Subunit composition of the membrane glycoprotein complex of Semliki Forest virus

The quaternary structure of the membrane glycoproteins E1, E2 and E3 of Semliki Forest virus has been determined in intact virus and in the protein complexes obtained after Triton X100 solubilization. Intact and solubilized virus were treated with a cleavable cross-linking reagent and the covalently cross-linked glycoprotein complexes were isolated and characterized using antibodies specific for the E1 and E2 membrane glycoproteins. The isolation and characterization procedure was done in a low sodium dodecyl sulphate concentration which prevented non-covalent association between glycoprotein species, but did not abolish antigen-antibody binding.The major glycoprotein complex seen after cross-linking of either intact or Triton X100 solubilized virus was an approximately 100,000 molecular weight species composed of E1-E2 heterodimers only. These findings show that E1 and E2 form a complex in the virus and that this complex is retained after solubilization with Triton X100. The smallest membrane glycoprotein E3 was not cross-linked to the other proteins and was therefore lost in the isolation procedure. However, the presence of E3 together with E1 and E2 in complexes obtained after Triton X100 solubilization of intact virus suggests that an E1-E2-E3 trimer is present in the virus. It is likely that this trimer forms the spike-like structures seen on the surface of the virus.We have observed that antibody specific for one component of the virus glycoprotein complex can induce rearrangement of uncross-linked complexes in Triton X100 solubilized form. This fact should be considered when using specific antibody for characterization of protein complexes.     

Studies on the amphipathic nature of the membrane proteins in Semliki Forest virus

The membrane glycoproteins E₁ and E₂ of Semliki Forest virus form spikes protruding from the external surface of the virion. They have been cleaved off by thermolysin or subtilisin leaving peptide segments in the membrane of the spikeless virus particles with a molecular weight of about 5000 enriched in hydrophobic amino acids. These peptides are soluble in chloroform/methanol and are solubilized into mixed micelles with Triton X100, with sodium dodecyl sulphate and with sodium deoxycholate. Peptide mapping studies show that each membrane glycoprotein has its own lipophilic peptide segment which presumably serves to anchor these proteins to the lipid membrane. The hydrophobic segments of the glycoproteins appear to be shielded from proteolysis not only by the lipids in the intact membrane but also by Triton X100 in the detergent-protein complexes obtained when this detergent is used to remove the lipid and solubilize the proteins.     

Semliki Forest virus membrane proteins, preparation and characterization of spike complexes soluble in detergent-free medium

After Triton X-100 delipidation and subsequent Triton X-100 removal in a sucrose gradient the membrane protein spikes of Semliki Forest virus remained soluble in aqueous buffers. It was shown they were present as octameric complexes with a molecular weight of 95 · 10⁴ and that they contain less than 4% lipid and detergent by weight. In electron microscopy after negative staining they appeared as “rosette”-shaped particles. Part of the protein could also be found associated in ordered paracrystalline arrays.     

Solubilization of the semliki forest virus membrane with sodium deoxycholate

The effects of increasing concentrations of sodium deoxycholate on Semliki Forest virus have been studied. Sodium deoxycholate begins to bind to the virus at less than 0.1 mM free equilibrium concentration and causes lysis of the viral membrane at $\text{0.9 ± 0.1}\text{mM}$ free equilibrium concentration when $\text{2.2 ± 0.2 ß 10}{}^3\text{mol}$ of sodium deoxycholate are bound per mol of virus. Liberation of proteins from the membrane begins at $\text{1.5 ± 0.1}\text{mM}$ sodium deoxycholate and the proteins released are virtually free from phospholipid above 2.0 mM sodium deoxycholate. The overall mechanism of sodium deoxycholate solubilization of the viral membrane resembles that of Triton X-100 and sodium dodecyl sulphate except that with sodium deoxycholate the various stages of membrane disruption occur at about 10-fold higher equilibrium free detergent concentrations. At sodium deoxycholate concentrations higher than 2.3 mM the viral spike glycoproteins can be separated by sucrose gradient centrifugation or gel filtration into constituent polypeptides E1, E2 and E3. E1 carries the haemagglutinating activity of the virus.     

Solubilization of the Semliki Forest virus membrane with sodium deoxycholate.

The effects of increasing concentrations of sodium deoxycholate on Semliki Forest have been studied. Sodium deoxycholate begins to bind to the virus at less than 0.1 mM free equilibrium concentration and causes lysis of the viral membrane at 0.9 +/- 0.1 mM free equilibrium concentration when 2.2 +/- 0.2 - 103 mol of sodium deoxycholate are bound per mol of virus. Liberation of proteins from the membrane begins at 1.5 +/- 0.1 mM sodium deoxycholate and the proteins released are virtually free from phospholipid above 2.0 mM sodium deoxycholate. The overall mechanism of sodium deoxycholate solubilization of the viral membrane resembles that of Triton X-100 and sodium dodecyl sulphate except that with sodium deoxycholate the various stages of membrane disruption occur at about 10-fold higher equilibrium free detergent concentrations. At sodium deoxycholate concentrations higher than 2.3 mM the viral spike glycoproteins can be separated by sucrose gradient centrifugation or gel filtration into constituent polypeptides E1, E2 and E3. E1 carries the haemagglutinating activity of the virus.     

Inhibition of cellular protein synthesis by simultaneous pretreatment of host cells with fowl plague virus and actinomycin D: a method for studying early protein synthesis of several RNA viruses.

A method is described for analysis of viral protein synthesis early after infection when minute amounts of viral proteins are effectively concealed by large amounts of produced host-specific proteins. The method is superior to a radioimmune assay, since all virus-induced proteins can be measured independent of their immunological reactivity. Host-specific protein synthesis can be suppressed by infection with fowl plague virus. Addition of actinomycin C 1.25 h postinfection does not prevent this suppression, but it does block effectively the formation of fowl plague virus-specific proteins. Such cells synthesize only small amounts of cellular proteins, as revealed by polyacrylamide electrophoresis. They can be superinfected with several different enveloped viruses, however, without significant diminution of virus yeilds. In pretreated cells the eclipse is shortened for Semliki Forest virus, Sindbis virus, and vesicular stomatitis virus, but prolonged for Newcastle disease virus. The onset of protein synthesis, specific for the superinfecting virus, could be clearly demonstrated within 1 h after superinfection. At this time, in cells superinfected with Semliki Forest virus, great amounts of NSP 75 (nonstructural protein; molecular weight, 75 X 10(3)) and reduced amounts of the core protein C could be deomonstrated. The precursor glycoprotein NSP 68 is followed by a new polypeptide, NSP 65: three proteins with molecular weights exceeding 100 X 10(3) were observed which are missing later in the infectious cycle. Similar results were obtained after superinfection with Sindbis virus. The formation of a new polypeptide with a molecular weight of about 80 X 10(3) was detected. After superinfection with vesicular stomatis virus or Newcastle disease virus the formation of new proteins, characteristic for the early stage of infeciton, was not observed.     

HETEROGENEITY OF ACETYLCHOLINESTERASE IN NEUROBLASTOMA

Abstract– Multiple forms of acetylcholine hydrolyzing activity have been observed in Triton X-100 treated homogenates of mouse neuroblastoma cells. All these forms appear to be the true acetylcholinesterase, AChE (EC 3.1.17): they are substrate-inhibited; hydrolyze acetylcholine > acetyl-β-methylcholine ≫ butrylcholine and are preferentially inhibited by specific AChE inhibitors. Almost all of the cell AChE activity is membrane associated, but readily 'solubilized' by Triton X-100 and as such appears free of membrane contamination. With the aid of affinity chromatography the 'solubilized' neuroblastoma AChE has been partially purified (490-fold) to a specific activity of 34,300 nmol/min/mg protein.
Four active neuroblastoma AChE species appear upon acrylamide gel electrophoresis (with MWs of 64,000; 116,000; 186,000 and 284,000) while three species (4S, 6S and 9.6S) have been found upon sucrose gradient sedimentation analysis. We have determined that the 4S form migrates on acrylamide as the 116,000 MW species and the 9.6S form contains, in equal amounts, the 186,000 and 284,000 MW acrylamide species. Numerous active AChE forms are seen on Sepharose 6B chromatography. From comparing the crude, 4S, 9.6S and partially purified AChEs on acrylamide gels, sucrose gradients and Sepharose, mouse neuroblastoma appears to contain active AChE units which are capable of multiple types of dissociation and reassociation. An attempt is made to correlate all the observed AChE forms as well as relate this data to that known about AChE obtained from other sources.     

Expression of Semliki Forest virus E1 protein in Escherichia coli. Low pH-induced pore formation

Exposure of Semliki Forest virus 1 to mildly acidic conditions results in conformational changes of the viral spike proteins, which in turn leads to a pore formation across its membrane. The ability to form a pore has been ascribed to the ectodomain of the Semliki Forest virus (SFV) E1 spike protein. To elucidate whether the E1 protein per se is sufficient for low pH-dependent pore formation, we expressed E1 in Escherichia coli in an inducible manner using the pET11c expression system. The data obtained clearly showed that the E1 protein was expressed in the bacterial cell membrane and that exposure of E. coli expressing the SFV E1 protein to low pH (<6.2) resulted in a permeability change of the membrane. Thus, we conclude that the E1 protein of SFV per se is sufficient to promote pore formation under mildly acidic conditions.     

Monomeric state of S100P protein: Experimental and molecular dynamics study

S100 proteins constitute a large subfamily of the EF-hand superfamily of calcium binding proteins. They possess one classical EF-hand Ca²⁺-binding domain and an atypical EF-hand domain. Most of the S100 proteins form stable symmetric homodimers. An analysis of literature data on S100 proteins showed that their physiological concentrations could be much lower than dissociation constants of their dimeric forms. It means that just monomeric forms of these proteins are important for their functioning. In the present work, thermal denaturation of apo-S100P protein monitored by intrinsic tyrosine fluorescence has been studied at various protein concentrations within the region from 0.04–10 μM. A transition from the dimeric to monomeric form results in a decrease in protein thermal stability shifting the mid-transition temperature from 85 to 75 °C. Monomeric S100P immobilized on the surface of a sensor chip of a surface plasmon resonance instrument forms calcium dependent 1 to 1 complexes with human interleukin-11 (equilibrium dissociation constant 1.2 nM). In contrast, immobilized interleukin-11 binds two molecules of dimeric S100P with dissociation constants of 32 nM and 288 nM. Since effective dissociation constant of dimeric S100P protein is very low (0.5 μM as evaluated from our data) the sensitivity of the existing physical methods does not allow carrying out a detailed study of S100P monomer properties. For this reason, we have used molecular dynamics methods to evaluate structural changes in S100P upon its transition from the dimeric to monomeric state. 80-ns molecular dynamics simulations of kinetics of formation of S100P, S100B and S100A11 monomers from the corresponding dimers have been carried out. It was found that during the transition from the homo-dimer to monomer form, the three S100 monomer structures undergo the following changes: (1) the helices in the four-helix bundles within each monomer rotate in order to shield the exposed non-polar residues; (2) almost all lost contacts at the dimer interface are substituted with equivalent and newly formed interactions inside each monomer, and new stabilizing interactions are formed; and (3) all monomers recreate functional hydrophobic cores. The results of the present study show that both dimeric and monomeric forms of S100 proteins can be functional.     

Characterization of a small, nonstructural viral polypeptide present late during infection of BHK cells by Semliki Forest virus.

BHK cells, late in infection with Semliki Forest virus, were found to contain a small virus-specific polypeptide not found in the mature virion. This polypeptide had an apparent molecular weight of 6,000 and is referred to here as the 6K protein. No [2-3H]mannose was incorporated into 6K, and hence it does not appear to be a glycoprotein. This protein appears to be a primary translation product of the subgenomic 26S mRNA, which encodes the viral structural proteins. The genes encoding the viral structural proteins are arranged on the message in the order of 5'-C-E3-E2-E1-3'. We have found that the gene coding for 6K is located to the 3' side of the gene encoding E2. Subcellular fractionation of pulse-labeled cells infected with Semliki Forest virus demonstrated that 6K, like the viral glycoproteins p62 and E1, was present predominantly in the rough microsomal membrane fraction. 6K appears to be analogous, therefore, to the nonstructural 4.2K protein present in cells infected with Sindbis virus.     

Fatty Chains of Different Lipid Classes of Semliki Forest Virus and Host Cell Membranes

Semliki Forest virus was grown in BHK-21 cells. The major classes of phospho-and glycolipids of the virus were analyzed for the compositions of fatty acids, aldehydes, and sphingosine bases, and the major glycerophospholipids were analyzed for the relative proportions of alkenyl-acyl, alkyl-acyl, and diacyl forms. All viral lipid classes proved to be mixtures of several molecular species. Each class contained a characteristic mixture of fatty chains, which was different in all other classes. All viral lipid classes resembled their counterparts of the host plasma membrane and also those of the endoplasmic reticulum. The gangliosides of the virus and the plasma membrane proved to be similar even at the level of individual molecular species. The number of certain lipid molecules in an average virion was less than the number of the protein molecules.     

The effect of colchicine and dibucaine on the morphogenesis of Semliki Forest virus

The effect of colchicine, Nocodazole, and dibucaine on the assembly of Semliki Forest virus was investigated. Colchicine, Nocodazole, and dibucaine reduced the production of extracellular virus by 75 to 90%. Lumicolchicine had no effect on virus growth. Other control experiments showed no effect by these drugs on the incorporation of [3H]leucine into material precipitated by trichloroacetic acid. Colchicine (100 micron) disrupted the microtubles of the baby hamster kidney cells (BHK-21), whereas dibucaine did not alter microtubule polymerization. The stage of virus assembly inhibited by colchicine and dibucaine was studied by experiments with [3H]-leucine or [35S]methionine. At various times after addition of one of these drugs, the incorporation of the labeled precursors into viral proteins associated with fractions enriched for endoplasmic reticulum or plasma membrane from the cell was evaluated. The results clearly show that the envelope and nucleocapsid proteins of the virus move to the plasma membrane of the cell where they accumulate. The studies strongly suggest that the cytoskeletal system is involved in the final stages of morphogenesis of Semliki Forest virus from the plasma membrane.     

Disruption of the quaternary structure of (Na+ + K+)-dependent adenosine triphosphatase by Triton X-100.

(Na⁺ + K⁺)-dependent adenosine triphosphatase (NaK ATPase) consists of two polypeptide chains, a large polypeptide with a molecular weight of about 100,000, and a sialoglycoprotein with a molecular weight of about 40,000. In the presence of Triton X-100 both polypeptides react to form high molecular weight aggregates with apparent molecular weights of 168,000, 200,000 and 260,000. These aggregates arise as a result of disulfide bond formation which results from the autooxidation of sulfhydryl groups on the two polypeptides of NaK ATPase. These data are discussed in light of studies aimed at determining the size and subunit structure of membrane proteins with Triton X-100.     

Detergent extraction of erythrocyte ghosts. Comparison of residues after cholate and Triton X-100 treatments.

1. Human erythrocyte ghosts were extracted with individual free and conjugated bile salts and, for comparison, with Triton X-100 under conditions approximating to physiological temperature, pH and tonicity. 2. Treatment with cholate, glycocholate, taurocholate, or with Triton X-100 gave lipid-depleted residues. These could still be seen as ghost-like profiles by phase contrast microscopy. Deopxycholate brought about complete membrane dissolutiom. 3. The cholate residue gave a trilamellar image by electron microscopy and in condensed form gave a smaller membrane repeat than untreated membranes. It had a polypeptide composition representing mainly integral proteins. 4. The Triton X-100 residue had a granular profile in the electron microscope and a polypeptide composition largely representing peripheral proteins.     

Activation of the Sendai virus fusion protein (f) involves a conformational change with exposure of a new hydrophobic region

The F protein of paramyxoviruses is actively involved in the induction of membrane fusion. This fusion may be between viral and cellular membranes, as in the initiation of infection or in virus-induced lysis of erythrocytes, or between the plasma membranes of different cells. The F protein is activated by proteolytic cleavage to yield two disulfide-linked polypeptides (F1 and F2); however, its mechanism of action is not clear. In the present study, the conformations of the inactive, uncleaved precursor of glycoprotein (F0), and the active, cleaved form (F1,2) have been compared. The UV circular dichroism spectra of the two forms of the F protein indicate that cleavage results in a conformational change. Detergent-binding studies by velocity sedimentation analysis of Triton X-100-protein complexes revealed an increase in exposed hydrophobic surface of the protein on cleavage. The inactive F0 bound an estimated 27 molecules of Triton X-100/F polypeptide; these molecules are presumably bound to the hydrophobic region of the glycoprotein that anchors the spike-like protein in the virus membrane and that is common to both forms of F. The active form, F1,2, bound 67 molecules of Triton X-100. This increase in the number of detergent binding sites upon F protein activation indicates the presence of a hydrophobic region that is peculiar to the active form, and that may be of functional significance in the membrane fusion reaction.     

The heterodimeric association between the membrane proteins of Semliki Forest virus changes its sensitivity to low pH during virus maturation.

The budding and the fusion processes of the enveloped animal virus Semliki Forest virus serve the purpose of transporting its nucleocapsid, containing its genome, from the cytoplasm of an infected cell into that of an uninfected one. We show here that, in the infected cell, the viral membrane (spike) proteins p62 and E1 are organized as heterodimers which are very resistant to dissociation in acidic conditions. In contrast, the mature form of the heterodimer, E2E1, which is found in the virus particle and which is generated by proteolytic processing of p62, is very prone to dissociate upon treatment with mildly acidic buffers. We discuss the possibility that this difference in behavior of the intracellular precursor form and the mature form of the spike protein complex represents an important regulatory mechanism for the processes involving membrane binding around the nucleocapsid during budding and membrane release from the nucleocapsid at the stage of virus fusion.     

Assembly of the semliki forest virus membrane glycoproteins in the membrane of the endoplasmic reticulum in vitro

A cell-free system has been constructed to study the mechanism by which a single messenger RNA directs the synthesis of proteins destined for two different cellular locations. The Semliki Forest virus (SFV) 26 S mRNA codes for the viral capsid protein (C protein) and the membrane proteins p62 and E1. The three virus proteins are read in this order from the messenger RNA using one initiation site. The C protein is left on the cytoplasmic side and the p62 and the El proteins are inserted into the endoplasmic reticulum membrane. Translation of 26 S mRNA in a HeLa cell-free system in the presence of microsomes from dog pancreas reproduced the segregation, and proteolytic processing and glycosylation observed in infected cells. The signal for membrane binding was in the amino-terminal end of p62. The results indicate that the membrane proteins become inserted in the nascent state. The cleavage between p62 and El was coupled to membrane insertion. If the membranes were added after a period corresponding to the synthesis of about 100 amino acids of the p62 protein, segregation, glycosylation and cleavage between p62 and E1 failed to occur.     

Two small virus-specific polypeptides are produced during infection with Sindbis virus.

We have identified and characterized two small virus-specific polypeptides which are produced during infection of cells with Sindbis virus, but which are not incorporated into the mature virion. The larger of these is a glycoprotein with an approximate molecular weight of 9,800 and is found predominantly in the medium of infected cells. Three independent lines of evidence demonstrate conclusively that this 9,800-dalton glycoprotein is produced during the proteolytic conversion of the precursor polypeptide, PE2, to the virion glycoprotein E2. This small glycoprotein is therefore analogous to the virion glycoprotein E3 of the very closely related alphavirus, Semliki Forest virus. The 9,800-dalton glycoprotein of Sindbis virus, unlike the E3 glycoprotein of Semliki Forest virus, is not, however, present in the viral particle. The other virus-specific polypeptide is 4,200 daltons in size, does not appear to be a glycoprotein, and is neither incorporated into the mature virus nor released into the culture medium. The gene for this small polypeptide is present in the viral 26S mRNA (the mRNA which encodes all the viral structural polypeptides) and appears to be located in the portion of the mRNA which encodes the two viral glycoproteins. The possibility that this 4,200-dalton polypeptide functions as a signal peptide during the synthesis of the viral membrane glycoproteins is discussed.     

Complete nucleotide sequence of the nonstructural protein genes of Semliki Forest virus.

The nucleotide sequence coding for the nonstructural proteins of Semliki Forest virus has been determined from cDNA clones. The total length of this region is 7381 nucleotides, it contains an open reading frame starting at position 86 and ending at an UAA stop codon at position 7379-7381. This open reading frame codes for a 2431 amino acids long polyprotein, from which the individual nonstructural proteins are formed by proteolytic processing steps, so that nsPl is 537, nsP2 798, nsP3 482 and nsP4 614 amino acids. In the closely related Sindbis and Middelburg viruses there is an opal stop codon (UGA) between the genes for nsP3 and nsP4. Interestingly, no stop codon is found in frame in this region of the Semliki Forest virus 42S RNA. In other aspects the amino acid sequence homology between Sindbis, Middelburg and Semliki Forest virus nonstructural proteins is highly significant.