Formation of ion-permeable channels by tumor necrosis factor-alpha.

Tumor necrosis factor-alpha (TNF, cachectin), a protein secreted by activated macrophages, participates in inflammatory responses and in infectious and neoplastic disease states. The mechanisms by which TNF exerts cytotoxic, hormonal, and other specific effects are obscure. Structural studies of the TNF trimer have revealed a central pore-like region. Although several amino acid side chains appear to preclude an open channel, the ability of TNF to insert into lipid vesicles raised the possibility that opening might occur in a bilayer milieu. Acidification of TNF promoted conformational changes concordant with increased surface hydrophobicity and membrane insertion. Furthermore, TNF formed pH-dependent, voltage-dependent, ion-permeable channels in planar lipid bilayer membranes and increased the sodium permeability of human U937 histiocytic lymphoma cells. Thus, some of the physiological effects of TNF may be elicited through its intrinsic ion channel-forming activity.

Second cytotoxic pathway of diphtheria toxin suggested by nuclease activity.

Diphtheria toxin (DTx) provokes extensive internucleosomal degradation of DNA before cell lysis. The possibility that DNA cleavage stems from direct chromosomal attack by intracellular toxin molecules was tested by in vitro assays for a DTx-associated nuclease activity. DTx incubated with DNA in solution or in a DNA-gel assay showed Ca2+- and Mg2+-stimulated nuclease activity. This activity proved susceptible to inhibition by specific antitoxin and migrated with fragment A of the toxin. Assays in which supercoiled double-stranded DNA was used revealed rapid endonucleolytic attack. Discovery of a DTx-associated nuclease activity lends support to the model that DTx-induced cell lysis is not a simple consequence of protein synthesis inhibition.

Characterization of a glycoprotein fusogen isolated from Sendai virus.

After isolation from Sendai virus, the glycoproteins HN and F retained their ability to induce hemagglutination and both heterologous and homologous cell-cell fusion. Both methods for demonstrating cell fusion indicated that the isolated HN and F glycoproteins compared favorably with whole Sendai virus as a fusogen. Conditions affecting the degree of fusion were examined and optimized. Whole virus and isolated glycoprotein preparations were characterized by electron microscopy and by SDS-polyacrylamide gel electrophoresis. Lipid analysis of the glycoprotein preparations by thin layer chromatography and gas chromatography/mass spectrometry indicated that they were partially lipid-depleted during the isolation protocol and the ratio of cholesterol to phospholipid was higher than in the whole virus. A complete fatty acid analysis was performed on lipid extracts from whole virus and from glycoprotein preparations. Detergent was removed from the glycoproteins by dialysis and by incubation with Amberlite XAD-2 resin. The detergent content of the glycoprotein preparations was monitored by gas chromatography and with [3H]Triton X-100. Both methods showed that virtually all (greater than or equal to 99.8%) of the originally added detergent was removed. Electron microscopy of the negatively-stained HN and F preparations showed primarily spherical particles 120 +/- 20 A in diameter (range 80-250 A). Since no organization reminiscent of envelopes could be demonstrated, we conclude that the fusogenic activity of Sendai virus resides in the glycoproteins per se rather than in bilayer integrated lipid-protein complexes.

Microinjection of arginase into enzyme-deficient cells with the isolated glycoproteins of Sendai virus as fusogen.

A method of introducing enzymes into the cytoplasm of fibroblasts in culture is described. Erythrocytes obtained from normal and arginase-deficient individuals were loaded with arginase in vitro and fused to arginase-deficient mouse and human fibroblasts. Erythrocyte ghost-fibroblast fusion was quantified by a 14C-radioactive assay for arginase in solubilized fibroblasts. Fusion was successfully induced by Sendai virus and also by the isolated glycoproteins of Sendai virus. After fusion the arginase activity associated with the Fibroblasts was 700--1500 U of arginase/mg of cell protein; this enzyme activity was 5- to 10-times higher than that normally found in the fibroblasts. The enrichment in arginase activity indicated that between four and ten ghosts had fused per fibroblast. The use of isolated viral proteins to mediate the transfer of enzymes into cells in vivo might alleviate clinical complications inherent in the use of whole virions. The enzyme replacement technique described in this report for a hyperargininemic model cell system should be applicable to the group of inborn errors of metabolism characterized by deficiency of an enzyme normally localized in the cytoplasmic compartment of cells.

The acid-triggered entry pathway of Pseudomonas exotoxin A.

In this study we examined the pH requirements and reversibility of early events in the Pseudomonas toxin entry pathway, namely, membrane binding, insertion, and translocation. At pH 7.4, toxin binding to vesicles and insertion into the bilayer are very inefficient. Decreasing the pH greatly increases the efficiencies of these processes. Acid-treated toxin exhibits pH 7.4 binding and insertion levels. This indicates that hydrophobic regions that become exposed upon toxin acidficiation become buried again when the pH is raised to 7.4. In contrast, the change in toxin conformation that occurs upon membrane binding is irreversible. Returning samples to pH 7.4, incubation with excess toxin, or dilution with buffer up to 1000-fold leads to very little loss of bound toxin. Bound toxin exhibits an extremely high susceptibility to trypsin compared to free toxin (at both pH 4 and pH 7.4). At pH 4, membrane-associated toxin slowly proceeds to a trypsin-protected state; neutralization halts this process. At low pH, toxin was found to bind and insert into DMPC vesicles very efficiently at temperatures both above and below 23 degrees C, the lipid melting point. With fluid targets, the proportion of bound toxin that was photolabeled from within the bilayer peaked rapidly and then decreased with time. With frozen targets, the efficiency of photolabeling peaked but then remained fairly constant.(ABSTRACT TRUNCATED AT 250 WORDS)

An endosomal model for acid triggering of diphtheria toxin translocation.

An endosomal model system was developed for studying the effects of pH on vesicle-entrapped diphtheria toxin. The "endosomes" were prepared from dioleoylphosphatidylcholine (1 mg), diphtheria toxin (0.25 mg), and lysozyme (2.25 mg) in water at pH 8.4. The method used for preparing large unilamellar vesicles was adapted from the procedure of Shew and Deamer (Shew, R. L., and Deamer, D. W. (1985) Biochim. Biophys. Acta 816, 1-8). Efficiencies of trapping (typically 45-75%) and separation from untrapped proteins (typically 95-100%) were assessed by fluorescamine assays conducted before and after column chromatography and in the presence and absence of Tergitol Nonidet P-40. Intramembranous photolabeling revealed that diphtheria toxin inserts into the vesicle bilayer when the pH is dropped to 4; surface labeling revealed that the same treatment leads to exposure of diphtheria toxin at the trans surface of the vesicles. Release of toxin to the solution was not detected under the experimental conditions employed (i.e. with nicked or unnicked toxin, +/- exogenous trypsin, pH 4 or 8.4). Preliminary results indicate that this model system will be a valuable tool for elucidating the pathway by which the ADP ribosyltransferase domain of diphtheria toxin gains access to the cytoplasmic compartment of cells after endosomal uptake.

Heat modifiability and detergent solubility of outer membrane proteins of Rhodopseudomonas sphaeroides.

The outer membrane fraction from Rhodopseudomonas sphaeroides was isolated by isopycnic density centrifugation. The purity of this fraction was assayed by several methods. When the outer membrane fraction obtained after French press lysis of cells was compared with the outer membrane fragments released during spheroplast formation, the polypeptide profiles were identical. Detergent solubilization of membrane fractions showed that Triton X-100 nonselectively solubilizes both the cytoplasmic membrane and the outer membrane, whereas Deriphat 160 selectively solubilizes the cytoplasmic membrane. Several outer membrane polypeptides, including the major outer membrane protein, exhibited changes in electrophoretic mobility that depended upon the temperature of solubilization in sodium dodecyl sulfate. Solubilization at room temperature in the presence of ions reproduced the effect of thermal denaturation on the major outer membrane polypeptide.

Mechanism of insertion of diphtheria toxin: peptide entry and pore size determinations.

Diphtheria toxin ( DTx ) is an extremely potent inhibitor of protein synthesis. It is secreted as a linear polypeptide, which is cleaved to produce disulfide-linked A and B fragments. Fragment A, the inhibitor of protein synthesis, requires fragment B, the recognition subunit, for entry into intact cells. Fragment B has been proposed to form a transmembrane channel through which A gains access to the cytosol. If it were demonstrated that the B subunit had an exclusive association with membrane lipid acyl chains, this might indicate that A is secluded in a proteinaceous B channel. However, our results from intramembranous photolabeling studies show that both subunits of DTx enter the hydrocarbon domain of the bilayer. Toxin cleavage is not required for penetration. Decreasing pH leads to increased binding and hence indirectly to increased penetration. Parallel permeability studies indicate that cleaved DTx does indeed form pores (24 A in diameter) and they are larger than those previously reported (5 A) with native toxin. The data suggest that these are dimeric structures. Cleaved DTx is much more effective than intact DTx at pore formation. Thus, we conclude that, while pore formation is a feature of toxin-membrane interaction, the pore structure does not protect A from contact with lipid side chains and may in fact consist of both the A and B domains in a dimeric configuration, (AB)2.

Photoreactive labeling of M13 coat protein in model membranes by use of a glycolipid probe.

Coliphage M13 coat protein in synthetic bilayer membranes was labeled by use of 12-(4-azide-2-nitrophenoxy)stearoyl[1-14C]glucosamine, a photoreactive glycolipid probe that spontaneously inserts into membranes. In this model system, the probe preferentially labeled the proteins over the lipids. Experiments designed to test the probe's restriction to integral membrane proteins revealed that extrinsic proteins as well as external peptide fragments of integral membrane proteins were not accessible to the photogenerated nitrene on the fatty acid chain. Only integral membrane peptides were labeled by the membrane-bound probe. These results indicate that protein labeling can be effected specifically from within the hydrocarbon milieu of a model membrane system.

Photolabelling of cholera toxin subunits during membrane penetration.

There has been much speculation about the mechanism by which cholera toxin exerts its effect on the cytoplasmic side of the membranes with which it interacts. After the pentamer of B subunits (5B) binds to membrane receptors, particularly the monosialylganglioside GM1, the disulphide-linked dimer A1SSA2 (which together with 5B constitutes the complete toxin) is thought to penetrate the membrane, perhaps through a channel formed by 5B and become reduced so that A1SH units reach the cytoplasm and stimulate adenylate cyclase. Evidence for this mechanism is circumstantial. If it is correct, a compound which will specifically label intramembranous sections of the toxin should label the channel-forming B subunits but not the channel-contained A1 subunit. We have tested this prediction with a photoreactive glycolipid compound and have obtained the opposite result. Therefore, we propose that only the A1 subunit enters the membrane and we provide here data on the kinetics of that process.

Fatty acid desaturase mutants of yeast: growth requirements and electron spin resonance spin-label distribution.

Two respiratory-sufficient and one respiratory-deficient (nuclear petite) strains of yeast Delta(9)-desaturase mutants were analyzed to determine which fatty acids would serve as replacements for the naturally occurring fatty acids, 16:1 Delta(9)cis and 18:1 Delta(9)cis. The requirement can be satisfied by several fatty acids differing in double-bond position, steric configuration, chain length, and degree of unsaturation. The features common to growth-supporting fatty acids are presented and the effects of varying the carbon source and temperature are considered. In addition, we illustrate several pitfalls encountered in membrane studies which exploit lipid-requiring organisms. Since the membrane fatty acid composition of these mutants can be modified readily, electron spin resonance spectroscopy is used to compare membranes of mutant strains enriched for different fatty acids. The lipid distribution pattern of the most commonly employed electron spin resonance spin-label, 12-nitroxide stearate, was ascertained and compared to that of 18:1 Delta(9)cis.

Comparison of the intoxication pathways of tumor necrosis factor and diphtheria toxin.

The mechanism by which tumor necrosis factor alpha (TNF) initiates tumor cell destruction is unknown. Having established that a brief drop in extracellular pH enhances the killing activity of TNF, our next objective was to explore whether TNF-induced cell death is dependent on endosomal acidification. Diphtheria toxin (DTx), a well-characterized acid-dependent cytotoxin, served as an indicator of the effectiveness of each treatment condition. Studies with lysosomotropic agents demonstrated that the cytotoxic pathway of TNF can operate independently of low pH exposure in contrast to the lethal pathway of DTx. When NH4Cl-treated cells were exposed to TNF at low pH, the level of killing increased two- to threefold over that attained with cells maintained at neutral pH (either with or without NH4Cl). Furthermore, inhibition of metabolic processes by sodium azide in combination with 2-deoxyglucose severely reduced DTx killing but stimulated TNF killing. Despite these differences, TNF and DTx provoked extensive internucleosomal DNA cleavage in prelytic target cells. Inhibitor of nuclear poly(ADP-ribose) transferase also evoked similar levels of cellular resistance to both cytotoxins. Models for DTx- and TNF-induced cytolysis are discussed in view of these new discoveries.

Characterization of the deoxyribonuclease activity of diphtheria toxin.

Having discovered that the A domain of diphtheria toxin exhibits intrinsic nuclease activity (Chang, M. P., Baldwin, R. L., Bruce, B., and Wisnieski, B. J. (1989) Science 246, 1165-1168), we proceeded to examine the requirements for optimal enzymic expression. In vitro assays with linear double-stranded DNA demonstrated that optimal activity occurs at pH 7.5 and 37 degrees C. A characterization of the stringent cation-dependence of the reaction revealed increasing activity with increasing Mn2+ up to 30 mM. In contrast, activity levels with Ca2+ or Zn2+ alone peaked at 100 microM and with Mg2+ alone at 1 mM. The Zn2(+)- and Mg2(+)-stimulated activities appear to be dependent on trace amounts of Ca2+. Indeed, inclusion of 2 mM Ca2+ plus 3 mM Mg2+ in the reaction buffer promoted a high level of DNA cleavage even though very little cleavage was seen with either cation alone at 2-3 mM. Addition of 20-200 mM NaCl or KCl caused progressive inhibition. Detection of diphtheria toxin nuclease activity under physiologically relevant conditions suggests that it may be operative in vivo and supports our contention that diphtheria toxin-induced cytolysis is not a simple consequence of protein synthesis inhibition, but rather the final step in a cytolytic pathway linked to chromosomal integrity.

Electron spin resonance evidence for vertical asymmetry in animal cell membranes.

Two electron spin resonance (ESR) spin labels were used to monitor the physical state of bacterial and animal cell membranes: 5N10, a nitroxide derivative of decane, and 12NS-GA, a glucosamine derivative of 12-nitroxide stearic acid. Spectra were recorded at 1 degrees C intervals from approximately 5 to 45 degrees C. Arrhenius plots of log hH/hP vs. 1/K were obtained by measuring the amplitudes of the hydrocarbon and water signals, hH and hP, respectively. Two discontinuities in the Arrhenius plot (at characteristic temperatures t1 and th) were observed with bacterial cell membranes independent of the spin label employed. Analysis of sealed animal cell membrane samples revealed four characteristic temperatures when the hydrophobic spin lable 5N10 was used, but only two when the amphiphilic spin label 12NS-GA was used. The specific set of characteristic temperatures revealed with 12NS-GA depended on whether the membrane preparation was inside out (ISO) or right side out (RSO). Analysis of Newcastle disease virus, a source of RSO plasma membrane derived from host, revealed two characteristic temperatures at approximately 14 and 33 degrees C. Analysis of phagosomes, a source of ISO plasma membrane derived from LM cells, revealed two characteristic temperatures at approximately 23 and 38 degrees C. When unsealed or disrupted membrane preparations were spin labeled with 12NS-GA, both sets (RSO and ISO) of characteristic temperatures were revealed. The results indicate that the inner and outer monolayers of animal cell membranes are physically distinct and that the glycosylated spin label, 12NS-GA, is apparently restricted in its ability to flip across the membrane bilayer. In this study, characteristic temperatures were pinpointed by computer analysis of the ESR spectral data.

Characterization of the insertion of Pseudomonas exotoxin A into membranes.

Pseudomonas aeruginosa exotoxin A (PTx) is an extremely potent inhibitor of protein synthesis, similar to diphtheria toxin in its mode of action. It is synthesized in precursor form and secreted as an Mr 66,583 protein lacking a 25-amino acid leader sequence. While the primary sequence and the nature of the enzyme activity that leads to inactivation of elongation factor 2 are known, the mechanism of PTx internalization remains obscure. To elucidate the entry pathway, we examined PTx-membrane interactions using vesicle targets of defined lipid composition. Insertion was monitored with an intramembranous photoreactive probe; pore formation was determined from liposomal swelling rates. Our results show that the efficiency of PTx binding to vesicles increases dramatically with decreasing pH. In general, the insertion efficiency correlated with the binding efficiency. At pH 4, we noted a slight decrease in binding below the melting point (23 degrees C) of the target vesicles. Not only was PTx able to insert into frozen bilayers, but the efficiency of penetration at 0 degrees C was actually somewhat higher than expected based on binding efficiency. Liposome swelling assays analyzed by the Renkin equations indicated that PTx-liposomes made at pH 4 were permeable to solutes up to 2.8 nm in diameter. Pores of a similar size were found when the liposomes were made at pH 7, but the efficiency of pore formation at this pH was very low. Chymotrypsin fragmentation profiles of PTx depended on incubation conditions, e.g., pH, presence of NAD, reducing agents, and membranes. Liposomes containing PTx cleaved at pH 4 displayed up to 40-fold more pore activity than liposomes containing uncleaved PTx or PTx cleaved at pH 7. Pore activity at pH 7 was negligible. Addition of reducing agents caused a 50 to 60% increase in pore activity. Cleaved toxin was active in target membrane insertion even at 0 degrees C, and all of the major fragments were photolabeled.

Effect of low pH on the conformation of Pseudomonas exotoxin A.

Previously we examined factors involved in the entry mechanism of Pseudomonas exotoxin A (PTx) at the level of lipid-protein interactions (Farahbakhsh, Z. T., Baldwin, R. L., and Wisnieski, B. J. (1986) J. Biol. Chem. 261, 11404-11408). Exposure to a low pH environment appears to be an obligatory trigger of the entry pathway. In this report we describe the effect of pH upon the conformation of PTx. We have found that the intrinsic fluorescence of PTx is strongly dependent on pH, decreasing between pH 7.4 and 4.0 with a red shift in the emission lambda max. The changes are reversible and associated with the acquisition of a binding site for the fluorescent dye 1-anilino-8-naphthalenesulfonic acid (ANS). The fluorescence intensity of ANS in the presence of PTx increases with decreasing pH and is accompanied by a blue shift in emission spectra, indicative of exposure of hydrophobic surfaces. These changes are also reversible. Both the intrinsic fluorescence and ANS binding profiles show a dramatic dependence on pH, with the transitions centered on pH 5.0 and 4.5, respectively. Circular dichroism studies reveal a 9% decrease in alpha-helicity between pH 7.7 and 4. The susceptibility of toxin to trypsin cleavage is also a function of pH, increasing with decreasing pH. The pH 7.4 cleavage profile is regained when the acid-treated samples are brought back to pH 7.4. The conformational changes observed in these pH shift experiments are likely to be physiologically significant because the conditions closely resemble those that the toxin would encounter if entry into the cytoplasm of a cell involves escape from an endosomal compartment.

Pseudomonas exotoxin A. Membrane binding, insertion, and traversal.

Using vesicle targets composed of phosphatidylcholine and cholesterol (1:1 molar ratio), we found that Pseudomonas aeruginosa exotoxin A (PTx) binding and insertion are not only dependent on pH (Zalman, L.S., and Wisnieski, B.J. (1985) Infect. Immun. 50, 630-635) but also on ionic strength, reaching a maximum in pH 4 buffer that contains 150-200 mM NaCl. Insertion was monitored by photolabeling with an intramembranous probe. Higher levels of binding and insertion were attained with vesicles that contained 2.5 mol% dicetylphosphate than with neutral vesicles. Positively charged vesicles (2.7 mol% stearylamine) were the least effective targets. At pH 7.4, all binding levels were depressed. While PTx binding increased with increasing temperature, the relative proportion of the vesicle-associated toxin that was photolabeled decreased. The most likely explanation for the decrease is that the bilayer translocation rates increased with increasing temperature, and hence fewer PTx molecules were accessible at the time of photolabeling. At 37 degrees C, binding and insertion both plateaued within 10 min of lowering the pH to 4. After 10 min, the amount of bound toxin decreased slightly with time but there was a dramatic decrease in photolabeling, indicating that inserted PTx had begun to cross the bilayer. This was verified by the finding that when PTx was incubated with vesicles that contained trypsin, cleavage occurred only in those samples in which the pH was shifted down to pH 4. Entry is triggered by an acid-induced conformational change that promotes productive binding and insertion. After insertion, the kinetics of membrane traversal appear to be regulated by the physical properties of the bilayer.

Mapping the membrane proteins of Newcastle-disease virus with a photoreactive glycolipid probe.

The envelope proteins of Newcastle-disease virus were preferentially labelled when a suspension of virus particles that contained the photoreactive probe 12-(4-azido-2-nitro-phenoxy)stearoyl[1-14C]glucosamine was irradiated. One of the proteins labelled was not readily accessible to surface labelling with 125I.