Localization of membrane-associated calcium following cytokinin treatment in Funaria using chlorotetracycline

We have investigated the changes in membrane-associated calcium that occur during cytokinin induced bud formation in Funaria hygrometrica Hedw. using the fluorescent Ca²⁺-chelate probe chlorotetracycline (CTC). In the target caulonema cells a localization of CTC fluorescent material becomes evident at the presumptive bud site 12 h after cytokinin treatment. By the time of the initial asymmetric division this region is four times as fluorescent as the entire caulonema cell. Bright CTC fluorescence remains localized in the dividing cells of the bud. To relate the changes in CTC fluorescence to changes in Ca²⁺ as opposed to membrane-density changes we employed the general membrane marker N-phenyl-1-naphthylamine (NPN). NPN fluorescence increases only 1.5 times in the initial bud cell. We conclude that the relative amount of Ca²⁺ per quantity of membrane increases in this localized area and is maintained throughout bud formation. We suggest that these increases in membrane-associated Ca²⁺ indicate a localized rise in intracellular free Ca²⁺ concentration brought about by cytokinin action.Abbreviations BA 6-benzyladenine - CTC chlorotetracycline - ER endoplasmic reticulum - NPN N-phenyl-1-naphthylamine     

Use of chlortetracycline fluorescence for the detection of Ca storing intracellular vesicles in normal human erythrocytes

The uptake of chlortetracycline (CTC) and the nature of the fluorescence of CTC was studied in intact human erythrocytes from apparently healthy donors. The uptake of CTC at 22 degrees C proceeded with a t1/2 of about 3 min, and after 15 min a stable equilibrium was achieved with an intracellular accumulation by a factor of 5-6 relative to the medium concentration. The accumulation did not change in the range of CTC concentrations tested (20-500 microM). The Ca specificity of the CTC fluorescence spectrum was confirmed by Ca depletion of red cells using A23187 in the presence of EGTA and 0.2 mM Mg. This procedure decreased the total intracellular calcium content by about 70% and reduced the fluorescence intensity to one-fourth. Fluorescence microscopy of red cells incubated with 100 microM CTC at 22 degrees C showed that the fluorescence originated mainly from the red cell membrane. In addition, in about 15% of erythrocytes one or more fluorescent dots (diameter greater than 0.2 less than 1 microns) were detected. The fluorescence of the dots and membranes was related to calcium, as evidenced by the reduction of their intensity in Ca depleted cells. The number of erythrocytes with fluorescent dots and the frequency of the dots per cell was largely unaffected by lowering the incubation temperature to 0 degrees C, indicating that the dots most probably do not represent endocytotic artifacts induced by CTC. The number of dots was increased in erythrocytes preincubated with primaquine, demonstrating that CTC fluorescence can be applied to monitor the appearance of intracellular Ca storing vesicles. It is concluded that in (at least) 15% of erythrocytes obtained from apparently healthy donors intracellular vesicles containing Ca can be detected by CTC fluorescence microscopy.     

Changes in calcium and calmodulin levels during microsporogenesis,pollen development and germination in Gasteria verrucosa (Mill.) H. Duval

Summary The distribution of membrane calcium and calmodulin (CaM) has been fluorimetrically determined in the anther of Gasteria verrucosa with particular attention to sporogenous cells, meiocytes, microspores, pollen and stages of pollen germination and tube growth using chlortetracycline (CTC) and fluphenazine (FPZ). CTC and FPZ fluorescence in sporogenous cells is relatively higher than in the adjacent tapetal cells, indicating higher membrane calcium and CaM levels in the former cell type. However, during meiosis there is a significant increase in membrane calcium and CaM levels in the meiocytes compared to that found in the young microspores. CTC and FPZ fluorescence in the sporogenous cells, meiocytes and young microspores is punctate and slightly diffused throughout the cytoplasm. In the microspores of the tetrad and the young released microspores CTC fluorescence (CTCf) is polarized and mainly associated with the area opposite the future colporal region. FPZ fluorescence (FPZf) becomes polarized in the young microspore. Subsequently, there is a shift in the polarity, and most of the CTCf and FPZf in the old microspores and pollen is regionalized towards the colporal region, and the fluorescence is more diffused, indicating a change in the organellar-bound calcium and CaM. This final graded distribution of CTCf is maintained during pollen germination in that the growing pollen tubes invariably show a tip to base membrane-calcium gradient. In the tapetal cells a high level of Ca²⁺ is present during the microspore stage. During the preparation for anthesis the endothecium differentiation is marked by the presence of Ca²⁺. Post-treatment of labelled cells with a Ca²⁺ chelator such as EGTA resulted in a substantial decrease in diffuse and punctate CTCf. Alternatively, treatment of cells with non-ionic detergent Nonidet P-40 resulted in the total elimination of CTCf, suggesting that the observed CTC fluorescence was due to membrane-associated calcium. The cytological specification of CTC as a probe for calcium is discussed. From cytofluorometric measurements and atomic absorption, it became clear that the level of Ca²⁺ in the anther is high during the sporogenous and meiotic phases. An increase in CTCf and FPZf occurred after microspore mitosis. An interaction of Ca²⁺ transport from tapetum to the young pollen is postulated. These findings suggest that the level of Ca²⁺ in the anther during meiosis is generally relatively higher than at the sporogenous or young microspore stage. These findings are discussed in the light of available information on the role of Ca²⁺ and CaM-mediated processes such as cell division, callose synthesis and pollen-tube tip growth.     

Intracellular divalent cation release in pancreatic acinar cells during stimulus-secretion coupling. II. Subcellular localization of the fluorescent probe chlorotetracycline

Subcellular distribution of the divalent cation-sensitive probe chlorotetracycline (CTC) was observed by fluorescence microscopy in isolated pancreatic acinar cells, dissociated hepatocytes, rod photoreceptors, and erythrocytes. In each cell type, areas containing membranes fluoresced intensely while areas containing no membranes (nuclei and zymogen granules) were not fluorescent. Cell compartments packed with rough endoplasmic reticulum or Golgi vesicles (acinar cells) or plasma membrane-derived membranes (rod outer segments) exhibited a uniform fluorescence. In contrast, cell compartments having large numbers of mitochondria (hepatocytes and the rod inner segment) exhibited a punctate fluorescence. Punctate fluorescence was prominent in the perinuclear and peri-granular areas of isolated acinar cells during CTC efflux, suggesting that under these conditions mitochondrial fluorescence may account for a large portion of acinar cell fluorescence. Fluorometry of dissociated pancreatic acini, preloaded with CTC, showed that application of the mitochondrial inhibitors antimycin A, NaCN, rotenone, or C1CCP, or of the divalent cation ionophore A23187 (all agents known to release mitochondrial calcium) rapidly decreased the fluorescence of acini. In the case of mitochondrial inhibitors, this response could be elicited before but not following the loss of CTC fluorescence induced by bethanechol stimulation. Removal of extracellular Ca2+ and Mg2+ or addition of EDTA also decreased fluorescence but did not prevent secretagogues or mitochondrial inhibitors from eliciting a further response. These data suggest that bethanechol acts to decrease CTC fluorescence at the same intracellular site as do mitochondrial inhibitors. This could be due to release of calcium from either mitochondria or another organelle that requires ATP to sequester calcium.     

Exploiting new terrain: an advantage to sociality in the slime mold Dictyostelium discoideum

Understanding the ecological benefits of social actions is centralto explaining the evolution of social behavior. The social amoebaDictyostelium discoideum has been well studied and is a modelfor social evolution and development, but surprisingly littleis known about its ecology. When starving, thousands of thenormally solitary amoebae aggregate to form a differentiatedmulticellular organism known as a slug. The slug migrates towardthe soil surface where it metamorphoses into a fruiting bodyof hardy spores held up by a dead stalk comprising about one-fifthof the cells. Multicellularity in D. discoideum is thought tohave evolved to lift the spores above the hazards of the soilwhere spores can be picked up for long-distance dispersal. Here,we show that multicellularity has another advantage: local dispersalto new food sources. We find that cells shed by D. discoideumslugs during migration consume and remove bacteria in the pathof the slug, although slugs themselves do not breakup. We alsoshow that slugs are adept at local dispersal by comparing migrationof slugs with migration of individual cells of the mutant, CAP2,which cannot aggregate and so rely only on cellular movement.In particular, the solitary cells of the aggregation mutantare unable to cross a soil barrier, easily crossed by slugs.We propose that the exploitation of local food patches is animportant selective benefit favoring multicellular cooperationin D. discoideum.     

A cell type-specific effect of calcium on pattern formation and differentiation in dictyostelium discoideum

Spatial gradients of sequestered and free cellular calcium (Ca2+) exist in the slug of Dictyostelium discoideum (Maeda and Maeda, 1973; Tirlapur et al., 1991; Azhar et al., 1995; Cubitt et al., 1995). When we vary intracellular Ca2+ with the help of calcium buffers and the ionophore Br-A23187, there are striking effects on slug morphology, patterning and cell differentiation. In the presence of a calcium ionophore, high external Ca2+ levels lead to an increase of intracellular sequestered and free Ca2+, the formation of long slugs, a decrease in the fraction of genetically defined prespore cells and 'stalky' fruiting bodies. Conversely, a lowering of external Ca2+ levels results in a decrease of intracellular Ca2+, the formation of short slugs, an increase in the prespore fraction and 'spory' fruiting bodies. We infer that Ca2+ plays a significant morphogenetic role in D. discoideum development, by selectively promoting the prestalk pathway relative to the prespore pathway.     

Fluorescent localization of calcium at sites of cell attachment and spreading

Chlorotetracycline (CTC), a calcium-chelating fluorescent probe identifies and localizes calcium when applied to cultured neural crest cells. The fluorescence occurs at specific membrane regions involved in cell attachment and spreading as well as with the formation of cytoskeletal stress fibers (actin microfilament bundles). The observed CTC reaction indicates that calcium sequestration and the development of these membrane-cytoskeletal features share a temporal and spatial pattern. Thus, the selective availability of calcium may be an important determinant of cell morphogenesis.     

Intracellular divalent cation release in pancreatic acinar cells during stimulus-secretion coupling. I. Use of chlorotetracycline as fluorescent probe

Stimulus-secretion coupling in pancreatic exocrine cells was studied using dissociated acini, prepared from mouse pancreas, and chlorotetracycline (CTC), a fluorescent probe which forms highly fluorescent complexes with Ca2+ and Mg2+ ions bound to membranes. Acini, preloaded by incubation with CTC (100 microM), displayed a fluorescence having spectral properties like that of CTC complexed to calcium (excitation and emission maxima at 398 and 527 nm, respectively). Stimulation with either bethanechol or caerulein resulted in a rapid loss of fluorescence intensity and an increase in outflux of CTC from the acini. After 5 min of stimulation, acini fluorescence had been reduced by 40% and appeared to be that of CTC complexed to Mg2+ (excitation and emission maxima at 393 and 521 nm, respectively). The fluorescence loss induced by bethanechol was blocked by atropine and was seen at all agonist concentrations that elicited amylase release. Maximal fluorescence loss, however, required a bethanechol concentration three times greater than that needed for maximal amylase release. In contrast, acini preloaded with ANS or oxytetracycline, probes that are relatively insensitive to membrane-bound divalent cations, displayed no secretagogue-induced fluorescence changes. These results are consistent with the hypothesis that CTC is able to probe some set of intracellular membranes which release calcium during secretory stimulation and that this release results in dissociation of Ca(2+)-complexed CTC.     

Localization of membrane-associated calcium during development of fucoid algae using chlorotetracycline

During the first day of development, fertilized eggs of fucoid algae generate an embryonic axis and commence rhizoid growth at one pole. Using Fucus distichus (L.) Powell, F. vesiculosus L. and Pelvetia fastigiata (J.Ag.) DeTony we have investigated the role of calcium in axis formation and fixation as well as in tip growth. The intracellular distribution of membrane-associated calcium was visualized with the fluorescent calcium probe chlorotetracycline (CTC). Punctate fluorescence associated with organelle-like structures was found in conjunction with diffuse staining at all developmental stages. This membrane-associated calcium remained uniformly distributed throughout the cortical cytoplasm while the axis was established, but increased in the rhizoid protuberance at germination. In subsequent development, fluorescence was restricted to the cortical cytoplasm at the elongating tip and at sites of crosswall biosynthesis.The requirement for Ca²⁺ uptake during development was investigated through inhibition studies; influx was impaired with transport antagonists or by removal of extracellular calcium. Both treatments curtailed germination and tip elongation but had little effect on axis polarization. Reductions in external calcium that interfered with elongation also markedly reduced the apical CTC fluorescencence, indicating that calcium uptake and localization are prerequisites for tip growth. This apical Ca²⁺ is probably involved in the secretory process that sustains tip elongation. By contrast, calcium was not implicated in the generation of an embryonic axis.Abbreviations ASW artificial seawater - CTC chlorotetracycline - DU developmental unit - EGTA erhylene glycol bis(amino-ethyl ether) N,N,N¹,N¹–tetraacetic acid - NPN N-phenyl-1-napthylamine     

Distribution of Membrane-bound Calcium and Activited Calmodulin in Isolated Zygotes and Young Embryos of Triticum aestivum

The method of non-enzymatic, manual microdissection was established to isolate zygotes and young embryos in Triticum aestivum L. The distribution of membrane-bound calcium and activated calmodulin in the isolated zygotes and young embryos was visualized by chlorotetracycline (CTC) and fluphenanize (FPZ) fluorescence probe respectively. The CTC fluorescence was polar distributed in the zygote protoplast. The distribution of the CFC and FPZ fluorescence from twocelled embryos to multicellular embryos was observed. In the young pear-shaped embryos the CTC and FPZ fluorescence of the embryos was slightly higher than that of the suspensor. In a pear-shaped embryo beginning with differentiation the CTC fluorescence was restricted to several-layer of cells between embryo and suspensor and the several ventral cells of the embryo. In the embryos with newly differentiated plumule the basal part of the embryo possessed a higher CTC fluorescence, while the FPZ fluorescence was only distributed in the basal part. It indicated that the distribution of CTC and FPZ fluorescence was in coincidence with the sites that plumule and radicle were beginning to differentiate. The technique of isolated zygotes and the possible function of calcium and calmodulin during embryo development are discussed.     

Ultrastructural Observations on CTC-Induced Callose Formation in Riella helicophylla

The Ca²⁺-chelator CTC binds to a specific site on both outer surfaces of all non-meristematic cells of the unistratose thallus of Riella, known to be rich in anionic wall components and calcium, and induces there the deposition of callose. Structural changes in this region during prolonged CTC treatment have been followed by light and transmission electron microscopy. With fluorescence microscopy punctate structures can be detected after 10 min, which upon longer incubation in CTC develop into large vesicular bodies, surrounded by a circular structure. The aniline blue-derived fluorescence intensity of these structures is highest in cells of the extension growth zone. At the ultrastructural level a mosaic of numerous smooth-surfaced vesicles, presumably containing callose, initially appears subjacent to the plasma membrane. These vesicles swell and fuse with each other, forming ultimately a circular fusion profile with the plasma membrane. This complex of callose-forming vesicles is thought to develop from elements of the partially coated reticulum (PCR), based on the presence of coated vesiculation profiles on the callose vesicles and numerous aggregates of coated vesicles in their immediate vicinity. After 30 min in CTC osmiophilic particles appear around these callose vesicles and at the cytoplasmic face of mitochondria. They are later (after 60 min) deposited in the periplasmic space between wall and plasma membrane and are also released into the surrounding medium. As judged by their reaction with FeCl₃, the osmiophilic particles appear to be phenolic in nature. We propose that upon binding of CTC a local increase of cytoplasmic calcium triggers callose synthesis in PCR-like compartments beneath the plasma membrane. However it remains to be shown as to why callose is synthesized exclusively in these intracellular compartments and not at the plasma membrane.     

X-ray microanalysis and chlorotetracycline staining of calcium vesicles in the green alga Mougeotia

Calcium ions have been proposed to play a key role in the sensory transduction of phytochrome-governed chloroplast movement in the green alga Mougeotia. To test this hypothesis, the intracellular pattern of calcium distribution was studied in this alga by two independent techniques, namely, X-ray microanalysis of fixed and of unfixed frozen-hydrated cells, as well as in vivo fluorescence by chlorotetracycline. Both methods of detection reveal a significant compartmentation of calcium in vesicles close to the chloroplast edge and, less frequently, in the cortical cytoplasm. Microfilaments, presumably actin, which could function in driving chloroplast movement, have been observed running between the chloroplast edge and the cortical cytoplasm (Wagner, G., Klein, K. (1978) Photochem. Photobiol. 27, 137). The vesicular calcium concentration is stable and decays only slowly in the absence of extracellular calcium much in the same way as the ability of the chloroplast to perform movements decreases. A functional relationship between vesicular calcium compartmentation and phytochrome-governed chloroplast movement in the green alga Mougeotia seems indicated.Abbreviation CTC chlorotetracycline     

Detection of the membrane-calcium distribution during mitosis in Haemanthus endosperm with chlorotetracycline

The distribution of membrane-associated calcium has been determined at various stages of mitosis in Haemanthus endosperm cells with the fluorescent chelate probe chlorotetracycline (CTC). CTC fluorescence in Haemanthus has two components: punctate, because of mitochondrial and plastid membrane-Ca++; and diffuse, primarily because of Ca++ associated with endoplasmic reticulum membranes. Punctate fluorescence assumes a polar distribution throughout mitosis. Cones of diffuse fluorescence in the chromosomse-to-pole regions of the metaphase spindle appear to coincide with the kinetochore fibers; during anaphase, the cones of fluorescence coalesce and this region of the spindle exhibits uniform diffuse fluorescence. Perturbation of the cellular Ca++ distribution by treatment with lanthanum, procaine, or EGTA results in a loss of diffuse fluorescence with no accompanying change in the intensity of punctate fluorescence. Detergent extraction of cellular membranes causes a total elimination of CTC fluorescence. CTC fluorescence of freshly teased crayfish claw muscle sarcoplasmic reticulum coincides with the A bands and is reduced by perfusion with lanthanum, procaine, and EGTA in a manner similar to that for diffuse fluorescence in the endosperm cells. These results are consistent with the hypothesis that a membrane system in the chromosome-to-pole region of the mitotic apparatus functions in the localized release of sequestered Ca++, thereby regulating the mechanochemical events of mitosis.     

In vitro capacitation and induction of acrosomal exocytosis in ram spermatozoa as assessed by the chlortetracycline assay

We have described the different patterns of chlortetracycline (CTC) binding to ram spermatozoa, immediately after ejaculation and upon in vitro capacitation and calcium ionophore-induced acrosomal exocytosis. Four different forms of CTC distribution were found. Form I showed an even distribution of fluorescence over the entire head, with a brighter band in the equatorial region. In Form II, uniform fluorescence was observed without equatorial band. Form III consisted of fluorescence in the anterior portion of the head. Form IV showed no fluorescence over the head. In all cases, fluorescence in the middle piece of the flagellum was observed as well. Immediately after ejaculation, Form I was the most abundant one (78%) in fresh semen with Forms II and III being relatively scarce (less than 15%). Form IV was virtually absent or appeared only occasionally. Incubation under in vitro capacitating conditions led to a significant decrease in Form I and to a significant increase in Forms II and III. Form II was mainly associated to intact acrosomes, while most spermatozoa in Form III showed intermediate forms of acrosomal status. Incubation of spermatozoa with the calcium ionophore A23187 resulted in 55% of spermatozoa showing Form IV, suggesting that it represents the acrosome-reacted stage. Form I was abruptly decreased at 30 min of incubation and was neglectible after 60 min. In contrast, Forms II and III increased at 30 min but decreased later on, suggesting that both forms represent intermediate stages before the acrosomal exocytosis. Analysis of acrosomal status in spermatozoa from individual CTC forms revealed that all spermatozoa that remained in Form II after incubation had intact acrosomes. Intermediate stages were predominant in Form III-spermatozoa, while most Form IV-spermatozoa underwent full acrosomal exocytosis. These results show that CTC binding can be used to monitor changes in ram spermatozoa during capacitation and acrosome-reaction.     

Human osteoblast-like cells respond not only to the extracellular calcium concentration but also to its changing rate

The effect of extracellular calcium on human osteoblast-like cells (HOS) has been demonstrated. An experimental setup was used for applying defined rates of change in the extracellular calcium concentration. The intracellular calcium concentration was monitored using the fluorescence dye fura-2. HOS cells showed qualitatively different responses of the intracellular calcium concentration to changes of the extracellular calcium concentration depending on its changing rate. A small rate caused only a small and slow increase of the intracellular calcium concentration, whereas faster changes are able to cause a rapid transient increase followed by a sustained elevation of the internal calcium level. Surprisingly, both an increasing as well as a decreasing external calcium concentration is able to cause cellular responses. These signals could be reduced by the IP₃-inhibitor neomycin. We propose that the G-protein dependent signalling pathway of HOS cells can not only sense the extracellular calcium concentration but also its time derivative. Received: 9 October 1997 / Revised version: 19 February 1998 / Accepted: 22 February 1998     

Metabolic requirements for maintenance of the chlortetracycline-labeled pool of membrane-bound calcium in human neutrophils

Human neutrophils labeled with chlortetracycline (CTC), commonly used as a probe of membrane-bound calcium, release lysosomal enzymes and exhibit a rapid decrease in fluorescence when exposed to the chemotactic peptide fMet-Leu-Phe or the lectin Con A. This decrease has been attributed to the release of calcium from a membrane-associated "trigger pool." The nature of this putative pool has been further characterized by examining the effects of various inhibitors on the CTC fluorescence response and lysosomal enzyme release from stimulated neutrophils. These agents included inhibitors of glycolysis (2-deoxyglucose and iodoacetate), an uncoupler of oxidative- phosphorylation (KCN), and a sulfhydryl inhibitor (N-ethylmaleimide). Resting neutrophils labelled with CTC demonstrated an enhanced decay of baseline fluorescence when exposed to 2-deoxyglucose or iodoacetate. This suggested that the pool of membrane-bound calcium labelled by this probe was maintained by glycolytic metabolism. Furthermore, 2-deoxyglucose and iodoacetate inhibited both the stimulated decrease in CTC fluorescence and lysosomal enzyme release induced by fMet-Leu-Phe and Con A in a time-dependent manner. KCN did not inhibit either response to stimulation, but did retard the recovery of CTC fluorescence observed when fMet-Leu-Phe was used as the stimulus. High concentrations of N-ethylmaleimide (100 microM) completely inhibited both the CTC fluorescence response and lysosomal enzyme release almost immediately; low concentrations of N-ethylmaleimide (30 microM) inhibited lysosomal enzyme release in a time-dependent manner without significantly affecting changes in CTC fluorescence. These results are consistent with the hypothesis that CTC serves as a probe of membrane-bound "trigger" calcium, the release of which is dependent upon intact glycolysis and is a requirement for lysosomal enzyme release.     

A Novel,Rapid Method to Quantify Intraplatelet Calcium Dynamics by Ratiometric Flow Cytometry

Cytosolic free calcium ions represent important second-messengers in platelets. Therefore, quantitative measurement of intraplatelet calcium provides a popular and very sensitive tool to evaluate platelet activation and reactivity. Current protocols for determination of intracellular calcium concentrations in platelets have a number of limitations. Cuvette-based methods do not allow measurement of calcium flux in complex systems, such as whole blood, and therefore require isolation steps that potentially interfere with platelet activation. Flow cytometry has the potential to overcome this limitation, but to date the application of calibrated, quantitative readout of calcium kinetics has only been described for Indo-1. As excitation of Indo-1 requires a laser in the ultraviolet range, such measurements cannot be performed with a standard flow cytometer. Here, we describe a novel, rapid calibration method for ratiometric calcium measurement in platelets using both Ar⁺-laser excited fluorescence dyes Fluo-4 and Fura Red. We provide appropriate equations that allow rapid quantification of intraplatelet calcium fluxes by measurement of only two standardisation buffers. We demonstrate that this method allows quantitative calcium measurement in platelet rich plasma as well as in whole blood. Further, we show that this method prevents artefacts due to platelet aggregate formation and is therefore an ideal tool to determine basal and agonist induced calcium kinetics.     

Studies ofNajas pollen tubes. Fine structure and the dependence of chlorotetracycline fluorescence on external free ions

Summary The distribution of membrane-associated calcium was investigated in pollen grains and tubes of the underwater pollinated angiospermNajas marina L. using chlorotetracycline (CTC). Tubes grown in distilled water (pH 6) showed the highest fluorescence in a subapical region that tapered basally into a fluorescent strand centrally located in the tube and extending back towards the pollen grain. The apical cap had low fluorescence as did the cytoplasm surrounding the fluorescent strand, the tube base and the pollen grain. Tubes grown in different pond waters (pH 8) revealed no intracellular CTC fluorescence. Instead there was an external fluorescence forming a distinct layer around the whole tube, frequently enhanced in a subapical region to form an external collar.Modification of the patterns of fluorescence could be induced by manipulation pH of the growth media and content of specific ions. For example tubes grown in distilled water with 10^–3 M Mg²⁺ salts showed a similar CTC fluorescence as those grown in pond water. In contrast, Ca²⁺ enrichment had no visible influence on the patterns of fluorescence. The pattern of fluorescence displayed by tubes grown in distilled water, could be reproduced in pond water if the pH was artificially reduced to pH 6.Ultrastructurally, there was no detectable difference in the markedly polar distribution of organelles between pollen tubes grown in the various growth media. The secretory vesicles found in the pollen grain prior to germination become distributed throughout the pollen tube but are least concentrated in regions that show highest internal CTC fluorescence. These regions appear to have large amounts of endoplasmic reticulum and include mitochondria.These results are discussed in relation to the significance of calcium gradients for tip growth and limitations in the use of CTC.Abbreviations CTC chlorotetracycline - SV secretory vesicle - ER endoplasmic reticulum - PIXE proton induced X-ray emissions     

Simultaneous measurement of intracellular Ca(2+) and nitric oxide: a new method

Different methods to measure the unstable radical nitric oxide (NO) have been established. We are going to present a new method to measure intracellular calcium and NO simultaneously in endothelial cells. A new fluorescent dye (DAF-2) has been developed recently which binds NO resulting in an enhanced fluorescence. We loaded porcine aortic endothelial cells with Fura-2, a fluorescent dye commonly used to measure intracellular calcium, and DAF-2 simultaneously (cell permeable dyes). Using excitation wavelengths of lambda 340 nm (Fura-2) and lambda 485 nm (DAF-2) we could show that thrombin induces an intracellular calcium increase and simultaneously a NO formation in endothelial cells which could be blocked by a NO synthase inhibitor. This new method of a simultaneous measurement of intracellular calcium and NO provides the possibility to follow intracellular calcium and NO distributions online, and is sensitive enough to monitor changes of NO formed by the constitutive endothelial NO-synthase.     

A comparison of the effects of soluble stimuli on free cytoplasmic and membrane bound calcium in human neutrophils

Calcium dynamics in human neutrophils have been studied using Quin 2 fluorescence as a measure of free cytoplasmic calcium and chlortetracycline fluorescence as an indicator of membrane-bound calcium. The results show that 1) FMLP-induced increased cytoplasmic calcium likely comes from at least two different pools. Calcium is released from one only after a high affinity receptor interaction and from the second also after a lower affinity interaction. The initial increment in cytosolic calcium does not appear to originate in the pool(s) reflected by CTC fluorescence. 2) Cytochalasin B strikingly alters the FMLP effect on membrane associated calcium, inducing a marked “recovery” phase which could be a reflection of fusion of granule membranes with the plasma membrane. 3) PMA, at concentrations inducing extensive specific granule release (≤ 10 ng/ml) has no measurable direct effect on membrane-bound or cytosolic calcium. However, PMA inhibits a subsequent CTC fluorescence response to FMLP and following the ionophore, A23187, it induces a clear decrease in cytosolic calcium. These indirect effects may be explained in terms of PMA's activation of protein kinase C.