The effects of chlorotetracycline on calcium movements in isolated rat liver mitochondria

Interaction of seminalplasmin with chlortetracycline, a fluorescent chelate probe of Ca2+

The interaction of seminalplasmin with chlortetracycline, a fluorescent chelate probe of Ca2+, was studied. The results indicate that seminalplasmin binds to chlortetracycline. The binding is not influenced by salt. Both Ca2+ and seminalplasmin probably bind to the same site on chlortetracycline. Seminalplasmin also reduced the Tb3+-associated fluorescence of bovine spermatozoal plasma membrane. These results are discussed in relation to the inhibitory effect of seminalplasmin on the uptake of Ca2+ in bovine spermatozoa.

Chlortetracycline and the transmembrane potential of the inner membrane of plant mitochondria

The oxidation of NADH or succinate by Jerusalem-artichoke (Helianthus tuberosus L.) mitochondria in the presence of chlortetracycline induced an increase in chlortetracycline fluorescence. Any treatment that prevented the formation of a transmembrane potential (as monitored by changes in safranine absorbance, A511-A533), e.g. uncoupling with carbonyl cyanide p-trifluoromethoxyphenylhydrazone, inhibition of dehydrogenase activity or electron transport, anaerobiosis or depletion of substrate, prevented the increase in chlortetracycline fluorescence or caused it to disappear. Changes in chlortetracycline fluorescence were always slower than changes in the safranine absorbance. The increase in chlortetracycline fluorescence caused by succinate oxidation had an excitation maximum at 393 nm, indicating that a Ca2+-chlortetracycline complex was involved. The increase in fluorescence was observed even in the presence of EDTA, which removes all external bivalent cations, indicating that internal Ca2+ is mobilized. Although NADH and succinate oxidations gave the same membrane potential and qualitatively had the same effect on chlortetracycline fluorescence, NADH oxidation caused a much larger (over 3-fold) increase in chlortetracycline fluorescence than did succinate oxidation. It is possible that this is connected with the Ca2+-dependence of NADH oxidation. In the presence of 2 mM external Ca2+, chlortetracycline collapsed the transmembrane potential and uncoupled succinate and duroquinone oxidation.

Chlortetracycline-mediated continuous Ca2+ oscillations in mitochondria of digitonin-treated Tetrahymena pyriformis

Ca2+ transport in mitochondria was studied in situ using digitonin-permeabilized cells of the ciliate protozoan Tetrahymena pyriformis GL. In the presence of oxidizable substrates and inorganic phosphate, mitochondria were able to accumulate a large amount of the added Ca2+ without subsequent uncoupling and mitochondrial damage. However, the maximal Ca2+ uptake dramatically decreased in the presence of micromolar concentrations of the fluorescent calcium indicator, chlortetracycline, which in aerobic conditions caused an uncoupling of the respiration in Ca2+-loaded mitochondria. Moreover, on reaching hypoxia, when the rate of oxygen diffusion from the air to the stirred incubation medium became a limiting factor, continuous Ca2+ oscillations were observed. Ca2+ fluxes were synchronous with the cyclic changes of the membrane potential and were followed with a significant delay by the changes of the membrane-associated fluorescence of Ca-chlortetracycline complexes. Both the chlortetracycline-induced uncoupling of the respiration and the oscillations were prevented by either EGTA or ruthenium red. It is suggested that in conditions of the limited rate of respiration the oscillations are generated as a result of the functioning of the two Ca2+-transport pathways: a Ca2+ uniport and a chlortetracycline-mediated electroneutral Ca2+ efflux.

Inhibition of polymorphonuclear leukocyte functions by chlortetracycline

Chortetracycline (CTC) inhibits chemotaxis, exocytosis and metabolic burst in rabbit polymorphonuclear leukocytes (PMNs), when these cells are activated in the absence of extracellular Ca2+. In the presence of extracellular Ca2+ CTC has little or no inhibiting effect on these functions. The inhibiting effect of CTC in the absence of Ca2+ occurs at concentrations which are not cytolytic. The inhibiting effect of CTC can be reversed by washing the cells or by addition of Ca2+ or Mg2+ to CTC-pretreated cells. Inhibition of the metabolic burst by CTC depends on the activator used. When phorbolmyristate acetate is used to activate the cells, the metabolic burst is inhibited at lower CTC concentrations than with chemotactic peptide as an activator. With due observance of the chemical properties of CTC and literature data about the requirement of intracellular Ca2+ for neutrophil functions, the results obtained are consistent with the view that CTC interferes with neutrophil functions, by complexing intracellular Ca2+, and that this inhibition is reversed when sufficient extracellular Ca2+ moves into the cell.

Chlortetracycline as a probe of membrane-associated calcium and magnesium: interaction with red cell membranes, phospholipids, and proteins monitored by fluorescence and circular dichroism

The fluorescence emission and circular dichroism spectra of chlortetracycline (CTC) have been measured, including the effects of multivalent cations (Ca, Mg, La), of medium polarity, and of interaction with human red cell membranes, lipids, and a variety of proteins. An obligatory role of Ca in the association of CTC with membranes was demonstrated. Binding and kinetic constants for the CTC-Ca chelate interaction with membranes and phospholipids were determined. The results suggest that the CTC-Ca chelate fluorescence is greatly enhanced in the vicinity of membrane phospholipid head groups. The circular dichroism spectra indicate a number of distinct CTC conformations corresponding to chelation of specific cations, to interaction with membranes and phospholipids, and to medium polarity. The high quantum yield CTC-Ca conformation associated with membranes or phospholipids was identified by its characteristic circular dichroism spectrum and is different from the CTC-Ca conformation in nonpolar media (80% methanol).

Studies on the Ca2+ transport mechanism of human erythrocyte inside-out plasma membrane vesicles. V. Chlortetracycline fluorescence

The measurement of chlortetracycline fluorescence was employed as a probe for measuring the process to calcium transport by human erythrocyte inside-out vesicles. Chlortetracycline is a divalent metal chelator which increases its fluorescence when bound to calcium in the presence of a membrane. Addition of calcium and ATP to inside out vesicles in the presence of chlortetracycline increased the chlortetracycline fluorescence as a function of time following an initial delay. Only after a threshold level of calcium had been accumulated did the fluorescence increase. The presence of both ATP and calcium were required. The addition of calmodulin increased the rate and absolute magnitude of the chlortetracycline fluorescence change. Similarly, calmodulin stimulated the rate and extent of 45Ca transport by inside-out vesicles. Moreover, the presence of saponin abolished both chlortetracycline fluorescence change and 45Ca uptake; a non-hydrolyzable ATP analog would not substitute for ATP in either 45Ca transport or chlortetracycline fluorescence experiments. Comparison between the slopes of the linear portions of chlortetracycline fluorescence change and calcium transport time courses at varied free calcium concentrations showed a consistent ratio between the slopes. This suggests that calcium transport change can be calibrated by employing chlortetracycline fluorescence. Based on this data, it is concluded that chlortetracycline fluorescence is a rapid and accurate method for monitoring calcium transport by human erythrocyte inside-out vesicles.

Pinocytosis and locomotion of amoebae. XV. Visualization of Ca++-dynamics by chlorotetracycline (CTC) fluorescence during induced pinocytosis in living Amoeba proteus

The dynamics of Ca++ during induced pinocytosis were studied in Amoeba proteus using chlorotetracycline (CTC). The fluorescence of the Ca++ - CTC-complex was monitored by an image intensification system, which has certain advantages over standard equipment: (1) Living cells are not subjected to the damaging influence of intensive microscopic illumination, (2) fluorescent probes are not bleached during observation, and (3) the rapid dynamics of the Ca++ -fluxes can be recorded using short exposure times. The results demonstrate the existence of Ca++ bound to intracellular and extracellular sites of the cell membrane complex in normal locomoting and pinocytotic Amoeba proteus. The application of cations inducing pinocytosis causes a rapid decrease in the external CTC-fluorescence probably due to a release of Ca++ from the mucous layer. The degree of fluorescence intensity is correlated with the capacity of pinocytotic channel formation, i.e., the fluorescence decreases as the number of channels increases. During the phase of vesiculation a distinct fluorescence mainly restricted to the basal region of the channels is observed. Intracellular Ca++ was detected in close vicinity to the plasma membrane after both microinjection and external application of CTC. The internal CTC-fluorescence is slightly decreased during the induction phase of pinocytosis. The observations are in good agreement with previous results on the localization of Ca++ -binding sites at the plasma membrane of Amoeba proteus and demonstrate the important role of Ca++ -fluxes for the process of pinocytosis.

Use of chlorotetracycline fluorescence to demonstrate Ca2+-induced release of Ca2+ from the sarcoplasmic reticulum of skinned cardiac cells

It has been proposed that the trans-sarcolemmal influx of Ca2+ occurring during the plateau of the mammalian cardiac action potentials is insufficient in itself to activate the myofilaments, but can trigger a release of Ca2+ from the sarcoplasmic reticulum (SR) which is sufficient for activation. The demonstration of this Ca2+-induced release of Ca2+ relied entirely on experiments in which the tension developed by the myofilaments was used as a sensor of the changes of myoplasmic free Ca2+ concentration ([free Ca2+]) in segments of single cardiac cells from which the sarcolemma had been removed by microdissection (skinned cardiac cells). The small size of these preparations has previously prevented the use of more direct methods for the detection of myoplasmic Ca2+ movements. The present study is a direct demonstration of Ca2+-induced release of Ca2+ from the SR of skinned cardiac cells treated with chlorotetracycline (CTC), a fluorescent chelate probe which enables changes in the amount of Ca2+ bound to a variety of biological membranes or micelles to be monitored. The fluorescence increases when more Ca2+ is bound.