Nucleic acid-dependent cross-linking of the nucleocapsid protein of Sindbis virus

The assembly of the alphavirus nucleocapsid core is a multistep event requiring the association of the nucleocapsid protein with nucleic acid and the subsequent oligomerization of capsid proteins into an assembled core particle. Although the mechanism of assembly has been investigated extensively both in vivo and in vitro, no intermediates in the core assembly pathway have been identified. Through the use of both truncated and mutant Sindbis virus nucleocapsid proteins and a variety of cross-linking reagents, a possible nucleic acid-protein assembly intermediate has been detected. The cross-linked species, a covalent dimer, has been detected only in the presence of nucleic acid and with capsid proteins capable of binding nucleic acid. Optimum nucleic acid-dependent cross-linking was seen at a protein-to-nucleic-acid ratio identical to that required for maximum binding of the capsid protein to nucleic acid. Identical results were observed when cross-linking in vitro assembled core particles of both Sindbis and Ross River viruses. Purified cross-linked dimers of truncated proteins and of mutant proteins that failed to assemble were found to incorporate into assembled core particles when present as minor components in assembly reactions, suggesting that the cross-linking traps an authentic intermediate in nucleocapsid core assembly. Endoproteinase Lys-C mapping of the position of the cross-link indicated that lysine 250 of one capsid protein was cross-linked to lysine 250 of an adjacent capsid protein. Examination of the position of the cross-link in relation to the existing model of the nucleocapsid core suggests that the cross-linked species is a cross-capsomere contact between a pentamer and hexamer at the quasi-threefold axis or is a cross-capsomere contact between hexamers at the threefold axis of the icosahedral core particle and suggests several possible assembly models involving a nucleic acid-bound dimer of capsid protein as an early step in the assembly pathway.     

Crystallization of Sindbis virus and its nucleocapsid.

Crystals of Sindbis virus, which contains a lipid-bilayer membrane, have been grown using polyethylene glycol. The space group is R32, a = b = 640 A, c = 1520 A. The crystals are highly mosaic, and recorded diffraction is therefore restricted to spacings of about 30 A. The crystals show that the packing of glycoproteins E1 and E2 in the icosahedral outer shell is sufficiently precise that it permits regular and repeated interactions between virus particles in the lattice. Crystals of Sindbis nucleocapsids have also been grown. The limited diffraction data are consistent with close packing of nucleocapsids 404 A in diameter.     

Actin-fragmin interactions as revealed by chemical cross-linking

A one to one complex of actin and fragmin (a capping protein from Physarum polycephalum plasmodia) was cross-linked with 1-ethyl-3-[3-(dimethylamino)propyl] carbodiimide. The cross-linking reaction generated two cross-linked products with slightly different molecular weights (88 000 and 90 000) as major species. They were cross-linked products of one actin and one fragmin. The cross-linking site of fragmin in the actin sequence was determined by peptide mappings [Sutoh, K. (1982) Biochemistry 21, 3654-3661] after partial chemical cleavages of cross-linked products with hydroxylamine. The results indicated that the N-terminal segment of actin spanning residues 1-12 participated in cross-linking with fragmin. The cross-linker used in this study covalently bridges lysine side chains and side chains of acidic residues when they are in direct contact. Therefore, it seems that acidic residues in the N-terminal segment of actin (Asp-1, Glu-2, Asp-3, Glu-4, and Asp-11), at least some of them, are in the binding site of fragmin. It has already been shown that the same acidic segment of actin is in the binding site of myosin or depactin (an actin-depolymerizing protein isolated from starfish oocytes). We suggest that the unusual amino acid sequence of the N-terminal segment of actin makes its N-terminal region a favorable anchoring site for various types of actin-binding proteins.     

Sindbis virus nucleocapsid assembly: RNA folding promotes capsid protein dimerization

In Sindbis virus, initiation of nucleocapsid core assembly begins with recognition of the encapsidation signal of the viral RNA genome by capsid protein. This nucleation event drives the recruitment of additional capsid proteins to fully encapsidate the genome, generating an icosahedral nucleocapsid core. The encapsidation signal of the Sindbis virus genomic RNA has previously been localized to a 132-nucleotide region of the genome within the coding region of the nsP1 protein, and the RNA-binding activity of the capsid was previously mapped to a central region of the capsid protein. It is unknown how capsid protein binding to encapsidation signal leads to ordered oligomerization of capsid protein and nucleocapsid core assembly. To address this question, we have developed a mobility shift assay to study this interaction. We have characterized a 32 amino acid peptide capable of recognizing the Sindbis virus encapsidation signal RNA. Using this peptide, we were able to observe a conformational change in the RNA induced by capsid protein binding. Binding is tight (K(d)(app) = 12 nM), and results in dimerization of the capsid peptide. Mutational analysis reveals that although almost every predicted secondary structure within the encapsidation signal is required for efficient protein binding, the identities of the bases within the helices and hairpin turns of the RNA do not need to be maintained. In contrast, two purine-rich loops are essential for binding. From these data, we have developed a model in which the encapsidation signal RNA adopts a highly folded structure and this folding process directs early events in nucleocapsid assembly.     

Form-determining functions in Sindbis virus nucleocapsids: nucleosomelike organization of the nucleocapsid.

Purified intact Sindbis virus nucleocapsids were treated at different pH values or with various concentrations of divalent cations, cation chelators, salt, or formamide. The resulting structures were examined by velocity sedimentation, electron microscopy, and protein-protein cross-linking. Changes in each of the test conditions led to alterations in the sedimentation profile of treated nucleocapsids. Appropriate concentrations of formamide or divalent cations generated beaded strandlike structures similar in morphology to those generated from adenovirus cores and nucleosomes. The capsid protein and RNA remained associated with each other at NaCl concentrations less than or equal to 1 M or after treatment of the structures with alkaline pH up to and including pH 10.7. Protein and RNA were dissociated by salt concentrations of greater than 1 M, suggesting that the arginine-rich, amino-terminal portion of the capsid protein is responsible for binding the RNA. Protein-protein cross-linking also indicated that the capsid proteins remained associated in small aggregates under some of the conditions that caused dissociation of the nucleocapsid and suggested the presence of more than one type of protein-protein interaction in the nucleocapsids. Collectively, these data suggest that, like histones and adenovirus core proteins, the Sindbis virus capsid protein serves to package segments of the genome into nucleoprotein beads which are capable of interacting with each other to form the nucleocapsid structure.     

Molecular links between the E2 envelope glycoprotein and nucleocapsid core in Sindbis virus

A three-dimensional reconstruction of Sindbis virus at 7.0 Å resolution presented here provides a detailed view of the virion structure and includes structural evidence for key interactions that occur between the capsid protein (CP) and transmembrane (TM) glycoproteins E1 and E2. Based on crystal structures of component proteins and homology modeling, we constructed a nearly complete, pseudo-atomic model of the virus. Notably, this includes identification of the 33-residue cytoplasmic domain of E2 (cdE2), which follows a path from the E2 TM helix to the CP where it enters and exits the CP hydrophobic pocket and then folds back to contact the viral membrane. Modeling analysis identified three major contact regions between cdE2 and CP, and the roles of specific residues were probed by molecular genetics. This identified R393 and E395 of cdE2 and Y162 and K252 of CP as critical for virus assembly. The N-termini of the CPs form a contiguous network that interconnects 12 pentameric and 30 hexameric CP capsomers. A single glycoprotein spike cross-links three neighboring CP capsomers as might occur during initiation of virus budding.     

Conformational changes in Sindbis virus induced by decreased pH are revealed by small-angle neutron scattering

Alphaviruses, such as Sindbis virus, undergo dramatic changes in three-dimensional structure upon exposure to low pH, and such exposure can establish conditions allowing fusion of the virus membrane with a cell plasma membrane upon return to neutral pH. While exposure to low pH is not required for entry of Sindbis virus into vertebrate or invertebrate cells, the conformational changes occurring at low pH may mimic those occurring upon virus-receptor interaction. Here, we employed small-angle neutron scattering with contrast variation to probe how the structure of a mammalian-grown Sindbis virus responds to moderately acidic pH. Several changes took place throughout the virion structure when the pH decreased from 7.2 to 6.4. Specifically, the RNA in the virion core underwent a conformational change. Additionally, the protein was redistributed. A significant amount of protein moved from the layer containing the lipid bilayer to the exterior of the virion. The results improve our understanding of the pH-driven alteration of Sindbis virus structure.     

Interactions of the cytoplasmic domain of Sindbis virus E2 with nucleocapsid cores promote alphavirus budding

Alphavirus budding from the plasma membrane occurs through the specific interaction of the nucleocapsid core with the cytoplasmic domain of the E2 glycoprotein (cdE2). Structural studies of the Sindbis virus capsid protein (CP) have suggested that these critical interactions are mediated by the binding of cdE2 into a hydrophobic pocket in the CP. Several molecular genetic studies have implicated amino acids Y400 and L402 in cdE2 as important for the budding of alphaviruses. In this study, we characterized the role of cdE2 residues in structural polyprotein processing, glycoprotein transport, and capsid interactions. Along with hydrophobic residues, charged residues in the N terminus of cdE2 were critical for the effective interaction of cores with cdE2, a process required for virus budding. Mutations in the C-terminal signal sequence region of cdE2 affected E2 protein transport to the plasma membrane, while nonbudding mutants that were defective in cdE2-CP interaction accumulated E2 on the plasma membrane. The interaction of cdE2 with cytoplasmic cores purified from infected cells and in vitro-assembled core-like particles suggests that cdE2 interacts with assembled cores to mediate budding. We hypothesize that these cdE2 interactions induce a change in the organization of the nucleocapsid core upon binding leading to particle budding and priming of the nucleocapsid cores for disassembly that is required for virus infection.     

A disulfide-bridge bifunctional imidoester as a reversible cross-linking reagent.

A disulfide-bridged bifunctional imidoester, dimethyl 3, 3′ dithio-bispropionimidate (DTP) has been prepared and investigated as a reagent to introduce covalent cross-links in proteins that can subsequently be broken by mild reduction. Such reversible cross-links were shown to be introduced by DTP in the soluble subunit proteins aldolase and Concanavalin A. DTP was also used to modify human intact erythrocytes. Such modification rendered the erythrocytes resistant to hypotonic lysis; subsequent treatment with mercaptoethanol lysed the cells. After DTP-modification of the cells, the hemoglobin contained in them could still be reversibly oxygenated and deoxygenated.     

DNA-DNA cross-linking mediated by bifunctional [SalenAlIII]+ complex

The aluminum (III) complex [SalenAl(III)]Cl (1), (Salen=(R,R)-N,N'-bis[5-methyl-3-(4-methylpiperazinyl)-salicylidene]-1,2-diphenylethanediamine) has been synthesized and characterized by elemental analysis, FT-IR, (1)H and (13)C NMR measurements. The interaction of complex (1) with calf thymus (CT) DNA has been studied extensively by experimental techniques. Thermal denaturation study of DNA with (1) revealed the DeltaT(m) of 5+/-0.2 degrees C. Viscosity and steady-state fluorescence measurements showed that the complex cross-links DNA and the metal center is interacting with DNA during the cross-linking. Also, the phenyl ring in the complex may intercalate between the base pairs of the DNA during the cross-linking. Competitive binding study shows that the enhanced emission intensity of ethidium bromide (EB) in the presence of DNA was quenched by the addition of the metal complex indicating that it displaces EB from its binding site in DNA and the apparent binding constant has been estimated to be (2.8+/-0.2)x10(5) M(-1). Further, time-resolved fluorescence experiments confirm the binding of (1) with DNA and its cross-linking nature. Aluminum ions shown to precipitate DNA completely above the pH 6.0, but no such precipitation was observed with complex (1). The DNA-DNA cross-linking mediated by (1) is further confirmed by gel electrophoresis.     

Synthesis of dioxane-based antiviral agents and evaluation of their biological activities as inhibitors of Sindbis virus replication

The crystal structure of the Sindbis virus capsid protein contains one or two solvent-derived dioxane molecules in the hydrophobic binding pocket. A bis-dioxane antiviral agent was designed by linking the two dioxane molecules with a three-carbon chain having R,R connecting stereochemistry, and a stereospecific synthesis was performed. This resulted in an effective antiviral agent that inhibited Sindbis virus replication with an EC(50) of 14 microM. The synthesis proceeded through an intermediate (R)-2-hydroxymethyl-[1,4]dioxane, which unexpectedly proved to be a more effecting antiviral agent than the target compound, as evidenced by its EC(50) of 3.4 microM as an inhibitor of Sindbis virus replication. Both compounds were not cytotoxic in uninfected BHK cells at concentrations of 1mM.     

Chemical cross-linking of chick oviduct progesterone-receptor subunits by using a reversible bifunctional cross-linking agent.

Chick oviduct progesterone-receptor proteins were treated in cytosol with the reversible cross-linking reagent methyl 4-mercaptobutyrimidate. The product of the reaction was a 7S complex that could be detected and recovered after sucrose-density-gradient centrifugation in 0.3M-KCl. The extent of the reaction was dependent on the concentration of methyl 4-mercaptobutyrimidate and independent of the presence of bound hormone, since unlabelled receptors could also be cross-linked. The cross-linking reaction required conditions in which the cytosol 6S complex was preserved. A Stokes radius of 7.3 nm was determined by gel filtration in Agarose A-1.5 m in 0.3 M-KCl. The sedimentation coefficient, which was also determined in 0.3 M-KCl, allowed us to calculate a mol. wt. of 228,000. We were also able to cross-link partially purified receptor forms isolated by using an Agarose A-15 m column. On reduction with beta-mercaptoethanol the complex broke down to 4S monomers that were identified by DEAE-cellulose and phosphocellulose chromatography, adsorption on DNA-cellulose and gel filtration in an Agarose A-1.5 m column. In most cases, A and B receptor proteins were released in equivalent amounts, implying that the cross-linked form was an A-B complex.     

Molecular views of viral polyprotein processing revealed by the crystal structure of the hepatitis C virus bifunctional protease-helicase

BACKGROUND: Hepatitis C virus (HCV) currently infects approximately 3% of the world's population. HCV RNA is translated into a polyprotein that during maturation is cleaved into functional components. One component, nonstructural protein 3 (NS3), is a 631-residue bifunctional enzyme with protease and helicase activities. The NS3 serine protease processes the HCV polyprotein by both cis and trans mechanisms. The structural aspects of cis processing, the autoproteolysis step whereby the protease releases itself from the polyprotein, have not been characterized. The structural basis for inclusion of protease and helicase activities in a single polypeptide is also unknown. RESULTS: We report here the 2.5 A resolution structure of an engineered molecule containing the complete NS3 sequence and the protease activation domain of nonstructural protein 4A (NS4A) in a single polypeptide chain (single chain or scNS3-NS4A). In the molecule, the helicase and protease domains are segregated and connected by a single strand. The helicase necleoside triphosphate and RNA interaction sites are exposed to solvent. The protease active site of scNS3-NS4A is occupied by the NS3 C terminus, which is part of the helicase domain. Thus, the intramolecular complex shows one product of NS3-mediated cleavage at the NS3-NS4A junction of the HCV polyprotein bound at the protease active site. CONCLUSIONS: The scNS3-NS4A structure provides the first atomic view of polyprotein cis processing. Both local and global structural rearrangements follow the cis cleavage reaction, and large segments of the polyprotein can be folded prior to proteolytic processing. That the product complex of the cis cleavage reaction exists in a stable molecular conformation suggests autoinhibition and substrate-induced activation mechanisms for regulation of NS3 protease activity.     

Identification of a region in the Sindbis virus nucleocapsid protein that is involved in specificity of RNA encapsidation.

The specific encapsidation of genomic RNA by an alphavirus requires recognition of the viral RNA by the nucleocapsid protein. In an effort to identify individual residues of the Sindbis virus nucleocapsid protein which are essential for this recognition event, a molecular genetic analysis of a domain of the protein previously suggested to be involved in RNA binding in vitro was undertaken. The experiments presented describe the generation of a panel of viruses which contain mutations in residues 97 through 111 of the nucleocapsid protein. All of the viruses generated were viable, and the results suggest that, individually, the residues mutated do not play a critical role in encapsidation. However, one mutant which had lost the ability to specifically encapsidate the genomic RNA was identified. This mutant virus, which contained a deletion of residues 97 to 106, encapsidated both the genomic RNA and the subgenomic mRNA of the virus. It is proposed that the encapsidation of this second species of RNA, which is not present in wild-type virions, is the result of the loss of a domain of the nucleocapsid protein required for specific recognition of the genomic RNA packaging signal. The results suggest that this region of the protein is important in dictating specificity in the encapsidation reaction in vivo. The isolation and preliminary characterization of two independent second-site revertants to this deletion mutant are also described.