Kinetics of Influenza Virus Fusion with the Endosomal and Plasma Membranes of Cultured Cells. Effect of Temperature

We performed a detailed kinetic analysis of influenza virus fusion with the endosomal and plasma membranes of Madin Darby canine kidney (MDCK) cells and provided a comparison of the kinetic parameters obtained for both cases at 20°C and 37°C. Using our mass action kinetic model, we determined that the fusion rate constant, f, for influenza virus with the endosomal membrane was 0.02 s^–1 at 37°C and 0.0035 s^–1 at 20°C. The analysis of the fusion kinetics of influenza virus with the plasma membrane yielded that the fusion rate constants were close to those deduced with the endosomal membrane. The systematic kinetic analysis performed in this study provides for the first time a biophysical support for studies on influenza virus-cell fusion where the acidic endosomal internal environment is simulated artificially by lowering the pH of the medium. Abbreviations: C₁₂E₈, octaethylene glycol dodecyl ether; HA, hemagglutinin; MDCK cells, Madin Darby canine kidney cells; R18, octadecylrhodamine B chloride.     

A New Water-Soluble Analogue of the Fusion Peptide of Influenza Virus Hemagglutinin: Synthesis and Properties

A water-soluble analogue F32 of the fusion peptide from influenza virus hemagglutinin was synthesized. It consisted of 32 aa residues and retained the ability to interact with lipid membranes; its N-terminal sequence 1–24 coincided with that of the fusion protein from hemagglutinin (strain A/PR/8/34), whereas residues 25–32 (GGGKKKKK) provided its solubility in water. The peptide induced the conductivity fluctuations in planar bilayer lipid membranes characteristic of active fusion peptides. Conditions were found using CD spectroscopy under which the structure of F32 inside detergent micelles, where it can be studied by high-resolution ¹H NMR spectroscopy, is close to the structure of the peptide during its interaction with phospholipid liposomes.     

Conformational transitions of membrane-bound HIV-1 fusion peptide

The human immunodeficiency virus type-1 (HIV-1) fusion peptide (FP) functions as a non-constitutive membrane anchor that translocates into membranes during envelope glycoprotein-induced fusion. Here, by means of infrared spectroscopy (IR) and of various bilayer-perturbation assays, we describe the peptide conformations that are accessible to its membrane-bound state and the transitions occurring between them. The peptide underwent a conformational transition from a predominantly α-helical structure to extended β-type strands by increasing peptide concentration in 1-palmitoyl-2-oleoylphosphatidylglycerol (POPG) vesicles. A comparable transition was observed at a fixed 1:100 peptide-to-lipid ratio when calcium was added to vesicles containing prebound α-helical peptide. Cation binding induced an increase in the amount of H-bonded carbonyls within the interfacial region of POPG. Calcium-promoted α→β conversion in membranes correlated with the closure of preformed lytic pores and took place in dispersed (nonaggregated) vesicles doped with poly(ethylene glycol)-lipid conjugates, showing that the conformational transition was independent of vesicle aggregation. We conclude that the target membrane conditions modulate the eventual structure adopted by the HIV-1 FP. Conformational polymorphism of the inserted peptide may contribute to the flexibility of the fusogenic complex during the fusion reaction cycle, and/or may be related to target membrane perturbation at the fusion locus.     

Interaction of Horse Heart Cytochrome c with Lipid Bilayer Membranes: Effects on Redox Potentials

Cyclic voltammetry has been used to study the effects of interactions between horse cytochrome c and solid-supported planar lipid membranes, comprised of either egg phosphatidylcholine (PC) or PC plus 20 mol.% cardiolipin (CL), on the redox potential and the electrochemical electron transfer rate between the protein and a semiconductor electrode. Experiments were performed over a wide range of cytochrome c concentrations (0–440 M) at low (20 mM) and medium (160 mM) ionic strengths. Three types of electrochemical behavior were observed, which varied as a function of the experimental conditions. At very low cytochrome c concentration (0.1 M), and under conditions where electrostatic forces dominated the protein–lipid membrane interaction (i.e., low ionic strength with membranes containing CL), a redox potential (265 mV) and an electrochemical electron transfer rate constant (0.09s ^–1)were obtained which compare well with those measured in other laboratories using a variety of different chemical modifications of the working electrode. Two other electrochemical signals (not reported with chemically modified electrodes) were also observed to occur at higher cytochrome c concentrations with this membrane system, as well as with two other systems (membranes containing CL under medium ionic strength conditions, and PC only at low ionic strength). These involved positive shifts of the cytochrome c redox potential (by 40 and 60 mV) and large decreases in the electron transfer rate (to 0.03 and 0.003 s^–1). The observations can be rationalized in terms of a structural model of the cytochrome c–membrane interaction, in which association involves both electrostatic and hydrophobic forces and results in varying degrees of insertion of the protein into the hydrophobic interior of the membrane.     

Soluble Glycosaminoglycans Inhibit the Interaction of TAT−PTD with Lipid Vesicles

Several models have been proposed for translocation of cell-penetrating peptides across membranes, but no general consensus on the mechanism of this process has emerged. It was hypothesized that heparan sulfate on the cell surface may play a role. We used fluorescence spectroscopy to study the effect of three soluble glycosaminoglycans—heparan sulfate, low-molecular-weight heparin, and dermatan sulfate—on the interaction of the fluorescently labeled peptide TAT−PTD with negatively charged small unilamellar vesicles. We found that the presence of glycosaminoglycans results in an order-of-magnitude increase in the apparent dissociation constant K _d of the electrostatic component of the peptide/membrane interaction (from 0.13 to 2.6 mM). Thus, rather than aiding in the peptide’s penetration, soluble glycosaminoglycans competitively decrease TAT−PTD’s binding to the membrane, presumably by neutralizing its charge, and thereby attenuating electrostatic forces involved in the interaction. Our results, however, do not exclude a possible role of membrane-anchored glycosaminoglycans in the endocytotic transduction of CPPs across the cell membrane.     

Fluorescence Studies of Red Blood Cell Membranes from Individuals with Huntington''s Disease

Fluorescence spectroscopic methods were used to investigate and compare the properties of erythrocyte membranes from individuals with Huntington's Disease (HD) and from normal individuals. Erythrocyte ghosts were labeled with four different fluorescent probes: 1,6-diphenylhexatriene (DPH); 6-lauroyl-2-(dimethylamino)-naphthalene (Laurdan); 2-(4-maleimide anilino)-naphthalene-6-sulfonic acid (MIANS) and 5-(iodoacetamidoethyl)aminoaphthalene-1-sulfonic acid (IAEDANS). DPH is sensitive to the microviscosity of the membranes. Laurdan is highly sensitive to the polarity and relaxation time of its environment. MIANS and IAEDANS both react covalently with sulfhydryl groups in membrane proteins. Erythrocyte membranes were labeled separately with each of these four probes, and we measured the centers of gravity of the fluorescence emission, the fluorescence anisotropies, and the fluorescence lifetimes. In 10 separate experiments, including a total of 24 patients and 14 control individuals, we found no significant differences between the two groups for any of the probes or spectral parameters. These results do not support the existence of a "generalized membrane defect" in individuals with HD.     

A GxxxG-like Motif within HIV-1 Fusion Peptide Is Critical to Its Immunosuppressant Activity,Structure, and Interaction with the Transmembrane Domain of the T-cell Receptor

To thrive in the human body, HIV fuses to its target cell and evades the immune response via several mechanisms. The fusion cascade is initiated by the fusion peptide (FP), which is located at the N-terminal of gp41, the transmembrane protein of HIV. Recently, it has been shown that the HIV-1 FP, particularly its 5–13 amino acid region (FP_5–13), suppresses T-cell activation and interacts with the transmembrane domain (TMD) of the T-cell receptor (TCR) complex. Specific amino acid motifs often contribute to such interactions in TMDs of membrane proteins. Using bioinformatics and experimental studies, we report on a GxxxG-like motif (AxxxG), which is conserved in the FP throughout different clades and strains of HIV-1. Biological activity studies and FTIR spectroscopy revealed that HIV FP_5–13-derived peptides, in which the motif was altered either by randomization or by a single amino acid shift, lost their immunosuppressive activity concomitant with a loss of the β-sheet structure in a membranous environment. Furthermore, fluorescence studies revealed that the inactive mutants lost their ability to interact with their target site, namely, the TMD of TCRα, designated CP. Importantly, lipotechoic acid activated macrophages (lacking TCR) were not affected by FP, further demonstrating the specificity of the immunosuppressant activity of CP. Finally, although the AxxxG WT and the GxxxG analog both associated with the CP and immunosuppressed T-cells, the AxxxG WT but not the GxxxG analog induced lipid mixing. Overall, the data support an important role for the AxxxG motif in the function of FP and might explain the natural selection of the AxxxG motif rather than the classical GxxxG motif in FP.     

Effect of N-acyl-phosphatidylethanolamine on the Membrane Fusion Between Sendai Virus and Liposome

We have compared the properties of two N-acyl derivatives of dilauryl phosphatidylethanolamine on lipid polymorphism, vesicle leakage and Sendai virus fusion. The derivatives contained either an N-lauroyl group (NLPE) or an N-acetyl group (NAcPE). Only the NAcPE markedly affected the bilayer to hexagonal transition temperature of dielaidoyl phosphatidylethanolamine, shifting it to higher values. In contrast the NLPE slightly lowered this phase transition temperature. The two lipids also have opposite effects on leakage from small unilamellar vesicles of egg phosphatidylcholine. The NLPE inhibits leakage, while the NAcPE promotes it. This vesicle stabilizing effect of NLPE against leakage is not manifested in alterations of rates or extents of Sendai virus fusion to liposomes of egg phosphatidylethanolamine plus 2% ganglioside G_D1a. The NLPE has no effect, while the NAcPE reduces the observed fusion, at least in part as a consequence of a reduction in the final extent of fusion. These results demonstrate that the bilayer stabilizing effects of NLPE do not result in a lower rate of viral fusion. Furthermore, these bilayer stabilizing effects against leakage are not solely a function of the lipid headgroup but also require a structure with three long acyl chains. The reduced leakage is not related to a loss in monolayer curvature strain.     

Fusion Peptide Interaction with Lipid Bilayer: Modeling with Monte Carlo Simulation and Continuum Electrostatics Calculation

Abstract

Conformation of 20-residue peptide E5, an analog of the fusion peptide of influenza virus hemagglutinin, was explored by Monte-Carlo technique starting with the fully buried in the membrane ideal α-helix. The lipid bilayer (of 30 Å width) together with surrounding water were modeled by the atomic solvation parameters. During the simulation, residues 2–18 of the peptide retained α-helical conformation, and the peptide was found to be partially immersed into the bilayer. In the resulting low-energy conformers, the N-terminus was buried inside the membrane, its position with respect to the bilayer surface (Z_NT) being varied from 2.5 to 7.5 Å, and the orientation of the helical axis relative to the membrane plane (Θ) – from 10 to 35°. The low-energy conformers (below -200kcal/mol) were clustered in the space (Z_NT, Θ) into 4 groups. To select low-energy states of the peptide compatible with NMR data, we calculated pKa values of E5 ionizable groups and compared them with the experimental values. It was shown that the best correlation coefficient (0.87) and rmsd (0.68 in pH units) were obtained for the group of states which is characterized by Θ = 15–19° and Z_NT = 3.5–4.5Å.     

纤维蛋白肽与低分子量尿激酶原融合蛋白的构建及性质

将人工合成的寡核苷酸片段进行定向连接后, 得到编码纤维蛋白β链N端(β 15～42)多肽的基因片段及连接区片段(linker), 再与低分子量尿激酶原(scuPA-32k) cDNA分子进一步连接后, 得到了Fβ(15～42)/scuPA-32k的融合基因.在大肠杆菌中经过IPTG诱导表达, 经过变性及复性, Zn²⁺螯合层析及Sephacryl S200凝胶层析后, 目的蛋白被纯化.SDS-聚丙烯酰胺凝胶电泳(PAGE)显示为一条蛋白质纯化条带, 分子质量为35 ku. 经纤维蛋白平板法测定比活为87 000 U/mg.经纤溶酶活化后的融合蛋白与低分子量尿激酶相比,对显色底物S2444酶促动力学性质相似.同时Fβ(15～42)/scuPA-32k具有较高的纤维蛋白的亲和性并能抑制纤维蛋白凝块的形成.     

Secondary structure, phospholipid membrane interactions, and fusion activity of two glutamate-rich analogs of influenza hemagglutinin fusion peptide

Two synthetic mutants of influenza HA2 fusion peptide (residues 1-25), containing Glu on the polar (residues 4,8-E5(4,8)) or the hydrophobic (residues 3,7-E5(3,7)) face of the amphipathic helix, were synthesized and labeled with NBD at the N-terminus. Introduction of Glu residues into the fusion peptide leads to increased sensitivity of various biochemical properties to pH compared to the wild type. The E5 peptides showed a decrease of alpha-helix content and increase of beta-sheet structure. Lipid binding was diminished, but not abolished even at high pH. The E5 analogs penetrate the lipid bilayer less deeply than the wild type, especially at high pH. The N-terminal half of the peptide showed significant variation of the depth of the penetration into the lipid bilayer. Both E5 peptides were fusion active. The properties of E5(3,7) were more affected by the Glu substitution and showed greater variation with pH than E5(4,8).     

血纤蛋白粘附肽与低分子量单链尿激酶融合产物活性分析

人工合成了血纤蛋白粘附肽基因,构建了粘附肽与低分子量单链尿激酶ｃＤＮＡ的融合基因,在大肠杆菌中表达了融合基因。融合基因表达产物的抗原性和天然尿激酶相同,并具有尿激酶的溶纤活性和粘附肽的抗纤维蛋白单体聚合的功能。     

NMR Structure of a Viral Peptide Inserted in Artificial Membranes: A VIEW ON THE EARLY STEPS OF THE BIRNAVIRUS ENTRY PROCESS*

Nonenveloped virus must penetrate the cellular membrane to access the cytoplasm without the benefit of membrane fusion. For birnavirus, one of the peptides present in the virus capsid, pep46 for infectious bursal disease virus, is able to induce pores into membranes as an intermediate step of the birnavirus-penetration pathway. Using osmotic protection experiments, we demonstrate here that pep46 and its pore-forming N-terminal moiety (pep22) form pores of different diameters, 5–8 and 2–4 nm, respectively, showing that both pep46 moieties participate to pore formation. The solution structures of pep46, pep22, and pep24 (the pep46 C-terminal moiety) in different hydrophobic environments and micelles determined by ¹H NMR studies provide structural insights of the pep46 domain interaction. In CDCl₃/CD₃OH mixture and in dodecylphosphocholine micelles, the N-terminal domain of pep46 is structured in a long kinked helix, although the C terminus is structured in one or two helices depending upon the solvents used. We also show that the folding and the proline isomerization status of pep46 depend on the type of hydrophobic environment. NMR spectroscopy with labeled phospholipid micelles, differential scanning calorimetry, and plasmon waveguide resonance studies show the peptides lie parallel to the lipid-water interface, perturbing the fatty acid chain packing. All these data lead to a model in which the two domains of pep46 interact with the membrane to form pores.     

Diphtheria Toxin Forms Pores of Different Sizes Depending on Its Concentration in Membranes: Probable Relationship to Oligomerization

Diphtheria toxin forms pores in biological and model membranes upon exposure to low pH. These pores may play a critical role in the translocation of the A chain of the toxin into the cytoplasm. The effect of protein concentration on diphtheria toxin pore formation in model membrane systems was assayed by using a new fluorescence quenching method. In this method, the movement of Cascade Blue labeled dextrans of various sizes across membranes is detected by antibodies which quench Cascade Blue fluorescence. It was found that at low pH the toxin makes pores in phosphatidylcholine/phosphatidylglycerol vesicles with a size that depends on protein concentration. At the lowest toxin concentrations only the entrapped free fluorophore (MW 538) could be released from model membranes. At intermediate toxin concentrations, a 3 kD dextran could be released. At the highest toxin concentration, a 10 kD dextran could be released, but not a 70 kD dextran. Similar pore properties were found using vesicles lacking phosphatidylglycerol or containing 30% cholesterol. However, larger pores formed at lower protein concentrations in the presence of cholesterol. The dependence of pore size on toxin concentration suggests that toxin oligomerization regulates pore size. This behavior may explain some of the conflicting data on the size of the pores formed by diphtheria toxin. The formation of oligomers by membrane-inserted toxin is consistent with the results of chemical crosslinking and measurements of the self-quenching of rhodamine-labeled toxin. Based on these experiments we propose diphtheria toxin forms oligomers with a variable stoichiometry, and that pore size depends on the oligomerization state. Reasons why oligomerization could assist proper membrane insertion of the toxin and other proteins that convert from soluble to membrane-inserted states are discussed. Received: 10 March 1999/Revised: 22 June 1999     

Neuroblastoma Cell Membranes: Specificity for Cell Fusion Mediated by a Temperature-Sensitive Mutant of Vesicular Stomatitis Virus

Abstract: Temperature-sensitive mutant G3 1 of vesicular stomatitis virus induces mouse neuroblastoma N-18 cells to fuse during infections that are nonpermissive for virus replication, but BHK-21 cells do not undergo the viral glycoprotein-mediated cell fusion. The viral glycoprotein was expressed at the cell surface of both N-18 and BHK-21 cells; therefore, the host cell specificity did not stem from an absence of the viral glycoprotein at the surface of BHK-21 cells. Cell fusion readily occurred between infected and uninfected N-18 cells in mixed cultures, demonstrating that the viral glycoprotein was interacting with an uninfected cell for the initial cell-cell interaction of the cell fusion. Mixing infected BHK-21 cells with uninfected N-18 cells resulted in cell fusion initiated by BHK-21 cell-synthesized viral glycoprotein, but 88% of the nucleiin polykaryocytes were N-18 nuclei. The N-18 cell fusion specificity was readily apparent when infected N-18 cells were mixed with uninfected BHK-21 cells; 98% of the nuclei in polykaryocytes were N-18 nuclei. Similar results also were obtained with mixed cultures of N-18 cells and primary astroglial cells. Thus, the viral glycoprotein synthesized in any of the cell types could initiate cell fusion, but the properties of plasma membranes of neuroblastoma cells appeared to be much more suitable for cell-cell fusion.     

带有穿膜结构域的转录因子蛋白Oct4和Sox2的融合表达

目的:克隆、表达及纯化带有穿膜结构域的转录因子蛋白Oct4和Sox2。方法:根据GenBank中的Oct4和Sox2基因序列,在其3’端引入穿膜结构域11R,并在其两端引入NdeⅠ和XhoⅠ酶切位点,进行全基因合成;将目的基因克隆至pET41a载体,进行酶切鉴定及测序;将所获阳性重组质粒转化感受态大肠杆菌BL21(DE3),经IPTG诱导表达后,对表达产物进行Western印迹鉴定;最后用Ni-NTA亲和层析柱对所获目的蛋白进行纯化。结果:质粒酶切鉴定结果表明带有目的基因的重组质粒构建成功;SDS-PAGE结果显示有相对分子质量约42×103和38×103的特异性蛋白表达条带,经Western印迹证实为目的蛋白;用Ni-NTA亲和层析柱纯化后,得到均一的Oct4和Sox2目的蛋白。结论:得到带有穿膜结构域的转录因子融合蛋白Oct4和Sox2,为今后安全开展诱导性多能干细胞研究奠定了基础。     

Epstein Barr Virus (EBV) Fusion with Hepathoma Cell Line (Li7A): A Possibility to Use Ebv Virosohes for Drugs Delivery to Liver Cells

Abstract

EBV a causative agent of mononucleosis and several human cancers, infects cell via complement receptor type 2 (CR2). Expression of this receptor is restricted to B lymphocytes, some epithelial cells and immature thymocytes, expression of CR2 like proteins has been also found on T cells. In the present report we identified the presence on the membrane of Li7A cells of a novel EBV receptor distinct from CR2 capable to trigger fusion with EBV virions with a kinetics faster than that found with lymphoblastoid cells (Raji).     

The Interaction of DMSO with Model Membranes. II. Direct Evidence of DMSO Binding to Membranes: An NMR Study

Abstract

Modern techniques in nuclear magnetic resonance (NMR) allow investigators to probe molecular interactions with greater sensitivity and speed than ever before. Exploiting the nuclear Overhauser effect (NOE), the intermolecular interactions between dimethylsulfoxide (DMSO) and lipid vesicles were investigated. The DMSO methyl proton signal varies with experimental mixing time suggesting the system behaves in a manner similar to that of a ligand weakly binding to a macromolecule.     

Biological Activity of Human Granulocyte-Macrophage Colony Stimulating Factor is Maintained in a Fusion with Seed Glutelin Peptide

Human granulocyte-macrophage colony stimulating factor (GM-CSF), a cytokine with many applications in clinical medicine, was produced specifically in the seeds of transgenic tobacco plants. Two rice endosperm-specific glutelin promoters of different size and sequence, Gt1 and Gt3, were used to direct expression. Also in the Gt3 construct, the GM-CSF coding region was in fusion with the first 24 nucleotides of the mature rice glutelin sequence at its 5' end. With the Gt1 construct plants, seed extracts contained the recombinant human GM-CSF protein up to a level of 0.03% of total soluble protein. Transgenic seed extracts actively stimulated the growth of human TF-1 cells suggesting that the seed-produced GM-CSF alone and in fusion with the rice glutelin peptide was stable and biologically active. Furthermore, native tobacco seed extracts inhibited the activity of E. coli-derived GM-CSF in this cytokine-dependent cell line. The seeds of F1 generation plants retained the biological activity of human GM-CSF protein indicating that the human coding sequence was stably inherited. The feasibility of oral delivery of such stable seed-produced cytokines is discussed.