The use of a cyanine dye in measuring membrane potential in yeast

An attempt was made to use 3,3'-dipropylthiacarbocyanine as a membrane potential probe in yeast by following both its fluorescence changes and its uptake by the cells under different conditions. It was found that the uptake of the dye into the cytoplasmic compartment was translated into an increased fluorescence, and the uptake by the mitochondria produced a quenching of the fluorescence. The experiments to measure uptake showed that a large amount of the dye was taken up by the cells under "deenergized" conditions. The uptake of the cyanine, however, was significantly reduced by the omission of the substrate, by deenergization of the mitochondria, or by the addition of K+, but not by Na+. This cyanine seems to be a good, qualitative indicator of the potential of the plasma membrane and of the mitochondria of the cells, with a faster response than those probes used before in yeast.     

Measurement of cytoplasmic calcium in aleurone protoplasts using indo-1 and fura-2

Previous attempts to measure cytoplasmic Ca2+ in plant cells using the new generation of fluorescent probes, indo-1 and fura-2, have been unsuccessful. We investigated the use of indo-1 and fura-2 to measure cytoplasmic Ca2+ in barley aleurone protoplasts and found that indo-1 could be successfully used when it was loaded into protoplasts in the Ca2+-sensitive form. The acetoxymethyl esters of both dyes accumulated in aleurone protoplasts, but fura-2 was sequestered in the vacuole and indo-1 was not adequately hydrolyzed. We developed a non-disruptive method for loading the Ca2+-sensitive form of indo-1 into aleurone protoplasts in mildly acidic solutions. Using this approach, protoplasts accumulate indo-1 in a pH-dependent manner. The accumulated dye is Ca2+-sensitive, it is not sequestered in vacuoles or the endomembrane system, and it is not rapidly secreted. Fluorescence from indo-1 in individual cells was quenched by Mn2+ in the presence of digitonin. We estimate the cytoplasmic Ca2+ concentration in aleurone protoplasts to be approximately 250 nM. The Ca2+ ionophore, ionomycin does not induce changes in the fluorescence of protoplasts loaded with indo-1, but fluorescence changes could be induced by changes in extracellular Ca2+ in the presence of digitonin. We conclude that the strategy of loading indo-1 at acidic pH provides a useful means of measuring cytoplasmic Ca2+ in the barley aleurone that may also be applicable to other types of plant cells.     

Structural changes in the vacuole and cytoskeleton are key to development of the two cytoplasmic domains supporting single-cell C<Subscript>4</Subscript> photosynthesis in <Emphasis Type="Italic">Bienertia sinuspersici</Emphasis>

Bienertia sinuspersici Akhani has an unusual mechanism of C₄ photosynthesis which occurs within individual chlorenchyma cells. To perform C₄, the mature cells have two cytoplasmic compartments consisting of a central (CCC) and a peripheral (PCC) domain containing dimorphic chloroplasts which are interconnected by cytoplasmic channels. Based on leaf development studies, young chlorenchyma cells have not developed the two cytoplasmic compartments and dimorphic chloroplasts. Fluorescent dyes which are targeted to membranes or to specific organelles were used to follow changes in cell structure and organelle distribution during formation of C₄-type chlorenchyma. Chlorenchyma cell development was divided into four stages: 1—the nucleus and chloroplasts occupy much of the cytoplasmic space and only small vacuoles are formed; 2—development of larger vacuoles, formation of a pre-CCC with some scattered chloroplasts; 3—the vacuole expands, cells have directional growth; 4—mature stage, cells have become elongated, with a distinctive CCC and PCC joined by interconnecting cytoplasmic channels. By staining vacuoles with a fluorescent dye and constructing 3D images of chloroplasts, and by microinjecting a fluorescence dye into the vacuole of living cells, it was demonstrated that the mature cell has only one vacuole, which is traversed by cytoplasmic channels connecting the CCC with the PCC. Immunofluorescent studies on isolated chlorenchyma cells treated with cytoskeleton disrupting drugs suspended in different levels of osmoticum showed that both microtubules and actin filaments are important in maintaining the cytoplasmic domains. With prolonged exposure of plants to dim light, the cytoskeleton undergoes changes and there is a dramatic shift of the CCC from the center toward the distal end of the cell.     

Mitochondrially-imported cytoplasmic tRNA(Lys)(CUU) of Saccharomyces cerevisiae: in vivo and in vitro targetting systems.

The cytoplasmic tRNA(Lys)(CUU) (tRNA(1Lys)) is the single yeast tRNA species to be traffiked from the cytoplasm into the mitochondrial compartment of the cell. To study mechanisms of this targetting we worked out two test systems. The in vivo system based on the electroporation of intact yeast cells was used to introduce labelled tRNAs into the cytoplasm. All tRNA species tested were effectively introduced into the cytoplasm, but only the cytoplasmic tRNA(1Lys) was found in the mitochondrial compartment within 1-2 hours after the electroporation procedure. The in vitro system permits specific transfer of the tRNA(1Lys) into isolated mitochondria. Contrary to the known systems for protein transport into isolated mitochondria, mitochondrial import of tRNA(1Lys) in vitro requires the presence of soluble cellular proteins in the reaction mixture. The translocation proved to be ATP-dependent and to require the presence of an ATP-generation system in the reaction. Preincubation of the tRNA with the total cellular extract of the cell markedly increases the rate of the translocation. Two protein fractions are necessary to direct the import in vitro. The first one has high heparin-binding affinity, while the other protein fraction is not retained by heparin-Sepharose.     

Spectral imaging of MC540 during murine and human colon carcinoma cell differentiation.

We studied the staining pattern of merocyanine 540 (MC540) by spectral imaging of murine CT26 and human HT29 colon carcinoma cells incubated with the dye MC540. This dye, usually considered a potential membrane probe, localized mainly in the cytoplasmic vesicles of the colon carcinoma cells. However, in cells incubated in an environment similar to that of a tumor (pH 6.7), high fluorescence was detected in the nuclear membrane and nucleoli. Under these acidic conditions, resembling the Krebs effect, a population of CT26 cells displayed fluorescent plasma membranes. In differentiating cells, exhibiting cell cycle arrest at G(1)-phase and an elevated level of alkaline phosphatase, MC540 fluorescence was confined to cytoplasmic vesicles and was not detected in the plasma membrane or in the nucleoli. Cell sorting analysis of both cell types at pH 5.0 revealed higher fluorescence intensity in proliferating cells compared to differentiating cells. The fluorescence intensity of MC540-stained cells reached a maximum at pH 5.0, although the fluorescence of MC540 dye was maximal at pH 7.2. This phenomenon may result from increased binding of MC540 monomers to the cells because disaggregation of the dye with Triton X-100 produced similar results. We conclude that nucleolar localization of MC540 and an elevated fluorescence intensity can be used as indicators for proliferating cells in the characteristically acidic tumor environment. (J Histochem Cytochem 49:147-153, 2001)     

Characterisation of proton fluxes across the cytoplasmic membrane of the yeast Saccharomyces cerevisiae.

We have tested the efficacy of fluorescent probes for the measurement of intracellular pH in Saccharomyces cerevisiae. Of the compounds tested (fluorescein, carboxyseminaphthorhodafluor-1 (C.SNARF-1) and 2',7'bis(carboxyethyl)-5(6')-carboxyfluorescein), C.SNARF-1 was found to be the most useful indicator of internal pH. Fluorescence microscopy showed that in Saccharomyces cerevisiae strain DAUL1, C.SNARF-1 and fluorescein had a heterogeneous distribution, with dye throughout the cytoplasm and concentration of the dye to an area close to the cell membrane. This region was also labeled by quinacrine, which is known to accumulate in acidic regions of the cell. Saccharomyces cerevisiae BJ4932, which carries a defect in vacuolar acidification, did not show the same degree of dye concentration, suggesting that the site of C.SNARF-1 and fluorescein localisation in DAUL1 is the acidic vacuole. Changes in intracellular pH could be monitored by measuring changes in the fluorescence intensity of C.SNARF-1. The addition of glucose caused an initial, rapid decrease in fluorescence intensity, indicating a rise in cellular pH. This was followed by slow acidification. Fluorescence intensity changes were similar in all strains studied, suggesting that the localisation of dye to acidic regions does not affect the measurement of intracellular pH in DAUL1. The changes in intracellular pH on the addition of glucose correlated well with glucose-induced changes in external pH. Preincubation of cells in the presence of the plasma membrane H(+)-ATPase inhibitor diethylstilbestrol reduced extracellular acidification and intracellular alkalinisation on the addition of glucose. Both amiloride and 5-(N-ethyl-N-isopropyl)amiloride also inhibited glucose-induced proton fluxes. Phorbol 12-myristate 13-acetate had no effect on the activity of the plasma membrane ATPase.     

Transport of a fluorescent macromolecule via endosomes to the vacuole in Saccharomyces cerevisiae

Fluorescein isothiocyanate-conjugated dextran (FITC-dextran) is internalized by endocytosis into the lysosome-like vacuoles of Saccharomyces cerevisiae (Makarow, M., 1985, EMBO (Eur. Mol. Biol. Organ.) J. 4:1861-1866). Here we show that under energy depletion conditions FITC-dextran accumulated in a cytoplasmic compartment, from which it could be chased to the vacuole when the energy block was removed. The internal pH of the intermediate compartment under energy depletion was determined by fluorometry to be 5.8. The pH could be raised by the lysosomotropic agent ammonium chloride, the protonophore carbonyl cyanide p-trifluoromethoxyphenyl-hydrazone (CCCP) and the ATPase inhibitors dicyclohexylcarbodiimide (DCCD) and sodium vanadate. The pH of the vacuole was found to be 6.5. It was raised by ammonium chloride, CCCP, and DCCD, but not with sodium vanadate. Efrapeptin had no effect on the internal pH of either compartment. By dissecting the endocytic pathway, two portions of the route leading to the vacuole could be studied separately. The internalization of FITC-dextran from the extracellular fluid to the intermediate compartment followed linear kinetics, was independent of energy, and occurred at temperatures of between 15 degrees and 37 degrees C. Transfer of the marker from the intermediate compartment to the vacuole required energy, took place at temperatures between 19 degrees and 37 degrees C, and had a half-time of 7 min at 37 degrees C. Transport of the marker from the exterior of the cell to the vacuole did not require acidic pH values in the intermediate compartment or the vacuole. We suggest that the cytoplasmic compartment revealed by FITC-dextran, under energy depletion, represents the equivalent of the endosomes of mammalian cells.     

ON THE NATURE OF THE DYE PENETRATING THE VACUOLE OF VALONIA FROM SOLUTIONS OF METHYLENE BLUE

When uninjured cells of Valonia are placed in methylene blue dissolved in sea water it is found, after 1 to 3 hours, that at pH 5.5 practically no dye penetrates, while at pH 9.5 more enters the vacuole. As the cells become injured more dye enters at pH 5.5, as well as at pH 9.5. No dye in reduced form is found in the sap of uninjured cells exposed from 1 to 3 hours to methylene blue in sea water at both pH values. When uninjured cells are placed in azure B solution, the rate of penetration of dye into the vacuole is found to increase with the rise in the pH value of the external dye solution. The partition coefficient of the dye between chloroform and sea water is higher at pH 9.5 than at pH 5.5 with both methylene blue and azure B. The color of the dye in chloroform absorbed from methylene blue or from azure B in sea water at pH 5.5 is blue, while it is reddish purple when absorbed from methylene blue and azure B at pH 9.5. Dry salt of methylene blue and azure B dissolved in chloroform appears blue. It is shown that chiefly azure B in form of free base is absorbed by chloroform from methylene blue or azure B dissolved in sea water at pH 9.5, but possibly a mixture of methylene blue and azure B in form of salt is absorbed from methylene blue at pH 5.5, and azure B in form of salt is absorbed from azure B in sea water at pH 5.5. Spectrophotometric analysis of the dye shows the following facts. 1. The dye which is absorbed by the cell wall from methylene blue solution is found to be chiefly methylene blue. 2. The dye which has penetrated from methylene blue solution into the vacuole of uninjured cells is found to be azure B or trimethyl thionine, a small amount of which may be present in a solution of methylene blue especially at a high pH value. 3. The dye which has penetrated from methylene blue solution into the vacuole of injured cells is either methylene blue or a mixture of methylene blue and azure B. 4. The dye which is absorbed by chloroform from methylene blue dissolved in sea water is also found to be azure B, when the pH value of the sea water is at 9.5, but it consists of azure B and to a less extent of methylene blue when the pH value is at 5.5. 5. Methylene blue employed for these experiments, when dissolved in sea water, in sap of Valonia, or in artificial sap, gives absorption maxima characteristic of methylene blue. Azure B found in the sap collected from the vacuole cannot be due to the transformation of methylene blue into this dye after methylene blue has penetrated into the vacuole from the external solution because no such transformation detectable by this method is found to take place within 3 hours after dissolving methylene blue in the sap of Valonia. These experiments indicate that the penetration of dye into the vacuole from methylene blue solution represents a diffusion of azure B in the form of free base. This result agrees with the theory that a basic dye penetrates the vacuole of living cells chiefly in the form of free base and only very slightly in the form of salt. But as soon as the cells are injured the methylene blue (in form of salt) enters the vacuole. It is suggested that these experiments do not show that methylene blue does not enter the protoplasm, but they point out the danger of basing any theoretical conclusion as to permeability on oxidation-reduction potential of living cells from experiments made or the penetration of dye from methylene blue solution into the vacuole, without determining the nature of the dye inside and outside the cell.     

Effect of Elicitation and Changes in Extracellular pH on the Cytoplasmic and Vacuolar pH of Suspension-Cultured Soybean Cells

We have employed both ³¹P nuclear magnetic resonance spectroscopy and two intracellular fluorescent pH indicator dyes to monitor the pH of the vacuole and cytoplasm of suspension-cultured soybean cells (Glycine max Merr cv Kent). For the ³¹P nuclear magnetic resonance studies, a flow cell was constructed that allowed perfusion of the cells in oxygenated growth medium throughout the experiment. When the perfusion medium was transiently adjusted to a pH higher than that of the ambient growth medium, a rapid elevation of vacuolar pH was observed followed by a slow (approximately 30 minute) return to near resting pH. In contrast, the concurrent pH changes in the cytoplasm were usually fourfold smaller. These data indicate that extracellular pH changes are rapidly communicated to the vacuole in soybean cells without significantly perturbing cytoplasmic pH. When elicitors were dissolved in a medium of altered pH and introduced into the cell suspension, the pH of the vacuole, as above, quickly reflected the pH of the added elicitor solution. In contrast, when the pH of either a polygalacturonic acid or Verticillium dahliae elicitor preparation was adjusted to the same pH as the ambient medium, no significant change in either vacuolar or cytoplasmic pH was observed during the 35 minute experiment. These results were confirmed in experiments with pH-sensitive fluorescent dyes. We conclude that suspension-cultured soybean cells do not respond to elicitation by significantly changing the pH of their vacuolar or cytoplasmic compartments.     

Degradation of Proteins Artificially Introduced into Vacuoles of Chara australis

When an exogenous protein, bovine serum albumin, was introduced into the vacuole of a Chara australis internodal cell, it was degraded with time. This degradation proceeded only in the vacuole as far as could be observed by sodium dodecylsulfate-polyacrylamide gel electrophoresis. Degradation was inhibited by protease inhibitors such as antipain and leupeptin. Endogenous proteins introduced into the vacuole were also degraded there. Furthermore, intravacuolar cytoplasmic drops, which were often formed by cell ligation, seemed to be degraded in the vacuole. However, bovine serum albumin degradation did not proceed when mixed with isolated vacuolar sap. These results show that the vacuole in the Chara internodal cell has the capacity to degrade cellular proteins, but that cytoplasmic support is needed for this degrading activity to be maintained.     

小麦RAN1在酵母系统中影响微管的完整性和核质运输过程

真核生物的小G蛋白Ran在进化过程中比较保守,它可直接参与细胞周期调控过程,它的缺失突变可以影响很多细胞生理进程.我们已经从小麦(Triticum aestivum L.cv.Jingdong No.1)cDNA文库中克隆到一个新的RanGTPase的同源基因TaRAN1.在此基础上利用裂殖酵母模式系统研究了该基因的功能.研究结果表明,TaRAN1基因超表达可产生缺陷的纺锤体微管,这可能是导致我们以前观察到的异常染色体分离现象的原因.反义TaRAN1基因表达的酵母细胞,微管系统受到破坏.我们推测TaRAN1蛋白在细胞有丝分裂的纺锤体组装和维持微管系统的完整与稳定过程中起着重要作用.透射电镜观察实验结果显示,超表达TaRAN1的酵母细胞具有异常的核膜结构,反义表达TaRAN1的酵母细胞有异常的液泡结构和紊乱的膜结构,由此推测,TaRAN1在整个核质运输事件中可能是必须的.     

High throughput assay to detect compounds that enhance the proton permeability of Candida albicans membranes.

We describe a 96-well microtiter plate format assay to detect changes in proton permeability in membranes of the pathogenic yeast, Candida albicans. Candida albicans cells were incubated with the lipophilic ester of 2',7'-bis-(2-carboxyethyl)-5-(and-6)-carboxyfluorescein (BCECF), a pH-sensitive fluorescein derivative. Inside the cells, BCECF was released and trapped in the vacuole. Compounds that destroyed membrane integrity increased the pH value of the vacuole due to proton leakage into the cytoplasm. This was paralleled by an increase in BCECF fluorescence intensity, which could be quantified. The test assay was validated with amphotericin B, as well as with other membrane-active compounds known to increase membrane permeability. Possible applications and limitations of this assay in the field of antifungal drug discovery are discussed.     

The Fab1/PIKfyve Phosphoinositide Phosphate Kinase Is Not Necessary to Maintain the pH of Lysosomes and of the Yeast Vacuole

Lysosomes and the yeast vacuole are degradative and acidic organelles. Phosphatidylinositol 3,5-bisphosphate (PtdIns(3,5)P₂), a master architect of endolysosome and vacuole identity, is thought to be necessary for vacuolar acidification in yeast. There is also evidence that PtdIns(3,5)P₂ may play a role in lysosomal acidification in higher eukaryotes. Nevertheless, these conclusions rely on qualitative assays of lysosome/vacuole pH. For example, quinacrine, an acidotropic fluorescent base, does not accumulate in the vacuoles of fab1Δ yeast. Fab1, along with its mammalian ortholog PIKfyve, is the lipid kinase responsible for synthesizing PtdIns(3,5)P₂. In this study, we employed several assays that quantitatively assessed the lysosomal and vacuolar pH in PtdIns(3,5)P₂-depleted cells. Using ratiometric imaging, we conclude that lysosomes retain a pH < 5 in PIKfyve-inhibited mammalian cells. In addition, quantitative fluorescence microscopy of vacuole-targeted pHluorin, a pH-sensitive GFP variant, indicates that fab1Δ vacuoles are as acidic as wild-type yeast. Importantly, we also employed fluorimetry of vacuoles loaded with cDCFDA, a pH-sensitive dye, to show that both wild-type and fab1Δ vacuoles have a pH < 5.0. In comparison, the vacuolar pH of the V-ATPase mutant vph1Δ or vph1Δ fab1Δ double mutant was 6.1. Although the steady-state vacuolar pH is not affected by PtdIns(3,5)P₂ depletion, it may have a role in stabilizing the vacuolar pH during salt shock. Overall, we propose a model in which PtdIns(3,5)P₂ does not govern the steady-state pH of vacuoles or lysosomes.     

A new vital stain for visualizing vacuolar membrane dynamics and endocytosis in yeast

We have used a lipophilic styryl dye, N-(3-triethylammoniumpropyl)-4- (p-diethylaminophenyl-hexatrienyl) pyridinium dibromide (FM 4-64), as a vital stain to follow bulk membrane-internalization and transport to the vacuole in yeast. After treatment for 60 min at 30 degrees C, FM 4- 64 stained the vacuole membrane (ring staining pattern). FM 4-64 did not appear to reach the vacuole by passive diffusion because at 0 degree C it exclusively stained the plasma membrane (PM). The PM staining decreased after warming cells to 25 degrees C and small punctate structures became apparent in the cytoplasm within 5-10 min. After an additional 20-40 min, the PM and cytoplasmic punctate staining disappeared concomitant with staining of the vacuolar membrane. Under steady state conditions, FM 4-64 staining was specific for vacuolar membranes; other membrane structures were not stained. The dye served as a sensitive reporter of vacuolar dynamics, detecting such events as segregation structure formation during mitosis, vacuole fission/fusion events, and vacuolar morphology in different classes of vacuolar protein sorting (vps) mutants. A particularly striking pattern was observed in class E mutants (e.g., vps27) where 500-700 nm organelles (presumptive prevacuolar compartments) were intensely stained with FM 4- 64 while the vacuole membrane was weakly fluorescent. Internalization of FM 4-64 at 15 degrees C delayed vacuolar labeling and trapped FM 4- 64 in cytoplasmic intermediates between the PM and the vacuole. The intermediate structures in the cytoplasm are likely to be endosomes as their staining was temperature, time, and energy dependent. Interestingly, unlike Lucifer yellow uptake, vacuolar labeling by FM 4- 64 was not blocked in sec18, sec14, end3, and end4 mutants, but was blocked in sec1 mutant cells. Finally, using permeabilized yeast spheroplasts to reconstitute FM 4-64 transport, we found that delivery of FM 4-64 from the endosome-like intermediate compartment (labeled at 15 degrees C) to the vacuole was ATP and cytosol dependent. Thus, we show that FM 4-64 is a new vital stain for the vacuolar membrane, a marker for endocytic intermediates, and a fluor for detecting endosome to vacuole membrane transport in vitro.     

Monitoring of real changes of plasma membrane potential by diS-C3(3) fluorescence in yeast cell suspensions

The fluorescent dye 3,3'-dipropylthiadicarbocyanine, diS-C(3)(3), is a suitable probe to monitor real changes of plasma membrane potential in yeast cells which are too small for direct membrane potential measurements with microelectrodes. A method presented in this paper makes it possible to convert changes of equilibrium diS-C(3)(3) fluorescence spectra, measured in yeast cell suspensions under certain defined conditions, into underlying membrane potential differences, scaled in the units of millivolts. Spectral analysis of synchronously scanned diS-C(3)(3) fluorescence allows to assess the amount of dye accumulated in cells without otherwise necessary sample taking and following separation of cells from the medium. Moreover, membrane potential changes can be quantified without demanding calibration protocols. The applicability of this approach was demonstrated on the depolarization of Rhodotorula glutinis yeast cells upon acidification of cell suspensions and/or by increasing extracellular K(+) concentration.     

Cytoplasmic alkalinization during germ tube formation in Candida albicans

Weak acids were used to measure the internal pH of yeast cells of Candida albicans that had been induced to form buds or germ tubes. Under conditions that supported germ tube formation the internal pH rose from around 6.8 to over 8.0 after 30 min in two different induction media. Internal pH measured by 31P NMR confirmed this pattern and also showed that the internal pH fell to around 7.0 prior to the outgrowth of germ tubes. Conditions which led to budding induced less cytoplasmic alkalinization. This alkalinization was brought about when cells were inoculated into media of neutral pH and at an increased temperature. Increasing the temperature of the medium augmented the alkalinization of the cytoplasm induced by raising the external pH. Strains of C. albicans defective in the ability to produce germ tubes did not show this dramatic cytoplasmic alkalinization under conditions which normally supported filamentous growth. The raising of internal pH may be due to the activation of the plasma membrane proton-pumping ATPase since diethylstilboestrol inhibited the cytoplasmic alkalinization and germ tube formation without causing irreversible loss of cell viability. The results show that the induction of the dimorphic transition in this organism is accompanied by a steep rise in internal pH. It is not known whether these changes are the cause or consequence of morphogenesis.     

Elucidation of the cytoplasmic and vacuolar components in the inorganic phosphate region in the 31P NMR spectrum of yeast

Subcellular compartments, such as the vacuole in yeast, play important roles in cell metabolism and in cell response to external conditions. Concentrations of inorganic phosphate and pH values of the vacuole and cytoplasm were determined for anaerobic Saccharomyces cerevisiae cells based upon (31)P NMR spectroscopy. A new approach allows the determination of these values for the vacuole in cases when the resonance for inorganic phosphate in the cytoplasm overlaps with the resonance for inorganic phosphate in the vacuole. The intracellular inorganic phosphate resonance was first decomposed into two components by computer analysis. The assignments of the components were determined from in vivo correlations of P(i) chemical shift and the chemical shifts of the cytoplasmic sugar phosphates, and the pH dependency of the resonance of pyrophosphate and the terminal phosphate of poly-phosphate (PP(1)) which reside in the vacuole. An in vivo correlation relating PP(1) and P(i) (vac) chemical shifts was established from numerous evaluations of intracellular compositions for several strains of S. cerevisiae. This correlation will aid future analysis of (31)P NMR spectra of yeast and will extend NMR studies of compartmentation to cellular suspensions in phosphate-containing medium. Application of this method shows that both vacuolar and extracellular P(i) were phosphate reserves during glycolysis in anaerobic S. cerevisiae. Net transport of inorganic phosphate across the vacuolar membrane was not correlated with the pH gradient across the membrane.     

Brilliant Blue as an alternative dye to Fast Green for in ovo electroporation

Chick embryo electroporation is a powerful tool for the introduction of transgenes into tissues of interest for the study of developmental biology. This method often uses Fast Green to visualize the injected area by staining the solution containing DNA green. Here, we show that Fast Green fluoresces in a red color after electroporation, suggesting that researchers need to be cautious when detecting red fluorescence. Fast Green solution did not show any fluorescence before injection into chick embryos, but fluoresced red within 3 min post-injection into chick embryos. We identified Brilliant Blue as suitable alternative dye for use as an indicator of injection sites in ovo electroporation. We found that 0.2% of Brilliant Blue was sufficient to track the area of DNA injection. In addition, this chemical did not show red fluorescence after electroporation. Our findings demonstrate that Brilliant Blue can be used for detecting red fluorescent proteins introduced into chick embryos by electroporation. Our study also shows useful examples for the application of Brilliant Blue for the precise quantification of two fluorescence intensities after EGFP and mCherry co-electroporation.     

Determination of intracellular pH of BALB/c-3T3 cells using the fluorescence of pyranine

In terms of accuracy and sensitivity, intracellularly trapped, pH-dependent fluorescent probes are appropriate to accurately measure intracellular pH. These probes are commonly introduced into living cells in esterified form, wherein the free acid is produced through enzymatic hydrolysis. The fluorescence characteristics of the ester and the free acid can differ markedly and spectral uncertainty can occur. We describe here the measurement of intracellular pH using 8-hydroxypyrene-1,3,6-trisulfonic acid (pyranine) that has been scrape-loaded into BALB/c-3T3 mouse cells. The excitation spectrum of pyranine is pH sensitive, with an isosbestic point at 415 nm and peaks at 405 and 465 nm which decrease and increase with pH, respectively. The 465/405 ratio can be used to monitor the pH, while the fluorescence at 415 nm indicates the total dye-dependent signal remaining. The scrape-loaded dye persists in cells for periods up to 6 h. We have calibrated this dye in situ using nigericin/high K+, and have found that the pKa of the dye in situ is 7.82, as compared to 7.68 in vitro. We have observed that the cells can slowly equilibrate their intracellular pH to near control levels when presented with either an acute alkaline or acid load.