A filtration method for measuring cellular uptake of [14C]methylamine and other highly permeant solutes

A filtration technique has been developed for study of the uptake of [14C]methylamine by Azotobacter vinelandii. This dual filter arrangement requires a precision microporous polycarbonate film which overlays a paper filter. Cellular uptake of radioactivity is terminated by vacuum filtration of the reaction mixture onto the polycarbonate filter without dilution or washing. Filtration was complete in 0.7 s with retention of less than 0.2% of the extracellular radioactivity. The dual filter method gave 20-fold higher levels for intracellular methylamine than filtration followed by washing. Without washing, nitrocellulose filters retained 18 times more extracellular [3H]sorbitol and 80 times more extracellular [14C]methylamine than polycarbonate filters. Use of an underlying paper filter did not significantly improve the performance of nitrocellulose filters. However, addition of a paper filter reduced extracellular methylamine and sorbitol retention on polycarbonate filters by 77 and 86%, respectively. This method is generally applicable to measurement of the uptake of highly permeant molecules by cells and subcellular organelles.     

Bicarbonate uptake by basolateral membrane vesicles from rat jejunum

Basolateral membranes from rat jejunal enterocytes have been obtained by self-orienting Percoll-gradient centrifugation. Bicarbonate and L-glucose uptake into osmotically active basolateral membrane vesicles has been studied by a rapid filtration technique. In closed vessels and at pH 8.2 the uptake kinetics of both [14C]bicarbonate and L[3H]glucose have been followed for 30 min at 18 degrees C. Bicarbonate uptake seems to be fast and in efflux experiments SITS and DIDS effect is negligible. This work demonstrates that it is possible to determine bicarbonate flux across basolateral membrane vesicles at pH and temperature values close to usual experimental conditions.     

Absorption filtration. A tool for the measurement of ion tracer flux in native membranes and reconstituted lipid vesicles

A rapid, simple and reproducible method has been developed for the measurement of ion tracer flux with both native membrane vesicles and reconstituted lipid vesicle systems. Following the absorption of vesicles onto glass fiber filters, tracer flux is performed directly upon the deposited samples. In contrast to the more conventional vacuum and gel filtration techniques, absorption filtration exhibits comprehensive data retrieval whereby the removal of extravesicular ions, the retention of intravesicular ions and the amount of ions fluxed can be accurately analyzed. Both influx and efflux assays have been designed to measure the carbamylcholine-induced flux of ²²Na⁺ which is characteristic of acetylcholine receptor-enriched membranes from Torpedo californica electroplax. The flux signal-to-background noise ratio is maximized in the efflux assay, since agonist activation is performed subsequent to the exhaustive removal of extravesicular tracer. An interesting feature of the influx assay is that the agonist-induced uptake of ²²Na⁺ can be repeated with the original vesicles which additionally maximizes the flux signal. With either approach, the inactivation of ionophoric activity due to prolonged exposure to agonists (‘desensitization’) can be reversed upon removal of agonist without dilution of the deposited samples. Due to the large array of glass fiber filters and ion-exchange disks, the absorption filtration technique should be able to accommodate the transport and binding of soluble molecules to a variety of intact cells, membranes and reconstituted lipid vesicles.     

Calcium uptake into rat small intestinal brush border membrane vesicles: characterization of transmembrane calcium transport at short initial incubation times

Calcium transport into brush border vesicles from rat small intestine was investigated by determining uptake rates at very short incubation periods. At incubation times up to 1 second a linear relationship between calcium uptake and time was observed at free calcium concentrations ranging from 1 microM to 5 mM. At time points above 1 second calcium uptake deviates progressively from linearity. Several lines of evidences (EGTA-wash, dependency on membrane potential, temperature sensitivity and effect of the calcium ionophore A23187) suggest transmembrane transport rather than extravesicular binding of calcium as being responsible for calcium uptake. Saturation experiments performed under initial linear and curvilinear uptake conditions show a saturable transport component in the mu molar and only a tendency to saturate in the molar concentration range. It is concluded that uptake values far from equilibrium are characteristic for transmembrane flux of calcium. Transmembrane flux of calcium is mediated by multiple and potential-sensitive mechanisms.     

A rapid-filtration technique for membrane fragments or immobilized enzymes: measurements of substrate binding or ion fluxes with a few-millisecond time resolution

The construction and use of a filtration system with milliseconds time resolution is described here. This apparatus allows measurements of substrate binding to immobilized enzyme or ion fluxes through membrane vesicles to be performed over a very large time scale, from 10 ms to seconds. The main advantage of this system compared to the widely used quench-flow technique is that it does not require the use of an inhibitor. Following adsorption of the enzyme in an adequately chosen filter, the reaction is allowed to proceed within the filter during a forced filtration of a buffer containing the reactive substrate (or of a washing solution in the case of efflux measurements). The design allows the duration of filtration and buffer flux to be finely and reproducibly controlled. This paper illustrates the use of this rapid-filtration system for time-resolved measurements of calcium binding and transport by sarcoplasmic reticulum Ca-ATPase and of the initial phase of ADP transport by the ADP/ATP carrier of intact mitochondria.     

Protein fouling during constant-flux virus filtration: Mechanisms and modeling

As biomanufacturers consider the transition from batch to continuous processing, it will be necessary to re-examine the design and operating conditions for many downstream processes. For example, the integration of virus removal filtration in continuous biomanufacturing will likely require operation at low and constant filtrate flux instead of the high (constant) transmembrane pressures (TMPs) currently employed in traditional batch processing. The objective of this study was to examine the effect of low operating filtrate flux (5–100 L/m²/h) on protein fouling during normal flow filtration of human serum Immunoglobulin G (hIgG) through the Viresolve® Pro membrane, including a direct comparison of the fouling behavior during constant-flux and constant-pressure operation. The filter capacity, defined as the volumetric throughput of hIgG solution at which the TMP increased to 30 psi, showed a distinct minimum at intermediate filtrate flux (around 20–30 L/m²/h). The fouling data were well-described using a previously-developed mechanistic model based on sequential pore blockage and cake filtration, suitably modified for operation at constant flux. Simple analytical expressions for the pressure profiles were developed in the limits of very low and high filtrate flux, enabling rapid estimation of the filter performance and capacity. The model calculations highlight the importance of both the pressure-dependent rate of pore blockage and the compressibility of the protein cake to the fouling behavior. These results provide important insights into the overall impact of constant-flux operation on the protein fouling behavior and filter capacity during virus removal filtration using the Viresolve® Pro membrane.     

Energy dependence and functional reconstitution of the gamma-aminobutyric acid carrier from synaptic vesicles.

The energy dependence of gamma-aminobutyric acid (GABA) uptake was characterized in rat brain synaptic vesicles and in proteoliposomes reconstituted with a new procedure from vesicular detergent extracts. The proteoliposomes displayed high ATP-dependent GABA uptake activity with properties virtually identical to those of intact vesicles. GABA uptake was similar at chloride concentrations of 0 and 150 mM, i.e. conditions under which either the membrane potential (delta psi) or the pH difference (delta pH) predominates. Delta psi was gradually dissipated by increasing the concentration of SCN-. GABA uptake was reduced by 10 mM SCN-, showing less sensitivity to delta psi reduction than glutamate uptake but more than dopamine uptake. Dissipation of delta pH with NH+4 abolished GABA uptake at pH 7.3, whereas no significant inhibition occurred at pH 6.5. In contrast, dopamine uptake was inhibited more strongly, even at pH 6.5, and glutamate uptake was not reduced in either condition. We conclude that GABA uptake is driven by both components of the proton electrochemical gradient, delta pH and delta psi, and that this is different from the uptake of both dopamine and glutamate, which is more strongly dependent on delta pH and delta psi, respectively. Thus, our data suggest that GABA uptake is electrogenic and occurs in exchange for protons.     

Renal palmitate transport: possible sites for interaction with a plasma membrane fatty acid-binding protein

Summary In previous studies from this laboratory [14], a mediated transport system for long chain fatty acids was observed in rat renal basolateral membrane vesicles. Transport was measured in the absence of albumin and indicated the presence of a Na⁺ independent anion exchange mechanism. The present experiments were done to characterize renal transport of fatty acids derived from fatty acid-albumin complexes. ³H-palmitate uptake by brush border (BBMV) and basolateral membrane vesicles (BLMV) isolated from rat renal cortex was determined using a rapid filtration technique. All incubation media contained 100 µM ³H-palmitate complexed to 100 µM bovine serum albumin. Up to 65% of initially bound fatty acid-albumin complexes were displaceable by washing with solution containing 0.1% albumin. Total palmitate uptake was measured as the remaining non-displaceable radioactivity. In BBMV in low ionic strength (300 mM mannitol) or ionic buffers (100 mM mannitol + 100 mM NaCl or KCl), total palmitate uptake at 15 sec did not differ from equilibrium (60 min) values of 10–11 nmoles/mg protein. Uptake was primarily due to binding. A similar pattern was seen with BLMV in 300 mM mannitol buffer: In BLMV in 100 mM NaCl or KCl buffers, equilibrium uptake was 10-fold lower than at 15 sec. This suggests binding followed by cation-dependent translocation. If a putative FABP_PM is involved in transport only, its presence should be confined to BLMV.     

A high-throughput assay for measurement of multidrug resistance protein-mediated transport of leukotriene C4 into membrane vesicles

This study investigated a high-throughput assay to measure multidrug resistance-associated protein (MRP1)-mediated uptake into membrane vesicles. Typically, a rapid filtration technique using a 12-filter vacuum manifold is used. We report here the development of a 96-well microtiter dish assay. MRP1-transfected HeLa cells (HeLa-T5) were used for the membrane vesicle preparations. The uptake of 50nM [3H]leukotriene C(4) (LTC(4)) was measured in a 96-well microtiter dish with rapid filtration onto a Perkin Elmer unifilter GF/B plate using a Perkin Elmer Filtermate 196. Counting of the isotype was conducted with a Perkin Elmer Top Count NXT. Uptake was adenosine 5'-triphosphate-dependent and linear over a 120-s time course. Uptake was inhibited by the leukotriene D(4) antagonist, MK 571, with a k(i) of 0.67 microM, and by the anti-MRP1 monoclonal antibody QCRL-3 but not by QCRL-1. Inhibition by estradiol-17-beta-glucuronide was 35-fold greater than inhibition by estradiol-3-beta-glucuronide. The kinetic parameters for LTC(4) uptake were determined to be a K(m) of 157nM with a V(max) of 344pmol/min/mg protein. The properties of MRP1-mediated transport of LTC(4) are consistent with those previously reported. The microtiter dish assay is a more expedient method for measuring transport into membrane vesicles and will have applications to other transporters.     

Aging reduces the GABA-dependent 36Cl- flux in rat brain membrane vesicles

The function of the chloride channel associated to GABAA receptor complex was analyzed in the brain of aged rats by measuring the chloride flux across the neuronal membrane and its modulation by drugs acting at the level of the GABA receptor complex and 35S-TBPS binding. The basal 36Cl- uptake by brain membrane vesicles of aged rats was higher (22%) than that observed in those of adult rats. The higher 36Cl- uptake found in cortical membrane vesicles of senescent rats was not sensitive to the action of bicuculline indicating that it was not the consequence of a tonic GABAergic modulation. Moreover, the stimulation of 36Cl- uptake induced by GABA was markedly lower in membrane vesicles of aged rats than that observed in those of adult rats. Accordingly, the stimulation of 36Cl- efflux elicited by GABA (18%) and pentobarbital (26%) was higher in membrane vesicles of adult rats with respect to that (8 and 16%, respectively) of old rats. Finally, a significant decrease of 35S-TBPS binding was observed in membrane preparation from the cerebral cortex, cerebellum and hippocampus of aged-rats. Scatchard plot analysis indicated that the decrease was entirely due to a reduction in the total number of binding sites with no change in their affinity. All together the results indicate that in the rat brain the function of the chloride channel coupled to the GABA/benzodiazepine/barbiturate receptor complex is reduced by aging.     

Phlorizin increases the permeability of intestinal mucosal membrane to sodium

We reported previously that when jejunal transmural glucose transport was inhibited by phlorizin the ratio of Na:glucose transport increased from 2.0:1 (in controls) to 3.3:1. To elucidate the mechanism of this increased ratio of Na:glucose transport, in the present study we have investigated the effect of phlorizin on Na uptake by brush border membrane vesicles and by everted sacs of hamster jejunum. In experiments on membrane vesicles the following observations were made. The time course of Na uptake showed that the control vesicles were in complete equilibrium with a Na-containing (100 mM) medium between 30 and 90 min incubation. In these periods of incubation, the vesicles incubated with phlorizin presumably also equilibrated with the medium, but lost their intravesicular Na during Millipore filtration and washing, and consequently the residual Na content was lower than that of controls. This effect of phlorizin was concentration dependent, and appeared to be unrelated to Na-coupled glucose transport, because it was also observed in the absence of glucose. This loss of Na during Millipore filtration and washing was also observed (i) when vesicles were equilibrated in a Na-containing solution in the absence of phlorizin and then exposed to a similar solution containing phlorizin, or (ii) when vesicles were equilibrated in a Na-containing solution in the presence of phlorizin and then washed repeatedly following Millipore filtration.(ABSTRACT TRUNCATED AT 250 WORDS)     

Intestinal amino acid absorption in tobacco hornworm larvae is stimulated by potassium and sodium but not rubidium or lithium

We used rapid filtration assays to determine the ion selectivity of ion gradientdriven phenylalanine uptake by brush border membrane vesicles prepared from the larval midgut of the tobacco hornworm (Manduca sexta). Phenylalanine uptake by these vesicles is stimulated by both potassium and sodium. Phenylalanine uptake by larval M. sexta midgut brush border membrane vesicles is voltage sensitive and shows little selectivity for potassium over sodium. However, phenylalanine uptake by these vesicles is stimulated by neither rubidium nor lithium.     

Transport mechanisms in isolated plasma membranes. Nucleoside processing by membrane vesicles from mouse fibroblast cells grown in defined medium.

Plasma membrane vesicles were isolated from a subline of L929 mouse fibroblasts grown on defined medium in the absence of serum. These vesicles were not significantly contaminated by mitochondria or endoplasmic reticulum. The isolation procedure, a modification of that originally developed by McKeel and Jarett (McKeel, D.W., and Jarett, L. (1970) J. Cell Biol. 44, 417-432) employs mechanical homogenization in isotonic medium followed by differential centrifugation. The resultant plasma membrane vesicles take up radioactivity when exposed to uniformly labeled nucleosides. Two subfractions of the plasma membrane were isolated, distinguished by their differing activity of 5'-nucleotidase and (Na+,K+)-stimulated ATPase, two well known plasma membrane enzyme markers. Uptake of nucleoside radioactivity was extensively studied in one subfraction; it was linear with time and membrane concentration over ranges used for the studies. Apparent Km values for uptake of radioactivity from adenosine, inosine, and uridine were 7.1 +/- 26 muM, respectively. Uptake of radioactivity from all three nucleosides exhibits a broad pH optimum from pH 7 to pH 9, but falls off rapidly at lower pH. N-Ethylmaleimide was an effective inhibitor of uptake of radioactivity from all three nucleosides; uptake of radioactivity from uridine is more sensitive than uptake of radioactivity from the purine nucleosides. Adenosine inhibited uptake of radioactivity from inosine more than from uridine. Inosine inhibited the uptake of radioactivity from adenosine, but uridine did not. Caffeine and 6-methylaminopurine riboside (6-N-methyladenosine differentially inhibit uptake of radioactivity from adenosine and inosine, and thus the vesicles apparently possess seperate transport systems for uptake of radioactivity from purine nucleosides and from uridine.     

The affinity of [3H]quinuclidinyl benzilate and some other radioligands for glass microfiber and cellulose filters in some common liquid scintillation solvents

The optimum conditions for measuring radioactivity in the filtration assay of muscarinic cholinoceptors with tritiated quinuclidinyl benzilate are to use Whatman GF/B filters and to add a simple toluene scintillant to them while they are still damp. Practically all the radioactive material is then slowly extracted into the scintillant and high counting efficiencies are obtained after 24 h. Dried filters, or dry filters in control experiments in the absence of receptor, adsorb much of the radioactivity with a 30% reduction in counting efficiency. Other scintillants were able to extract the radioactive material from dry filters, but were generally not preferable to toluene. The GF/B filters performed better than other glass microfiber and cellulose filters in terms of retention of receptor-bound ligand, rapid filtration rates, and low filter blanks. Toluene is unsuitable as a scintillant with GF/B filters for some other radioligands examined.     

Performance of an anaerobic membrane bioreactor in which granular sludge and dynamic filtration are integrated

To alleviate the fouling of a filter, simple substrates, dynamic filtration, and granular sludge were applied in an anaerobic membrane bioreactor (AnMBR). The results showed that under a transmembrane pressure < 20 kPa, the filter flux ranged between 15 and 20 l (m^?2 h)^?1 for a period of 30 days. The flux was higher than the typical flux of AnMBRs with conventional membranes and most current dynamic filters. In addition, the low cost of the filter avoided the need for a higher flux. Moreover, a stable granular sludge bed, which consumed all volatile fatty acids, was maintained. A compact fouling/filtration layer formed on the filter, which contributed to low effluent chemical oxygen demand concentrations and turbidity. In addition, substrate scarcity in the filtration zone resulted in the evolution of diverse bacteria on the filter.     

Influence of fermentation conditions and microfiltration processes on membrane fouling during recovery of glucuronane polysaccharides from fermentation broths.

We have investigated the recovery of exopolysaccharides produced by Sinorhizobium meliloti M5N1 CS bacteria from fermentation broths using different membrane filtration processes: cross-flow filtration with a 7 mm i.d. tubular ceramic membrane of 0.5-microm pores under fixed transmembrane pressure or fixed permeate flux and dynamic filtration with a 0.2 microm nylon membrane using a 16-cm rotating disc filter. With the tubular membrane, the polysaccharide mass flux was mainly limited by polymer transmission that decayed to 10% after 90 min. The mass flux of polymer produced under standard fermentation conditions (70 h at 30 degrees C) stabilized after 70 min to 15 g/h/m(2). This mass flux rises to 36 g/h/m(2) when the mean stirring speed during fermentation is increased and to 123 g/h/m(2) when fermentation is extended to 120 h. In both cases, the mean molecular weight of polysaccharides drops from 4.0 10(5) g/mol under standard conditions to 2.7 10(5) g/mol. A similar reduction in molecular weight was observed when the fermentation temperature was raised to 36 degrees C without benefit to the mass flux. These changes in fermentation conditions have little effect on stabilized permeate flux, but raise significantly the sieving coefficient, due probably to molecular weight reduction and the filamentous aspect of the polymer as observed from SEM photographs. The polymer-mass flux was also increased by reducing transmembrane pressure (TMP) and raising the shear rate by inserting a rod in the membrane lumen. Operation under fixed permeate flux instead of constant TMP inhibited fouling during the first 4 h, resulting in higher sieving coefficients and polymer mass fluxes. The most interesting results were obtained with dynamic filtration because it allows operation at high-shear rates and low TMP. Sieving coefficients remained between 90 and 100%. With a smooth disc, the polysaccharide mass flux remained close to 180 g/h/m(2) at 1500 rpm and cell concentrations from 1 to 3 g/L. When radial rods were glued to the disc to increase wall shear stress and turbulence, the mass flux rose to 275 g/h/m(2) at the same speed and cell concentration.     

A simple and rapid method to measure cholesterol binding to P450s and other proteins

Cholesterol plays an important role in cellular function and membrane compartmentalization and is involved in the interaction with more than a dozen of different proteins. Using three cholesterol-metabolizing cytochrome P450s (P450s 7A1, 46A1, and 11A1), we have developed a rapid and simple assay for measurements of nanomolar to micromolar cholesterol affinities. In this assay, the P450 is incubated with a fixed amount of radiolabeled cholesterol and varying concentrations of cold cholesterol followed by separation of free and protein-bound cholesterol via filtration through a membrane. Free cholesterol is found in the flow-through fraction, whereas P450 binds to the membrane. The radioactivity of the membranes is then measured, and a saturation curve is generated after correction for nonspecific binding of cholesterol to the filter. The validity of the filter assay was confirmed by spectral assay, a traditional method to evaluate the interaction of the P450 enzymes with their substrates. Two types of membranes, one binding positively charged proteins and another binding negatively charged proteins, were identified. These membranes were also found to hold proteins through hydrophobic interactions. Thus, the cholesterol binding properties of a wide variety of proteins could be characterized using this filter assay.     

The mechanism of biliary secretion of reduced glutathione. Analysis of transport process in isolated rat-liver canalicular membrane vesicles

Transport of reduced glutathione (GSH) was studied in isolated rat liver canalicular membrane vesicles by a rapid filtration technique. The membrane vesicles exhibit uptake of [2-3H]glycine--labeled GSH into an osmotically reactive intravesicular space. Although the canalicular membrane vesicles possess gamma-glutamyltransferase and aminopeptidase M, enzymes that hydrolyze glutathione into component amino acids, inactivation of the vesicle-associated transferase by affinity labeling with L-(alpha S,5S)-alpha-amino-3-chloro-4,5-dihydro-5-isoxazoleacetic acid (AT-125) had no effect on the initial rate of GSH transport. Chemical analysis revealed that intact GSH accounted for most of vesicle-associated radioactivity. The initial rate of transport followed saturation kinetics with respect to GSH concentration; an apparent Km of 0.33 mM and V of 1.47 nmol/mg protein in 20 s were calculated. These results indicate that transport of GSH across the canalicular membranes is a carrier-mediated process. Replacement of NaCl in the transport medium by KCl, LiCl or choline chloride had no effect on the transport activity of the vesicles. The rate of GSH uptake by the vesicles was enhanced by valinomycin-induced K+-diffusion potential (vesicle inside-positive) and was inhibited by probenecid, indicating that GSH transport across the canalicular membranes is electrogenic and involves the transfer of negative charge. The transport of GSH was inhibited by oxidized glutathione or S-benzyl-glutathione. This transport system in canalicular plasma membranes may function in biliary secretion of GSH and its derivatives which are synthesized in hepatocytes by oxidative processes or glutathione S-transferase.     

Calcium channels are present in the apical plasma membranes of the hepatopancreatic B-cells of<Emphasis Type="Italic"> Marsupenaeus japonicus</Emphasis>

This study demonstrates the existence of calcium channels in the apical membranes of the hepatopancreatic blister (B) cells of Marsupenaeus japonicus. Using brush-border membrane vesicles we demonstrated that the channel-mediated calcium passive flux was saturable and was stimulated by a transmembrane electrical potential difference and inhibited by barium. We raised a monoclonal antibody (Mab 24A4) against the calcium channel, which allowed us to inhibit the channel-mediated calcium uptake. By immunocytochemistry, using Mab 24A4, we demonstrated that these channels are located at the apical membrane of hepatopancreatic B cells. Finally, by measuring the calcium uptake in R- and B-enriched cell suspensions, we showed that only the plasma membrane of the B cells expresses a channel-mediated calcium uptake inhibited by barium, verapamil and the monoclonal antibody 24A4. The plasma membrane of R cells did not show calcium channels.Abbreviations ELISA enzyme-linked immunosorbent assay - BBMV brush-border membrane vesiclesCommunicated by G. Heldmaier     

A gel filtration assay to determine glycogen synthase activity

We developed a gel filtration assay for the determination of glycogen synthase activity in cultured cells or tissue homogenates. Compared to the commonly used filter paper assay, the gel filtration assay resulted in a more than 5-fold reduction of background levels leading to an--at least--twofold increase in precision. These benefits allow the gel filtration method to detect differences of +/-5% in enzyme activity out of 300 microg total cell protein. In addition to high precision and sensitivity, the method's additional salient advantages include lesser expenditure of time and labour and reduced exposure time of the personnel to radioactivity.