Purification, characterization, and substrate specificity of a novel highly glucose-tolerant beta-glucosidase from Aspergillus oryzae

Aspergillus oryzae was found to secrete two distinct beta-glucosidases when it was grown in liquid culture on various substrates. The major form had a molecular mass of 130 kDa and was highly inhibited by glucose. The minor form, which was induced most effectively on quercetin (3,3',4',5,7-pentahydroxyflavone)-rich medium, represented no more than 18% of total beta-glucosidase activity but exhibited a high tolerance to glucose inhibition. This highly glucose-tolerant beta-glucosidase (designated HGT-BG) was purified to homogeneity by ammonium sulfate precipitation, gel filtration, and anion-exchange chromatography. HGT-BG is a monomeric protein with an apparent molecular mass of 43 kDa and a pI of 4.2 as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and isoelectric focusing polyacrylamide gel electrophoresis, respectively. Using p-nitrophenyl-beta-D-glucoside as the substrate, we found that the enzyme was optimally active at 50 degreesC and pH 5.0 and had a specific activity of 1,066 micromol min-1 mg of protein-1 and a Km of 0.55 mM under these conditions. The enzyme is particularly resistant to inhibition by glucose (Ki, 1. 36 M) or glucono-delta-lactone (Ki, 12.5 mM), another powerful beta-glucosidase inhibitor present in wine. A comparison of the enzyme activities on various glycosidic substrates indicated that HGT-BG is a broad-specificity type of fungal beta-glucosidase. It exhibits exoglucanase activity and hydrolyzes (1-->3)- and (1-->6)-beta-glucosidic linkages most effectively. This enzyme was able to release flavor compounds, such as geraniol, nerol, and linalol, from the corresponding monoterpenyl-beta-D-glucosides in a grape must (pH 2.9, 90 g of glucose liter-1). Other flavor precursors (benzyl- and 2-phenylethyl-beta-D-glucosides) and prunin (4',5,7-trihydroxyflavanone-7-glucoside), which contribute to the bitterness of citrus juices, are also substrates of the enzyme. Thus, this novel beta-glucosidase is of great potential interest in wine and fruit juice processing because it releases aromatic compounds from flavorless glucosidic precursors.

Improvement of nitrogen assimilation and fermentation kinetics under enological conditions by derepression of alternative nitrogen-assimilatory pathways in an industrial Saccharomyces cerevisiae strain

Metabolism of nitrogen compounds by yeasts affects the efficiency of wine fermentation. Ammonium ions, normally present in grape musts, reduce catabolic enzyme levels and transport activities for nonpreferred nitrogen sources. This nitrogen catabolite repression severely impairs the utilization of proline and arginine, both common nitrogen sources in grape juice that require the proline utilization pathway for their assimilation. We attempted to improve fermentation performance by genetic alteration of the regulation of nitrogen-assimilatory pathways in Saccharomyces cerevisiae. One mutant carrying a recessive allele of ure2 was isolated from an industrial S. cerevisiae strain. This mutation strongly deregulated the proline utilization pathway. Fermentation kinetics of this mutant were studied under enological conditions on simulated standard grape juices with various nitrogen levels. Mutant strains produced more biomass and exhibited a higher maximum CO2 production rate than the wild type. These differences were primarily due to the derepression of amino acid utilization pathways. When low amounts of dissolved oxygen were added, the mutants could assimilate proline. Biomass yield and fermentation rate were consequently increased, and the duration of the fermentation was substantially shortened. S. cerevisiae strains lacking URE2 function could improve alcoholic fermentation of natural media where proline and other poorly assimilated amino acids are the major potential nitrogen source, as is the case for most fruit juices and grape musts.

Multiwavelength videomicrofluorometric study of some human leukemic lymphoblasts: effect of adriamycin on some biological parameter

The development of multidrug resistance (MDR) in heterogeneous cell sensitive and resistant populations to a variety of clinically important cytotoxic drugs poses a major obstacle to cancer chemotherapy. The MDR phenotype is characterized by a decrease the intracellular drug accumulation and by an overexpression of the MDR1 gene which encodes the membrane protein, P-glycoprotein (Pgp). To evaluate the MDR phenotype, rationale investigations of the cytotoxic processes and effect,s of Adriamycin (ADR) were done to obtain information on individual cells. Such information could be obtained through a multiparametric approach involving multiwavelength microfluorometry and numerical image analysis on single living cells. To achieve this, cells should be simultaneously stained with Hoechst 33342 (nuclear staining), Rhodamine 123 (mitochondria staining) and Nile Red (cell contour delineation). Changes in the biological parameters accessible from R123, Ho33342 and C-SNARF-1/AM (probe used for the pHi measurements) labelling were found more informative than changes in morphological parameters for the discrimination of sensitive and resistant cells. Furthermore, this approach allows the discrimination between two resistant cell lines expressing different mechanisms of resistance.

Arthroscopic stabilization of the shoulder for acute primary dislocations using a transglenoid suture technique

Many studies report the results of arthroscopic stabilization for recurrent shoulder instability, with widely variable recurrence rates; however, there are very few reports of the use of these techniques in acute first-time dislocations. We report the clinical outcomes of 17 patients who had arthroscopic stabilization using a transglenoid suture technique for acute primary dislocation. The surgery took place between March 1992 and March 1994 and, to date, there has been one recurrent dislocation (6%) and no recurrent subluxation. There were no major complications, although a number of patients found the knot tied over the infraspinatus fascia to be uncomfortable until it resorbed. All patients examined had normal power and range of motion, and a clinically stable shoulder. All 16 patients without recurrence were satisfied with their result. Nine patients returned to sports at the same or higher level, including such vigorous contact sports as Australian Rules football and rugby. Three patients did not return to the same level of sporting activity because of lack of confidence in the shoulder or a fear of dislocation despite no clinical evidence of instability. Five patients reported a lack of confidence in the shoulder without clinical evidence of instability. We suggest that arthroscopic stabilization with transglenoid sutures or a suture anchor technique is a reasonable option for the athlete with an acute primary shoulder dislocation who wishes to return to sports.

Relationship Between Effect of Ethanol on Proton Flux Across Plasma Membrane and Ethanol Tolerance, inPichia stipitis

Pichia stipitis efficiently converts glucose or xylose into ethanol but is inhibited by ethanol concentrations exceeding 30 g/L. In Saccharomyces cerevisiae, ethanol has been shown to alter the movement of protons into and out of the cell. In P. stipitis the passive entry of protons into either glucose- or xylose-grown cells is unaffected at physiological ethanol concentrations. In contrast, active proton extrusion is affected differentially by ethanol, depending on the carbon source catabolized. In fact, in glucose-grown cells, the H(+)-extrusion rate is reduced by low ethanol concentrations, whereas, in xylose-grown cells, the H(+)-extrusion rate is reduced only at non-physiological ethanol concentrations. Thus, the ethanol inhibitory effect on growth and ethanol production, in glucose-grown cells, is probably caused by a reduction in H(+)-extrusion. Comparison of the rates of H(+)-flux with the related in vitro H(+)-ATPase activity suggests a new mechanism for the regulation of the proton pumping plasma membrane ATPase (EC 3.6.1.3) of P. stipitis, by both glucose and ethanol. Glucose activates both the ATP hydrolysis and the proton-pumping activities of the H(+)-ATPase, whereas ethanol causes an uncoupling between the ATP hydrolysis and the proton-pumping activities. This uncoupling may well be the cause of ethanol induced growth inhibition of glucose grown P. stipitis cells.

Intracellular accumulation of rhodamine 110 in single living cells

To gain a better understanding of the internalization of rhodamines, vital staining of living cells in situ by two different rhodamines, R110 and R123, was studied by microfluorometry. These dyes differ strongly in their lipophilic properties because of differences in charge distribution. Microspectrofluorometry was used to study the fluorescence emission spectra of R110-loaded cells to determine reliable loading conditions. Cell uptake and cell efflux studies of R110 were performed by numerical microfluorescence imaging. A slower uptake was observed for R110 (14 hr) vs R123 (2 hr), but the R110 efflux was much more rapid (30 min) than that of R123 (> 24 hr). Although it appeared in the R110 and R123 co-localization study that R110 was able to accumulate in mitochondria, labeling with R110 was lower than with R123. Our results indicate that, rhodamine 110 in its acid cationic form is able to cross the plasma and mitochondrial membrane and to accumulate in cell compartments as does the cationic rhodamine 123. However, because of its acido-basic properties, R110 should be able to decrease the pH of cell compartments, depending on their ability to regulate pH. In such a model, mitochondrial pH should be more greatly decreased than cytosolic pH, leading to a lower mitochondrial accumulation of R110 than of R123. Surprisingly, these effects, which should affect the energetic state of mitochondria, do not influence cell growth, because no cytotoxic effect was observed.

Determination of the relative ploidy in different Saccharomyces cerevisiae strains used for fermentation and 'flor' film ageing of dry sherry-type wines

The full chromosomal karyotype of six enological Saccharomyces cerevisiae strains used for fermentation and biological ageing of sherry-type wines was studied. A genetic method based on the analysis of segregation frequencies of auxotrophic markers, among random spore progeny of hybrids, constructed between laboratory and industrial wine strains (Bakalinsky and Snow, 1990) was used. This method was combined with the analysis of strains by pulsed-field gel electrophoresis. The results obtained clearly indicate the presence of two, three or four copies of a chromosome in the industrial strains examined, and thus confirm that aneuploidy/polyploidy is not uncommon in these strains. In all strains examined, chromosome XIII polysomy is observed. This chromosome contains the ADH2 and ADH3 loci, that code for the ADHII and ADHIII isoenzymes of alcohol dehydrogenase, which are involved in ethanol oxidative utilization during biological ageing of wines. Tetrad analysis for the 'flor formation' character suggest two possibilities: this character is either regulated by at least a digenic system, or by only one gene present on a chromosome which is, at least, disomic.

Evidence for a selective and electroneutral K+/H(+)-exchange in Saccharomyces cerevisiae using plasma membrane vesicles

The existence of a K+/H+ transport system in plasma membrane vesicles from Saccharomyces cerevisiae is demonstrated using fluorimetric monitoring of proton fluxes across vesicles (ACMA fluorescence quenching). Plasma membrane vesicles used for this study were obtained by a purification/reconstitution protocol based on differential and discontinuous sucrose gradient centrifugations followed by an octylglucoside dilution/gel filtration procedure. This method produces a high percentage of tightly-sealed inside-out plasma membrane vesicles. In these vesicles, the K+/H+ transport system, which is able to catalyse both K+ influx and efflux, is mainly driven by the K+ transmembrane gradient and can function even if the plasma membrane H(+)-ATPase is not active. Using the anionic oxonol VI and the cationic DISC2(5) probes, it was shown that a membrane potential is not created during K+ fluxes. Such a dye response argues for the presence of a K+/H+ exchange system in S. cerevisiae plasma membrane and established the non-electrogenic character of the transport. The maximal rate of exchange is obtained at pH 6.8. This reversible transport system presents a high selectivity for K+ among other monovalent cations and a higher affinity for the K+ influx into the vesicles (exit from cells). The possible role of this K+/H+ exchange system in regulation of internal potassium concentration in S. cerevisiae is discussed.

Effects of a strain of Saccharomyces cerevisiae (Levucell SC1), a microbial additive for ruminants, on lactate metabolism in vitro

The effect of Levucell SC, a strain of Saccharomyces cerevisiae marked as a feed additive for ruminants, was investigated in vitro on lactate metabolism by the ruminal bacteria Streptococcus bovis and Megasphaera elsdenii. The coculture between 10(7) live cells x mL(-1) of SC and a Streptococcus bovis strain in the presence of glucose reduced lactate production by the bacterial strain. Live yeast cells were able to compete with Streptococcus bovis for glucose utilization in strictly anaerobic conditions, so less glucose was available for the bacterium. SC also stimulated L-lactate utilization by a strain of M. elsdenii. The effect depended on the concentration of yeast cells added. Bacterial growth and fermentation end-product concentrations were also increased in the presence of SC. Some amino acids and vitamins, but not dicarboxylic acids, stimulated the bacterial specific activity of L-lactate uptake. SC was able to provide amino acids to M. elsdenii. In a coculture of Streptococcus bovis and M. elsdenii on glucose, the reduction of lactate concentration was improved by SC, the same trend being observed when maltose or soluble starch were used as carbon and energy source. These results indicate that SC can be a very useful tool to reduce lactate accumulation in vitro during fermentation of soluble sugars.

Discrimination between tumour and normal cells by staining with 3,4,5,6,16,17-hexadehydro-16-(methoxycarbonyl)-19 alpha-methyl-20 alpha-oxayohimbanium: the uracil ring as a target for the specific interaction between RNA(s) and the fluorescent probe

3,4,5,6,16,17-Hexadehydro-16-(methoxycarbonyl)-19 alpha-methyl-20 alpha-oxayohimbanium (Alstonine) is a fluorescent alcaloid which has been known to stain tumour cells more efficiently than normal ones. In this paper the spectral properties of Alstonine were first investigated and its capability for preferential staining of tumour cells verified in culture using SK-OV-3 cells as tumour cells and Mouse 3T3 fibroblasts as controls. Then interactions between Alstonine and biological macromolecules were investigated to provide the rationale for preferential labelling. Molecular filtration techniques have demonstrated that binding occurs only with RNA molecules. Similar experiments were performed with different isopolynucleotides to find an explanation for that specificity. They provide evidence that binding occurs only in the presence of a uridyl ring. This is consistent with the specificity of the linkage to RNA. As the linkage of Alstonine with RNA did not induce any shift or obvious change in the intensity of its fluorescence spectrum, it is concluded that the binding might involve the side chain of the fluorescent compound.

Malolactic fermentation by engineered Saccharomyces cerevisiae as compared with engineered Schizosaccharomyces pombe

The ability of yeast strains to perform both alcoholic and malolactic fermentation in winemaking was studied with a view to achieving a better control of malolactic fermentation in enology. The malolactic gene of Lactococcus lactis (mleS) was expressed in Saccharomyces cerevisiae and Schizosaccharomyces pombe. The heterologous protein is expressed at a high level in cell extracts of a S. cerevisiae strain expressing the gene mleS under the control of the alcohol dehydrogenase (ADH1) promoter on a multicopy plasmid. Malolactic enzyme specific activity is three times higher than in L. lactis extracts. Saccharomyces cerevisiae expressing the malolactic enzyme produces significant amounts of L-lactate during fermentation on glucose-rich medium in the presence of malic acid. Isotopic filiation was used to demonstrate that 75% of the L-lactate produced originates from endogenous L-malate and 25% from exogenous L-malate. Moreover, although a small amount of exogenous L-malate was degraded by S. cerevisiae transformed or not by mleS, all the exogenous degraded L-malate was converted into L-lactate via a malolactic reaction in the recombinant strain, providing evidence for very efficient competition of malolactic enzyme with the endogenous malic acid pathways. These results indicate that the sole limiting step for S. cerevisiae in achieving malolactic fermentation is in malate transport. This was confirmed using a different model, S. pombe, which efficiently degrades L-malate. Total malolactic fermentation was obtained in this strain, with most of the L-malate converted into L-lactate and CO2. Moreover, L-malate was used preferentially by the malolactic enzyme in this strain also.

Is reduced accumulation of Hoechst 33342 in multidrug resistant cells related to P-glycoprotein activity?

Although bisbenzimidazole-DNA interactions have been studied in solution, little information has been available in living cells. The reduced accumulation of the nuclear dye Hoechst 33342 (H342) in cells with multidrug resistant (MDR) phenotype suggested its possible use in a functional test for detection of these cells. We performed experiments to elucidate the mechanisms involved in the H342-exclusion from resistant cells. As contradictory results have been reported in literature, we compared the entire fluorescence spectra of H342 in solution and in intact living cells under different experimental conditions. The study was performed by fluorescence image cytometry. This technique allow accurate quantification of the amount of H342 bound to DNA in living cells. The dye uptake was followed in sensitive and resistant cells, a lymphoblastoid cell line, CCRF-CEM, and its resistant variant selected with vinblastine CEM/VLB100 under conditions that could modulate H342-cell binding. Competition experiments with sodium azide, verapamil, and vinblastine indicated that resistant cells did not differ in the number of possible binding sites for H342. The obtained results ruled out the possibility of discriminating cells on the basis of a spectral shift. Two modes of binding, differing in their affinity for the dye, seem to co-exist in intact cells. Although it clearly appeared that the P-glycoprotein expressed in MDR cells was mainly responsible for the H342-exclusion, other mechanisms might also be involved.

Are intracellular ionic concentrations accessible using fluorescent probes? The example of Mag-indo-1

The study of the physicochemical properties of Mag-indo-1, a fluorescent probe used for intracellular magnesium measurements, has shown that in a biological environment the deprotonated form of this probe is in simultaneous equilibrium with a protonated form, a protein and a magnesium-bound form. The complex emission fluorescence spectrum emitted by a single living cell was analyzed using a computerized method, allowing the evaluation of the contribution of each species of the Mag-indo-1 to the cellular fluorescence. This approach used to evaluate intracellular Mg2+ concentration has also shown the variability of the important participation of protein-bound Mag-indo-1 to the cellular fluorescence. Thus the widely used ratioing method, unable to take into account this variability, cannot afford a reliable evaluation of [Mg2+]. Whatever the technique used for investigation (microfluorimetry, flow cytometry, etc.) the evaluation of [Mg2+]i using the fluorescent probe Mag-indo-1 requires a method able to quantify, in complex fluorescence, the fluorescence intensity of the forms involved in the equilibrium with Mg2+.

Effects of vinblastine, colchicine, and verapamil on rhodamine 123 accumulation in human P-glycoprotein-positive leukemia cells

Multidrug-resistant (MDR) cells have been characterized by reduced accumulation of rhodamine 123 (R123). We addressed the question of whether R123 could compete with substrates or inhibitors (vinblastine, colchicine, verapamil) of P-glycoprotein (Pgp) overexpressed in MDR cells, using fluorescence image cytometry. Verapamil caused a dose-dependent increase in R123 accumulation. R123 accumulation was increased by vinblastine only at high levels and colchicine had no effect on R123 accumulation. Treatments with two drugs altered R123 accumulation depending on drug concentration ratio. The results indicate that vinblastine, R123 and verapamil can compete for outward transport by Pgp. A dual effect of vinblastine suggests that vinblastine can activate Pgp at low concentrations and inhibit R123 transport at higher concentrations.

Modulation of rhodamine 123 uptake by nigericin in sensitive and multidrug resistant leukemic cells

We have investigated the effect of the ionophore nigericin (NIG) in multidrug resistant (MDR) cells, using intracellular accumulation of the fluorescent dye rhodamine 123 (R123). NIG increased the accumulation of R123 in half of the murine MDR RFLC3 population but not in the human MDR CEM/VLB 100 cells. Co-treatment of RFLC3 with NIG plus verapamil showed additive effect on the accumulation of R123. The increase in R123 accumulation observed in RFLC3 was not the consequence of a direct effect of NIG on P-glycoprotein and was accompanied by a redistribution of the dye throughout the cell and a high cytotoxicity, which prevents the use of NIG as a resistance modulating agent.

Use of quantitative image microfluorometry to follow fluorescent ricin internalization in single living cells

We used microspectrofluorometry and videomicrofluorometry to follow the binding and internalization of fluorescein-labeled toxic lectin ricin in living Zajdela hepatoma cells. Microspectrofluorometry showed that when ricin was specifically labeled on its B-chain with one molecule of fluorescein (ABF), its fluorescence spectrum did not alter during its binding to the cell surface and subsequent internalization. This enabled us to use image analysis to follow cell internalization of labeled ricin. Accordingly, we measured the appropriate fluorescent cell parameters, comprising total fluorescence intensity, cell surface area, mean fluorescence intensity and its standard error, and used the measurements for mono- and biparametric studies of cell fluorescence distribution. The results showed that (a) ricin binds two different subpopulations of Zajdela hepatoma cells, (b) Zajdela hepatoma cells internalize ricin rapidly and after a relatively stable period of 1-2 hr, internalization starts again at 4 hr, and (c) the distribution of intracellular fluorescence is heterogeneous and ABF accumulates in certain cellular localizations. Our results demonstrate that quantitative microfluorometry is an effective and interesting approach for real-time studies of macromolecule internalization in living cells.

Measurement of intracellular magnesium concentration in 3T3 fibroblasts with the fluorescent indicator Mag-indo-1

Mag-indo-1, a fluorescent probe for measuring intracellular magnesium concentration, was used in 3T3 fibroblasts with microspectrofluorometry. The complex emission fluorescence spectrum emitted by a single living cell was analyzed with a computerized method, making it possible to evaluate the contribution of each species of Mag-indo-1 to the total fluorescence. The dye self-association observed in solutions at high dye concentration was not encountered in cells. The model of equilibria of Mag-indo-1 (monomer form) with protons, magnesium, and protein was then applied to calculate the intracellular magnesium concentration. The spectral analysis evaluated the contribution of each fluorescent species of Mag-indo-1 (a deprotonated, a magnesium-bound, and a protein-bound form) and of the cell autofluorescence to the total cell fluorescence. This method permitted accurate and reproducible measurements of intracellular magnesium concentration. Finally, this method was applied to the measurement of intracellular magnesium concentration in a 3T3 fibroblast population in exponential growth phase.

Nile red labeling of single living cells for contour delineation to quantify and evaluate the distribution of rhodamine 123 with fluorescence image cytometry

Simultaneous study of intracellular quantification and distribution of fluorescent probes is difficult when cell staining is not homogeneous. This occurs after mitochondrial staining with rhodamine 123 (R123). Classical techniques for evaluation of intracellular R123 fluorescence, such as flow cytometry, are based on measurement of the global fluorescence intensity but do not take into account parameters that reflecting cellular distribution of the probe. For simultaneously studying intracellular quantification and distribution of R123 with fluorescence image analysis, we delineated a mask of the cell, generated from a fluorescent image of the plasma membrane stained by nile red (NR). After a preliminary study of the fluorescence characteristics of R123 and NR to avoid artifacts and optimize conditions of staining, quantification and distribution of intracellular R123 studies were performed by superimposition of the mask on the R123 fluorescence image. This protocol was applied to leukemic cells and allowed estimation of individual cell parameters such as mean fluorescence intensity and standard deviation, the latter providing information of the cellular distribution of R123. Moreover, it permitted demonstration of the redistribution of R123 in the whole cell when coincubated in the presence of nigericin.

Staining with Hoechst 33342 and rhodamine 123: an attempt to detect multidrug resistant phenotype cells in leukemia

Development of resistance is the major cause of failure in chemotherapeutic treatments. We have previously shown that the level of labeling with Hoechst 33342 and rhodamine 123 in established cell lines was decreased in cells with 'classic' MDR phenotype. This functional test was carried out using fluorescence image cytometry on living cells. We applied this protocol to patients with chronic lymphocytic leukemia. Although a large variability of the labeling is observed in cells from healthy donors, this approach seems to be useful for early detection of P-gp-dependent resistance in leukemia cells and for identification of new reversing agents on patient lymphocytes.

Detection of human leukemia cells with multidrug-resistance phenotype using multilabeling with fluorescent dyes

Reduced accumulation of multiple drugs is a characteristic of cells overexpressing P-glycoprotein. This phenotype is referred to as multidrug-resistance (MDR). A protocol based on reduced accumulation of fluorescent dyes is proposed for discriminating MDR cells in cell populations. The combination of three fluorescent dyes, Hoechst 33342, rhodamine 123 and Nile red, with different intracellular targets, has been designed to characterize cells with different levels of resistance, using image cytometry. The fluorescence intensity of each dye was quantified in living cells. The protocol was applied to human leukemia cell lines, (K562, K562/ADR, CCRF-CEM, CEM/VLB100, CEM/VM-1). The effect of verapamil on dye accumulation is emphasized.

Investigation of noncalcium interactions of fura-2 by classical and synchronous fluorescence spectroscopy

Several authors have reported unexpected intracellular spectra of both indo-1 and fura-2. One of the major methodological problems in the evaluation of calcium concentration using fluorescent probes is that it is assumed that only two forms of the dyes are detectable within the cells. We show in this study of fura-2 properties that this calcium probe is pH-sensitive and able to bind to cellular proteins. The excitation spectra of protonated and protein-bound forms of fura-2 exhibit a maximum in the same region as that associated with the calcium-free form (i.e., near 365 nm). The very small shift in the excitation spectra upon proton or protein binding precludes the use of classical methods to determine the spectral composition of mixtures of several forms of fura-2. We therefore used the synchronous fluorescence technique to detect the protein-bound form of fura-2 selectively, in order to assess the pH dependence of the fura-2/protein interaction. The nonspecific binding of fura-2 to proteins is reinforced at acidic pH and inhibited by calcium. The fact that the same type of interaction was found between fura-2 and poly-L-lysine suggests that it could be mediated by basic amino acids. Because of the strong overlap of the excitation spectrum of the unprotonated free fura-2 with those associated with the protonated and protein-bound forms, a cytoplasmic acidification may lead to an artifactual measurement of low calcium levels.

Cloning and expression in yeast of a plant potassium ion transport system

A membrane polypeptide involved in K+ transport in a higher plant was cloned by complementation of a yeast mutant defective in K+ uptake with a complementary DNA library from Arabidopsis thaliana. A 2.65-kilobase complementary DNA conferred ability to grow on media with K+ concentration in the micromolar range and to absorb K+ (or 86Rb+) at rates similar to those in wild-type yeast. The predicted amino acid sequence (838 amino acids) has three domains: a channel-forming region homologous to animal K+ channels, a cyclic nucleotide-binding site, and an ankyrin-like region.

The effect of irrigating solutions on the strength of the cement-bone interface

Irrigating solutions are commonly used in the preparation of bony surfaces before total joint replacement components are cemented. Using an experimental cemented arthroplasty model, metal pseudo-prostheses were cemented to a cadaveric bone surface prepared with a specific irrigating solution. A tension load was then applied to the prosthesis until failure occurred at the cement-bone interface. A quantitative analysis of the effect of three commonly used irrigating solutions on the strength of the cement-bone interface is presented. Sixty trials were performed with normal saline, povidone iodine and hydrogen peroxide. Irrigation with hydrogen peroxide afforded statistically superior cement fixation in this arthroplasty model when compared with either normal saline or povidone iodine (P less than 0.01 Chi-squared test).

Identification of multi-drug resistant cells in sensitive Friend leukemia cells by quantitative videomicrofluorimetry

The cellular resistance to cytotoxic drugs, particularly to anthracyclines, remains a major problem in cancer chemotherapy. A number of biochemical mechanisms have been described, one of them being a lower accumulation of drugs in resistant cells. The accumulation of Ho33342 in sensitive and resistant Friend leukemia cells was studied by quantitative fluorescence image analysis, a method which allows investigations to be made on living tissues and cells. The intensity of fluorescence is related to the amount of Ho33342 accumulated into the cells and has been found to be more intense in sensitive cells than in resistant ones. Moreover, the retention of this vital dye was inversely related to the degree of resistance in the three resistant cell lines. The addition of verapamil, which is known to reverse resistance to anthracyclines, resulted in an increase of the amount of Ho33342 accumulated in the resistant cells. Ho33342 presents a higher quantum yield than any other anthracyclines, such as adriamycin and can be used as a microfluorimetric probe to identify the resistant cells in a heterogeneous cell population.