Influence of salts on electrostatic interactions between poliovirus and membrane filters.

Neither solutions of salts nor solutions of detergents or of an alcohol at pH 4 are capable of eluting poliovirus adsorbed to membrane filters. However, solutions containing both a salt, such as magnesium chloride or sodium chloride, and a detergent or alcohol at pH 4 were capable of eluting adsorbed virus. The ability of ions to promote elution of virus at low pH in the presence of detergent or alcohol was dependent on the size of the ions and the ionic strength of the medium. These results suggest that both electrostatic and hydrophobic interactions are important in maintaining virus adsorption to membrane filters. Hydrophobic interactions can be disrupted by detergents or alcohols. It appears that electrostatic interactions can be disrupted by raising the pH of a solution or by adding certain salts. Disruption of either electrostatic or hydrophobic interactions alone does not permit efficient elution of the adsorbed virus at low pHs. However, when both interactions are disrupted, most of the poliovirus adsorbed to membrane filters is eluted, even at pH 4.     

Influence of salts on electrostatic interactions between poliovirus and membrane filters

Neither solutions of salts nor solutions of detergents or of an alcohol at pH 4 are capable of eluting poliovirus adsorbed to membrane filters. However, solutions containing both a salt, such as magnesium chloride or sodium chloride, and a detergent or alcohol at pH 4 were capable of eluting adsorbed virus. The ability of ions to promote elution of virus at low pH in the presence of detergent or alcohol was dependent on the size of the ions and the ionic strength of the medium. These results suggest that both electrostatic and hydrophobic interactions are important in maintaining virus adsorption to membrane filters. Hydrophobic interactions can be disrupted by detergents or alcohols. It appears that electrostatic interactions can be disrupted by raising the pH of a solution or by adding certain salts. Disruption of either electrostatic or hydrophobic interactions alone does not permit efficient elution of the adsorbed virus at low pHs. However, when both interactions are disrupted, most of the poliovirus adsorbed to membrane filters is eluted, even at pH 4.     

Model System for the Adsorption of Tobacco Mosaic Virus

Materials which can adsorb tobacco mosaic virus (TMV) were isolated from tobacco leaves and studied for applicability as a model system for TMV adsorption. Leaves were homogenized and fractionated by sucrose density gradient centrifugation. One fraction adsorbed TMV in the presence of polyornithine. Deduced from its sensitivity to trypsin and detergent as well as from its manner of isolation, the material responsible for adsorption of TMV seemed to be cytoplasmic membrane. Membrane derived from light particulate, as well as cytoplasmic membrane, seemed to be capable of adsorbing TMV. Shorter rods obtained by sodium dodecyl sulfate or sonic treatment of TMV could adsorb to membrane as efficiently as TMV. Viral protein subunit could not adsorb whereas helical rods made of viral protein aggregates could. A two-step nature of the adsorption of TMV was suggested: a salt-sensitive and a subsequent salt-resistant steps. In the first step, ionic bonding plays a main role in the combination between TMV and membrane. Adsorption of ¹⁴C-labeled TMV was inhibited by an excess amount of non-labeled TMV or cucumber green mottle mosaic virus but not by potato virus X or rice dwarf virus, suggesting the specific nature of adsorption. In contrast to the observed specificity on the part of virus, a membrane fraction isolated from various plants, including non-hosts for TMV, could adsorb TMV. This may imply that adsorption and injection are not the determinant of host specificity in plant viral infection.     

Membrane adsorption characteristics determine the kinetics of flow-through transductions

Retrovirus-mediated gene transfer is currently limited by random Brownian motion of the retrovirus. This limitation can be overcome by flowing the retrovirus solution through a porous membrane that supports the target cells, leading to a significant increase in the transduction efficiency. This procedure is termed "flow-through transduction." In this study, we characterized the effects of the fluid flowrate and the influence that membrane characteristics have on the flow-through transduction procedure. The transduction efficiencies increased with flowrate until a plateau was reached at average flow velocities exceeding 0.3 cm/h for flow times of 3 to 4 h, using a collagen-coated depth (COL) membrane. A correlation between the optimal time for maximal gene transfer using flow-through transductions and the optimal time for maximal virus activity on the membrane was found, suggesting that the membrane adsorption capacity for virus determined the amount of gene transfer that could occur.Membrane adsorption characteristics were further investigated using two different membrane types: a tracketched polyester screen (PE) membrane and the COL membrane. Flow-through transductions using the PE and COL membranes showed that a high level of gene transfer could be attained using the COL membrane while the PE membrane gave much lower transduction efficiencies. The addition of the polycation polybrene (PB) changed these results markedly, making transductions achieved on the PE membrane similar in number to those obtained on the COL membrane. Since PB is believed to influence the virus adsorption to PE membrane, these results further support the conclusion that the increase in gene transfer achieved by the flow-through transduction procedure is due to virus adsorption to the membrane. The flow-through transduction procedure thus leads to co-localization of the viral vector and the target cell that in turn leads to a high transduction efficiency. (c) 1996 John Wiley & Sons, Inc.     

Perspectives on the mitochondrial multiple conductance channel

A multiple conductance channel (MCC) with a peak conductance of over 1 nS is recorded from mitoplasts (mitochondria with the inner membrane exposed) using patch-clamp techniques. MCC shares many general characteristics with other intracellular megachannels, many of which are weakly selective, voltage-dependent, and calcium sensitive. A role in protein import is suggested by the transient blockade of MCC by peptides responsible for targeting mitochondrial precursor proteins. MCC is compared with the peptide-sensitive channel of the outer membrane because of similarities in targeting peptide blockade. The pharmacology and regulation of MCC by physiological effectors are reviewed and compared with the properties of the pore hypothesized to be responsible for the mitochondrial inner membrane permeability transition.     

Quantitation of Human Seroresponsiveness to Merkel Cell Polyomavirus

Merkel cell carcinoma (MCC) is a relatively uncommon but highly lethal form of skin cancer. A majority of MCC tumors carry DNA sequences derived from a newly identified virus called Merkel cell polyomavirus (MCV or MCPyV), a candidate etiologic agent underlying the development of MCC. To further investigate the role of MCV infection in the development of MCC, we developed a reporter vector-based neutralization assay to quantitate MCV-specific serum antibody responses in human subjects. Our results showed that 21 MCC patients whose tumors harbored MCV DNA all displayed vigorous MCV-specific antibody responses. Although 88% (42/48) of adult subjects without MCC were MCV seropositive, the geometric mean titer of the control group was 59-fold lower than the MCC patient group (p<0.0001). Only 4% (2/48) of control subjects displayed neutralizing titers greater than the mean titer of the MCV-positive MCC patient population. MCC tumors were found not to express detectable amounts of MCV VP1 capsid protein, suggesting that the strong humoral responses observed in MCC patients were primed by an unusually immunogenic MCV infection, and not by viral antigen expressed by the MCC tumor itself. The occurrence of highly immunogenic MCV infection in MCC patients is unlikely to reflect a failure to control polyomavirus infections in general, as seroreactivity to BK polyomavirus was similar among MCC patients and control subjects. The results support the concept that MCV infection is a causative factor in the development of most cases of MCC. Although MCC tumorigenesis can evidently proceed in the face of effective MCV-specific antibody responses, a small pilot animal immunization study revealed that a candidate vaccine based on MCV virus-like particles (VLPs) elicits antibody responses that robustly neutralize MCV reporter vectors in vitro. This suggests that a VLP-based vaccine could be effective for preventing the initial establishment of MCV infection.     

Effect of phosphoric acid pretreatment on enzymatic hydrolysis of microcrystalline cellulose

Microcrystalline cellulose (MCC) was pretreated with phosphoric acid at 323 K for 10 h. X-ray diffraction (XRD) and Atomic Force Microscope (AFM) analyses revealed that the fiber surface morphology of pretreated MCC (P-MCC) were uneven and rough with the crystalline diffraction peaks of P-MCC decreased to a distinct range. The X-ray Photoelectron Spectroscopy (XPS) analysis showed that the uneven and rough surface of P-MCC could enhance the adsorption of cellulose to the molecular surface of cellulose, which is one of the key factors affecting enzymatic hydrolysis of cellulose. A reversible first order kinetics was employed to describe the adsorption kinetics of cellulase to MCC and P-MCC, and the adsorption rate constants of MCC and P-MCC were found to be 0.016, 0.024, 0.041, and 0.095, 0.149, 0.218 min^− 1, respectively at 278 K, 293 K and 308 K. The activation energies of MCC and P-MCC hydrolysis reactions were found to be 22.257 and 19.721 kJ mol^− 1. The major hydrolysis products of MCC and P-MCC were cellobiose and glucose. Hydrolysis of MCC for 120 h resulted in yields of glucose (7.21%), cellobiose (13.16%) and total sugars (20.37%). However, after the pretreatment with phosphoric acid, the corresponding sugar yields resulted from enzymatic hydrolysis of P-MCC were increased to 24.10%, 41.42%, and 65.52%; respectively, which were 3.34, 3.15, and 3.22 times of the sugars yields from enzymatic hydrolysis of MCC.     

Interaction of influenza virus proteins with planar bilayer lipid membranes. I. Characterization of their adsorption and incorporation into lipid bilayers

Alterations in the surface potential difference (delta U) of asolectin planar bilayer lipid membranes were measured following the adsorption of isolated matrix protein (M-protein) or neuraminidase of influenza virus. The method used was based upon measurement of the bilayer lipid membrane capacitance current second harmonic. The delta U dependence on the M-protein and neuraminidase concentration indicates different mechanisms of adsorption of these viral proteins by the lipid bilayer. The conductance (G0) dependence of the bilayer lipid membrane with different compositions on the concentration of isolated surface glycoproteins, hemagglutinin and neuraminidase, M-protein or neuraminidase was investigated. The change in G0 for M-protein was observed only after adsorption saturation had been achieved. Neuraminidase alone does not affect the membrane conductivity. The surface charge and lipid composition of the lipid bilayer influences the adsorption and incorporation of influenza virus M-protein and surface glycoproteins. The reversibility of protein incorporation into the bilayers was investigated by a perfusion technique. The results show reversibility of surface glycoprotein incorporation while M-protein binding appears to be irreversible.     

Plasma membrane microdomains regulate turnover of transport proteins in yeast

In this study, we investigate whether the stable segregation of proteins and lipids within the yeast plasma membrane serves a particular biological function. We show that 21 proteins cluster within or associate with the ergosterol-rich membrane compartment of Can1 (MCC). However, proteins of the endocytic machinery are excluded from MCC. In a screen, we identified 28 genes affecting MCC appearance and found that genes involved in lipid biosynthesis and vesicle transport are significantly overrepresented. Deletion of Pil1, a component of eisosomes, or of Nce102, an integral membrane protein of MCC, results in the dissipation of all MCC markers. These deletion mutants also show accelerated endocytosis of MCC-resident permeases Can1 and Fur4. Our data suggest that release from MCC makes these proteins accessible to the endocytic machinery. Addition of arginine to wild-type cells leads to a similar redistribution and increased turnover of Can1. Thus, MCC represents a protective area within the plasma membrane to control turnover of transport proteins.     

一种基于胶体微晶纤维素的改良病毒蚀斑测定法的建立与评价北大核心CSCD

胶体微晶纤维素(avicel)是一种由微晶纤维素(microcrystalline cellulose, MCC)和羧甲基纤维素(carboxymethyl cellulose,CMC)制成的混合物,可用于病毒蚀斑测定。常用的avicel由FMC公司生产,其MCC和CMC比例相对固定,无法很好地适应所有类型病毒的蚀斑测定实验。本研究通过对比不同的MCC和CMC配制比例对avicel在病毒蚀斑测定作用的影响,建立了一种操作简便、实用性好和稳定性好的改良avicel病毒蚀斑测定法。为了配制不同浓度MCC和CMC的混合物,本研究制备出12种2×avicel覆盖层,测定其总体黏度及底层黏度,评估其与传统覆盖层相比,使用时的操作难易程度。进一步将12种2×avicel覆盖层制备成avicel-DMEM营养覆盖层,测定96孔板中猪流行性腹泻病毒滴度,比较12种avicel覆盖层及传统覆盖层蚀斑大小、清晰度、稳定性及滴度准确性等的差异,筛选出最佳测定方法。结果显示,12种2×avicel覆盖层中,除4.8%MCC+1.4%CMC和4.8%MCC+1.0%CMC外,其余2×avicel覆盖层在实际使用中均比2×CMC覆盖层更容易吸取和配制营养覆盖层。最后,利用avicel病毒蚀斑测定法测定96孔板中猪流行性腹泻病毒滴度,结果显示CMC浓度越高蚀斑越小,其中终浓度为0.6%MCC+0.7%CMC的avicel覆盖层测定蚀斑染色最清晰,准确度与传统覆盖层相似,但操作较传统覆盖层更简便。综上所述,本研究建立了一种操作简便、实用性好和稳定性好的改良avicel病毒蚀斑测定法,为病毒的病原学、抗病毒药物及疫苗等相关研究的展开提供了良好的实验基础。     

Localization of MCC (mutated in colorectal cancer) in various tissues of mice and its involvement in cell differentiation.

Localization of the MCC (mutated in colorectal cancer) gene product, a cell cycle-regulating protein mutated in several colorectal tumors, in various mouse tissues was examined by immunohistochemistry and immunoelectron microscopy. MCC was localized on microvilli and in the apical cytoplasm in renal proximal tubule epithelial cells and pancreatic acinar cells. In hepatocytes, MCC was exclusively detected on microvilli. MCC was highly expressed in the cerebral cortex and the molecular layer of the cerebellar cortex and was partially associated with membrane organelles in neuronal elements. Adrenal chromaffin cells showed little expression of MCC. MCC was localized to the cell margins of ependymal cells, thyroid follicular cells, and anterior pituitary cells. In parotid acinar cells, only the apical surface was immunopositive. MCC was not expressed in skeletal and cardiac muscle. MCC was present at lateral cell borders in the duodenum and colon epithelium. In addition, the apical cytoplasm of colon epithelial cells exhibited intense immunoreactivity. The amount of MCC increased during differentiation of NGF-treated PC12 cells. In conclusion, MCC was expressed in differentiated cells and was associated with the plasma membrane and membrane organelles. In addition to the negative regulation of the cell cycle, MCC may be involved in cell differentiation.     

Interactions between protein molecules and the virus removal membrane surface: Effects of immunoglobulin G adsorption and conformational changes on filter performance

Membrane fouling commonly occurs in all filter types during virus filtration in protein‐based biopharmaceutical manufacturing. Mechanisms of decline in virus filter performance due to membrane fouling were investigated using a cellulose‐based virus filter as a model membrane. Filter performance was critically dependent on solution conditions; specifically, ionic strength. To understand the interaction between immunoglobulin G (IgG) and cellulose, sensors coated with cellulose were fabricated for surface plasmon resonance and quartz crystal microbalance with energy dissipation measurements. The primary cause of flux decline appeared to be irreversible IgG adsorption on the surface of the virus filter membrane. In particular, post‐adsorption conformational changes in the IgG molecules promoted further irreversible IgG adsorption, a finding that could not be adequately explained by DLVO theory. Analyses of adsorption and desorption and conformational changes in IgG molecules on cellulose surfaces mimicking cellulose‐based virus removal membranes provide an effective approach for identifying ways of optimizing solution conditions to maximize virus filter performance. © 2017 American Institute of Chemical Engineers Biotechnol. Prog., 34:379–386, 2018     

Dynamic behavior of adsorber membranes for protein recovery

In recent years there has been a considerable interest in developing membrane chromatography systems that function as a short, wide chromatographic column in which the adsorptive packing consists of one or more microporous membranes. This study reports the use of new adsorber membranes prepared by the incorporation of various types of ion exchange resins into an EVAL porous membrane for protein recovery. The obtained heterogeneous matrixes composed of solid particles surrounded by the polymeric film possess a good accessibility for the protein to the adsorptive sites. Furthermore, small particles can be embedded into porous polymeric structures without the disadvantages of classical chromatographic columns (high pressure drop, fouling and plugging sensitivity, low flow rate), but with the advantages of membrane technology (easy scale-up, low-pressure drop, high flow rate). The adsorptive membranes feature high static as well as dynamic protein adsorption capacities for operating flow rates ranging from 200 to 400 L h bar per m(2) and ionic strength of 20-200 mM. In a sequential desorption step by changing the pH and/or the ionic strength of the eluent, up to 90% protein recovery was obtained. Next to the separation, the mixed matrix adsorber membrane functions as a concentration medium since the protein can be concentrated up to 20-fold in the eluent. The adsorber membranes can be reused in multiple adsorption/desorption cycles with good adsorption performances.     

Interaction of influenza virus proteins with planar bilayer lipid membranes. II. Effects of rimantadine and amantadine

The dependence of the surface potential difference (delta U), transversal elasticity module (E1) and membrane conductivity (G0) on the concentrations of the antiviral drugs, rimantadine and amantadine was studied in the planar bilayer lipid membrane system. The method used was based on independent measurements of the second and third harmonics of the membrane capacitance current. The binding constants of bilayer lipid membranes obtained from the drug adsorption isotherms were 2.1 X 10(5) M-1 and 1.3 X 10(4) M-1 for rimantadine and amantadine, respectively. The changes in G0 took place only after drug adsorption saturation had been achieved. The influence of rimantadine and amantadine on the interaction of bilayer lipid membranes with matrix protein from influenza virus was also investigated. The presence of 70 micrograms/ml rimantadine in the bathing solution resulted in an increase in the concentration of M-protein at which the adsorption and conductance changes were observed. The effects of amantadine were similar to those of rimantadine but required a higher critical concentration of amantadine. The results obtained suggest that the antiviral properties of rimantadine and amantadine may be related to the interaction of these drugs with the cell membrane, which can affect virus penetration into the cell as well as maturation of the viral particle at the cell membrane.     

Neutralizing antibodies specific for glycoprotein H of herpes simplex virus permit viral attachment to cells but prevent penetration.

Monoclonal antibodies specific for gH of herpes simplex virus were shown previously to neutralize viral infectivity. Results presented here demonstrate that these antibodies (at least three of them) block viral penetration without inhibiting adsorption of virus to cells. Penetration of herpes simplex virus is by fusion of the virion envelope with the plasma membrane of a susceptible cell. Electron microscopy of thin sections of cells exposed to virus revealed that neutralized virus bound to the cell surface but did not fuse with the plasma membrane. Quantitation of virus adsorption by measuring the binding of purified radiolabeled virus to cells revealed that the anti-gH antibodies had little or no effect on adsorption. Monitoring cell and viral protein synthesis after exposure of cells to infectious and neutralized virus gave results consistent with the electron microscopic finding that the anti-gH antibodies blocked viral penetration. On the basis of the results presented here and other information published elsewhere, it is suggested that gH is one of three glycoproteins essential for penetration of herpes simplex virus into cells.     

Multiple conductance levels in rat heart inner mitochondrial membranes studied by patch clamping.

The behavior of the mitochondrial inner membrane multiple conductance channel (MCC) which has a peak conductance of 1-1.5 nS has been examined in rat heart mitochondria. MCC can display several unique characteristics: (a) prolonged open and closed times on the order of seconds to minutes, (b) a voltage dependence in which MCC opens (negative potential) or closes (positive potential) generally in steps, (c) a response to inhibitors such as amiodarone in steps corresponding at least approximately to those in (b), (d) a 'free-running mode' in which the current level rapidly fluctuates between a minimum of nine conductance levels but with a preferred occupation of the 0.5-0.7 nS levels, and (e) very large transitions (1-1.5 nS) resolved at 4 kHz bandwidth as single events with variable mean open time.     

Early interactions of pseudorabies virus with host cells: functions of glycoprotein gIII.

Adsorption of mutants of pseudorabies virus (PrV) lacking glycoprotein gIII is slower and less efficient than is that of wild-type virus (C. Schreurs, T. C. Mettenleiter, F. Zuckermann, N. Snugg, and T. Ben-Porat, J. Virol. 62:2251-2257, 1988). To ascertain the functions of gIII in the early interactions of PrV with its host cells, we compared the effect on wild-type virus and gIII- mutants of antibodies specific for various PrV proteins. Although adsorption of wild-type virus was inhibited by polyvalent antisera against PrV as well as by sera against gIII and gp50 (but not sera against gII), adsorption of the gIII- mutants was not inhibited by any of these antisera. These results suggest that, in contrast to adsorption of wild-type PrV, the initial interactions of the gIII- mutants with their host cells are not mediated by specific viral proteins. Furthermore, competition experiments showed that wild-type Prv and the gIII- mutants do not compete for attachment to the same cellular components. These findings show that the initial attachment of PrV to its host cells can occur by a least two different modes--one mediated by glycoprotein gIII and the other unspecific. gIII- mutants not only did not adsorb as readily to cells as did wild-type virus but also did not penetrate cells as rapidly as did wild-type virus after having adsorbed. Antibodies against gIII did not inhibit the penetration of adsorbed virus (wild type or gIII-), whereas antibodies against gII and gp50 did. It is unlikely, therefore, that gIII functions directly in virus penetration. Our results support the premises that efficient adsorption of PrV to host cell components is mediated either directly or indirectly by gIII (or a complex of viral proteins for which the presence of gIII is functionally essential) and that this pathway of adsorption promotes the interactions of other viral membrane proteins with the appropriate cellular proteins, leading to the rapid penetration of the virus into the cells. The slower penetration of the gIII- mutants than of wild-type PrV appears to be related to the slower and less efficient alternative mode of adsorption of PrV that occurs in the absence of glycoprotein gIII.     

The Plaque-Antiserum Method: an Assay of Virus Infectivity and an Experimental Model of Virus Infection

Areas of cytopathic effect can be circumscribed in cell monolayers by adding antiserum to the liquid nutrient medium after adsorption of virus. This procedure represents a simple and reliable tool for the titration of virus infectivity and provides an experimental model for studying some aspects of virus infection.     

Concentration of Virus from Water by Electro-Osmosis and Forced-Flow Electrophoresis

A Canalco Model CF-3 Electrophoretic Filter/Concentrator (modified ter Bier) was used to concentrate Type 1 polio virus from water using ectro-osmotic and forced-flow electrophoretic principles. Using2 ectro-osmosis water can be removed at a rate of up to 0.8 ral/hr/cm membrane area. Under conditions of 12–14 V/cm (5–6 amps) and adjusted mping rates, 20 fold concentration, without virus loss, can be achieved. ring forced-flow electrophoresis, the virus, which is negatively charged an alkaline buffer, moves toward the positive pole. At 20 V/cm and th adjusted pumping rates, the best that could be achieved was a 3 fold ncentration of virus and a 10 fold dehydration. Virus spill-over at e cathode and/or virus adsorption at the anode accounted for the poor suits, but theoretically this can be overcome by adjustment of the V/cm upled with adjustment of the pumping rates. Voltage (30 V/cm) and rrent (6 amps) have no detrimental effects on viral stability. These chniques appear to be more rapid and gentle than other methods for ncentration of virus and could be scaled up for practical use.