Expression and Ni-NTA-Agarose Purification of Recombinant Hepatitis C Virus E2Ectodomain Produced in a Baculovirus Expression System.

In this protocol, we describe the production and purification of the ectodomain of the E2661 envelope protein (amino acids 384-661) of the Hepatitis C virus, which plays a fundamental role in the entry of the virus into the host cell. This protein has been expressed in both prokaryotic and eukaryotic systems but in small quantities or without native protein characteristics. In our case, we use the Baculovirus expression system in insect cells. E2661 is secreted into the extracellular medium and purified by means of affinity chromatography a Ni-NTA-column because the protein has a tag of six histidines at its amino terminal end. The purified protein possesses a native-like conformation and it is produced in large quantities, around 5-6 mg per liter.

In vitro Membrane Interaction and Liposome Fusion Assays Using Recombinant Hepatitis C Virus Envelope Protein E2.

In order to study the mechanism underlying the Hepatitis C Virus (HCV) fusion process we have performed assays using phospholipid liposomes and a truncated form of E2 protein, E2661 (amino acids 384-661 of the HCV polyprotein) lacking the transmembrane region. E2661 has been previously generated by using the baculovirus expression system. This form has been used in lipid-protein interaction studies with different model vesicles at different pHs, and monitored using a variety of fluorescent assays. After the analysis of the results, we observed that E2661 is able to insert into lipid bilayers and to induce vesicle aggregation, lipid mixing and liposome leakage, showing higher values of membrane destabilization for negatively charged phospholipids at acidic pH. This is indicative of the role of E2 glycoprotein in the HCV initial infective steps, interacting with the target membranes and producing their destabilization.

Fusogenic properties of the Ectodomain of HCV E2 envelope protein.

The steps leading from hepatitis C virus (HCV) attachment to the hepatocytes to the fusion of viral and cellular membranes remain uncharacterized. In this regard, we have studied the mechanism underlying the HCV fusion process using liposomes and a truncated form of E2 protein lacking the transmembrane region, E2661 (amino acids 384-661). E2661 has been previously obtained by using the baculovirus expression system and shown to behave as an independent folding domain (M. Rodriguez-Rodriguez, D. Tello, B. Yelamos, J. Gomez-Gutierrez, B. Pacheco, S. Ortega, A.G. Serrano, D.L. Peterson, F. Gavilanes, Structural properties of the ectodomain of hepatitis C virus E2 envelope protein, Virus Res. 139 (2009) 91-99). This form has been used in lipid-protein interaction studies with different model vesicles, at different pHs and by employing a variety of fluorescent assays. The obtained results indicate that E2661 induces vesicle aggregation, lipid mixing and liposome leakage, reaching higher values in the presence of negatively charged phospholipids and cholesterol at acidic pH. Therefore, the results of these studies would be indicative of an HCV infection process through receptor mediated endocytosis. Accordingly, E2 might be important in the HCV initial infective steps, interacting with the target membranes and giving rise to their subsequent destabilization.

The deletion of residues 268-292 of E1 impairs the ability of HCV envelope proteins to induce pore formation.

We have obtained a chimeric protein containing the ectodomains of hepatitis C virus (HCV) envelope proteins but lacking the region 268-292 of E1. All its structural properties are coincident with those of the corresponding full length chimera. The deleted and entire chimeras were compared in terms of their membrane destabilizing properties. No differences were found in their ability to induce vesicle aggregation and lipid mixing but the deleted chimera showed a reduced capacity to promote leakage. The role of the deletion was also studied by obtaining HCV pseudoparticles (HCVpp). Both E1 and E2, and also the E1 deleted mutant, were incorporated into HCVpp to a similar level. However, HCVpp containing the E1 deleted protein are almost unable to infect Huh7 cells. These results point to the involvement of the region 268-292 in the formation of pores in the membrane necessary for the complete fusion of the membranes.

Study of the putative fusion regions of the preS domain of hepatitis B virus.

In a previous study, it was shown that purified preS domains of hepatitis B virus (HBV) could interact with acidic phospholipid vesicles and induce aggregation, lipid mixing and leakage of internal contents which could be indicative of their involvement in the fusion of the viral and cellular membranes (Núñez, E. et al. 2009. Interaction of preS domains of hepatitis B virus with phospholipid vesicles. Biochim. Biophys. Acta 17884:417-424). In order to locate the region responsible for the fusogenic properties of preS, five mutant proteins have been obtained from the preS1 domain of HBV, in which 40 amino acids have been deleted from the sequence, with the starting point of each deletion moving 20 residues along the sequence. These proteins have been characterized by fluorescence and circular dichroism spectroscopy, establishing that, in all cases, they retain their mostly non-ordered conformation with a high percentage of ß structure typical of the full-length protein. All the mutants can insert into the lipid matrix of dimyristoylphosphatidylglycerol vesicles. Moreover, we have studied the interaction of the proteins with acidic phospholipid vesicles and each one produces, to a greater or lesser extent, the effects of destabilizing vesicles observed with the full-length preS domain. The ability of all mutants, which cover the complete sequence of preS1, to destabilize the phospholipid bilayers points to a three-dimensional structure and/or distribution of amino acids rather than to a particular amino acid sequence as being responsible for the membrane fusion process.

Purification and structural stability of white Spanish broom (Cytisus multiflorus) peroxidase.

New plant peroxidase has been isolated to homogeneity from the white Spanish broom Cytisus multiflorus. The enzyme purification steps included homogenization, NH(4)SO(4) precipitation, extraction of broom colored compounds and consecutive chromatography on Phenyl-Sepharose, HiTrap™ SP HP and Superdex-75 and 200. The novel peroxidase was characterized as having a molecular weight of 50 ± 3 kDa. Steady-state tryptophan fluorescence and far-UV circular dichroism (CD) studies, together with enzymatic assays, were carried out to monitor the structural stability of C. multiflorus peroxidase (CMP) at pH 7.0. Thus changes in far-UV CD corresponded to changes in the overall secondary structure of enzyme, while changes in intrinsic tryptophan fluorescence emission corresponded to changes in the tertiary structure of the enzyme. It is shown that the process of CMP denaturation can be interpreted with sufficient accuracy in terms of the simple kinetic scheme, N ⟶ kD, where k is a first-order kinetic constant that changes with temperature following the Arrhenius equation; N is the native state, and D is the denatured state. On the basis of this model, the parameters of the Arrhenius equation were calculated.

High-yield production of a chimeric glycoprotein based on permuted E1 and E2 HCV envelope ectodomains.

In this report it is described for the first time the expression and purification of large quantities of a soluble and correctly folded chimeric recombinant protein, E2661E1340, containing the permuted Hepatitis C virus (HCV) glycoprotein ectodomains E1 (amino acids 192-340) and E2 (amino acids 384-661). Using the baculovirus/insect cell expression system, 8mg of secreted protein were purified from 1L of culture media, a yield 4 times higher than the described for its counterpart E1341E2661. This permuted chimeric protein is glycosylated and possesses a high tendency to self-associate. The fluorescence emission spectrum indicates that Trp residues occupy a relatively low hydrophobic environment. The secondary structure was determined by deconvolution of the far-UV circular dichroism spectrum yielding 13% α-helix structure, 49% extended structure and 38% non-ordered structure. E2661E1340 binds to antibodies present in human sera from HCV-positive patients, a binding that is blocked at different levels by a rabbit anti-E2661 antibody. All these structural and antigenic features of E2661E1340 are very similar to those described for E1340E2661, Thus, this high-yield isolated chimeric protein may be a valuable tool to study the first steps of the HCV infection.

Production and characterization of the ectodomain of E2 envelope glycoprotein of hepatitis C virus folded in the presence of full-length E1 glycoprotein.

Hepatitis C virus (HCV) envelope glycoproteins, E1 and E2, are involved in the first steps of virus infection. The E2 ectodomain can be produced as an isolated form (E2661). However, there is some concern about its proper conformation and the role that E1 can play as a chaperone for the folding of E2. In order to verify this fact we have expressed a chimeric protein (E1tmbE2) based on the full-length E1 sequence followed by the E2 ectodomain using the baculovirus-insect cells system. The E2 ectodomain is folded in the presence of the E1, proteolytically processed by cellular proteases and secreted to cell culture media (E2661p), while the E1 protein is retained into the cell due to its transmembrane sequence. The purification of E2661p from culture media was facilitated by a His tag introduced in its amino terminus. Both E2661 and E2661p glycoproteins shared very similar structural features, monitored by spectroscopic and antigenic studies. Moreover, their functional properties, tested by means of CD81 binding, were almost indistinguishable, indicating that the E2 ectodomain constitutes an independent folding unit.

Fusogenic properties of the ectodomains of hepatitis C virus envelope proteins.

We have used an isolated chimeric protein E1340 E2661 that includes the ectodomains of the envelope proteins of hepatitis C virus to study its interaction with model membranes. E1340 E2661 has some of the membrane destabilization properties, vesicle aggregation, lipid mixing and the release of internal aqueous content, which have previously been ascribed to fusion proteins. The effects are preferentially produced on vesicles of acidic phospholipids which would indicate the importance of the electrostatic interactions. In fact, an increase of the ionic strength of the buffer induced a considerable decrease of the destabilizing properties. Moreover, fluorescence polarization studies show that the recombinant protein reduces the amplitude of the thermal transition of dimyristoylphosphatidylglycerol vesicles and increases the transition temperature at pH 5.0 in a dose-dependent manner, indicating its insertion into the bilayer. Furthermore, a decrease of the pH induces a conformational change in the protein structure as evidenced by fluorescence of tryptophan residues and 4,4'-bis(1-anilinonaphthalene-8-sulfonate). A model for the fusion of hepatitis C virus with the host cell membrane can be postulated. The dissociation of E1E2 dimers would uncover the fusion peptides which can then interact with the polar lipid heads of the outer leaflet of the lipid bilayer and next insert into the hydrophobic moiety producing the destabilization of the bilayer which finally leads to fusion.

Annexin-phospholipid interactions. Functional implications.

Annexins constitute an evolutionary conserved multigene protein superfamily characterized by their ability to interact with biological membranes in a calcium dependent manner. They are expressed by all living organisms with the exception of certain unicellular organisms. The vertebrate annexin core is composed of four (eight in annexin A6) homologous domains of around 70 amino acids, with the overall shape of a slightly bent ring surrounding a central hydrophilic pore. Calcium- and phospholipid-binding sites are located on the convex side while the N-terminus links domains I and IV on the concave side. The N-terminus region shows great variability in length and amino acid sequence and it greatly influences protein stability and specific functions of annexins. These proteins interact mainly with acidic phospholipids, such as phosphatidylserine, but differences are found regarding their affinity for lipids and calcium requirements for the interaction. Annexins are involved in a wide range of intra- and extracellular biological processes in vitro, most of them directly related with the conserved ability to bind to phospholipid bilayers: membrane trafficking, membrane-cytoskeleton anchorage, ion channel activity and regulation, as well as antiinflammatory and anticoagulant activities. However, the in vivo physiological functions of annexins are just beginning to be established.

Spectroscopic characterization and fusogenic properties of preS domains of duck hepatitis B virus.

In order to shed light on the hepatitis B virus fusion mechanism and to explore the fusogenic capabilities of preS regions, a recombinant duck hepatitis B virus (DHBV) preS protein (DpreS) containing six histidines at the carboxy-terminal end has been obtained. The DpreS domain, which has an open and mostly nonordered conformation as indicated by fluorescence and circular dichroism spectroscopies, has the ability to interact with negatively charged phospholipid vesicles. The observed interaction differences between neutral and acidic phospholipids can be interpreted in terms of an initial ionic interaction between the phospholipid polar headgroup and the protein followed by the insertion of probably the N-terminal region in the cellular membrane. Fluorescence polarization studies detect a decrease of the transition enthalpy together with a small modification of the transition temperature, typical effects of integral membrane proteins. The interaction of the protein with acidic phospholipid vesicles induces aggregation, lipid mixing, and leakage of internal contents, properties that have been ascribed to membrane destabilizing proteins. The fact that the preS domains of the hepadnaviruses have little similarity but share a very similar hydrophobic profile points to the importance of the overall three-dimensional structure as well as to its conformational flexibility and the distribution of polar and apolar amino acids on the expression of their destabilizing properties rather than to a particular amino acid sequence. The results presented herein argue for the involvement of DpreS in the initial steps of DHBV infection. Taken together with previously reported results, the conclusion that both S and preS regions participate in the fusion process of the hepadnaviridae family may be drawn.

Expression and structural properties of a chimeric protein based on the ectodomains of E1 and E2 hepatitis C virus envelope glycoproteins.

Hepatitis C virus encodes two enveloped glycoproteins, E1 and E2, which are involved in viral attachment and entry into target cells. We have obtained in insect cells infected by recombinant baculovirus a chimeric secreted recombinant protein, E1(341)E2(661,) containing the ectodomains of E1 and E2. The described procedure allows the purification of approximately 2mg of protein from 1L of culture media. Sedimentation velocity experiments and SDS-PAGE in the absence of reducing agents indicate that the protein has a high tendency to self-associate, the dimer being the main species observed. All the oligomeric forms observed maintain a conformation which is recognized by the conformation-dependent monoclonal antibody H53 directed against the E2 ectodomain. The spectroscopic properties of E1(341)E2(661) are those of a three-dimensionally structured protein. Moreover, the chimeric protein is able to bind to human antibodies present in HCV-positive human sera. Accordingly, this chimeric soluble polypeptide chain may be a valuable tool to study the structure-function relationship of HCV envelope proteins.

Interaction of preS domains of hepatitis B virus with phospholipid vesicles.

The role of preS domains of the hepatitis B virus (HBV) envelope proteins in the first steps of viral infection has been restricted to their implication in virus attachment to a putative hepatocyte receptor. In order to explore a fusion activity in these regions, we used recombinant preS domains to characterize their interaction with liposomes. Binding experiments carried out with NBD-labeled proteins indicated that preS were able to interact in a monomeric way with acidic phospholipid vesicles, being the partition coefficient similar to that described for peptides which can insert deeply into bilayers. Fluorescence depolarization of DPH-labeled vesicles confirmed the specificity for negative charged phospholipids. Upon interaction the proteins induced aggregation, lipid mixing and release of internal contents of acidic vesicles at both acid and neutral pH in a concentration-dependent manner. Taken together, all these data indicate that preS domains are able to insert into the hydrophobic core of the bilayer. Moreover, the insertion resulted in a protein conformational change which increased the helical content. Therefore all these results suggest that, besides their participation in the recognition of a cellular receptor, the preS domains could be involved in the fusion mechanism of HBV with the plasma membrane of target cells.

Structural properties of the ectodomain of hepatitis C virus E2 envelope protein.

We describe the structural and antigenic properties of a soluble form of hepatitis C virus E2 envelope protein ectodomain ending at residue 661 (E2(661)) which is obtained in large quantities in a baculovirus/insect cell system. The protein is secreted to the cellular medium by virus-infected cells. E2(661) is glycosylated and possesses a high tendency to self-associate. In fact, analytical ultracentrifugation and size exclusion chromatography studies show that the purified protein is mainly composed of dimers, trimers and tetramers being the dimer the smallest species present in solution. The secondary structure was determined by deconvolution of the far-UV circular dichroism spectrum yielding 8% alpha-helix structure, 47% extended structure and 45% non-ordered structure. The near-UV CD spectrum is indicative of a folded structure. The fluorescence emission spectrum indicates that Trp residues occupy a relatively low hydrophobic environment. Finally, E2(661) binds to a monoclonal conformation specific antibody and to antibodies present in human sera from HCV-positive patients. All these features suggest that the secreted protein possesses a native-like conformation. The use of this independent folding domain may contribute to shed light on the biology of HCV and could also be used as a vaccine in the prevention of HCV infection.

Insights into the oligomerization state-helicase activity relationship of West Nile virus NS3 NTPase/helicase.

West Nile virus (WNV) is a member of the Flaviviridae family of positive-strand RNA viruses. Its viral RNA is translated to produce a polyprotein precursor that is further processed into three structural and seven non-structural proteins. The non-structural protein 3 (NS3) possess both protease and helicase activities. The C-terminal portion of the NS3 contains the ATPase/helicase domain presumably involved in viral replication. This domain has been expressed in Escherichia coli, purified in soluble form and structurally characterized. As judged by analytical centrifugation and size exclusion chromatography, the purified enzyme behaves as a monomer in solution. It has ATPase activity that is stimulated by the presence of RNA and single-stranded DNA molecules (ssDNA). However, we were unable to detect helicase activity at protein concentrations up to 500nM. It has been reported that longer constructions of NS3 helicase domains from other flavivirus, like those which include residues of the linker region between the protease and the helicase domains, have helicase activity. Since all the conformational features of the purified WNV NS3 domain are those of a native protein, it is tempting to assume that the linker region plays a critical role in determining the protein-protein interactions that leads to the formation of the active oligomer.

N-type inactivation of the potassium channel KcsA by the Shaker B "ball" peptide: mapping the inactivating peptide-binding epitope.

The effects of the inactivating peptide from the eukaryotic Shaker BK(+) channel (the ShB peptide) on the prokaryotic KcsA channel have been studied using patch clamp methods. The data show that the peptide induces rapid, N-type inactivation in KcsA through a process that includes functional uncoupling of channel gating. We have also employed saturation transfer difference (STD) NMR methods to map the molecular interactions between the inactivating peptide and its channel target. The results indicate that binding of the ShB peptide to KcsA involves the ortho and meta protons of Tyr(8), which exhibit the strongest STD effects; the C4H in the imidazole ring of His(16); the methyl protons of Val(4), Leu(7), and Leu(10) and the side chain amine protons of one, if not both, the Lys(18) and Lys(19) residues. When a noninactivating ShB-L7E mutant is used in the studies, binding to KcsA is still observed but involves different amino acids. Thus, the strongest STD effects are now seen on the methyl protons of Val(4) and Leu(10), whereas His(16) seems similarly affected as before. Conversely, STD effects on Tyr(8) are strongly diminished, and those on Lys(18) and/or Lys(19) are abolished. Additionally, Fourier transform infrared spectroscopy of KcsA in presence of (13)C-labeled peptide derivatives suggests that the ShB peptide, but not the ShB-L7E mutant, adopts a beta-hairpin structure when bound to the KcsA channel. Indeed, docking such a beta-hairpin structure into an open pore model for K(+) channels to simulate the inactivating peptide/channel complex predicts interactions well in agreement with the experimental observations.