Coordinated regulation of free Ca2+ by isolated organelles from a rat insulinoma

Experiments aimed at the partial reconstitution of the intracellular transport systems regulating the cytosolic free Ca2+ homeostasis are reported. Rat insulinoma subcellular fractions enriched in mitochondria, endoplasmic reticulum (microsomes), and secretory granules were studied. The ambient free Ca2+ concentration maintained by the separate or combined organelles was determined with a Ca2+-selective minielectrode. The data demonstrate that ambient [Ca2+] is established by the microsomes, not by the mitochondria or the secretory granules, in the range of resting cytosolic Ca2+ concentrations (0.1-0.2 microM Ca2+). Furthermore, the microsomes are able to deplete largely the mitochondria of their exchangeable calcium. Nonetheless, both mitochondria and microsomes, but not secretory granules, function as a coordinated unit to restore the previous ambient [Ca2+] following its perturbation. Thus, mitochondria play a major role in bringing down rapidly ambient [Ca2+] to the submicromolar range, whereas the endoplasmic reticulum acts as a relay in the transport mechanisms which lower [Ca2+] to the resting level.     

High voltage electron microscopy studies of axoplasmic transport in neurons: a possible regulatory role for divalent cations

Light and high voltage electron microscopy (HVEM) procedures have been employed to examine the processes regulating saltatory motion in neurons. Light microscope studies demonstrate that organelle transport occurs by rapid bidirectional saltations along linear pathways in cultured neuroblastoma cells. HVEM stereo images of axons reveal that microtubules (Mts) and organelles are suspended in a continuous latticework of fine microtrabecular filaments and that the Mts and lattice constitute a basic cytoskeletal structure mediating the motion of particles along axons. We propose that particle transport depends on dynamic properties of nonstatic microtrabecular lattice components. EXperiments were initiated to determine the effects of changes in divalent cation concentrations (Ca2+ and Mg2+) on: (a)the continuation of transport and (b) the corresponding structural properties of the microtrabecular lattice. We discovered that transport continues or is stimulated to a limited extent in cells exposed to small amounts of exogenously supplied Ca2+ and Mg2+ ions (less than 0.1 mM). Exposure of neurons to increased dosages of Ca2+ and Mg2+ (0.2-1.0 mM) stimulates transport for 2-4 min at 37 degrees C, but after a 5- to 20-min exposure the saltatory movements of organelles are observed gradually to become shorter in duration and rate particle motion ceases to occur. HVEM observations demonstrated that Ca2+ - and with the cessation of motion. Ca2+-containing solutions produced contractions of the microtrabecular filaments, whereas Mg2+-containing solutions had the opposing effect of stimulating an elongation and assembly (expansion) of microtrabeculae. On the basis of these observations we hypothesize that cycles of Ca2+/Mg2+-coupled contractions and expansions of the microtrabecular lattice probably regulate organelle motion in nerve cells.     

Characteristics of Mg2+-dependent, ATP-activated Ca2+ transport in synaptic and microsomal membranes and in permeabilized synaptosomes

Synaptic plasma membranes isolated from rat brain exhibited a Ca2+ transport process that was strictly dependent on the presence of Mg2+ and activated by ATP hydrolysis. The characteristics of this ATP-activated transport process included a high affinity for Ca2+ and ATP with the Kact for these two substrates being 0.7 and 5 microM, respectively, and a lower affinity for Mg2+, Kact = 54 microM. The estimated constants for ATP-activated Ca2+ transport into synaptic membrane vesicles and the dependence of such transport on Mg2+ were indicative that such transport was related to the previously described high affinity (Ca2+ + Mg2+)-ATPase in synaptic membranes. An ATP- and Mg2+-dependent Ca2+ transport process with very similar kinetic characteristics was present also in a general microsomal membrane fraction obtained from brain tissue. The synaptic and microsomal membrane ATP-activated transport processes exhibited differences in their sensitivity to vanadate inhibition. Interaction with vanadate was fairly complex and best analyzed by a two-component model. Thus, the estimated Ki values for vanadate were 0.2 and 6.6 microM for the synaptic membranes and 0.7 and 13.8 microM for the microsomes. Since the microsomal membranes contain a substantial population of intraneuronal endoplasmic reticulum vesicles, the effects of vanadate on Ca2+ transport into intraneuronal membrane organelles, other than mitochondria, was determined in saponin-permeabilized synaptosomes. The estimated Ki values for vanadate inhibition of Ca2+ transport activity were 0.7 and 13 microM. The accumulation of Ca2+ into synaptic plasma membrane vesicles was readily reversed by activation of the Na+-Ca2+ exchange carrier, whereas the Ca2+ associated with intrasynaptosomal organelles was not affected by changes in [Na+]. Thus, there are at least two ATP-dependent Ca2+ transporting processes localized on two distinct neuronal membranes, one on the plasma membrane and the second on intraneuronal membranes.     

Effect of ethanol on intracellular Ca2+ metabolism

The aim of this review is to summarize current thinking on ethanol effects on the Ca2+ homeostasis in the excitable tissue cells. It has been shown that acute exposure to ethanol decreases cytoplasmic Ca2+ concentration due to Ca2+ channels inhibition and Ca2+ pumps activation. Whereas chronic exposure to ethanol increases the intracellular Ca2+ concentration in cells due to activation of passive Ca2+ transport systems and inhibition of energy-dependent Ca2+ transport systems. The emphasis is place on a possible role of pharmacologic agents that preserve Ca2+ homeostasis in protecting against ethanol-induced diseases.     

Mechanisms of regulation of Ca2+ levels in myometrium cells

The ways and mechanisms of the Ca2+ concentration regulation in myometrium cells are analyzed. The plasma membrane is thoroughly studied for its role in the calcium control provision for the contractile activity of the uterus. The systems of Mg2+-ATP-dependent transport of Ca2+, sodium-calcium metabolism as well as regularities of the Ca2+ passive transfer in the sarcolemma vesicles are considered. The systems of the Mg2+-ATP- and N+-dependent transport of calcium are discussed for their contribution into regulation of calcium concentration in the myoplasm. Oxytocin and ions of bivalent metals (stimulators of the contractile activity of the uterus) are studied for their effect on the activity of the sarcolemma calcium pump.     

Sites and mechanisms of Ca2+ movement in non-excitable cells

The level of free cytosolic Ca2+ ([Ca2+]i) in cells is firmly established as a second messenger alternative to the cyclic nucleotides. Regulation of the activity of Ca2+ requires the use of membrane transporters of various types which can be classified in terms of their transport rate; channels (fast), carriers (intermediate) and pumps (slow). In general channels are used to elevate [Ca2+]i whereas pumps decrease [Ca2+]i. At physiological membrane potential and Na+ gradients, carriers such as the 3Na+/Ca2+ exchanger also deplete the cell of Ca2+. The carriers could also function in a reverse mode especially with plasma membrane depolarization. Intracellular organelles which can incorporate Ca2+ from and return Ca2+ to the cytosol play a central role in determining [Ca2+]i in resting and stimulated cells. In the resting cell they function as the major Ca2+ buffering system while in the stimulated cell they participate in the dynamic control of [Ca2+]i. The collection of papers in this volume discusses the mechanisms of modulation of cell Ca2+ by these organelles.     

Calcium transport mechanisms in basolateral plasma membrane-enriched vesicles from rat parotid gland.

Ca2+ transport was studied by using basolateral plasma membrane vesicles from rat parotid gland prepared by a Percoll gradient centrifugation method. In these membrane vesicles, there were two Ca2+ transport systems; Na+/Ca2+ exchange and ATP-dependent Ca2+ transport. An outwardly directed Na+ gradient increased Ca2+ uptake. Ca2+ efflux from Ca2+-preloaded vesicles was stimulated by an inwardly directed Na+ gradient. However, Na+/Ca2+ exchange did not show any 'uphill' transport of Ca2+ against its own gradient. ATP-dependent Ca2+ transport exhibited 'uphill' transport. An inwardly directed Na+ gradient also decreased Ca2+ accumulation by ATP-dependent Ca2+ uptake. The inhibition of Ca2+ accumulation was proportional to the external Na+ level. Na+/Ca2+ exchange was inhibited by monensin, tetracaine and chlorpromazine, whereas ATP-dependent Ca2+ transport was inhibited by orthovanadate, tetracaine and chlorpromazine. Oligomycin had no effect on either system. These results suggest that in the parotid gland cellular free Ca2+ is extruded mainly by an ATP-dependent Ca2+ transport system, and Na+/Ca2+ exchange may modify the efficacy of that system.     

A plethora of interacting organellar Ca2+ stores

The endoplasmic reticulum is not the only major agonist-releasable Ca2+ store within cells; it is now clear that virtually all organelles so far studied have the ability to act as mobilizable Ca2+ stores. From recent findings with regard to Ca2+ transportation and Ca2+ homeostasis within a variety of cell organelles such as the mitochondria, nucleus, Golgi and lysosomes, it emerges that many of these organellar Ca2+ stores appear to interact with each other, adding a further level of complexity to Ca2+ signalling events.     

The Ca 2+ pumps and the Na + / Ca 2+ exchangers

The Ca 2+ ATPases or Ca 2+ pumps transport Ca 2+ ions out of the cytosol, by using the energy stored in ATP. The Na + / Ca 2+ exchanger uses the chemical energy of the Na + gradient (the Na + concentration is much higher outside than inside the cell) to remove Ca 2+ from the cytosol. Ca 2+ pumps are found in the plasma membrane and in the endoplasmic reticulum of the cells. The pumps are probably present in the membrane of other organelles, but little experimental information is available on this matter. The Na + / Ca 2+ exchangers are located on the plasma membrane. A Na + / Ca 2+ exchanger was found in the mitochondria, but very little is known on its structure and sequence. These transporters control the Ca 2+ concentration in the cytosol and are vital to prevent Ca 2+ overload of the cells. Their activity is controlled by different mechanisms, that are still under investigation. A number of the possible isoforms for both types of proteins has been detected.© Kluwer Academic Publishers     

Calcium and GTP: essential components in vesicular trafficking between the endoplasmic reticulum and Golgi apparatus

Ca2+ and GTP hydrolysis are shown to be required for the transport of protein between the ER and the cis-Golgi compartment in semiintact cells, an in vitro system that reconstitutes transport between intact organelles. Transport was inhibited rapidly and irreversibly in the presence of micromolar concentrations of the nonhydrolyzable GTP analogue, GTP gamma S. The transport block in the presence of GTP gamma S was found to be distal to a post-ER, pre-Golgi compartment where proteins accumulate during incubation at 15 degrees C. In addition, transport was completely inhibited in the absence of free Ca2+. A sharp peak defining optimal transport between the ER and the cis-Golgi was found to occur in the presence of 0.1 microM free Ca2+. Inhibition of transport in the absence of free Ca2+ was found to be fully reversible allowing the step inhibited by GTP gamma S to be assigned to a position intermediate between the ER and the Ca2+ requiring step. The results suggest that GTP hydrolysis may trigger a switch to insure vectorial transport of protein along the ER/Golgi pathway, and that a free Ca2+ level similar to the physiological levels found in interphase cells is essential for a terminal step in vesicle delivery to the cis-Golgi compartment.     

Calcium signalling mechanisms in endoplasmic reticulum activated by inositol 1,4,5-trisphosphate and GTP

Ca2+ signals are known to mediate an array of cellular functions including secretion, contraction, and conductivity changes. In spite of the obvious role of Ca2+ in signalling, the control of Ca2+ within cells is known to be a complex phenomenon involving a number of distinct active and passive transport systems functioning within different organelles. Inositol 1,4,5-trisphosphate (IP3) is now established as a central mediator of Ca2+ mobilization, and the endoplasmic reticulum (ER) has been considered to be the site of action of IP3. However, this role has been ascribed almost by default to the ER, based on the knowledge that IP3 functions to release Ca2+ from an intracellular, nonmitochondrial, Ca2+-pumping organelle. Our interest has been to ascertain by what mechanism IP3 activates Ca2+ movements, at what intracellular locations it functions, and how the size and replenishment of the IP3-sensitive Ca2+ pool occurs. During the course of such studies, another mechanism inducing profound movements of Ca2+ within cells was identified. This process is activated by a highly sensitive and specific guanine nucleotide regulatory mechanism, which, while inducing fluxes of Ca2+ that resemble the action of IP3 under certain conditions, has now been determined to involve a quite distinct mechanism. The characteristics of this mechanism are described below. Although involving a very different Ca2+ translocation process to that activated by IP3, several important conclusions have been drawn on the relationship between IP3- and GTP-activated Ca2+ movements leading us to believe that the latter may have a regulatory role in controlling the size and/or entry of Ca2+ into the IP3-sensitive Ca2+ pool.     

Nanomolar concentrations of Cd2+ inhibit Ca2+ transport systems in plasma membranes and intracellular Ca2+ stores in intestinal epithelium

The interactions of Cd2+ with active Ca2+ transport systems in rat intestinal epithelial cells have been investigated. ATP-driven Ca2+ transport in basolateral plasma membrane vesicles was inhibited by Cd2+ with an I50 value of 1.6 nM free Cd2+ at 1 microM free Ca2+, using EGTA and HEEDTA to buffer Ca2+ and Cd2+ concentrations, respectively. The inhibition was competitive in nature since the Km value of Ca2+ increased with increasing Cd2+ concentrations while the Vmax remained constant. Cd2+ had similar effects on ATP-dependent Ca2+ uptake by permeabilized enterocytes, indicating that non-mitochondrial and mitochondrial Ca2+ stores are also inhibited by nanomolar concentrations of Cd2+. We conclude that ATP-driven Ca2+ transport systems are the most sensitive elements so far reported in Cd2+ intoxication.     

Ca2+ fluxes in developing Trichoderma viride mycelium

The properties of both Ca2+ influx and efflux in the mycelium during the life cycle of Trichoderma viride were studied by means of 45Ca2+ and by X-ray fluorescence spectroscopy measurements. The properties of the 45Ca2+ influx and effluxes indicate that they are mediated by different transport systems. The Ca2+ influx could be mediated by an electrogenic Ca2+/nH+ antiport, or by an Ca2+ uniport system. Both Ca2+ influx and efflux were stimulated by the uncouplers (and the treatment leading to the suppression of energy metabolism) and by azalomycin F, an antifungal agent. Salicylate stimulated the Ca2+ efflux, but inhibited the Ca2+ influx. In the isolated preparation of crude vacuolar/mitochondrial fraction, salicylate induced the Ca2+ release, as did A23187. Azalomycin F moderately released Ca2+ from the microsomal fraction. On the other hand, uncouplers did not release Ca2+ from the isolated organelles, but inhibited to a different extent the ATP-dependent and -independent Ca2+ influx. The results could be explained in terms of the capacitative Ca2+ influx mechanism. The rate of 45Ca2+ influx, or of the 40Ca2+ content, was maximal after about 30 h of submerged cultivation, and then decreased. The results show that loading of internal Ca2+ stores occurs in the early stages of the development of mycelium only, and the Ca2+ influx mechanism is developmentally down-regulated, being almost nonexistent during its later stages. In older mycelium, growth seems to be autonomous of the extracellular Ca2+ until the onset of conidiation.     

Mitochondria as regulators of stimulus-evoked calcium signals in neurons

An important challenge in the study of Ca2+ signalling is to understand the dynamics of intracellular Ca2+ levels during and after physiological stimulation. While extensive information is available regarding the structural and biophysical properties of Ca2+ channels, pumps and exchangers that control cellular Ca2+ movements, little is known about the quantitative properties of the transporters that are expressed together in intact cells or about the way they operate as a system to orchestrate stimulus-induced Ca2+ signals. This lack of information is particularly striking given that many qualitative properties of Ca2+ signals (e.g. whether the Ca2+ concentration within a particular organelle rises or falls during stimulation) depend critically on quantitative properties of the underlying Ca2+ transporters (e.g. the rates of Ca2+ uptake and release by the organelle). This monograph describes the in situ characterization of Ca2+ transport pathways in sympathetic neurons, showing how mitochondrial Ca2+ uptake and release systems define the direction and rate of net Ca2+ transport by this organelle, and how the interplay between mitochondrial Ca2+ transport and Ca+2 transport across the plasma membrane contribute to depolarization-evoked Ca2+ signals in intact cells.     

Induction of Ca2+ ion transport in human thrombocytes as affected by thyroid hormone receptors from malignant transformed cells

The effect of thyroid hormone receptors isolated from normal and malignant cells on the induction of Ca2+ transport to platelets was studied. It is established that the receptor isolated from malignant cells by thyroxin (T4) or triiodothyronine (T3) stimulates (three-fold) the induction of Ca2+ transport to platelets. The effect is blocked by verapamil, which is the inhibitor of Ca2+ channels in plasma membranes. It is shown that neither the receptor of cancer cells, nor hormones (T3 or T4) influence the transport of Ca2+ to platelets without preliminary complexing. The hormone-receptor complex failed to affect the concentration of "cytoplasmic" Ca2+ in platelets analogous experimental conditions. It is suggested that the increased Ca2+ content in cancer cells can be partially attributed to the ability of thyroid hormone receptor of cancer cells to induce Ca2+ transport across the plasma membrane.     

Functional links between mucolipin-1 and Ca2+-dependent membrane trafficking in mucolipidosis IV

Most of the membrane trafficking phenomena including those involving the interactions between endosomes and lysosomes are regulated by changes in intracellular Ca2+ (Cai). These processes are disturbed in some types of mucolipidoses and other lysosomal storage disorders, such as mucolipidosis IV (MLIV), a neurological disorder that usually presents during the first year of life with blindness, cognitive impairment, and psychomotor delays. It is caused by mutations in MCOLN1, the gene encoding mucolipin-1 (MLN1), which we have recently established to represent a Ca2+-permeable cation channel that is transiently modulated by changes in Cai. The cells of MLIV patients contain enlarged lysosomes that are likely associated with abnormal sorting and trafficking of these and related organelles. We studied fibroblasts from MLIV patients and found disturbed Ca2+ signaling and large acidic organelles such as late endosomes and lysosomes (LEL) with altered cellular localization in these cells. The fusion between LEL vesicles in these cells was defective. This is a Ca2+-dependent process related to signaling pathways involved in regulation of Ca2+ homeostasis and trafficking. The MLN1 channels could play a key role in Ca2+ release from LEL vesicles, which triggers the fusion and trafficking of these organelles. The characterization of this MLN1-mediated Ca2+-dependent process should provide new insights into the pathophysiological mechanisms that lead to the development of MLIV and other mucolipidoses associated with similar disturbances in membrane trafficking.     

Characterization and Distribution of Transferrin Receptors in the Rat Brain

The mechanism of calcium transport across the plasma membrane of chromaffin cells was studied using plasma membrane vesicles prepared from cells of adrenal medulla. Purification of the plasma membrane was about 30-fold, based on the alpha-bungarotoxin binding activity. The isolated membrane vesicles have both Na+/Ca2+ exchange and calcium pump activities. The Na+/Ca2+ exchange activity increased with the free calcium concentration and was not saturated at 1 mM, the highest concentration tried. The K1/2 of the calcium pump for calcium is 0.06 microM. Part of the Na+/Ca2+ exchange activity was inhibited by preincubation of the membrane vesicles with veratridine and the effect of veratridine was reversed by tetrodotoxin. The calcium taken up by the calcium pump was released by 0.005% saponin, but was not affected by oxalate. The calcium taken up by the calcium pump was released by exchanging with the external sodium, which suggests that the two calcium transport systems are located on the same population of membrane vesicles. The above evidence indicates that both calcium transport activities are located on the plasma membrane and not on contaminating organelle membranes. The significance of the two calcium transport systems in regulation of cytosolic calcium concentration of chromaffin cells is discussed.     

Control of cytosolic free calcium by intracellular organelles in bovine adrenal glomerulosa cells. Effects of sodium and inositol 1,4,5-trisphosphate

The regulation of cytosolic free Ca2+ concentration ([Ca2+]c) by intracellular organelles was studied in permeabilized bovine adrenal glomerulosa cells. Two compartments, with distinct characteristics, were able to pump Ca2+. A first pool, sensitive to ruthenium red and presumably mitochondrial, required respiratory chain substrates to maintain [Ca2+]c around 700 nM. Ca2+ efflux from this compartment was activated by Na+ (ED50 = 5 mM). Inositol 1,4,5-trisphosphate (IP3) had no effect on this pool. A second nonmitochondrial pool required ATP to lower [Ca2+]c to about 200 nM and released Ca2+ transiently upon addition of IP3. When the two systems were allowed to work simultaneously, the nonmitochondrial pool regulated [Ca2+]c and IP3 released Ca2+ in a concentration-dependent manner (EC50 = 0.6 microM). Under these conditions the mitochondria seemed Ca2+ depleted. Upon repeated stimulations with IP3, a marked attenuation of the response was observed. This phenomenon was due to Ca2+ sequestration by a nonmitochondrial IP3-insensitive pool. Neither dantrolene (200 microM) nor 8-(N,N-diethylamino)octyl-3,4,5-trimethoxybenzoate (10 microM) were able to abolish IP3-induced Ca2+ release, though both compounds efficiently inhibited aldosterone production in intact cells stimulated with angiotensin II (10 nM) or K+ (12 mM). These results suggest that in permeabilized adrenal glomerulosa cells: the nonmitochondrial pool is responsible for buffering [Ca2+]c and for releasing Ca2+ in response to IP3; at resting [Ca2+]c levels, the mitochondria appear Ca2+ depleted; when [Ca2+]c rises above their set point, the mitochondria accumulate Ca2+ as a function of [Na+]c; 4) the mitochondria are not involved in the desensitization mechanism of the response to IP3.     

Localization of calcium in nerve fibers

Using the desheathed nerve preparation, a pyroantimonate precipitation method was used to examine the distribution of electron-dense particles seen in various organelles of the nerve fibers following exposure of nerve to various levels of Ca2+ in vitro. The presence of Ca2+ in the electron-dense particles was indicated by their extraction with EGTA and by the use of energy-dispersive X-ray microanalysis. In normal Ringer or in a Ca2+ -free medium, electron-dense particles were seen associated with the outer membrane of the mitochondria, with the smooth endoplasmic reticulum (SER), along the axolemma and yet others scattered throughout the axoplasm. When nerves were incubated in media containing higher than normal concentrations of 20-60 mM Ca2+, an increase in the number of such electron-dense particles was seen in the axoplasm and within the mitochondrial matrix. Nerves loaded with a high concentration of 60mM Ca2+ could be depleted of these particles after transfer to a Ca2+ -free or low Ca2+ Ringer medium. The sequestration of Ca2+ in axonal organelles is discussed with respect to Ca2+-regulatory mechanisms in the axon needed to maintain a low level of Ca2+ which is optimal for the support of axoplasmic transport.     

Calcium and the mechanism of axoplasmic transport

Using desheathed cat peroneal nerves in in vitro studies, Ca2+ was recently shown to be required to maintain axoplasmic transport. Calmodulin was also shown to be present in nerve and to participate in transport. These findings open up new possibilities for a better understanding of the underlying mechanism of transport. In the transport filament model, the materials transported are bound to a common carrier, the transport filaments, which are moved along the microtubules by means of an interaction with the side arms of the microtubules. This is an energy-requiring process that depends on a supply of ATP, which is utilized by the Ca2+,Mg2+-ATPase associated with the side arms of the microtubules. The Ca2+,Mg2+-ATPase is activated by calmodulin at the low micromolar levels of free Ca2+ present in the axon. The level is kept low by calcium-regulatory mechanisms that include mitochondria, endoplasmic reticulum, and calcium-binding proteins. Nerves exposed to higher-than-normal concentrations of Ca2+ in the medium show an increased number of particles in these organelles as expected of their Ca2+-regulatory role. The nature of the calmodulin-Ca,Mg-ATPase complex associated with the side arms is discussed on the basis of the transport model. Also discussed is slow transport, which is explained on the basis of the model as a differential binding affinity to the transport filaments.