Mechanism of human erythrocyte hemolysis induced by short-chain phosphatidylcholines and lysophosphatidylcholine

The incorporation and accumulation of a certain amount of short-chain phosphatidylcholine or lysophosphatidylcholine into lipid bilayers of erythrocyte membranes is the first step causing membrane perturbation in the process of hemolysis. Accumulation of dilauroylglycerophosphocholine into membranes makes human erythrocytes "permeable cells"; Ions such as Na+ or K+ can permeate through the membrane, though large molecules such as hemoglobin can not. The "pore" formation was partially reproduced in liposomes prepared from lipids extracted from human erythrocyte membranes; C12:0PC induced the release of glucose from liposomes but did not significantly induce the release of dextran. It was suggested that the phase boundary between dilauroylglycerophosphocholine and the host membrane bilayer or dilauroylglycerophosphocholine rich domain itself behaves as "pores." Erythrocytes could expand to 1.5 times the original cell volume without any appreciable hemolysis when incubated with C12:0PC at 37 degrees C. The capacity of the erythrocytes to expand was temperature dependent. The capacity may play an important role in the resistance of the cells against lysis. The "permeable cell" stage could be hardly observed when erythrocytes were treated with didecanoylglycerophosphocholine and lysophosphatidylcholine. Perturbation induced by accumulation of didecanoylglycerophosphocholine or lysophosphatidylcholine may cause non specific destruction of membranes rather than formation of a kind of "pore."     

Lidocaine: An inhibitor in the free‐radical‐induced hemolysis of erythrocytes

Lidocaine was reported to protect erythrocytes from hemolysis induced by 2,2′‐azobis(2‐amidinopropane) dihydrochloride (AAPH). Since AAPH‐induced hemolysis was a convenient in vitro experimental system to mimic erythrocytes undergoing peroxyl radicals attack, the aim of this work was to investigate the antioxidant effect of lidocaine on AAPH‐induced hemolysis by chemical kinetics. As a result, one molecule of lidocaine can only trap 0.37 radical, much lower than melatonin. Meanwhile, lidocaine cannot protect erythrocytes from hemolysis induced by hemin, which the mechanism of hemolysis was due to the erythrocyte membrane destroyed by hemin. Accordingly, lidocaine protected erythrocytes by scavenging radicals preferentially rather than by stabilizing membrane. Moreover, the interactions of lidocaine with two radical species, including 2,2′‐azinobis(3‐ethylbenzothiazoline‐6‐sulfonate) radical cation (ABTS^+?) and 2,2′‐diphenyl‐1‐picrylhydrazyl (DPPH), indicated that lidocaine can reduce ABTS^+? with 260 µM as the 50% inhibition concentration (IC₅₀) and cannot react with DPPH. Thus, lidocaine served as a reductant rather than a hydrogen donor to interact with radicals. Finally, the quantum calculation proved that, compared with the melatonin radical, the stabilization of N‐centered radical of lidocaine was higher than the amide‐type N‐centered radical but lower than the indole‐type N‐centered radical in melatonin. These results provided basic information for lidocaine to be an antiradical drug. © 2009 Wiley Periodicals, Inc. J Biochem Mol Toxicol 23:81–86, 2009; Published online in Wiley InterScience ( www.interscience.wiley.com ). DOI 10.1002/jbt.20267     

Nitric oxide‐mediated inhibition of NFκB regulates hyperthermia‐induced apoptosis

Ascertaining the upstream regulatory mechanisms of hyperthermia‐induced apoptosis is important to understand the role of hyperthermia in combined modality cancer therapy. Accordingly, we investigated whether (i) hyperthermia‐induced apoptosis is mediated through the nitric oxide (NO) signaling pathway and (ii) inhibition of post‐translational modification of IκBα and down regulation of NFκB‐DNA binding activity is an intermediate step in NO‐dependent apoptosis in MCF‐7 breast cancer cells. For hyperthermia treatment, the cells were exposed to 43°C. Intracellular NO levels measured by the fluorescent intensity of DAF‐2A and iNOS expression by immunobloting revealed an increased level of iNOS dependent NO production after 43°C. Apoptosis measured by Annexin V expression and cell survival by clonogenic assay showed a 20% increase in apoptosis after 43°C treatments. EMSA analysis showed a dose‐dependent inhibition of NFκB‐DNA binding activity. The hyperthermia‐mediated inhibition of NFκB was persistent even after 48 h. Inhibition of NO by L ‐NAME rescued the NFκB‐DNA binding activity and inhibits heat‐induced apoptosis. Similarly, over‐expression of NFκB by transient transfection inhibits heat‐induced apoptosis. These results demonstrate that apoptosis upon hyperthermia exposure of MCF‐7 cells is regulated by NO‐mediated suppression of NFκB. J. Cell. Biochem. 106: 999–1009, 2009. © 2009 Wiley‐Liss, Inc.     

A perforin‐like protein mediates disruption of the erythrocyte membrane during egress of Plasmodium berghei male gametocytes

Successful gametogenesis of the malaria parasite depends on egress of the gametocytes from the erythrocytes within which they developed. Egress entails rupture of both the parasitophorous vacuole membrane and the erythrocyte plasma membrane, and precedes the formation of the motile flagellated male gametes in a process called exflagellation. We show here that egress of the male gametocyte depends on the function of a perforin‐like protein, PPLP2. A mutant of Plasmodium berghei lacking PPLP2 displayed abnormal exflagellation; instead of each male gametocyte forming eight flagellated gametes, it produced gametocytes with only one, shared thicker flagellum. Using immunofluorescence and transmission electron microscopy analysis, and phenotype rescue with saponin or a pore‐forming toxin, we conclude that rupture of the erythrocyte membraneis blocked in the mutant. The parasitophorous vacuole membrane, on the other hand, is ruptured normally. Some mutant parasites are still able to develop in the mosquito, possibly because the vigorous motility of the flagellated gametes eventually leads to escape from the persisting erythrocyte membrane. This is the first example of a perforin‐like protein in Plasmodium parasites having a role in egress from the host cell and the first parasite protein shown to be specifically required for erythrocyte membrane disruption during egress.     

Protein-dependent lipid lateral phase separation as a mechanism of human erythrocyte ghost resealing

The hypothesis of a correlation between a 10°–20°C lipid phase transition and the resealing process of human erythrocyte membrane has been investigated. The conditions required to reseal human erythrocyte ghosts have been studied by measuring the amount of fluorescein-labeled dextran (FD) that is trapped into the membrane. Temperature per se was sufficient to induce membrane resealing: (1) at 5 mM sodium phosphate, pH 7.8 (5P8), resealing began at 12°C; (2) at salt concentrations above 8 mM sodium phosphate, it occurred at lower temperature; and (3) in isotonic saline was detected just above 5°C. The removal of peripheral membrane proteins from unsealed membranes by chymotrypsin at 0°C in 5P8 was followed by membrane resealing. This seems to imply that the presence of proteins is necessary to maintain the membrane unsealed. Protein-induced lateral phase separation of lipids may be a reasonable mechanism for the observed phenomena. In fact, the permeability of phosphatidylserine-phosphatidylcholine mixed liposomes to FD is modified by lipid lateral phase separation induced by pH or poly-L-lysine. Electron spin resonance studies of membrane fluidity by a spin labeled stearic acid showed a fluidity break around 11°C, which may be due to a gel–liquid phase transition. Fluidity changes are abolished by chymotrypsin treatment. It is suggested that a lateral phase separation is responsible for the permeability of open ghosts to FD. Accordingly, disruption of phase separation apparently produces membrane reconstitution. In this respect peripheral proteins and particularly the spectrin-actin network, may play a major role in membrane resealing.     

The effect of temperature on lysis of human erythrocytes by palmitic acid]

An analysis of kinetic curves of erythrocyte hemolysis induced by palmitic acid has shown the existence of some stages of this process. The activation energy of hemolysis, as determined by the temperature dependence of the hemolysis rate constant, was 210 +/- 30 kJ/mol. It was shown by the method of stepwise thermoinactivation of erythrocytes proteins that at temperature of 49 degrees C which corresponded to the framework protein spectrin denaturation temperature, the erythrocyte membrane stability sharply decreased. On the contrary, changes of the cell shape induced by the hyperosmotic medium (0.5 M sucrose) inhibited the palmitic acid-induced erythrocytes hemolysis.     

Effects of Low‐Dose Embryonic Thyroid Disruption and Rearing Temperature on the Development of the Eye and Retina in Zebrafish

Thyroid hormones are required for vertebrate development, and disruption of the thyroid system in developing embryos can result in a large range of morphologic and physiologic changes, including in the eye and retina. In this study, our anatomic analyses following low‐dose, chronic thyroid inhibition reveal that both methimazole (MMI) exposure and rearing temperature affect eye development in a time‐ and temperature‐dependent fashion. Maximal sensitivity to MMI for external eye development occurred at 65 hr postfertilization (hpf) for zebrafish reared at 28°C, and at 69 hpf for those reared at 31°C. Changes in eye diameter corresponded to changes in thickness of two inner retinal layers: the ganglion cell layer and the inner plexiform layer, with irreversible MMI‐induced decreases in layer thickness observed in larvae treated with MMI until 66 hpf at 28°C. We infer that maximal sensitivity to MMI between 65 and 66 hpf at 28°C indicates a critical period of thyroid‐dependent eye and retinal development. Furthermore, our results support previous work that shows spontaneous escape from MMI‐induced effects potentially due to embryonic compensatory actions, as our data show that embryos treated beyond the critical period generally resemble controls     

Use of vitamin E deficient red cells to detect a dialyzable hemolytic factor produced by peroxidizing rat liver microsomes.

The tendency of rat red blood cells to hemolyze in the presence of peroxidizing rat liver microsomes is greatly increased if the red cells are obtained from vitamin E deficient rats. Adequate dietary vitamin E supplementation imparts resistance against hemolysis. Dietary butylated hydroxytoluene or the level of erythrocyte glutathione or total thiols are relatively unimportant factors in determining red cell sensitivity to hemolysis induced by perixiziding microsomes. When separated from peroxidizing microsomes by a dialysis membrane, vitamin E deficient cells are completely hemolyzed. Hemolytically active material can be separated from peroxidized microsomes by dialysis at 0°C.     

Ceranib‐2‐induced suicidal erythrocyte death

Ceramide is known to trigger apoptosis of nucleated cells and eryptosis of erythrocytes. Eryptosis is characterized by cell shrinkage and cell membrane scrambling with phosphatidylserine translocation to the erythrocyte surface. Besides ceramide, stimulators of eryptosis include increase of cytosolic Ca²⁺‐activity ([Ca²⁺]_i) and oxidative stress. Ceramide is degraded by acid ceramidase and inhibition of the enzyme similarly triggers apoptosis. The present study explored, whether ceramidase inhibitor Ceranib‐2 induces eryptosis. Flow cytometry was employed to quantify phosphatidylserine‐exposure at the cell surface from annexin‐V‐binding, cell volume from forward scatter, [Ca²⁺]_i from Fluo3‐fluorescence, reactive oxygen species (ROS) from DCF dependent fluorescence, and ceramide abundance utilizing specific antibodies. Hemolysis was estimated from hemoglobin concentration in the supernatant. A 48 h exposure of human erythrocytes to Ceranib‐2 significantly increased the percentage of annexin‐V‐binding cells (≥50 μM) and the percentage of hemolytic cells (≥10 μM) without significantly modifying forward scatter. Ceranib‐2 significantly increased Fluo3‐fluorescence, DCF fluorescence and ceramide abundance. The effect of Ceranib‐2 on annexin‐V‐binding was not significantly blunted by removal of extracellular Ca²⁺. Ceranib‐2 triggers phospholipid scrambling of the erythrocyte cell membrane, an effect at least in part due to increase of ceramide abundance and induction of oxidative stress, but not dependent on Ca²⁺ entry. Copyright © 2016 John Wiley & Sons, Ltd.     

Identification of a direct hemolytic effect dependent on the catalytic activity induced by phospholipase‐D (dermonecrotic toxin) from brown spider venom

Brown spiders have world‐wide distribution and are the cause of health problems known as loxoscelism. Necrotic cutaneous lesions surrounding the bites and less intense systemic signs like renal failure, DIC, and hemolysis were observed. We studied molecular mechanism by which recombinant toxin, biochemically characterized as phospholipase‐D , causes direct hemolysis (complement independent). Human erythrocytes treated with toxin showed direct hemolysis in a dose‐dependent and time‐dependent manner, as well as morphological changes in cell size and shape. Erythrocytes from human, rabbit, and sheep were more susceptible than those from horse. Hemolysis was not dependent on ABO group or Rhesus system. Confocal and FACS analyses using antibodies or GFP‐phospholipase‐D protein showed direct toxin binding to erythrocytes membrane. Moreover, toxin‐treated erythrocytes reacted with annexin‐V and showed alterations in their lipid raft profile. Divalent ion chelators significantly inhibited hemolysis evoked by phospholipase‐D , which has magnesium at the catalytic domain. Chelators were more effective than PMSF (serine‐protease inhibitor) that had no effect on hemolysis. By site‐directed mutation at catalytic domain (histidine 12 by alanine), hemolysis and morphologic changes of erythrocytes (but not the toxin's ability of membrane binding) were inhibited, supporting that catalytic activity is involved in hemolysis and cellular alterations but not toxin cell binding. The results provide evidence that L. intermedia venom phospholipase‐D triggers direct human blood cell hemolysis in a catalytic‐dependent manner. J. Cell. Biochem. 107: 655–666, 2009. © 2009 Wiley‐Liss, Inc.     

Short‐term high temperature treatment reduces viability and inhibits respiration and DNA repair enzymes in Araucaria angustifolia cells

We evaluated the effect of global warming on Araucaria angustifolia (Bert.) O. Kuntze, a critically endangered native tree of Southern Brazil, by studying the effects of short‐term high temperature treatment on cell viability, respiration and DNA repair of embryogenic cells. Compared with control cells grown at 25°C, cell viability was reduced by 40% after incubation at 30 and 37°C for 24 and 6 h, respectively, while 2 h at 40 and 42°C killed 95% of the cells. Cell respiration was unaffected at 30–37°C, but dramatically reduced after 2 h at 42°C. The in vitro activity of enzymes of the base excision repair (BER) pathway was determined. Apurinic/apyrimidine endonuclease, measured in extracts from cells incubated for 2 h at 42°C, was completely inactivated while lower temperatures had no effect. The activities of three enzymes of the mitochondrial BER pathway were measured after 30‐min preincubation of isolated mitochondria at 25–40°C and one of them, uracil glycosylase, was completely inhibited at 40°C. We conclude that cell viability, respiration and DNA repair have different temperature sensitivities between 25 and 37°C, and that they are all very sensitive to 40 or 42°C. Thus, A. angustifolia will likely be vulnerable to the short‐term high temperature events associated with global warming.     

Cationic oligopeptides with the repeating sequence L‐lysyl‐L‐alanyl‐L‐alanine: conformational and thermal stability study using optical spectroscopic methods

The infrared (IR), vibrational circular dichroism (VCD), and electronic circular dichroism (ECD) spectra of short cationic sequential peptides (L ‐Lys‐L ‐Ala‐L ‐Ala)_n (n = 1, 2, and 3) were measured over a range of temperatures (20–90 °C) in aqueous solution at near‐neutral pH values in order to investigate their solution conformations and thermally induced conformational changes. VCD spectra of all three oligopeptides measured in the amide I′ region indicate the presence of extended helical polyproline II (PPII)‐like conformation at room temperature. UV‐ECD spectra confirmed this conclusion. Thus, the oligopeptides adopt a PPII‐like conformation, independent of the length of the peptide chain. However, the optimized dihedral angles ? and ψ are within the range ?82 to ?107° and 143–154°, respectively, and differ from the canonical PPII values. At elevated temperatures, the observed intensity and bandshape variations in the VCD and ECD spectra show that the PPII‐like conformation of the Lys‐Ala‐Ala sequence is still preferred, being in equilibrium with an unordered conformer at near‐neutral pH values within the range of temperatures from 20 to 90 °C. This finding was obtained from analysis of the temperature‐dependent spectra using the singular value decomposition method. The study presents KAA‐containing oligopeptides as conformationally stable models of biologically important cationic peptides and proteins. Copyright © 2009 European Peptide Society and John Wiley & Sons, Ltd.     

The diversity of FtsY‐lipid interactions

The bacterial signal recognition particle (SRP) receptor FtsY forms a complex with the SRP Ffh to target nascent polypeptide chains to the bacterial inner membrane. How FtsY interacts with lipids and associates to the membrane is unclear. Here, we show that vesicle binding leads to partial protection against proteolytic degradation and a change in secondary structure, which differs depending on whether the lipids are simple mixtures of zwitterionic and anionic lipids, mimics of Escherichia coli lipids, or lysolipids. Lipid binding alters the stability of FtsY. Thermal unfolding of FtsY in buffer shows two transitions, one occurring at ～60°C and the other at ～90°C. The thermal intermediate accumulating between 60 and 90°C has structural features in common with the state induced by binding to E. coli lipids. E. coli lipid extract induces a single transition around 70°C, anionic lipids have no effect while cooperative unfolding is completely removed in lysolipids. Thus, the lipid environment profoundly influences the dynamic properties of FtsY, leading to three different kinds of FtsY‐lipid interactions with different effects on structure, proteolytic protection, and stability, and is driven both by hydrophobic and electrostatic interactions. Trypsin digestion experiments highlight the central role of the N‐domain in lipid contacts, whereas the A‐ and G‐domains appear to play a more minor part. © 2010 Wiley Periodicals, Inc. Biopolymers 93: 595–606, 2010. This article was originally published online as an accepted preprint. The “Published Online” date corresponds to the preprint version. You can request a copy of the preprint by emailing the Biopolymers editorial office at biopolymers@wiley.com     

Evaluation of Staphylococcus aureus DNA aptamer by enzyme‐linked aptamer assay and isothermal titration calorimetry

To monitor the specificity of Staphylococcus aureus aptamer (SA‐31) against its target cell, we used enzyme‐linked aptamer assay. In the presence of target cell, horseradish peroxidase–conjugated streptavidin bound to biotin‐labeled SA‐31 showed specific binding to S   aureus among 3 different bacteria with limit of detection of 10³ colony‐forming unit per milliliter. The apparent K _a was 1.39 μM⁻¹ ± 0.3 μM⁻¹. The binding of SA‐31 to membrane proteins extracted from cell surface was characterized using isothermal titration calorimetry, and the effect of changes in binding temperature and salt concentrations of binding buffer was evaluated based on thermodynamic parameters (K _a, ΔH , and ΔG ). Since binding of aptamer to its targets solely depends on its 3‐dimensional structure under experimental conditions used in selection process, the change in temperature and ion concentration changed the affinity of SA‐31 to its target on surface of bacteria. At 4°C, SA‐31 did not show an affinity to its target with poor heat change upon injection of membrane fraction to aptamer solution. However, the apparent association constants of SA‐31 slightly varied from K _a = 1.56 μM⁻¹ ± 0.69 μM⁻¹ at 25°C to K _a = 1.03 μM⁻¹ ± 0.9 μM⁻¹ at 37°C. At spontaneously occurring exothermic binding reactions, affinities of S  aureus aptamer to its target were also 9.44 μM⁻¹ ± 0.38 μM⁻¹ at 50mM, 1.60 μM⁻¹ ± 0.11 μM⁻¹ at 137mM, and 3.28 μM⁻¹ ± 0.46 μM⁻¹ at 200 mM of salt concentration. In this study, it was demonstrated that enzyme‐linked aptamer assay and isothermal titration calorimetry were useful tools for studying the fundamental binding mechanism between a DNA aptamer and its target on the outer surface of S  aureus .     

Revisiting the membrane interaction mechanism of a membrane‐damaging β‐barrel pore‐forming toxin Vibrio cholerae cytolysin

Vibrio cholerae cytolysin (VCC) permeabilizes target cell membranes by forming transmembrane oligomeric β‐barrel pores. VCC has been shown to associate with the target membranes via amphipathicity‐driven spontaneous partitioning into the membrane environment. More specific interaction(s) of VCC with the membrane components have also been documented. In particular, specific binding of VCC with the membrane lipid components is believed to play a crucial role in determining the efficacy of the pore‐formation process. However, the structural basis and the functional implications of the VCC interaction with the membrane lipids remain unclear. Here we show that the distinct loop sequences within the membrane‐proximal region of VCC play critical roles to determine the functional interactions of the toxin with the membrane lipids. Alterations of the loop sequences via structure‐guided mutagenesis allow amphipathicity‐driven partitioning of VCC to the membrane lipid bilayer. Alterations of the loop sequences, however, block specific interactions of VCC with the membrane lipids and abort the oligomerization, membrane insertion, pore‐formation and cytotoxic activity of the toxin. Present study identifies the structural signatures in VCC implicated for its functional interactions with the membrane lipid components, a process that presumably acts to drive the subsequent steps of the oligomeric β‐barrel pore‐formation and cytotoxic responses.     

Changes in apoplastic peroxidase activity and cell wall composition are associated with cold‐induced morpho‐anatomical plasticity of wheat leaves

• Temperate grasses, such as wheat, become compact plants with small thick leaves after exposure to low temperature. These responses are associated with cold hardiness, but their underlying mechanisms remain largely unknown. Here we analyse the effects of low temperature on leaf morpho‐anatomical structure, cell wall composition and activity of extracellular peroxidases, which play key roles in cell elongation and cell wall thickening, in two wheat cultivars with contrasting cold‐hardening ability.
• A combined microscopy and biochemical approach was applied to study actively growing leaves of winter (ProINTA‐Pincén) and spring (Buck‐Patacón) wheat developed under constant warm (25 °C) or cool (5 °C) temperature.
• Cold‐grown plants had shorter leaves but longer inter‐stomatal epidermal cells than warm‐grown plants. They had thicker walls in metaxylem vessels and mestome sheath cells, paralleled with accumulation of wall components, predominantly hemicellulose. These effects were more pronounced in the winter cultivar (Pincén). Cold also induced a sharp decrease in apoplastic peroxidase activity within the leaf elongating zone of Pincén, and a three‐fold increase in the distal mature zone of the leaf. This was consistent with the enhanced cell length and thicker cell walls in this cultivar at 5 °C.
• The different response to low temperature of apoplastic peroxidase activity and hemicellulose between leaf zones and cultivar types suggests they might play a central role in the development of cold‐induced compact morphology and cold hardening. New insights are presented on the potential temperature‐driven role of peroxidases and hemicellulose in cell wall dynamics of grasses.

     

Effect of egg‐phosphatidylcholine on the chilling sensitivity and lipid phase transition of Asian elephant (Elephas maximus) spermatozoa

This study was conducted in an effort to improve our understanding of the response of Asian elephant (Elephas maximus, Em) spermatozoa to chilling. Semen was collected from two elephant bulls by means of the manual rectal stimulation method. Five out of seven semen collections were deemed to be suitable for use based on motility (ranging from 20% to 60%) and membrane integrity. We evaluated the chilling sensitivity by incubating the sperm with a fluorescent dye (5‐carboxyfluorescein diacetate (cFDA)) at 16°C, 12°C, 4°C, and 22°C (control). Cells with an intact membrane retained the dye and were identified as viable. The membrane lipid phase transition (LPT) temperature curve was determined with a Fourier transform infrared (FTIR) spectrometer connected to an FTIR microscope. The LPT center, T_m, was determined by statistical analysis. The LPT and T_m were also assessed in fresh spermatozoa and spermatozoa incubated with egg yolk or egg‐phosphatidylcholine (EPC) liposomes at 16°C, 12°C, 4°C, and 26°C (control). The results show that the membrane integrity of spermatozoa incubated at 16°C, 12°C, and 4°C decreased by 39%, 62%, and 67%, respectively, compared to the control. The LPT temperatures were between room temperature (26°C) and 10°C, with T_m at 14–16°C. The T_m for sperm incubated with liposomes or egg‐yolk extender was below the measured range (2°C). Chilling sensitivity was found at a wide range of temperatures and transition temperatures, suggesting the presence of a wide variety of fatty acids (FAs) in the membrane with a high ratio of saturated‐to‐polyunsaturated FAs. Here we show that the protection afforded by the presence of egg yolk or liposomes in the extender is accomplished by shifting the T_m to below the 4°C point at which chilled semen is maintained for transport, or the point at which fast freezing begins to minimize cellular damage. Zoo Biol 0:1–13, 2005. © 2005 Wiley‐Liss, Inc.     

The role of stearate attachment to the hemagglutinin‐esterase‐fusion glycoprotein HEF of influenza C virus

The only spike of influenza C virus, the hemagglutinin‐esterase‐fusion glycoprotein (HEF) combines receptor binding, receptor hydrolysis and membrane fusion activities. Like other hemagglutinating glycoproteins of influenza viruses HEF is S‐acylated, but only with stearic acid at a single cysteine located at the cytosol‐facing end of the transmembrane region. Previous studies established the essential role of S‐acylation of hemagglutinin for replication of influenza A and B virus by affecting budding and/or membrane fusion, but the function of acylation of HEF was hitherto not investigated. Using reverse genetics we rescued a virus containing non‐stearoylated HEF, which was stable during serial passage and showed no competitive fitness defect, but the growth rate of the mutant virus was reduced by one log. Deacylation of HEF does neither affect the kinetics of its plasma membrane transport nor the protein composition of virus particles. Cryo‐electron microscopy showed that the shape of viral particles and the hexagonal array of spikes typical for influenza C virus were not influenced by this mutation indicating that virus budding was not disturbed. However, the extent and kinetics of haemolysis were reduced in mutant virus at 37°C, but not at 33°C, the optimal temperature for virus growth, suggesting that non‐acylated HEF has a defect in membrane fusion under suboptimal conditions.     

Ultrastructural analysis of the membrane insertion of domain 3 of streptolysin O

Streptolysin O (SLO) is a membrane-damaging toxic protein produced by group A streptococci. We performed an ultrastructural analysis of pore formation and the mechanism of hemolysis by SLO, using a mutant form of SLO [SLO(C/A)-SS] and native SLO. SLO(C/A)-SS was unable to penetrate the erythrocyte membrane as a consequence of immobilization that was due to a disulfide bond between domains. The SLO(C/A)-SS molecules that bound to membranes formed numerous single-layered ring-shaped structures that did not result in pores on the membranes. These structures were similar to the structures formed by native SLO at 0 degrees C. After treatment with dithiothreitol, SLO(C/A)-SS that had bound to membranes formed double-layered rings with pores on the membranes, as does native SLO at room temperature. Our morphological evidence demonstrates that an increase in temperature is necessary for the occurrence of conformational changes and for the formation of double-layered rings after the insertion of domain 3 into the host cell membrane. On the basis of a model of the oligomeric structure of SLO, we propose some new details of the mechanism of hemolysis by SLO.