Ionophores and weak bases inhibit phagolysosomal proteolysis in Paramecium.

In a recent report we showed that ionophores and weak bases inhibit digestive vacuoles (DV) acidification primarily and lysosome-DV fusion secondarily but have no effect on lysosome-DV fusion when acidification is normal. In this study we attempted 1) to show that fluorescein isothiocyanate (FITC)-albumin taken up by phagocytosis could be used for a sensitive proteolytic assay, 2) to use this assay to determine the effect of ionophores and weak bases on proteolysis and 3) to learn how an inhibition of acidification and/or lysosome-DV fusion would affect proteolysis. When cells were pulsed with FITC-albumin and latex beads for 3 min and chased, the amount of albumin degraded increased linearly from 9 to 27 min, reaching a plateau by 30 min, and was inhibited by leupeptin and pepstatin A by 47 to 89%. These results showed that the degradation of FITC-albumin occurred in the phagolysosomes. When added before acidification had commenced, carbonyl cyanide p-trifluoro-methoxyphenyl hydrazone (FCCP), monensin and NH4Cl partially inhibited lysosome-DV fusion (25-50%) and strongly inhibited proteolysis by 64 to 79%. Added between acidification and lysosome-DV fusion, fusion was unaffected while proteolysis was reduced by 40 to 50%. Added after lysosome-DV fusion was completed, proteolysis was still reduced by the same amount. Chloroquine at 0.25 mM had no effect on proteolysis except when added before acidification, it inhibited fusion by 22% and proteolysis by 16%. These data, together with those published recently, showed that 1) ionophores and weak bases inhibited acidification first, lysosome-DV fusion second and proteolysis third, but they also inhibited proteolysis directly and independent of the prior steps and 2) the proteolysis inhibitory effects were additive.

Rapid and sensitive assays for phagosomal acidification in Paramecium and Tetrahymena.

Biochemical and cytochemical procedures were developed to measure the rate of phagosomal acidification for phagosomal pH ranging from 5 to 2.5. These assays were based on the pH-dependent inactivation with time of horseradish peroxidase (HRP) activity, a result attributable to the dissociation of this enzyme to a colorless protein and ferriprotoporphyrin in acidic solutions. When preincubated in buffers of varying pH, the rate of HRP inactivation followed a sigmoid curve, with the highest rate of inactivation between 4.3 and 3.5 when using citrate-phosphate buffer and between pH 3.4 and 2.8 when using the universal ABC buffer. This inactivation was temperature but not concentration dependent. When Paramecium caudatum, members of the P. aurelia complex or Tetrahymena thermophila was pulsed briefly with HRP and small fluorescent beads, the loss of HRP activity, measured biochemically in cell homogenates and/or cytochemically in phagosomes, was rapid and followed the kinetics of a first-order rate reaction. Both assays gave similar values for the rate constant for acidification and similar rates of inhibition when P. caudatum was exposed to a proton ionophore, carbonyl cyanide p-trifluoromethoxyphenyl hydrazone. These assays can readily be adapted to other phagocytic cells as long as a rapid procedure is available for removing all unphagocytosed HRP and latex beads. These procedures are sensitive and rapid thus allowing many samples to be quickly prepared and analyzed.

Phagosomal acidification in Paramecium: effects on lysosomal fusion.

Phagosomes of paramecia and amoeba and endosomes of fibroblasts and other mammalian cells are acidified prior to lysosomal fusion. The question, whether the phagosomal acidification process in paramecia is required for phagosome-lysosome fusion, was studied using ionophores, weak bases, and cytochalasin B (CB) in combination with monoclonal antibodies, acid phosphatase (AcPase) cytochemistry, and lysosome morphometry. Digestive vacuoles (DVs) of known ages were treated and examined. In untreated cells, lysosome binding to the membrane of the acidified DV increased linearly with age and reached a maximum before lysosome-DV fusion. When the fusion of the acidosomes with the very young DVs was prevented by CB, causing a block in the normal vacuole-pH drop, lysosome binding to the DVs as well as the rate and extent of lysosome-DV fusion were all greatly reduced. These effects of CB were reversible. When present prior to acidification, three ionophores and two weak bases did not inhibit the acidosome-DV fusion but raised the phagosomal pH and reduced both the rates of DV acidification and of lysosome-DV fusion. However, when added after acidification but prior to lysosome-DV fusion, five of the six perturbants studied did not inhibit this fusion but prolonged the period when DVs remained AcPase positive. Lastly, lysosome-DV fusion rates were found to be related to acidification rates. We conclude that an inhibition in acidosome-DV fusion or a reduction in both the acidification rate and vacuolar-pH drop would inhibit lysosome-DV fusion.

Use of nile red as a rapid measure of lipid content in ciliates.

We report the use of nile red as a rapid and inexpensive method to estimate cellular lipids in three species of Paramecium and in Tetrahymena by the direct application of the dye to living or fixed cells without extraction and purification. Qualitative estimates of the relative changes in the lipid content of cells of varying culture ages were obtained using fluorescence microscopy, while semiquantitative determinations were obtained by measuring the total fluorescence from the emission spectrum (excitation, 535 nm) of fixed cells treated with excess nile red. The relative amounts of neutral (excitation, 488 nm; emission, 540 nm) and polar (excitation, 535 nm; emission, 680 nm) lipids were approximated using fluorescence intensity at these selected spectral conditions to avoid any spill over from each other. The patterns of change with culture age in total lipids in Tetrahymena and in total, neutral and polar lipids in Paramecium obtained using nile red agreed well with published gravimetric data for these ciliates.

Occurrence of furan in commercial processed foods in Brazil.

Selected commercial processed foods available in the Brazilian market (306 samples) were analysed for furan content using a validated gas chromatography-mass spectrometry method preceded by headspace solid phase micro-extraction (HS-SPME-GC/MS). Canned and jarred foods, including vegetable, meat, fruit and sweet products, showed levels up to 32.8 µg kg⁻¹, with the highest concentrations observed in vegetables and meats. For coffee, furan content ranged from 253.0 to 5021.4 µg kg⁻¹ in the roasted ground coffee and from not detected to 156.6 µg kg⁻¹ in the beverage. For sauces, levels up to 138.1 µg kg⁻¹ were found. In cereal-based products, the highest concentrations (up to 191.3 µg kg⁻¹) were observed in breakfast cereal (corn flakes), cracker (cream crackers) and biscuit (wafer). In general, these results are comparable with those reported in other countries and will be useful for a preliminary estimate of the furan dietary intake in Brazil.

A survey of lectin binding in Paramecium.

To better understand the general distribution of glycoproteins and the distribution of specific glycoprotein-bound sugar residues in Paramecium, a survey of the binding pattern of selected lectins was carried out in P. tetraurelia, P. caudatum, and P. multimicronucleatum. Lectins studied were concanavalin A (Con A), Griffonia simplicifolia agglutinins I and II (GS I and GS II), wheat germ agglutinin (WGA), Ulex europaeus (UEA I), peanut agglutinin (PNA), Ricinis communis toxin (RCA60) and agglutinin (RCA120), soybean agglutinin (SBA), Bauhinia purpurea agglutinin (BPA), Dolichos biflorus agglutinin (DBA), and Maclura pomifera agglutinin (MPA). Those giving the most distinctive patterns were Con A, GS II, WGA, UEA I, and PNA. No significant differences were found between the three species. Concanavalin A, a mannose/glucose-binding lectin, diffusely labeled the cell surface and cytoplasm and, unexpectedly, the nuclear envelopes. Events of nuclear division, and nuclear size and number were thus revealed. Both WGA and GS II, which are N-acetylglucosamine-binding lectins, labeled trichocyst tips, the cell surface, and the oral region, revealing stages of stomatogenesis. The lectin WGA, in addition, labeled the compartments of the phagosome-lysosome system. The lectin PNA, an N-acetyl galactosamine/galactose-binding protein, was very specific for digestive vacuoles. Finally, UEA I, a fucose-binding lectin, brightly labeled trichocysts, both their tips and body outlines. We conclude that a judicious choice of lectins can be used to localize glycoproteins and specific sugar residues as well as to study certain events of nuclear division, cellular morphogenesis, trichocyst discharge, and events in the digestive cycle of Paramecium.

Characterization of monoclonal antibodies to trichocyst antigens in Paramecium.

Ten mouse monoclonal antibodies (mAbs) were raised against trichocyst contaminants present in crude or enriched lysosome fractions of Paramecium multimicronucleatum. Using an indirect immunofluorescence assay (IFA) and immunogold labelling on frozen thin sections, epitopes were located on the outer edge, cortex and the core of the trichocyst body, as well as the sheath covering the tip. Except for the two on the tip, epitopes were reactive after SDS-PAGE under non-reducing conditions. Four mAbs (131C1E8, A1-3, A16-2, D7) were directed to a trio of bands of 37, 34 and 29 (x 10(3] Mr from the beaded or meshlike trichocyst body sheath. A fifth mAb (135B9E7), directed to epitopes on the cortex inside the beaded body sheath, reacted strongly with the 37 and 34 bands, but weakly with the 29 x 10(3) Mr band. The last three mAbs (270D5, 22D7F2, D8) were reactive with one or more of three families of antigens found on the trichocyst core. mAb 270D5 reacted mainly with the 34 and 29 (x 10(3] Mr bands of the family containing the above trio, while mAb 22C7F2 reacted consistently with the 47 x 10(3) band of the higher Mr family but variably with both the trio of bands and the 17 x 10(3) band of the lower Mr family. mAb D8, which was directed to epitopes on the trichocyst core and small vesicles in the endoplasm, reacted only with the 29 x 10(3) Mr band. The mAbs were cross-reactive with the trichocysts of P. primaurelia, P. tetraurelia, P. caudatum and P. calkinsi with some small variation in blotting patterns.(ABSTRACT TRUNCATED AT 250 WORDS)

Phagosome formation in Paramecium: effects of solid particles.

Digestive vacuole (DV) formation in Paramecium can be separated into four steps: sequestration and recycling of the spent DV membrane, sweeping and concentrating of particles into the nascent DV, vacuole growth, and the release of the nascent DV. How the size, load and surface charge of solid particles affected formation and subsequently the digestive processes in log-phase cells were investigated. Pulsing cells continuously with beads resulted in an initial linear increase, followed by a steady state, of labelled DVs. Above a certain threshold concentration, the rate of formation and the size of the DVs formed (as well as the steady state) all increased with increasing bead load, so that for a 16-fold increase in bead load, a corresponding fourfold increase in the incorporation of the recycled membrane into the DVs was observed. The threshold values, which depended on the sensitivity of the technique used to score these DVs, were lowered as bead size increased. The steady state of labelled DVs was shown to correspond to a strict balance between the formation and defecation rates as shown by efflux measurements and pulse-chase protocols using two consecutive labels. The duration of the pulse required to reach these steady states was inversely proportional to the logarithm of the bead number at low bead loads but remained constant at higher bead loads. The formation rates and the DV size were similar when cells were pulsed with beads from 0.5 to 3 microns, but DV size increased using beads of 4.5 and 5.7 microns. The maximal bead size that could be ingested was approximately 10 microns.(ABSTRACT TRUNCATED AT 250 WORDS)

Monoclonal antibody study of the decorated spongiome of contractile vacuole complexes of Paramecium.

A monoclonal antibody (mAb) has been developed and selected by immunofluorescence for the radial canals of the contractile vacuole complex (CVC) of Paramecium multimicronucleatum. By applying indirect immunogold labeling to thin frozen sections this mAb has been shown at the electron microscopic level to be specific for the decorated spongiome. We have used the mAb to study the normal interfission appearance as well as developmental stages of the decorated spongiomes. Two decorated spongiomes, presumably involved in water sequestration, radiate as 5-10 bands from unlabeled, circular, 25 microns diameter centers. Two new CVCs arise just anterior to the space occupied by the old spongiomes, the new anterior CVC appearing slightly before the posterior one. Development of the new spongiomes around a 10 microns unlabeled central zone is accompanied by a regression of old spongiome bands until the lengths of these bands in both old and new CVCs are equal just before cell division. After division both old and new spongiome bands grow at equal rates to the same length. Exceptions to the above general scheme, both in number of CVCs in interfission, as well as in position of the new relative to the old CVCs, are also observed.