Low temperature slowing and cold-block of fast axoplasmic transport in mammalian nerves in vitro

1) Fast axoplasmic transport in mammalian nerve in vitro was studied using an isotope labeling technique. The rate of outflow in cat sciatic nerve fibers of 410 mm/day in vitro was reduced at temperatures below 38°C with a Q₁₀ of 2.0 in the range 38–18°C and a Q₁₀ of 2.3 at 38–13°C. 2) At a temperature of 11°C a partial failure of transport occurred. At temperatures below 11°C a complete block of fast axoplasmic transport occurred, a phenomenon termed “cold-block.” No transport at all was seen over the temperature range of 10–0°C for times lasting up to 48 hr. 3) Transport was resumed after a period of cold-block lasting up to 22 hr when the nerves were brought back to a temperature of 38°C. Some deleterious effects due to cold-block were seen in the recovery phase as indicated by a reduction in crest amplitude, change in its form, and slowed rate. 4) The ∼P level (combined ATP and creatine phosphate) remained near control level in nerves kept at low or cold-block temperatures for times as long as 64 hr. The reduction in fast axoplasmic transport rate seen at low temperatures for times up to 22 hr was therefore considered due to a decrease in the utilization of ATP, a concept in accord with the “transport filament” model proposed to account for fast axoplasmic transport. 5) The sloping of the front of the crest over the temperature range of 18–13°C suggests an additonal factor at the lower temperatures. A disassembly of microtubules is discussed as a possible explanation of the cold-block phenomenon.     

Axoplasmic transport in the crayfish nerve cord. The role of fibrillar constituents of neurons

(a) Axoplasmic transport of tritium-labeled proteins in crayfish nerve cord was confirmed at a slow rate of 1 mm/day. A second proteinaceous component which moves at a rate of 10 mm/day was also detected. Radioautography and biochemical analysis indicate that proteins migrating at these velocities have a perikaryal origin and move caudad within axons as sharply defined peaks. (b) Evidence is presented for the blockage of the slow and the fast movement of proteins by intraganglionic injection of the anti-mitotic agent vinblastine sulfate (0.1 mM). (c) Electron microscope observations of vinblastine-treated ganglia revealed a reduction in the number of axonal microtubules and the formation of intracellular aggregates presumably composed of microtubular protein. (d) These findings would be compatible with the involvement of microtubules in both slow and fast axoplasmic transport. However, the block induced by vinblastine was detected in regions of the cord (up to 10 mm away from the injection site) where the number and morphology of microtubules appeared unaltered. In addition, axons showing effects of vinblastine occasionally contained mitochondria with remarkably dense and thickened membranes. (e) In association with the surfaces of axonal microtubules are lateral filamentous elements (40–80 A in diameter) which also showed vinblastine-induced alterations. Our observations indicate that such filiform structures, associated with microtubules, may be a necessary component in the transport mechanism(s).     

Displacement and Return Movement of Chloroplasts in the Marine Dinophyte Pyrocystis noctiluca. Experiments with Optical Tweezers

Infrared laser traps (optical tweezers) were used to study laser-induced organelle movements in the marine alga Pyrocystis noctiluca (Dinophyta). These cells are highly suitable for optical micromanipulation due to their large size and extensive vacuole. Experiments were done with plastids held by optical tweezers and moved from the nuclear area into the vacuole. The subsequent retraction movement was analysed for speed. The displaced organelles remained connected to their original position by a thin cytoplasmic strand, often less than 1 μm in diameter. When the organelles were released they rapidly returned at an initial rate of 81.7 ± 7.8 μm . s^?1 (overall displacement 50 μm, measured distance 20 μm, 25 °C ± 1 °C, number of cells 22), slowing down with progressive retraction of the connecting strand. The return movement was reduced to 4.2 ± 0.2 μ .s^?1 (n = 10) when the organelles were displaced and held for 1 min. Displacement to a longer distance increased the rate of return movement. A change from a high to a low environmental temperature significantly reduced movement from 94.5 ± 9.0 . s^?1 (30 °C ± 1 °C, n = 22) to 34.5 ± 2.7 μm .s^?1 (5°C ± 1 °C, n = 22). Nocodazole and N-ethylmaleimide (NEM), inhibitors of microtubules and acto-myosin, respectively, did not affect the retraction of the connecting strand, but at high concentrations of NEM it became increasingly difficult to move organelles away from the nuclear area. We suggest that the return movement of organelles within laser-induced artificial strands mainly depends on the viscoelastic properties of the tonoplast. The quantification of these properties by optical tweezers allows determination of reactions of plant cells to temperature changes.     

Mechanism of inhibitory action of capsaicin on particulate axoplasmic transport in sensory neurons in culture

The inhibitory effect of capsaicin on axoplasmic transport in cultured dorsal root ganglion cells was analyzed by video-enhanced contrast microscopy. Capsaicin inhibited particle transports in a dose-dependent manner, irrespective of the diameter of axons. The effect of capsaicin was reversible at low concentrations. Capsaicin affected both the anterograde and retrograde transport. Large organelles were more sensitive to capsaicin than small ones in the retrograde transport. An experiment using calcium-sensitive dye, Fura 2, indicated that capsaicin raised the intraneuronal free calcium concentration preceding the inhibition of the transport. Electron microscopy revealed that microtubules and neurofilaments are disorganized and disoriented by capsaicin. We reached a conclusion that capsaicin inhibits fast axoplasmic transport of both anterograde and retrograde directions in all types of somatosensory neurons in culture by disorganizing intraaxonal cytoskeletal structures, through the elevated intracellular Ca²⁺ concentration. © 1993 John Wiley & Sons, Inc.     

[32P]orthophosphate and [35S]methionine label separate pools of neurofilaments with markedly different axonal transport kinetics in mouse retinal ganglion cells in vivo

Newly synthesized neurofilament proteins become highly phosphorylated within axons. Within 2 days after intravitreously injecting normal adult mice with [³²P]orthophosphate, we observed that neurofilaments along the entire length of optic axons were radiolabeled by a soluble³²P-carrier that was axonally transported faster than neurofilaments.³²P-incorporation into neurofilament proteins synthesized at the time of injection was comparatively low and minimally influenced the labeling pattern along axons.³²P-incorporation into axonal neurofilaments was considerably higher in the middle region of the optic axons. This characteristic non-uniform distribution of radiolabel remained nearly unchanged for at least 22 days. During this interval, less than 10% of the total³²P-labeled neurofilaments redistributed from the optic nerve to the optic tract. By contrast, newly synthesized neurofilaments were selectively pulse-labeled in ganglion cell bodies by intravitreous injection of [³⁵S]methionine and about 60% of this pool translocated by slow axoplasmic transport to the optic tract during the same time interval. These findings indicate that the steady-state or resident pool of neurofilaments in axons is not identical to the newly synthesized neurofilament pool, the major portion of which moves at the slowest rate of axoplasmic transport. Taken together with earlier studies, these results support the idea that, depending in part on their phosphorylation state, transported neurofilaments can interact for short or very long periods with a stationary but dynamic neurofilament lattice in axons.Special issue dedicated to Dr. Sidney Ochs.     

Microtubule inhibitors differentially affect translational movement,cell surface expression,and endocytosis of transferrin receptors in K562 cells

We used quantitative fluorescence microscopy and fluorescence photobleaching recovery techniques to investigate the translational movement, cell surface expression, and endocytosis of transferrin receptors in K562 human erythroleukemia cells. Receptors were labeled with fluorescein-conjugated transferrin (FITC-Tf). Coordinated decreases in surface fluorescence counts, the photobleachig parameter K, and transferrin receptor fractional mobility were observed as FITC-Tf was cleared from the cell surface by receptor-mediated endocytosis. Based on the kinetics of decrease in these parameters, first order rate constants for FITC-Tf uptake at 37°C and 21°C were calculated to be 0.10-0.15 min^?1 and 0.02–0.03 min, respectively. K562 cells were treated with colchicine or vinblastine to investigate the role of microtubules in transferrin receptor movement and endocytosis. Treatment of cells for 1 hr with a microtubule inhibitor prevented transferrin receptor endocytosis but had no effect on the translational mobility of cell surface receptors. In contrast, drug treatment for 3 hr caused translational immobilization of cell surface receptors as well as inhibition of endocytosis. These effects were not produced by β-lumicolchicine, an inactive colchicine analog, or by cytochalasin, a microfilament inhibitor. The effect of microtuble inhibitors on transferrin receptor mobility was reversed by pretreating cells with taxol, a microtubule-stabilizing agent. Microtubule inhibitors had no effect on the translational mobility of cell surface glycophorins or phospholipids, indicating that intact microtubules were not required for translational movement of these molecules. We conclude that the translational movement of cell surface transferrin receptors is directed by a subpopulation of relatively drug-resistant microtubules. In contrast, transferrin receptor endocytosis depends on a subpopulation of microtubules that is relatively sensitive to the action of inhibitors. These results appear to demonstrate at least two functional roles for microtubules in receptor-mediated transferrin uptake in K562 cells. © 1994 Wiley-Liss, Inc.     

A COMPARISON OF AXONALLY TRANSPORTED PROTEINS IN THE RAT SCIATIC NERVE BY IN VITRO AND IN VIVO TECHNIQUES

An in vitro system for studying fast axonal transport in mammalian nerves has been developed. The viability of in vitro nerve preparations was established on the basis of three criteria: electron microscopy, electrical properties, and the activities of two marker enzymes, 5'-nucleotidase and total ATPase. The specific activity of transported proteins was greater using the in vitro procedure, and the level of locally incorporated radioactivity lower, when compared to in vivo transport experiments. Separation of solubilized transported proteins on polyacrylamide gels in the presence of sodium dodecyl sulfate showed that a large number of polypeptides are transported. Using a double label procedure which employed L-[³H]methionine and L-[³⁵S]methionine, proteins transported in vitro and in vivo were compared. No differences in the electrophoretic distribution of transported proteins from the two systems was seen. The major component of transported proteins electrophoresed with an apparent molecular weight of 105,000 ± 24,000. Using the in vitro system, transported proteins were compared to those labelled locally in either Schwann cells or cells of the dorsal root ganglion. Large differences in the labelling patterns were observed in both comparisons. We conclude that in vitro procedures provide a valid means of studying rapid axoplasmic transport. The proteins carried by rapid axoplasmic transport differ from those synthesized in either the Schwann cells of the sciatic nerve or the cells of the dorsal root ganglion.     

Organelle, bead, and microtubule translocations promoted by soluble factors from the squid giant axon

A reconstituted system for examining directed organelle movements along purified microtubules has been developed. Axoplasm from the squid giant axon was separated into soluble supernatant and organelle-enriched fractions. Movement of axoplasmic organelles along MAP-free microtubules occurred consistently only after addition of axoplasmic supernatant and ATP. The velocity of such organelle movement (1.6 micron/sec) was the same as in dissociated axoplasm. The axoplasmic supernatant also supported movement of microtubules along a glass surface and movement of carboxylated latex beads along microtubules at 0.5 micron/sec. The direction of microtubule movement on glass was opposite to that of organelle and bead movement on microtubules. The factors supporting movements of microtubules, beads, and organelles were sensitive to heat, trypsin, AMP-PNP and 100 microM vanadate. All of these movements may be driven by a single, soluble ATPase that binds reversibly to organelles, beads, or glass and generates a translocating force on a microtubule.     

Routing of transported materials in the dorsal root and nerve fiber branches of the dorsal root ganglion

After injection of the L7 dorsal root ganglion with ³H-leucine, fast axoplasmic transport carries some 3–5 × more labeled materials down the sensory fibers branches entering the sciatic nerve as compared to the dorsal root fiber branches of the neurons. Freeze-substitution preparations taken from the two sides of the lumbar seventh dorsal root ganglia of cats and monkeys showed little difference in the histograms of nerve fiber diameters of the sensory nerve fiber branch of these neurons as compared to the dorsal root fiber branches. A similar density of microtubules and of neurofilaments in the dorsal root and sensory nerve fiber branches over a wide range of fiber diameters was found in electron micrograph preparations. In the absence of an anatomical difference in the fibers to account for the asymmetrical outflow, a functional explanation based on the transport filament model was advanced.     

Defect in translation of poliovirus RNA at the restrictive temperature.

Translation of the RNA of LSc type 1 poliovirus was examined in vivo at the restrictive temperature (39 °C). During the first two hours of infection at 39 °C the levels of viral polyribosomes were 50% lower than at 35 °C (permissive temperature). During the third hour of infection at 39 °C, only 4 to 10% of the control levels of polyribosomes were observed. Three experiments indicate that the elongation of viral peptides was not occurring properly at 39 °C. First, cultures incubated at 39 °C during the third hour of infection with both [³⁵S]methionine and [³H]uridine exhibit a fourfold increase in the ratio of viral protein/viral RNA in the polyribosome region of sucrose gradients in comparison to controls kept at 35 °C. However, at both temperatures the relative size distribution of polyribosomes was similar. Second, the ratios of released protein/nascent protein after 90-second and 5-minute pulses with [³⁵S]methionine indicate that elongation of peptide chains was inhibited at 39 °C. Third, when initiation of synthesis of viral protein was blocked with 150 mM-NaCl, the polyribosomes disaggregated four to five times more rapidly at 35 °C than at 39 °C. The data indicate that translation of viral RNA is inhibited at the restrictive temperature because of a reduced rate of elongation of viral proteins. The reduced rate of peptide chain elongation at 39 °C was fully reversible when cultures were shifted to 35 °C in the presence of 150 mm-NaCl. The latter finding indicates a conformational change in viral protein at 39 °C.     

Stable complexes of axoplasmic vesicles and microtubules: protein composition and ATPase activity

Fast transport of axonal vesicles and organelles is a microtubule-associated movement (Griffin, J. W., K. E. Fahnestock, L. Price, and P. N. Hoffman, 1983, J. Neuroscience, 3:557-566; Schnapp, B. J., R. D. Vale, M. P. Sheetz, and T. S. Reese, 1984, Cell, 40:455-462; Allen, R. D., D. G. Weiss, J. H. Hayden, D. T. Brown, H. Fujiwake, and M. Simpson, 1985, J. Cell Biol., 100:1736-1752). Proteins that mediate the interactions of axoplasmic vesicles and microtubules were studied using stable complexes of microtubules and vesicles (MtVC). These complexes formed spontaneously in vitro when taxol-stabilized microtubules were mixed with sonically disrupted axoplasm from the giant axon of the squid Loligo pealei. The isolated MtVCs contain a distinct subset of axoplasmic proteins, and are composed primarily of microtubules and attached membranous vesicles. The MtVC also contains nonmitochondrial ATPase activity. The binding of one high molecular mass polypeptide to the complex is significantly enhanced by ATP or adenyl imidodiphosphate. All of the axoplasmic proteins and ATPase activity that bind to microtubules are found in macromolecular complexes and appear to be vesicle-associated. These data allow the identification of several vesicle-associated proteins of the squid giant axon and suggest that one or more of these polypeptides mediates vesicle binding to microtubules.     

New technique for measuring dynamic axonal transport and its application to temperature effects

A new technique was devised for the dynamic detection of the axoplasmic transport of β-radioactively labeled materials in which a semiconductor radiation detector was used as the β-ray counter. The detector element is a silicon p-n junction diode and has a diameter of 2.0 mm. With this detector, the β-radioactive distribution of axoplasmic transport could be measured in an axon maintained physiologically without cutting nerves. This method makes possible determination of the transport rate using one bundle of peripheral nerves. The rate in the bullfrog was 6.4 mm per hour at 24.0 °C. Temperature effects on the bullfrog axoplasmic transport were also observed at different temperatures, ranging from 5.0 to 24.0 °C. At these temperatures the rate increased as an exponential function of temperature from 1.1 to 6.4 mm per hour. Within this temperature range, the Q₁₀ is 2.5 and an Arrhenius plot of the natural logarithm of velocity versus the reciprocal of absolute temperature yielded an apparent activation energy of 14.8 Kcal. This technique offers great advantages in permitting direct study of the axoplasmic flow of the axon in a physiological condition.     

Effect of the phase transition on the transbilayer movement of dimyristoyl phosphatidylcholine in unilamellar vesicles

Dimyristoyl phosphatidylcholine rapidly exchanges between vesicles at 37°C without vesicle fusion.The rate of the transbilayer movement of dimyristoyl phosphatidylcholine in sonicated vesicles has been measured employing ¹³C NMR using N-¹³CH_3? labeled lipids which are introduced into the outer monolayer of non-labeled vesicles by a phosphatidylcholine exchange protein. The rate of transbilayer movement of dimyristoyl phosphatidylcholine shows a distinct maximum (halftime 4 h) in the temperature range at which the hydrocarbon phase transition occurs.The activation energy of the flip-flop rate above the phase transition is 23.7 ± 2.0 kcal/mol.     

Heat-induced stimulation of 3-O-methylglucose transport in rat thymocytes.

Cells incubated at 41–46 °C show a gradual increase in the initial rate of 3-O-methylglucose uptake when subsequently assayed at 37 °C. Cellular ATP levels remain constant throughout this temperature range, but at temperatures higher than 46 °C, ATP levels decline as does the extent of transport stimulation. Cells incubated at 45 °C for 5 min continue to show a gradual increase in transport activity throughout a subsequent 25-min incubation period at 37 °C. The increase in transport activity is characterized by an increase in the proportion of the rapid phase of 3-O-methylglucose uptake, with little or no change in the half-time of either the rapid phase or the slow phase. Transport stimulation at high temperatures is blocked by inhibitors of oxidative phosphorylation. Cells depleted of intracellular exchangeable Ca²⁺ by treatment with the ionophore A23187 in the presence of ethylene glycol bis(β-aminoethyl ether)-N,N′-tetraacetic acid show nearly the same degree of stimulation at high temperatures as untreated cells, suggesting that exchangeable Ca²⁺ ions do not play an obligatory role in the mechanism of transport stimulation. It is suggested that structural changes occur at 41–46 °C in the membrane proteins controlling glucose transport activity.     

MODULATION OF THE HEAT SHOCK UBIQUITIN POOL IN SKELETONEMA COSTATUM (BACILLARIOPHYCEAE)1

Immunoblotting experiments performed with an anti-ubiquitin antibody revealed that Skeletonema costatum (Grev.) Cleve cells contained free ubiquitin as well as ubiquitin conjugated to various endogenous proteins. A temperature shift from 18° to 30°C greatly increased the total amount of ubiquitin and particularly the ubiquitin fraction in high molecular mass conjugates. A solid-phase immunoassay indicated values of 0.031 ± 0.004 pmol·10^?6 cells for free ubiquitin and 0.046 ± 0.004 pmol·10^?6 cells for conjugated ubiquitin for cells grown at 18°C, and 0.056 ± 0.008pmol·10^?6cells and 0.21 ± 0.03 pmol·10^?6cells, respectively, after a temperature increase from 18° to 30°C. Cell-free extracts of S. costatum were equally able to form thiol ester linkages with ¹²⁵I-ubiquitin in an adenosine triphosphate–dependent manner at 18° C and at 30°C. Cell-free extracts were also able to conjugate ¹²⁵I-ubiquitin to endogenous proteins, but the ubiquitin conjugation rate at 30°C was lower than at 18°C. Incubation of S. costatum for 3 h at 30°C and then for 3 h at 18°C resulted in the formation of high amounts of ubiquitin conjugates, suggesting that partially inactive or denaturated proteins accumulate during heat stress. These denaturated proteins are then conjugated to ubiquitin very efficiently when the physiological temperature is restored. Thus, S. costatum cells contain ubiquitin and an active ubiquitin conjugation system responding to stress conditions (temperature stress). The intracellular concentration of ubiquitin conjugates is most likely limited by the availability of protein substrates to be conjugated rather than by ubiquitin-conjugating activity.     

Characterization of the fast and slow components of axonal transport in retinal ganglion cells

The constituent proteins of the fast (110–150 mm/day) and slow (1.5–2 mm/day) components of axonal transport in the retinal ganglion cells of the rabbit were investigated. The fast and slow components were labelled by intraocular injection of (³H)- and (¹⁴C)-leucine, respectively. Subcellular fractionation of the optic nerve and tract and subsequent gel electrophoresis of the fractions showed that most of the soluble proteins moved with the slow phase of axonal transport, whereas only some of the soluble proteins were transported with the rapid phase. Extraction of the microsomal fraction with triton X-100 resulted in the solubilization of highly labelled proteins belonging to the rapid phase. These proteins showed a relatively low electrophoretic mobility.     

Depolymerization of cortical microtubules is not a primary cause of chilling injury in corn (Zea mays L. cv Black Mexican Sweet) suspension culture cells

Cold-induced depolymerization of cortical microtubules were examined in suspension culture cells of corn (Zea mays L. cv Black Mexican Sweet) at various stages of chilling. In an attempt to determine whether microtubule depolymerization contributes to chilling injury, experiments were carried out with and without abscisic acid (ABA) pretreatment, since ABA reduces the severity of chilling injury in these cells. Microtubule depolymerization was detectable after 1 h at 4°C and became more extensive as the chilling was prolonged. There was little chilling injury after 1 d at 4°C in either ABA-treated or non-ABA-treated cells. After 3 d at 4°C, there was about 26% injury for ABA-treated and 40% injury for non-ABA-treated cells, as evaluated by 2,3,5-triphenyl-tetrazolium chloride reduction and by regrowth. After 1d at 4°C, less than 10% of cells retained full arrays of microtubules in both ABA-treated and non-ABA-treated cells, the remainder having either partial arrays or no microtubules. After 3d at 4°C, about 90% of cells showed complete or almost complete depolymerization of microtubules in both ABA-treated and non-ABA-treated cells. ABA did not stabilize the cortical microtubules against cold-induced depolymerization. In about 66% of ABA-treated cells and 57% of non-ABA-treated cells that had been held at 4°C for 3d, repolymerization of cortical microtubules occurred after 3h at 28°C. These results argue against the hypothesis that depolymerization of cortical microtubules is a primary cause of chilling injury.     

Axoplasmic transport of microtubule-associated proteins in the rat sciatic nerve

32P-ATP was injected into the L5 dorsal root ganglion and axoplasmic transport of the phosphorylate MA proteins 2, microtubule-associated proteins 2, was observed. After the injection of 32P-ATP, the nerve was dissected out at prescribed time intervals and sliced into 5-mm pieces. Each segment was electrophoresed on an SDS-polyacrylamide slab gel and subjected to autoradiography. A protein of 310,000 dalton was transported at a velocity of 6.6-10.6 mm/day in the axon with the electrophoretic mobility identical to that of MA proteins 2, one of the key components associated with the microtubules.     

Changes in the rates of protein synthesis in the brain of goldfish at various temperatures.

Intraperitoneal injections of [¹⁴C] tyrosine suspension into goldfish produced a relatively constant specific activity of free tyrosine in the brain over an 8 hour experimental period. This made the measurement of the rate of cerebral protein synthesis in this time period possible. The increase of protein-bound [¹⁴C] tyrosine was linear with time and occured in most protein fractions. In the absence of a net increase of protein it was an indicator of the rate of cerebral protein turnover. Rates of incorporation of tyrosine into brain proteins were 0.52 per cent/hour at 34° and 0.026 per cent/hour at 10°, i.e., the rate at 34° was about 20-fold that at 10°. Temperature gradients of protein turnover were similar in fish and rat brain.     

Agonists that Increase [Ca<Superscript>2+</Superscript>]<Subscript>i</Subscript> Halt the Movement of Acidic Cytoplasmic Vesicles in MDCK Cells

Translocation of vesicles within the cytoplasm is essential to normal cell function. The vesicles are typically transported along the microtubules to their destination. The aim of this study was to characterize the vesicular movement in resting and stimulated renal epithelial cells. MDCK cells loaded with either quinacrine or acridine orange, dyes taken up by acidic vesicles, were observed at 37°C in semiopen perfusion chambers. Time-lapse series were analyzed by Imaris software. Our data revealed vigorous movement of stained vesicles in resting MDCK cells. These movements seem to require intact microtubules because nocodazole leads to a considerable reduction of the vesicular movements. Interestingly, we found that extracellular ATP caused the vesicular movement to cease. This observation was obvious in time lapse. Similarly, other stimuli known to increase the intracellular Ca²⁺ concentration ([Ca²⁺]_i) in MDCK cells (increment in the fluid flow rate or arginine vasopressin) also reduced the vesicular movement. These findings were quantified by analysis of single vesicular movement patterns. In this way, ATP was found to reduce the lateral displacement of the total population of vesicles by 40%. Because all these perturbations increase [Ca²⁺]_i, we speculated that this increase in [Ca²⁺]_i was responsible for the vesicle arrest. Therefore, we tested the effect of the Ca²⁺ ionophore, ionomycin (1 μM), which in the presence of extracellular Ca²⁺ resulted in a considerable and sustained reduction of vesicular movement amounting to a 58% decrease in average lateral vesicular displacement. Our data suggest that vesicles transported on microtubules are paused when subjected to high intracellular Ca²⁺ concentrations. This may provide an additional explanation for the cytotoxic effect of high [Ca²⁺]_i.