary large amount of extra-mitochondrial Ca²⁺ in the whole tissue. Electron microscopy of crab mitochondria loaded with Ca²⁺ and phosphate showed large electron-dense deposits, presumably of precipitated calcium phosphate. They consisted of bundles of needle-like crystals, whereas Ca²⁺-loaded rat liver mitochondria show only amorphous deposits of calcium phosphate under similar conditions. The very pronounced capacity of crab hepatopancreas mitochondria for transport of Ca²⁺ appears to be adapted to a role in the storage and release of Ca²⁺ during the molting cycle of this crustacean.     

Inhibition by Sr2+ of specific mitochondrial Ca2+-efflux pathways

The effect of Sr²⁺ on the set point for external Ca²⁺ was studied in rat heart and liver mitochondria with the aid of a Ca²⁺-sensitive electrode. In respiring mitochondria the set point is determined by the rates of Ca²⁺ influx on the Ca²⁺ uniporter and efflux by various mechanisms. We studied the Ca²⁺-Na⁺ exchange pathway in heart mitochondria and the Δψ-modulated efflux pathway in liver mitochondria. Prior accumulation of Sr²⁺ was found to shift the set points towards lower external Ca²⁺ both in heart mitochondria under conditions of Ca²⁺-Na⁺ exchange and in liver mitochondria under conditions that should promote opening of the Δψ-modulated pathway. The effect on the set point was found to be due to inhibition of Ca²⁺ efflux by Sr²⁺ taken up by the mitochondria, while Sr²⁺ efflux was too slow to be measurable.     

The active transport of Mg++ and Mn++ into the yeast cell

Certain bivalent cations, particularly Mg⁺⁺ and Mn⁺⁺, can be absorbed by yeast cells, provided that glucose is available, and that phosphate is also absorbed. The cation absorption is stimulated by potassium in low concentrations, but inhibited by higher concentrations. From the time course studies, it is apparent that the absorption rather than the presence of phosphate and the potassium is the important factor. Competition studies with pairs of cations indicate that binding on the surface of the cell is not a prerequisite to absorption. The absorption mechanism if highly selective for Mg⁺⁺ and Mn⁺⁺, as compared to Ca⁺⁺, Sr⁺⁺, and UO₂⁺⁺, whereas the binding affinity is greatest for UO₂⁺⁺, with little discrimination between Mg⁺⁺, Ca⁺⁺, Mn⁺⁺, and Sr⁺⁺. In contrast to the surface-bound cations which are completely exchangeable, the absorbed cations are not exchangeable. It is concluded that Mg⁺⁺ and Mn⁺⁺ are actively transported into the cell by a mechanism involving a phosphate and a protein constituent.     

Cation activation of desoxyribonuclease

The activation of desoxyribonuclease on desoxyribonucleate, known to occur with Mg⁺⁺ and Mn⁺⁺, has been shown to occur equally well with Co⁺⁺, to nearly the same extent with Fe⁺⁺, and to a lesser extent with Ca⁺⁺, Ba⁺⁺, Sr⁺⁺, Ni⁺⁺, Cd⁺⁺, and Zn⁺⁺. The conditions under which the optimal activation is revealed vary among these ions. Thus, Mg⁺⁺, Mn⁺⁺, and Co⁺⁺ may show marked activation under conditions in which Fe⁺⁺ is nearly ineffective. Since too high a concentration of an ion may be as ineffective as too little, concentration-activation curves were determined for each ion. Per micromole of nucleic acid phosphorus, the optimal effective amount of each ion in micromoles is as follows: Mg⁺⁺ 3, Mn⁺⁺ 3, Co⁺⁺ 3, Fe⁺⁺ 0.3, Ni⁺⁺ 0.3, Ba⁺⁺ 1.7, Ca⁺⁺ 3, Sr⁺⁺ 3, Zn⁺⁺ 0.3, and Cd⁺⁺ 0.3.The optimum pH for the activation with Mg⁺⁺, Co⁺⁺, and Ca⁺⁺ is about 6.5, that with Fe⁺⁺ is at 5.7, while Mn⁺⁺ shows two optima at pH 6.8 and 8.0.Experiments conducted in Pyrex and in quartz vessels showed the same results, and indicated that there was no activation of desoxy-ribonuclease in the absence of added salts.     

IONIC EFFECTS ON LIGNIFICATION AND PEROXIDASE IN TISSUE CULTURES

Crown-gall tumor tissue cultures release peroxidase into the medium in response to the concentration of specific ions in the medium. This release is not due to diffusion from cut surfaces or injured cells. Calcium, magnesium, and ammonium were, in that order, most effective in increasing peroxidase release. The enzyme was demonstrated cytochemically on the cell walls and in the cytoplasm. Cell wall fractions, exhaustively washed in buffer, still contained bound peroxidase. This bound peroxidase could be released by treating the wall fractions with certain divalent cations or ammonium. The order of effectiveness for removing the enzyme from the washed cell walls is: Ca⁺⁺ ≈ Sr⁺⁺ > Ba⁺⁺ > Mg⁺⁺ > NH₄⁺. These data support the thesis presented that specific ions can control the deposition of lignin on cell walls by affecting the peroxidase levels on these walls.     

Measurement of uptake of chelated and unchelated Ca and Sr from solution culture

Summary The uptake of Ca and Sr by three-week old tomato (Lycopersicon esculentum) plants from solutions containing Ca⁺⁺ and Sr⁺⁺, and chelated Ca and Sr (CaL and SrL) was measured over a two-day period. The solution was double-labelled with Ca⁴⁵ and Sr⁸⁵. Two chelates, EDTA (ethylenediaminetetraacetic acid) and DTPA (diethylenetriaminepentaacetic acid) were used at five chelate-cation ratios. When the Ca and Sr content of the solution was held constant, addition of chelate reduced uptake. The reduction was greater with EDTA than with DTPA.The Ca/Sr ratio of uptake was used to measure the proportion of uptake as the chelated and unchelated species. The Ca⁺⁺/Sr⁺⁺ ratio was different from the CaL/SrL ratio in solution because of the different equilibrium reactions of Ca and Sr with L. Direct uptake of the CaL and SrL was indicated. In solutions where Ca⁺⁺ = CaL, uptake of CaEDTA was 0.47 of uptake of Ca⁺⁺ and uptake of CaDTPA was 0.95 of uptake of Ca⁺⁺.Journal Paper No. 4969. Purdue University Agricultural Experiment Station, Lafayette, Indiana 47907. Contribution from the Department of Agronomy. This research was supported in part by the U.S. Atomic Energy Commission under Contract AT(11-1)-1495.     

The Initiation of Spike Potential in Barnacle Muscle Fibers under Low Intracellular Ca++

Electrical properties of the muscle fiber membrane were studied in the barnacle, Balanus nubilus Darw. by using intracellular electrode techniques. A depolarization of the membrane does not usually produce an all-or-none spike potential in the normal muscle fiber even though a mechanical response is elicited. The intracellular injection of Ca⁺⁺-binding agents (K₂SO₄ and K salt of EDTA solution, K₃ citrate solution, etc.) renders the fiber capable of initiating all-or-none spikes. The overshoot of such a spike potential increases with increasing external Ca concentration, the increment for a tenfold increase in Ca concentration being about 29 mv. The threshold membrane potential for the spike and also for the K conductance increase shifts to more positive membrane potentials with increasing [Ca⁺⁺]_out. The removal of Na ions from the external medium does not change the configuration of the spike potential. In the absence of Ca⁺⁺ in the external medium, the spike potential is restored by Ba⁺⁺ and Sr⁺⁺ but not by Mg⁺⁺. The overshoot of the spike potential increases with increasing [Ba⁺⁺]_out or [Sr⁺⁺]_out. The Ca influx through the membrane of the fiber treated with K₂SO₄ and EDTA was examined with Ca⁴⁵. The influx was 14 pmol per sec. per cm² for the resting membrane and 35 to 85 pmol per cm² for one spike. From these results it is concluded that the spike potential of the barnacle muscle fiber results from the permeability increase of the membrane to Ca⁺⁺ (Ba⁺⁺ or Sr⁺⁺).     

Triple helix formation and disulphide bonding during the biosynthesis of glomerular basement membrane collagen.

White erythrocyte membranes, or ghosts, were monoconcave discocytes when incubated in 50mM N-tris (hydroxymethyl) methyl-2-aminoethane sulfonic acid titrated to pH 7.4 with triethanolamine. If 3mM MgCl₂ was included in the incubation medium, the ghosts were predominantly echinocytes. The echinocytic form could also be induced by Co⁺⁺, Ni⁺⁺, Li⁺, Na⁺, K⁺, $\text{NH}{}_4{}^{\mathrm{+}}$ and tetramethylammonium ion, all as chloride salts. The concentration of cation necessary for 50% of the ghosts to be echinocytes was correlated with the hydrated charge density of the cation with the most highly charged cations being the most effective. The cations Ca⁺⁺, Sr⁺⁺, Ba⁺⁺ and La⁺⁺⁺, (also as chloride salts) did not induce the normal echinocytic form, but at high levels induced a few misshapen forms with some resemblance to echinocytes. Instead Ca⁺⁺, Sr⁺⁺, Ba⁺⁺ and La⁺⁺⁺ suppressed the formation of echinocytes in the presence of Mg⁺⁺ and other ions. This suggests the presence of a specific Ca⁺⁺ binding site important to shape control in the erythrocyte membrane.     

Effect of mersalyl on mitochondrial Mg++ flux

The mercurial mersalyl has little effect either on rapid Mg⁺⁺ binding by isolated rat liver mitochondria or on the total Mg⁺⁺ content of these organelles measured after 0.75 min of incubation at 20°C. The data do not support the previous suggestion that the increased permeability to K⁺ of mitochondria treated with mersalyl results from release of endogenous Mg⁺⁺. An increased pH-dependence of unidirectional Mg⁺⁺ flux into respiring rat liver mitochondria is suggested to arise indirectly from inhibition by mersalyl of pH shifts associated with exchanges of endogenous phosphate. In addition, mersalyl appears to have a stimulatory effect on Mg⁺⁺ influx. Mersalyl also increases the average rate of unidirectional efflux of endogenous Mg⁺⁺. The stimulatory effects of mersalyl on Mg⁺⁺ flux are similar to, although quantitatively less than, the previously reported effects of mersalyl on mitochondrial K⁺ flux.     

The migration of divalent cations in mitochondria visualized by a fluorescent chelate probe

Summary The use of the fluorescent chelate probe, chlorotetracycline, in mitochondria is described. The probe shows a high fluorescence in the presence of mitochondria which may be ascribed to binding of the probe to membrane-associated Ca⁺⁺ and Mg⁺⁺. The fluorescence excitation and emission spectra are diagnostic of binding of the probe to Ca⁺⁺ in coupled mitochondria and Mg⁺⁺ in uncoupled mitochondria. The fluorescence polarization spectra are diagnostic of the cations having a moderately high mobility in the membrane environment. The effects of exogenous EDTA and of endogenous Mn⁺⁺ indicate that the probe is primarily visualizing actively accumulated Ca⁺⁺ on the inner surface of the inner membrane. By employing the Ca⁺⁺ transport inhibitor, Tb⁺⁺⁺, the fluorescence changes associated with metabolic alterations are shown to arise partly from cation transport and partly through alterations in the binding properties of the inner surface of the membrane. Chlorotetracycline is a probe for divalent cations associated with the membrane and is of general utility in the study of cation migrations in cellular and subcellular systems.     

Ultrastructural distribution of Ca++ within neurons

Summary We used the oxalate-pyroantimonate technique to determine the ultrastructural distribution of Ca⁺⁺ in neurons of the rat sciatic nerve. The content of the precipitate was confirmed by X-ray microanalysis and appropriate controls. In the cell bodies of the dorsal root ganglia, Ca⁺⁺ precipitate was found in the Golgi, mitochondria, multivesicular bodies and large vesicles of the cytoplasm but not in lysosomes, and was prominently absent from regions of rough endoplasmic reticulum and ribosomes. It was seen in the nucleus but not in the nuclear bodies or nucleolus.Within the axon itself, Ca⁺⁺ precipitate was also found sequestered in mitochondria and smooth endoplasmic reticulum. In addition Ca⁺⁺ precipitate found diffusely throughout the axoplasm exhibited a discrete and heterogeneous distribution. In myelinated fibers the amount of precipitate decreased predictably in the axoplasm beneath the Schmidt-Lanterman clefts and in the paranodal regions at the nodes of Ranvier. This correlated with the presence of dense precipitate in the Schmidt-Lanterman clefts them-selves and in the paranodal loops of myelin.Intracytoplasmic ionic Ca⁺⁺ is maintained at 10^–7 M by balanced processes of influx, sequestration and extrusion. The irregular distribution of Ca⁺⁺ precipitate in the axoplasm of myelinated fibers suggests that there may be specific regions of preferential efflux across the axolemma.