Air slugs entrapped cross-flow filtration of bacterial suspensions

A novel cross-flow technique for membrane filtration of bacterial cell suspensions was established. This is an air slugs entrapped cross-flow method in which air slugs were generated by introducing air into the cross-flow stream. As air slugs moved along with cross-flow, the disturbance of cell sublayer formation on membrane surface was enhanced. As a consequence, filtration flux was improved and stabilized. The effect of air slugs on improving filtration flux was more pronounced in filtering gram-negative Escherichia coli cell than grampositive Brevibacterium flavum cell. Moreover, air slug was about 50% more effective on reducing filtration resistance using ultrafiltration (UF) membrane of 300,000 molecular weight cutoff (MWCO) than microfiltration (MF) membrane of 0.2 mum. (c)1993 John Wiley & Sons, Inc.     

Filtration-based perfusion of hybridoma cultures in protein-free medium: Reduction of membrane fouling by medium supplementation with DNase I

In this study, a filtration-based perfusion process was developed for the production of monoclonal antibodies (IgM) by suspended hybridoma cells grown in protein-free medium. It was found that the use of protein-free medium for perfusion culture generated the formation of numerous visible suspended particles consisting of dead cells and cellular debris aggregated into fibrous material. Surprisingly high apparent viabilities were observed in such protein-free cultures. In addition, membrane fouling occurred more rapidly in protein-free medium than in conventional serum-supplemented medium. By the addition of deoxyribonuclease I (DNase I) to the protein-free medium, it was possible to prevent the formation of aggregates and to follow the evolution of the total cell population more accurately. Moreover, DNase I significantly reduced the fouling of filtration membranes, and that, for two different types of separation systems (cross-flow and vortex-flow filtration) and two different types of membranes (polycarbonate and hydrophilized polysultone). From these results, it is clear that the presence of DNA fragments liberated following cellular death is playing an important role in membrane fouling. Longevity of filtration membranes was found to be considerably greater using a vortex-flow filtration module than with a static plate-and-frame cross-flow filtration module. The use of vortex-flow filtration of conjuction with DNase I allowed maintenance of perfusion cultures for more than 1 month without membrane fouling or antibody retention and with a constant permeate IgM concentration of 250 mg/L. Hybridomacells appeared to gradually adapt to increasing rotational speed in the vortex-flow filtration module.     

Pressure effects in cross-flow microfiltration of suspensions of whole bacterial cells

The effect of Trans-Membrane Pressure (TMP) on permeate flux during cross-flow microfiltration of bacterial cell suspensions in tubular ceramic membranes is studied experimentally. Continuous filtration experiments with suspensions of whole bacterial cells (Mycobacterium M156) show a dramatic permeate flux decline with increasing TMP. During the very early stages of the filtration process, a linear relationship between permeate flux and TMP is observed, suggesting an initial surface sorption of cells on the membrane surface. At longer times, the permeate flux vs. TMP data exhibit a critical pressure beyond which the permeate flux declines with increasing trans-membrane pressure. This is interpreted in terms of the formation of a compressible cake, whose permeability can be described through the Carman-Kozeny equation.     

Ultrastructural characteristics of the 1st cortical layer of the cingulate area of the brain in rats

The limiting membrane, participating in formation of the liquor- and hematoencephalic barrier on the brain surface, and specialized intercellular contacts are considered as factors regulating entrance of substances from liquor and blood into the intercellular medium. Heteromorphism of the cingulate cortex first layer takes place: in the 1-b sublayer a large amount of myelinated fibres is revealed, in the 1-c sublayer numerous longitudinal sections of dendrites are seen, they arrange perpendicularly or tangentially to the brain surface. In the 1-a sublayer, more often than in others, multifocal axodendritic synapses are observed they are of convergent or divergent types, several synapses occur. In the first layer of the cingulate cortex, axonal profiles are revealed, they resemble axons of the neurosecretory cells described in the literature. This cannot exclude any hormonal mechanisms affecting the neurons of the cingulate cortex. Numerous synaptic contacts, formed by afferent fibers that come from different brain structures, with processes of the first layer cells and ascending dendrites of deeper layers are considered as a morphological substrate of integrative and modulating activity of the first layer.     

Strategy for selection of methods for separation of bioparticles from particle mixtures

The desired product of bioprocesses is often produced in particulate form, either as an inclusion body (IB) or as a crystal. Particle harvesting is then a crucial and attractive form of product recovery. Because the liquid phase often contains other bioparticles, such as cell debris, whole cells, particulate biocatalysts or particulate by-products, the recovery of product particles is a complex process. In most cases, the particulate product is purified using selective solubilization or extraction. However, if selective particle recovery is possible, the already high purity of the particles makes this downstream process more favorable. This work gives an overview of typical bioparticle mixtures that are encountered in industrial biotechnology and the various driving forces that may be used for particle-particle separation, such as the centrifugal force, the magnetic force, the electric force, and forces related to interfaces. By coupling these driving forces to the resisting forces, the limitations of using these driving forces with respect to particle size are calculated. It shows that centrifugation is not a general solution for particle-particle separation in biotechnology because the particle sizes of product and contaminating particles are often very small, thus, causing their settling velocities to be too low for efficient separation by centrifugation. Examples of such separation problems are the recovery of IBs or virus-like particles (VLPs) from (microbial) cell debris. In these cases, separation processes that use electrical forces or fluid-fluid interfaces show to have a large potential for particle-particle separation. These methods are not yet commonly applied for large-scale particle-particle separation in biotechnology and more research is required on the separation techniques and on particle characterization to facilitate successful application of these methods in industry.     

Freeze-fracturing and surface labelling of embryonic neural retina cells

Freeze-fracturing of dissociated and aggregating neural retina cells from 7-day chick embryos revealed on the inner faces (PF) of the cell membrane numerous particles 6–20 nm in size. In contrast, the PF faces of blebs and some of the lobopodia that project from the cell surface were practically devoid of such particles. However, the elongated filopodia that abound on these cells showed numerous particles on their PF faces. These regional differences in the distribution of particles on PF faces of these cells are interpreted as reflecting membrane activity that leads to the formation of blebs and lobopodia. The frequent presence of “pits” at the basis of blebs and lobopodia is described. It is suggested that the “pits” are associated with the formation of these membrane projections; they may represent anchoring sites for microfilaments and for microtubules involved in the dynamic structure of the cell surface. ConA-binding sites on these cells were studied by scanning electron microscopy, using labeling with hemocyanin. The distribution of these sites on different regions of the cell surface coincided with the regional differences in the distribution of the inner membrane particles.     

Preferential deposition of smaller cells during cross-flow microfiltration of a yeast suspension

Summary By examining the size distribution of cells that do not deposit during cross-flow microfiltration of a yeast suspension, we demonstrate that the smaller cells in the suspension are preferentially deposited on the membrane. The extent to which the deposition process favours smaller cells was found to be unaffected by cell concentration or membrane type over the range of concentrations examined.     

A novel technique for the study of cake formation during cross-flow microfiltration of microbial cells

Summary A novel technique involving the measurement of cell concentration changes in the suspension recycle reservoir was used to study cake formation in cross-flow microfiltration. Using this technique, cake formation was found to be enhanced by increasing transmembrane pressure and decreasing cross-flow velocity, and to be more pronounced on a microfiltration membrane than on an ultrafiltration membrane of equal hydraulic resistance. In the case of the microfiltration membrane, it was found that the build-up of cake was not a completely reversible process.     

Ultrastructural changes in the plasma membrane of A-431 cells exposed to epidermal growth factor

The plasma membrane ultrastructural changes after the action of epidermal growth factor were studied in A-431 cells using freeze-fracture methods. The incubation with EGF (100 ng/ml, 0 degree C, 60 min) led to a decrease in density of intramembrane particles on the P surface of ventral cell membrane, while the number of coated pits increased there. The revealed effects of EGF may be related to direct consequences of EGF-receptor complex formation, because all the temperature dependent steps of its processing were blocked. The data obtained testify to an active involvement of the membrane ventral surface in the formation of cell response towards growth factors.     

Cholesterol removal by methyl-beta-cyclodextrin inhibits poliovirus entry

Upon binding to the poliovirus receptor (PVR), the poliovirus 160S particles undergo a conformational transition to generate 135S particles, which are believed to be intermediates in the virus entry process. The 135S particles interact with host cell membranes through exposure of the N termini of VP1 and the myristylated VP4 protein, and successful cytoplasmic delivery of the genomic RNA requires the interaction of these domains with cellular membranes whose identity is unknown. Because detergent-insoluble microdomains (DIMs) in the plasma membrane have been shown to be important in the entry of other picornaviruses, it was of interest to determine if poliovirus similarly required DIMs during virus entry. We show here that methyl-beta-cyclodextrin (MbetaCD), which disrupts DIMs by depleting cells of cholesterol, inhibits virus infection and that this inhibition was partially reversed by partially restoring cholesterol levels in cells, suggesting that MbetaCD inhibition of virus infection was mediated by removal of cellular cholesterol. However, fractionation of cellular membranes into DIMs and detergent-soluble membrane fractions showed that both PVR and poliovirus capsid proteins localize not to DIMs but to detergent-soluble membrane fractions during entry into the cells, and their localization was unaffected by treatment with MbetaCD. We further demonstrate that treatment with MbetaCD inhibits RNA delivery after formation of the 135S particles. These data indicate that the cholesterol status of the cell is important during the process of genome delivery and that these entry pathways are distinct from those requiring DIM integrity.     

Structural changes in the membrane of vero cells infected with a paramyxovirus

Vero cells productively infected with the Halle strain of measles virus have been studied by means of surface replication, freeze-fracturing, and surface labeling with horseradish peroxidase-measles antibody conjugate in order to examine changes in the structure of the cell membrane during viral maturation. Early in infection, the surfaces of infected cells are embossed by scattered groups of twisted strands, and diffuse patches of label for viral antigens cover regions marked by these strands. At later stages, when numerous nucleocapsids become aligned under the plasmalemmal strands, the strands increase in number and width and become more convoluted. At this stage, label for viral antigens on the surface of the cell membrane is organized into stripes lying on the crests of strands. Finally, regions of the membrane displaying twisted strands protrude to form ridges or bulges, and the freeze-fractured membrane surrounding these protrusions is characterized by an abundance of particles small than those found on the rest of the cell membrane. The fractured membranes of viral buds are continuous sheets of these small particles, and the spacing between both nucleocapsids and stripes of surface antigen in buds is less than in the surrounding cell membrane. Detached virus is covered with a continuous layer of viral antigen, has unusually large but no small particles on its membrane surfaces exposed by freeze-fracturing, and no longer has nucleocapsids aligned under its surface. Thus, surface antigens, membrane particles, and nucleocapsids attached to the cell membrane are mobile within the plane of the membrane during viral maturation. All three move simutaneously in preparation for viral budding.     

Morphological observations on the formation and stability of the crystalline arrays in the plasma membrane of Saccharomyces cerevisiae

Two-dimensional crystalline arrays of freeze-fracture particles are known to occur in abundant quantities in the plasma membrane of stationary state yeast cells. Although these crystalline arrays are seen only infrequently in cells during mid-exponential growth, we now observe that formation of crystalline arrays can be induced in such cells by a “metabolic starvation” protocol. Surprisingly, starvation-induced formation of crystalline patches can be prevented by inhibition of new protein synthesis during the starvation period. The size and quantity of crystalline arrays can be increased by removal of the cell wall prior to starvation. Induction of crystalline arrays in protoplasts has made it possible to investigate the surface morphology of the crystalline particles in isolated membranes as well as at the extracellular surface of intact protoplasts. The stability of isolated crystalline arrays to several detergents has been investigated and conditions have been found that result in improved morphological purity of the isolated crystalline patches.     

Effect of Ethylenediaminetetraacetate upon the Surface of Escherichia coli

The effect of ethylenediaminetetraacetate (EDTA) on the envelope of two strains of Escherichia coli (B and Cla) was studied with freeze-fracturing methods. Untreated cells showed the outer membrane's outer surface with a fine texture of randomly spaced depressions of about 4.5-nm diameter; small areas with symmetrical arrangements of structural surface elements were also observed. The outer membrane's fracture plane revealed a random distribution of particles on its "concave" plane, only occasionally interrupted by particle-free areas. The "convex" aspect of the outer membrane's fracture plane showed only a few scattered particles. The cleavage plane of the inner membrane was often interrupted by many localized elevated plateaus, at which the cleaving process had, for short distances, switched to the outer membrane. The effects of EDTA treatment were mainly seen in the structure of the freeze-etched outer membrane: (i) the pits as well as the symmetrical surface elements of the outer membrane's outer surface had disappeared; (ii) a number of plateaus (about 20 to 50/cell) were seen at which a cleavage plane within the inner membrane had switched to the hydrophobic portion of the outer membrane (outer membrane's fracture plane). These plateaus were also visible in untreated cells; however, EDTA treatment apparently caused an increased exposure of plateaus. Surface areas, exposed by freeze-etching, revealed the underlying plateaus as elevations in the surface contour of the cell, suggesting a slower etching rate in the zones of the plateaus relative to the rest of the outer membrane. Well-defined, particle-free patches in the outer membrane's fracture plane, concave, were more frequent and larger in size after EDTA treatment than in the controls. In the presence of glycerol, the cells often cleaved in the outer membrane's fracture plane, but isolated plateaus were rarely observed. After metabolic poisoning of cells for 15 to 25 min at 37 degrees C, the plateaus had widened. These data suggest that the material of the plateaus has a slow rate of lateral diffusion. Placement of EDTA-treated cells in fresh medium at 37 degrees C caused, after 3 to 5 min, the reoccurrence of the pitted surface structure. We propose that the plateaus represent localized zones, at which newly synthesized lipopolysaccharide has been inserted.     

Rotavirus protein rearrangements in purified membrane-enveloped intermediate particles.

Rotavirus, a double-shelled nonenveloped member of the REoviridae family, becomes transiently membrane enveloped during its maturation process, as single-shelled particles bud from cytoplasmic viroplasm structures into the adjacent endoplasmic reticulum. The present study describes the isolation of these membrane-enveloped viral intermediates from rotavirus SA11-infected Ma104 cells. The enveloped intermediates comprised the proteins VP1, VP2, VP4, VP6, VP7, and NS28 and small amounts of NS35 and NS34. VP7 in the intermediate particles was recognized by either a polyclonal antibody to VP7, which previous studies had shown recognizes the membrane-associated form of VP7, or a monoclonal antibody which recognizes VP7 on mature virus. NS28, VP7, and VP4 could be complexed to a higher-molecular-weight form when the membrane-permeable cross-linker dithiobis(succinimidylproprionate) was used. However, when an impermeable cross-linker was used, the structural proteins, including VP7, were not accessible to cross-linking. Velocity sedimentation of cross-linked immunoisolated enveloped virus particles showed that VP7 and VP4 were located in the same fractions only when the membrane-permeable cross-linker was used, implying their heterooligomeric association during outer capsid formation. When intermediate enveloped virus particles were treated with protease, VP6 and VP7 were protected, but not in the presence of detergent. Taken together, these results support the idea that in the membrane-enveloped intermediate, VP7 is repositioned from its location in the endoplasmic reticulum lumen back across the viral membrane envelope to the inferior of the virus particle during the maturation process.     

A review of the harvesting of micro-algae for biofuel production

Many researchers consider efficient harvesting is the major challenge of commercialising micro-algal biofuel. Although micro-algal biomass can be ‘energy rich’, the growth of algae in dilute suspension at around 0.02–0.05 % dry solids poses considerable challenges in achieving a viable energy balance in micro-algal biofuel process operations. Additional challenges of micro-algae harvesting come from the small size of micro-algal cells, the similarity of density of the algal cells to the growth medium, the negative surface charge on the algae and the algal growth rates which require frequent harvesting compared to terrestrial plants. Algae can be harvested by a number of methods; sedimentation, flocculation, flotation, centrifugation and filtration or a combination of any of these. This paper reviews the various methods of harvesting and dewatering micro-algae for the production of biofuel. There appears to be no one method or combination of harvesting methods suited to all micro-algae and harvesting method will have a considerable influence on the design and operation of both upstream and downstream processes in an overall micro-algal biofuel production process.     

African swine fever virus induces filopodia-like projections at the plasma membrane

When exiting the cell vaccinia virus induces actin polymerization and formation of a characteristic actin tail on the cytosolic face of the plasma membrane, directly beneath the extracellular particle. The actin tail acts to propel the virus away from the cell surface to enhance its cell-to-cell spread. We now demonstrate that African swine fever virus (ASFV), a member of the Asfarviridae family, also stimulates the polymerization of actin at the cell surface. Intracellular ASFV particles project out at the tip of long filopodia-like protrusions, at an average rate of 1.8 microm min(-1). Actin was arranged in long unbranched parallel arrays inside these virus-tipped projections. In contrast to vaccinia, this outward movement did not involve recruitment of Grb2, Nck1 or N-WASP. Actin polymerization was not nucleated by virus particles in transit to the cell periphery, and projections were not produced when the secretory pathway was disrupted by brefeldin A treatment. Our results show that when ASFV particles reach the plasma membrane they induce a localized nucleation of actin, and that this process requires interaction with virus-encoded and/or host proteins at the plasma membrane. We suggest that ASFV represents a valuable new model for studying pathways that regulate the formation of filopodia.     

The ultrastructure of cell wall formation and of gamma particles during encystment of Allomyces macrogynus zoospores

Structural changes during cell wall formation by populations of semisynchronously germinating zoospores were studied in the water mold Allomyces macrogynus. Fluorescence microscopy using Calcofluor white ST (which binds to -1,4-linked glycans) demonstrated that Calcofluor-specific material was deposited around most cells between 2–10 min after the induction of encystment (beginning when a wall-less zoospore retracts its flagellum and rounds up). During the first 15 min of encystment there was a progressive increase in fluorescence intensity. Ultrastructural analysis of encysting cells showed that within 2–10 min after the induction of encystment small vesicles 35–70 nm diameter were present near the spore surface, and some were in the process of fusing with the plasma membrane. The fusion of vesicles with the zoospore membrane was concomitant with the appearance of electron-opaque fibrillar material outside the plasma membrane. Vesicles similar to those near the spore surface were found within the gamma () particles of encysting cells. These particles had a crystalline inclusion within the electron-opaque matrix. During the period of initial cyst cell wall formation numerous vesicles appeared to arise at the crystal-matrix interface. Approximately 15–20 min was required for the cell wall to be formed. We suggest that the initial response of the zoospore to induction of encystment is the formation of a cell wall mediated by the fusion of cytoplasmic vesicles with the plasma membrane.Non-Standard Abbreviations GlcNac N-Acetylglucosamine - DS sterile dilute salts solution - PYG peptone-yeast extract-glucose broth     

Partial and complete detachment of neutrophils and eosinophils from schistosomula: evidence for the establishment of continuity between a fused and normal parasite membrane

Neutrophils and eosinophils adhering to the surface of schistosomula of Schistosoma mansoni have been partially or completely detached with hypertonic sucrose or by pipetting. The sucrose-treated neutrophils are attached only in areas where there are pentalaminar fusions between the neutrophil and tegumental membranes, suggesting that these fusions attach the cells to the parasites. Pipetting breaks many of the attached cells. In thin section, the tegumental membrane underlying these cells is seen to be pentalaminar. By freeze-fracture techniques, modified attachment areas are found. The edge zone often appears as a single strand of intramembrane particles (IMPs) on the P2 face and as a groove on the E2 face. The edge zone may also have large discontinuities, in which case it no longer separates membrane faces of unequal IMP density from one another. In addition, the IMPs on the IMP- rich areas become aggregated and surrounded by craters in the membrane. These experiments suggest that the fusions may be the mechanism by which the parasite acquires some host membrane components on its surface. On the other hand, eosinophil plasma membranes are seen adhering to a layer of electron-dense material on the parasite after the cells have been disrupted by pipetting. This suggests that eosinophils adhere to the parasite surface through their discharged granule material and not by membrane fusions.     

Microfiltration conditions modify Lactobacillus bulgaricus cryotolerance in response to physiological changes

This work aimed at analyzing the effect of microfiltration conditions (cross-flow velocity and transmembrane pressure) on the quality of frozen Lactobacillus bulgaricus CFL1 starters produced on pilot scale. Microfiltered cells were less resistant during the concentration process than centrifuged cells. In contrast, bacterial cryotolerance during freezing was improved after microfiltration, in a range of 28–88%, depending on the microfiltration conditions. During frozen storage, cell resistance was also affected by microfiltration conditions, either positively or negatively, compared to centrifugation. The best cryotolerance was obtained for cells microfiltered at a cross-flow velocity of 2 m/s and a transmembrane pressure of 0.15 MPa. This improvement was explained by considering membrane fatty acid composition of Lb. bulgaricus CFL1. This condition increased unsaturated to saturated and cyclic to saturated fatty acid ratios, which enhanced membrane fluidity, thus helping the cells to better resist freezing and frozen storage.     

HIV gp120-induced interaction between CD4 and CCR5 requires cholesterol-rich microenvironments revealed by live cell fluorescence resonance energy transfer imaging

Binding of the human immunodeficiency virus (HIV) envelope gp120 glycoprotein to CD4 and CCR5 receptors on the plasma membrane initiates the viral entry process. Although plasma membrane cholesterol plays an important role in HIV entry, its modulating effect on the viral entry process is unclear. Using fluorescence resonance energy transfer imaging, we have provided evidence here that CD4 and CCR5 localize in different microenvironments on the surface of resting cells. Binding of the third variable region V3-containing gp120 core to CD4 and CCR5 induced association between these receptors, which could be directly monitored by fluorescence resonance energy transfer on the plasma membrane of live cells. Depletion of cholesterol from the plasma membrane abolished the gp120 core-induced associations between CD4 and CCR5, and reloading cholesterol restored the associations in live cells. Our studies suggest that, during the first step of the HIV entry process, gp120 binding alters the microenvironments of unbound CD4 and CCR5, with plasma membrane cholesterol required for the formation of the HIV entry complex.