Lipid-impregnated filters as a tool for studying the electric current-generating proteins.

Porous filters and collodion film impregnated with decane solution of phospholipids, were used for measurements of electric potential differences generated by bacteriorhodopsin, chromatophore redox chain, H⁺-ATPase, pyrophosphatase, and mitochondrial respiratory chain. It was shown that reconstituted proteoliposomes, containing e.g., bacteriorhodopsin or natural coupling membrane vesicles, such as Rhodospirillum rubrum chromatophores, can be attached to a filter surface by means of Ca²⁺ or Mg²⁺ ions. Addition of the respective energy source was found to result in electric potential difference being generated across the filter. This effect was measured directly by $\text{Ag}\text{AgCl}$ electrodes immersed into electrolyte solutions on both sides of the filter. Using a phospholipid-impregnated collodion film one can measure electric responses as fast as 300 nsec. The phospholipid-impregnated filters turned out to be sensitive and reliable electrodes for measuring the concentration of synthetic penetrating ions, such as phenyldicarbaundecaborane, tetraphenylborate, tetrapentylammonium, and tetraphenylphosphonium. By measuring changes in the concentration of these ions in the suspension of proteoliposomes, chromatophores, mitochondria, or bacterial cells, one can follow the formation and dissipation of transmembrane potential differences in these systems. It is shown that the phospholipid-impregnated filters are much more reliable and handy than planar phospholipid membranes previously used for studying electrogenic activity of electric current-producing membrane proteins.     

The use of phospholipid-impregnated millipore filters for recording nonelectrogenic cation flows in the presence of Men+/nH+ exchangers

It has been shown that with a cation (K+, Na+, Ca2+) concentration gradient on a Millipore filter impregnated with a decane solution of phospholipid, in the presence of a Men+/nH+ exchanger (nigericin, monensin, A23187), addition of a protonophore induces the formation of an electric potential positively charged on the side where the concentration of the cation is lower. The formation of the potential is induced by the hydrogen ion concentration gradient in the filter and in the unstirred layers as a result of the Men+/nH+ exchange. In such a system, with a pH gradient on the filter in the presence of monensin and valinomycin, a potential is generated with the plus on the side of the lower concentration of hydrogen. The effect is the result of the formation of a potassium ion concentration gradient in the unstirred layers in the course of the K+/H+ exchange. It is concluded that phospholipid-impregnated filters can be used for search and identification of electroneutral membrane ionophores of the Men+/nH+ exchanger type.     

SOME PROBLEMS INHERENT IN TRANSPORT STUDIES IN SYNAPTOSOMES

A technique utilizing a 30-place manifold has been developed to study synaptosomal transport; some problems associated with such studies have been identified and clarified. The time course of L-glutamic acid uptake has been used to test variations in experimental protocol. Synaptosomes apparently become increasingly labile with increased time of incubation. This is indicated by a drop in the curve of uptake vs time after 8–12 min. Ninety seven to 98% of the glutamate taken up from a 10^?6m solution is released by osmotic shock. Synaptosomes can be stored in 0.32 m ice-cold sucrose suspension for periods up to 50 min without decline in measured uptake. Storage for 3 h or more results in a very substantial decline in measured uptake. Neither the decline in measured uptake with time, nor the decline with storage, is prevented by increasing the osmolarity of the solutions used or by use of synaptosomes from the initial 1085 g supemate rather than after sedimentation and resuspension. Although prewarming synaptosomes at 30°C for 20 min prior to their use lessened or eliminated the decline following peak uptake, the difference between stored and non-stored synaptosomes was not improved. Uptake was also much less when synaptosomes were used from the first supernate or when warmed prior to their use. Storage of tissue prior to homogenization resulted in synaptosomes that gave minimal reductions in measured uptake. Washing synaptosomes after separation from incubation medium resulted in a variable loss of substrate radioactivity, depending on such variables as brand of filter, pore size, composition of wash solution, and temperature of wash solution. The results support the hypothesis that washing causes lysis of a portion of the synaptosomes. However, with Millipore filters (0.45 μm) and a 30°C Krebs-Henseleit wash solution, the loss caused by washing is minimized (about 15%). Measured uptake is found to depend on the type of filter used. Uptake is much greater with Millipore 0.45 pm filters than with Gelman 0.45 μm filters. Use of Nuclepore (0.4 μm) filters results in measured uptakes only about 5% of that when Millipore 0.45 μm filters are used. With Millipore filters, 0.30 μm pore size filters gave uptakes only 68% of that using 0.45 pm pore size filters.     

Interference of tooth differentiation with interposed filters

The effect of interposed Nuclepore filters on the epithelio-mesenchymal interaction in embryonic mouse tooth was studied. Filters with pore sizes of 0.6 and 0.2 μm allowed differentiation of odontoblasts and ameloblasts in the bell-stage tooth germ. This differentiation progressed more rapidly when the 0.6-μm pore size filter was used. Nuclepore filters with 0.1-μm pores prevented differentiation. Electron microscopic examination revealed penetration of cell processes into the filter pores. Cytoplasmic material could be seen in the 0.6-μm pore-size filter within 3 days of cultivation, whereas, in the 0.2-μm filter pores, penetration was slight. After 6 days of cultivation, cytoplasmic material was found at all levels of the 0.2-μm pore-size filter, but not in the channels of the 0.1-μm pore-size filters, preventing differentiation. It is concluded that the 0.1-μm pore-size filter blocks tooth development at the level of mesenchymal cell differentiation into odontoblasts. It is suggested that this differentiation requires a close association between the interacting mesenchymal and epithelial cells.     

On the Pharyngeal Feeding Filter of the Salp Pegea confoederata (Tunicata: Thaliacea)

In Pegea, scanning electron microscopy of what appear to be the least damaged portions of the filter shows that it has a regular rectangular mesh consisting of thick (100 nm) fibres at right angles to thinner (50 nm) fibres. The rectangular pores of the filter are around 3.3 × 0.57 μm. These measured values from filters that have suffered shrinkage (to an uncertain degree) during preparation are considered to indicate that the actual pore size in life is some 4.0 × 0.7 μm. The mucous-net feeding filter of salps differs from that of other tunicates since flow through it results from muscular activity. Calculations based on the estimated pore size and filtering rate suggest that during part of the filtering cycle, the pressure drop across the filter is considerably greater than that across other tunicate mucous-net filters.     

Studies on the Minimum Reproducible Unit of Staphylococcal L-Forms

The minimum size of a reproducible unit of staphylococcal L-forms was determined by filtration and electron microscopic methods. Ultrathin sections of an induced strain of Staphylococcal L-forms (STA-EMT-1) in liquid medium revealed several types of structures, all of which were bound by a single membrane and most of which possessed ribosome-like granules. Many of the small granules were less than 0.3 μm and were attached to the membrane of the large bodies. Using a serial filtration method, it was observed that viable L-forms were still detected in 0.22 μm filtrate, but the viable cell count of L-forms decreased in number with the decrease in pore size of membrane filters. A fractionation technique, using L-forms filtered through a membrane filter with a 0.45 μm pore size, revealed that there were three classes of small bodies but only the first class with ribosome-like granules over approximately 0.2 μm in diameter seems to be able to reproduce.     

Two swinging-bucket ultracentrifugal filters for receptor-binding assays

Centrifugal filters for SW 25.1 and 50.1 swinging-bucket ultracentrifuge rotors have been tested up to the maximum speeds allowed, 90,000 and 300,000g, respectively. The filters are 1 and 0.5 in. in diameter and accept standard 25-mm polycarbonate filter membranes. The filter membranes are both cup-shaped to prevent loss of particulates to the support materials of the filters. The filter for the SW 25.1 rotor can take 0.75 ml and that of the 50.1 head 0.5 ml. The fluid retained after centrifuging consists of the fluid on the filter membrane and in its pores and that retained by the material filtered. The calculated volume of the pores of the 0.2-μm filter was 0.46 μl. Total liquid retentions of about 0.8 μl have been achieved with both filters using a particulate concentration of 0.5 mg/ml.     

LOSS OF NUTRIENTS FROM WATER SAMPLES BY FILTRATION AND ITS AFFECT ON ALGAL BIOASSAY PROCEDURES

SUMMARY

Water samples were collected from fourteen sampling points along the Hunyani River system and subjected to various filtration treatments involving glass fibre filters and 1,2 and 0,45 pm membrane filters. Chemical analyses of the filtered waters showed that nitrogen, phosphorus and iron were lost by different filtration treatments. Filtration by membrane filters led to a reduction of algal growth potential as demonstrated by algal bioassays using Selanastrwn capricornutum Printz as the test alga.

Algal bioassays showed that biologically available phosphorus was primarily removed by the 1,2 μm membrane filter while biologically available nitrogen and iron was principally lost by filtration through the 0,25 μm membrane filter. A refined algal bioassay designed to determine the identity of limiting micronutrients found that all essential micronutrients were affected by membrane filtration.     

Membrane filter (pore size, 0.22-0.45 micro m; thickness, 150 micro m) passing-through activity of Pseudomonas aeruginosa and other bacterial species with indigenous infiltration ability

Bacteria growing on MF-Millipore filters (thickness, 150 micro m) passed through the underlying membrane by their infiltration activity. Bacillus subtilis, Staphylococcus aureus, Klebsiella pneumoniae, and Escherichia coli passed through a 0.45- micro m pore size filter within 48-96 h. Pseudomonas aeruginosa, Serratia marcescens, and Listeria monocytogenes passed through a 0.3- micro m pore size filter. P. aeruginosa passed through a 0.22- micro m pore size filter. The membranes which allowed passing-through of bacteria showed normal bubble point values in the integrity test. Studies with isogenic S. marcescens mutants indicated that flagellum-dependent motility or surface-active exolipid were important in the passing-through. P. aeruginosa PAO1 C strain defective in twitching motility was unable to pass through the 0.22- micro m filter. Scanning electron microscopy showed bacteria passing-through the 0.22- micro m filter. Millipore membrane filters having well-defined reticulate structures will be useful in the study of infiltration activity of microbes.     

Picoplankton size distributions in marine and fresh waters: problems with filter fractionation studies

Abstract The retention of algal picoplankton by Nuclepore polycarbonate filters of 0.2, 1.0, 2.0 and 3.0 μm pore size was tested in 2 marine and 3 freshwater sites. When 1 μm Nuclepore filters were used, the percentage of the total cyanobacterial cells passing the filter varied between sites and with increasing depth within sites. As much as 99% of the Synechococcus -like cells was retained by a 1 μm filter. This could lead to an underestimation of the picoplanktonic contribution or, more seriously, an apparent distribution pattern that is an artifact of the choice of filter pore size. Filter retention was also dependent on vaccum pressure during filtration. This study emphasizes the need for direct observation of picoplankton numbers in filter fractionation studies.     

The effect of filtration method on the efficiency of environmental DNA capture and quantification via metabarcoding

Environmental DNA (eDNA) is a promising tool for rapid and noninvasive biodiversity monitoring. eDNA density is low in environmental samples, and a capture method, such as filtration, is often required to concentrate eDNA for downstream analyses. In this study, six treatments, with differing filter types and pore sizes for eDNA capture, were compared for their efficiency and accuracy to assess fish community structure with known fish abundance and biomass via eDNA metabarcoding. Our results showed that different filters (with the exception of 20‐μm large‐pore filters) were broadly consistent in their DNA capture ability. The 0.45‐μm filters performed the best in terms of total DNA yield, probability of species detection, repeatability within pond and consistency between ponds. However performance of 0.45‐μm filters was only marginally better than for 0.8‐μm filters, while filtration time was significantly longer. Given this trade‐off, the 0.8‐μm filter is the optimal pore size of membrane filter for turbid, eutrophic and high fish density ponds analysed here. The 0.45‐μm Sterivex enclosed filters performed reasonably well and are suitable in situations where on‐site filtration is required. Finally, prefilters are applied only if absolutely essential for reducing the filtration time or increasing the throughput volume of the capture filters. In summary, we found encouraging similarity in the results obtained from different filtration methods, but the optimal pore size of filter or filter type might strongly depend on the water type under study.     

Preparation of lipid emulsions by pressure extrusion

Lipid emulsions consisting of a surface monolayer of phospholipid enclosing a core of neutral lipids have been prepared by repeated extrusion through polycarbonate filters of defined pore size. Particle size, as measured by photon correlation spectroscopy, decreases on successive passes through a 100 nm filter, reaching a near constant value (130-150 nm) after 4 passes. A corresponding decrease in the standard deviation of the particle size distribution occurs during this process. The recovery of lipids, especially of cholesterol and cholesterol ester, is improved if the emulsion is sonicated before extrusion through filters. [31P]-NMR and fluorescence techniques are used to confirm that the resulting structures are emulsions rather than lipid bilayers.     

Intraspecific aflatoxin inhibition in Aspergillus flavus is thigmoregulated, independent of vegetative compatibility group and is strain dependent

Biological control of preharvest aflatoxin contamination by atoxigenic stains of Aspergillus flavus has been demonstrated in several crops. The assumption is that some form of competition suppresses the fungus's ability to infect or produce aflatoxin when challenged. Intraspecific aflatoxin inhibition was demonstrated by others. This work investigates the mechanistic basis of that phenomenon. A toxigenic and atoxigenic isolate of A. flavus which exhibited intraspecific aflatoxin inhibition when grown together in suspended disc culture were not inhibited when grown in a filter insert-plate well system separated by a .4 or 3 μm membrane. Toxigenic and atoxigenic conidial mixtures (50∶50) placed on both sides of these filters restored inhibition. There was ～50% inhibition when a 12 μm pore size filter was used. Conidial and mycelial diameters were in the 3.5-7.0 μm range and could pass through the 12 μm filter. Larger pore sizes in the initially separated system restored aflatoxin inhibition. This suggests isolates must come into physical contact with one another. This negates a role for nutrient competition or for soluble diffusible signals or antibiotics in aflatoxin inhibition. The toxigenic isolate was maximally sensitive to inhibition during the first 24 hrs of growth while the atoxigenic isolate was always inhibition competent. The atoxigenic isolate when grown with a green fluorescent protein (GFP) toxigenic isolate failed to inhibit aflatoxin indicating that there is specificity in the touch inhibiton. Several atoxigenic isolates were found which inhibited the GFP isolate. These results suggest that an unknown signaling pathway is initiated in the toxigenic isolate by physical interaction with an appropriate atoxigenic isolate in the first 24 hrs which prevents or down-regulates normal expression of aflatoxin after 3-5 days growth. We suspect thigmo-downregulation of aflatoxin synthesis is the mechanistic basis of intraspecific aflatoxin inhibition and the major contributor to biological control of aflatoxin contamination.     

The use of phospholipid-impregnated millipore filters for recording nonelectrogenic cation flows in the presence of Me/nH exchangers

It has been shown that with a cation (K⁺, Na⁺, Ca²⁺) concentration gradient on a Millipore filter impregnated with a decane solution of phospholipid, in the presence of a Meⁿ⁺/nH⁺ exchanger (nigericin, monensin, A23187), addition of a protonophore induces the formation of an electric potential positively charged on the side where the concentration of the cation is lower. The formation of the potential is induced by the hydrogen ion concentration gradient in the filter and in the unstirred layers as a result of the Meⁿ⁺/nH⁺ exchange. In such a system, with a pH gradient on the filter in the presence of monensin and valinomycin, a potential is generated with the plus on the side of the lower concentration of hydrogen. The effect is the result of the formation of a potassium ion concentration gradient in the unstirred layers in the course of the K⁺/H⁺ exchange. It is concluded that phospholipid-impregnated filters can be used for search and identification of electroneutral membrane ionophores of the Meⁿ⁺/nH⁺ exchanger type.     

Filter-extruded liposomes revisited: a study into size distributions and morphologies in relation to lipid-composition and process parameters

Filter-extrusion is a widely used technique for down-sizing of phospholipid vesicles. In order to gain a detailed insight into size and size distributions of filter-extruded vesicles composed of egg phosphatidyl-choline (with varying fractions of cholesterol) – in relation to extrusion-parameters (pore-size, number of filter passages, and flow-rate), flow field-flow fractionation in conjunction with multi-angle laser light scattering (AF4-MALLS, Wyatt Technology Corp., Santa Barbara, CA) was employed. Liposome size-distributions determined by AF4-MALLS were compared with those of dynamic light scattering and correlated with cryo-transmission electron microscopy and ³¹P-NMR-analysis of lamellarity. Both the mean size of liposome and the width of size distribution were found to decrease with sequential extrusion through smaller pore size filters, starting at a size range of ≈70–415?nm upon repeated extrusion through 400?nm pore-filters, eventually ending with a size range from ≈30 to 85?nm upon extrusion through 30?nm pore size filters. While for small pores sizes (50?nm), increased flow rates resulted in smaller vesicles, no significant influence of flow rate on mean vesicle size was seen with larger pores. Cholesterol at increasing mol fractions up to 0.45 yielded bigger vesicles (at identical process conditions). For a cholesterol mol fraction of 0.5 in combination with small filter pore size, a bimodal size distribution was seen indicating cholesterol micro-crystallites. Finally, a protocol is suggested to prepare large (～?300?nm) liposomes with rather narrow size distribution, based on the filter extrusion at defined flow-rates in combination with freeze-/thaw-cycling and bench-top centrifugation.     

A closed system for the filtration of Mycobacterium bovis liquid cultures using disposable capsule filters

A filtration system was designed to sterilize large volumes of Mycobacterium bovis BCG Tokyo culture safely, needed to purify protein antigens for immunodiagnosis of bovine tuberculosis. A closed system consists of culture bottles connected to three disposable filter capsules of decreasing pore size in series : a depth prefilter over a 1·2 μm filter ; a 0·8 μm prefilter over a 0·45 μm filter ; and a 0·2 μm sterile filter. Low air pressure (3 psi) forces liquid from below the bacillary pellicle. The system features a stainless steel clamp to hold rubber stoppers on the culture bottles, pleated filters to exclude bacillary clumps, a quick disconnector to minimize aerosols, and a closed system with plastic disposable filters that can be autoclaved as a unit without dismantling.     

Membrane Filtration of the Reiter Treponeme

A membrane filtration technique with commercially available membrane filters (Millipore Corp.) was effective for the removal of Reiter treponemes from liquids such as fluorescent-antibody conjugates, to which the organisms are added for adsorption. Reiter treponemes from an 8-day culture were not microscopically detectable in filtrates through membranes with a pore diameter of 0.45 μm, but treponemes were demonstrated in the filtrate by cultural methods. No organisms of the 8-day culture passed through a membrane filter having a pore size of 0.22 μm, as determined by microscopy and culture. Culture data indicated that a filter with a pore size of 0.1 μm was necessary to prevent passage of treponemes from 4-day cultures. It is recommended that a membrane filter with a pore size of 0.22 μm or smaller be used for the removal of Reiter treponemes from suspensions and that the age of the culture be considered in choosing filter pore size.     

Prefiltration enhances performance of sterile filtration for glycoconjugate vaccines

Recent studies have reported very low capacity during sterile filtration of glycoconjugate vaccines due to rapid fouling of the sterile filter. The objective of this study was to explore the potential for significantly increasing the capacity of the sterile filter through the use of an appropriate prefilter. Data were obtained using prefilters with different pore size and chemistry, with the sterile filtration performed at constant filtrate flux using 0.22 μm nominal pore size Durapore® polyvinylidene difluoride membranes. Prefiltration through 5 μm pore size Durapore® or Nylon prefilters nearly eliminated the fouling of the sterile filter, leading to more than a 100-fold reduction in the rate of pressure increase for the sterile filter. This dramatic improvement in sterile filter performance was due to the removal of large components (greater than 1 μm in size) as confirmed by dynamic light scattering. These results demonstrate the potential of using large pore size prefilters to significantly enhance the performance of the sterile filtration process for the production of important glycoconjugate vaccines.     

An on-line method for the reduction of fouling of spin-filters for animal cell perfusion cultures

The main limitation in the use of spin-filters during perfusion cultures of animal cells was revealed to be filter fouling. This phenomenon involves cell-sieve interactions as well as cell attachment to, and growth on, the filter surface. The cell attachment effect has been analysed in the present study during long-term perfusion simulations with CHO animal cells. It was demonstrated that at low filter acceleration, below 6.2 m/s2, a high perfusion rate of 25 cm/h induced rapid filter pore clogging within 3 days, whereas increasing the filter acceleration to 25 m/s2 increased filter longevity from 3 to 25 days, for filters with a pore size of 8.5 microm. Increasing the filter pore size to 14.5 microm improved filter longevity by 84% with less viable and dead cell deposits on the filter surface. However, it was demonstrated that filter longevity was not necessarily dependent on the amount of cell deposit on the filter surface. In the second part of this study, ultrasonic technology was used to reduce filter fouling. Filter vibration, induced by a piezo actuator, improved filter longevity by 113% during CHO cells perfusion cultures.     

Comparison of different filter types on chlorophyll-a retention and nutrient measurements

In studies on the biochemical compounds in phytoplankton, water samples generally are (pre-) filtered to retain the organisms for extraction. Such filters can be used for further investigations in microscopic or chromatographic (for example High-Performance-Liquid-Chromatography, HPLC) methods, while the filtrates can be used for nutrient or fluorometric measurements as well as for microscopic examinations. Which filter is chosen for a study often depends on its pore size, the costs and, in particular for HPLC measurements, on its chemical compatibility. In our study we compared the chlorophyll-a retention on the filters by HPLC as well as the fluorescence before and after filtration, and nutrient content of the filtrates. The filters we tested were of different material and with various pore sizes. Although Whatman GF/C and GF/F filters are preferred in phytoplankton studies, we found that the Nylon Membrane filter of 0.2 μm pore size provided the most consistent results in chlorophyll-a retention and the one of 0.45 μm pore size in nutrient investigations.