风疹病毒包膜糖蛋白E1中二硫键对其细胞融合活性的影响

为了探讨风疹病毒包膜糖蛋白E1中二硫键对风疹病毒细胞融合活性的影响,在构建重组载体pBSK-SPE2E1的基础上,利用PCR定点突变与体内同源重组相结合的方法,构建了11个突变体,分别将E1外功能区的11个半胱氨酸残基突变为其它氨基酸残基,从而去除一个二硫键,利用Giemsa染色法定性检测由此引起的细胞融合情况,流式细胞术检测导入的外源DNA在细胞表面的表达效率,血吸附检测重组表达的突变体蛋白的受体识别活性。结果表明E1外功能区的10个二硫键对RV的细胞融合活性都有重要影响,任何一个二硫键的去除均导致E1的细胞融合活性丧失;其中第5和第8个半胱氨酸残基所形成的二硫键与E2和E1的相互作用有关,第3、第4和第13个半胱氨酸残基所形成的二硫键可能直接影响E1的细胞融合功能。     

Redox modification of cysteine residues regulates the cytokine activity of high mobility group box-1 (HMGB1)

High mobility group box 1 (HMGB1) is a nuclear protein with extracellular inflammatory cytokine activity. It is released passively during cell injury and necrosis, and secreted actively by immune cells. HMGB1 contains three conserved redox-sensitive cysteine residues: C23 and C45 can form an intramolecular disulfide bond, whereas C106 is unpaired and is essential for the interaction with Toll-Like Receptor (TLR) 4. However, a comprehensive characterization of the dynamic redox states of each cysteine residue and of their impacts on innate immune responses is lacking. Using tandem mass spectrometric analysis, we now have established that the C106 thiol and the C23-C45 disulfide bond are required for HMGB1 to induce nuclear NF-κB translocation and tumor necrosis factor (TNF) production in macrophages. Both irreversible oxidation to sulphonates and complete reduction to thiols of these cysteines inhibited TNF production markedly. In a proof of concept murine model of hepatic necrosis induced by acetaminophen, during inflammation, the predominant form of serum HMGB1 is the active one, containing a C106 thiol group and a disulfide bond between C23 and C45, whereas the inactive form of HMGB1, containing terminally oxidized cysteines, accumulates during inflammation resolution and hepatic regeneration. These results reveal critical posttranslational redox mechanisms that control the proinflammatory activity of HMGB1 and its inactivation during pathogenesis.     

S acylation of the hemagglutinin of influenza viruses: mass spectrometry reveals site-specific attachment of stearic acid to a transmembrane cysteine

S acylation of cysteines located in the transmembrane and/or cytoplasmic region of influenza virus hemagglutinins (HA) contributes to the membrane fusion and assembly of virions. Our results from using mass spectrometry (MS) show that influenza B virus HA possessing two cytoplasmic cysteines contains palmitate, whereas HA-esterase-fusion glycoprotein of influenza C virus having one transmembrane cysteine is stearoylated. HAs of influenza A virus having one transmembrane and two cytoplasmic cysteines contain both palmitate and stearate. MS analysis of recombinant viruses with deletions of individual cysteines, as well as tandem-MS sequencing, revealed the surprising result that stearate is exclusively attached to the cysteine positioned in the transmembrane region of HA.     

Critical role for the cysteines flanking the internal fusion peptide of avian sarcoma/leukosis virus envelope glycoprotein

The transmembrane subunit (TM) of the envelope glycoprotein (Env) of the oncovirus avian sarcoma/leukosis virus (ASLV) contains an internal fusion peptide flanked by two cysteines (C9 and C45). These cysteines, as well as an analogous pair in the Ebola virus GP glycoprotein, are predicted to be joined by a disulfide bond. To examine the importance of these cysteines, we mutated C9 and C45 in the ASLV subtype A Env (EnvA), individually and together, to serine. All of the mutant EnvAs formed trimers that were composed of the proteolytically processed surface (SU) and TM subunits. All mutant EnvAs were incorporated into murine leukemia virus pseudotyped virions and bound receptor with wild-type affinity. Nonetheless, all mutant EnvAs were significantly impaired ( approximately 1,000-fold) in their ability to support infectivity. They were also significantly impaired in their ability to mediate cell-cell fusion. Our data are consistent with a model in which the internal fusion peptide of ASLV-A EnvA exists as a loop that is stabilized by a disulfide bond at its base and in which this stabilized loop serves an important function during virus-cell fusion. The fusion peptide of the Ebola virus GP glycoprotein may conform to a similar structure.     

Conformational change of the coronavirus peplomer glycoprotein at pH 8.0 and 37 degrees C correlates with virus aggregation and virus-induced cell fusion.

We have obtained biochemical and electron microscopic evidence of conformational changes at pH 8.0 and 37 degrees C in the coronavirus spike glycoprotein E2 (S). The importance of these changes is reflected in the loss of virus infectivity, the aggregation of virions, and increased virus-induced cell fusion at the same pH. Coronavirus (MHV-A59) infectivity is exquisitely sensitive to pH. The virus was quite stable at pH 6.0 and 37 degrees C (half-life, approximately 24 h) but was rapidly and irreversibly inactivated by brief treatment at pH 8.0 and 37 degrees C (half-life, approximately 30 min). Virions treated at pH 8.0 and 37 degrees C formed clumps and large aggregates. With virions treated at pH 8.0 and 37 degrees C, the amino-terminal peptide E2N (or S1) was released from virions and the remaining peptide, E2C (S2), was aggregated. Viral spikes isolated from detergent-treated virions also aggregated at pH 8.0 and 37 degrees C. Loss of virus infectivity and E2 (S) aggregation at pH 8.0 and 37 degrees C were markedly enhanced in the presence of dithiothreitol. On the basis of the effects of dithiothreitol on the reactions of the peplomer, we propose that release of E2N (S1) and aggregation of E2C (S2) may be triggered by rearrangement of intramolecular disulfide bonds. The aggregation of virions and the isolated E2 (S) glycoprotein at pH 8.0 and 37 degrees C or following treatment with guanidine and urea at pH 6.0 and 37 degrees C indicate that an irreversible conformational change has been induced in the peplomer glycoprotein by these conditions. It is interesting that coronavirus-induced cell fusion also occurred under mildly alkaline conditions and at 37 degrees C. Some enveloped viruses, including influenza viruses and alphaviruses, show conformational changes of spike glycoproteins at a low pH, which correlates with fusion and penetration of those viruses in acidified endocytic vesicles. For coronavirus MHV-A59, comparable conformational change of the spike glycoprotein E2 (S) and cell fusion occurred at a mildly alkaline condition, suggesting that coronavirus infection-penetration, like that of paramyxoviruses and lentiviruses, may occur at the plasma membrane, rather than within endocytic vesicles.     

Reduced monomeric CD4 is the preferred receptor for HIV

CD4 is a co-receptor for binding of T cells to antigen-presenting cells and the primary receptor for the human immunodeficiency virus type 1 (HIV). CD4 exists in three different forms on the cell surface defined by the state of the domain 2 cysteine residues: an oxidized monomer, a reduced monomer, and a covalent dimer linked through the domain 2 cysteines. The disulfide-linked dimer is the preferred immune co-receptor. The form of CD4 that is preferred by HIV was examined in this study. HIV entry and envelope-mediated cell-cell fusion were tested using cells expressing comparable levels of wild-type or disulfide bond mutant CD4 in which the domain 2 cysteines were mutated to alanine. Eliminating the domain 2 disulfide bond increased entry of HIV reporter viruses and enhanced HIV envelope-mediated cell-cell fusion 2-4-fold. These observations suggest that HIV enters susceptible cells preferably through monomeric reduced CD4, whereas dimeric CD4 is the preferred receptor for binding to antigen-presenting cells. Cleavage of the domain 2 disulfide bond is possibly involved in the conformational change in CD4 associated with fusion of the HIV and cell membranes.     

Charge-based analysis of antibodies with engineered cysteines

THIOMABs are antibodies with an engineered unpaired cysteine residue on each heavy chain that can be used as intermediates to generate antibody-drug conjugates. Multiple charge variant peaks were observed during cation-exchange chromatography (CEX) and imaged capillary isoelectric focusing (cIEF) analysis of several different THIOMABs. This charge heterogeneity was due to cysteinylation and/or glutathionylation at the engineered and unpaired cysteines through disulfide bonds formed during the cell culture process. Cysteine treatment followed by analysis using CEX, LC/MS and electrophoresis demonstrates that cysteine is a mild reductant that can remove glutathione and cysteine bound to the engineered cysteines without disrupting the inter- or intra-chain disulfide bonds of antibodies. We further demonstrated that using a cysteine/cystine redox pair (rather than cysteine alone) can not only effectively remove glutathione at the engineered cysteines, but also generate homogeneously cysteinylated species, which resulted in one main peak in both CEX-HPLC and imaged cIEF assays for antibodies with engineered and unpaired cysteines.     

结构域B在鼠冠状病毒S蛋白的抗原性及膜融合中的作用

棘突(spike, S)蛋白是冠状病毒表面必不可少的跨膜糖蛋白,在病毒进入宿主细胞时具有结合受体和诱导膜融合的双重作用。大部分冠状病毒S蛋白的受体结合域位于S1-CTD(即相对应的结构域B),而经典的乙型冠状病毒模型鼠肝炎病毒(mouse hepatitis virus, MHV)的受体mCEACAM1a与S1-NTD(即相对应的结构域A)结合,其结构域B的作用仍未完全清楚。本研究通过构建结构域B和S2膜融合元件的缺失突变体,并使其在鼠神经母细胞瘤细胞系Neuro-2a内成功表达,证实了结构域B对病毒S蛋白导致的细胞-细胞间膜融合是必需的。用不同方法处理的病毒颗粒作为抗原免疫小鼠,所获得的多克隆抗体进一步显示,结构域B不但是S蛋白的主要抗原决定簇,而且能诱导中和抗体明显抑制病毒感染和S蛋白介导的膜融合作用。此结果为阐述不同冠状病毒的致病性与感染性差异提供了新思路。     

Role of Spike Protein Endodomains in Regulating Coronavirus Entry

Enveloped viruses enter cells by viral glycoprotein-mediated binding to host cells and subsequent fusion of virus and host cell membranes. For the coronaviruses, viral spike (S) proteins execute these cell entry functions. The S proteins are set apart from other viral and cellular membrane fusion proteins by their extensively palmitoylated membrane-associated tails. Palmitate adducts are generally required for protein-mediated fusions, but their precise roles in the process are unclear. To obtain additional insights into the S-mediated membrane fusion process, we focused on these acylated carboxyl-terminal intravirion tails. Substituting alanines for the cysteines that are subject to palmitoylation had effects on both S incorporation into virions and S-mediated membrane fusions. In specifically dissecting the effects of endodomain mutations on the fusion process, we used antiviral heptad repeat peptides that bind only to folding intermediates in the S-mediated fusion process and found that mutants lacking three palmitoylated cysteines remained in transitional folding states nearly 10 times longer than native S proteins. This slower refolding was also reflected in the paucity of postfusion six-helix bundle configurations among the mutant S proteins. Viruses with fewer palmitoylated S protein cysteines entered cells slowly and had reduced specific infectivities. These findings indicate that lipid adducts anchoring S proteins into virus membranes are necessary for the rapid, productive S protein refolding events that culminate in membrane fusions. These studies reveal a previously unappreciated role for covalently attached lipids on the endodomains of viral proteins eliciting membrane fusion reactions.     

Structural and redox properties of the leaderless DsbE (CcmG) protein: both active-site cysteines of the reduced form are involved in its function in the Escherichia coli periplasm

The thiol/disulfide oxidoreductases play important roles in ensuring the correct formation of disulfide bonds, of which the DsbE protein, also called CcmG, is the one implicated in electron transfer for cytochrome c maturation in the periplasm of Escherichia coli. The soluble, N-terminally truncated DsbE was overexpressed and purified to homogeneity. Here we report the structural and redox properties of the leaderless form (DsbEL-). During the redox reaction, the protein undergoes a structural transformation resulting in a more stable reduced form, but this form shows very low reactivity in thiol/ disulfide exchange of cysteine residues and low activity in accelerating the reduction of insulin. The standard redox potential (E'0) for the active thiol/ disulfide was determined to be -0.186 V; only one of the two cysteines (Cys80) was suggested to be the active residue in the redox reaction. From the aspect of biochemical properties, DsbE can be regarded as a weak reductant in the Escherichia coli periplasm. This implies that the function of DsbE in cytochrome c maturation can be ascribed to its active-site cysteines and the structure of the reduced form.     

Development of a family of redox-sensitive green fluorescent protein indicators for use in relatively oxidizing subcellular environments

Green fluorescent protein (GFP) indicators were previously developed that rapidly and quantitatively respond to changes in the thiol/disulfide equilibrium within subcellular compartments. In these indicators, surface-exposed cysteines residues were introduced so as to form a labile redox-active disulfide that in turn controls the emission properties of the internal chromophore. The biosensors have been shown to be effective reporters of the thiol/disulfide status within reducing compartments such as the mitochondria and cytosol for several cell types. However, due to the high thermodynamic stability of the introduced disulfide bond, the indicators are not useful for quantitative analysis within more oxidizing compartments such as the endoplasmic reticulum. Here we report the development of a new family of GFP-based redox indicators (roGFP1-iX) in which the thermodynamic stability of the disulfide is substantially lowered by insertion of a single amino acid into the main chain, adjacent to cysteine 147. The insertions result in indicators with midpoint potentials of -229 to -246 mV and are thus better suited for study of relatively oxidizing subcellular compartments. Atomic resolution crystallographic analyses suggest that two important factors act to destabilize the disulfide linkage in roGFP1-iX. In the oxidized state, an unusual non-proline cis-peptide bond adjacent to one of the cysteines introduces geometric strain into the system, while in the reduced state, a dramatic loop opening lowers the effective concentration of the reacting species.     

Cysteines flanking the internal fusion peptide are required for the avian sarcoma/leukosis virus glycoprotein to mediate the lipid mixing stage of fusion with high efficiency

We previously showed that the cysteines flanking the internal fusion peptide of the avian sarcoma/leukosis virus subtype A (ASLV-A) Env (EnvA) are important for infectivity and cell-cell fusion. Here we define the stage of fusion at which the cysteines are required. The flanking cysteines are dispensable for receptor-triggered membrane association but are required for the lipid mixing step of fusion, which, interestingly, displays a high pH onset and a biphasic profile. Second-site mutations that partially restore infection partially restore lipid mixing. These findings indicate that the cysteines flanking the internal fusion peptide of EnvA (and perhaps by analogy Ebola virus glycoprotein) are important for the foldback stage of the conformational changes that lead to membrane merger.     

Entry of hepatitis delta virus requires the conserved cysteine residues of the hepatitis B virus envelope protein antigenic loop and is blocked by inhibitors of thiol-disulfide exchange

Hepatitis delta virus (HDV) particles are coated with the envelope proteins (large, middle, and small) of the hepatitis B virus (HBV). The large protein bears an infectivity determinant in its pre-S1 domain, whereas a second determinant has been proposed to map to the cysteine-rich antigenic loop (AGL) within the S domain of all three envelope proteins (G. Abou Jaoudé and C. Sureau, J. Virol. 79:10460-10466, 2006). In this study, the AGL cysteines were substituted by serine or alanine, and the mutants were evaluated for their function at viral entry using HDV particles and susceptible HepaRG cells. Mutations of cysteines 121 to 149 were tolerant of the production of HDV virions. The mutations altered the structure and antigenicity of the conserved “a” determinant of the AGL, as measured by conformation-sensitive antibodies, and they created a block to infectivity. Substitution of Cys-90 or Cys-221, located outside of the AGL, had no impact on the “a” determinant or viral entry. Furthermore, infectivity was maintained when the AGL CxxC motif at position 121 to 124 was modified by single-amino-acid deletion or insertion, suggesting that cysteines 121 and 124 are not catalyzers of thiol/disulfide exchange. However, membrane-impermeable inhibitors of thiol/disulfide isomerazation demonstrated a dose-dependent inhibition of infection in an in vitro assay when applied to the virus prior to inoculation or during the virus-cell interaction period. Overall, the results demonstrate the essential role of the AGL cysteines at viral entry, and they establish a correlation between the cysteine disulfide network, the conformation of the “a” determinant, and infectivity.     

The redox state of cysteines 201 and 317 of the erythrocyte anion exchanger is critical for ankyrin binding

Previous studies have demonstrated that modification of erythrocyte membrane cysteine residues via disulfide cross-briding or direct derivatization with thiol reagents promotes massive morphological, rheological, and structural changes in the cell. To determine whether disruption of the band 3-ankyrin interaction, the major membrane-cytoskeletal linkage, might contribute to the above lesions, we quantitatively measured the band 3-ankyrin interaction following modification of Cys-201 and/or Cys-317 of the cytoplasmic domain of band 3. It was observed that irreversible alkylating agents (e.g. N-ethylmaleimide or iodoacetamide and its derivatives), reversible derivatizing compounds (.e.g. p-chloromercuribenzenesulfonate or glutathione), and native disulfide bond formation all blocked the ankyrin interaction. Comparison of the extent of sulfhydryl modification with the degree of inhibition of ankyrin binding further confirmed that cysteine modification was directly responsible for the inhibition. However, analysis of the site of sulfhydryl derivatization revealed that inhibition of ankyrin binding could be initiated in some cases with derivatization of Cys-201, while in other cases obstruction of Cys-317 appeared to be essential. This apparent discrepancy was resolved by demonstrating that Cys-201 of one strand of the cytoplasmic domain of band 3 dimer could disulfide bond with Cys-317 of the opposite strand, thus demonstrating that all four cysteines of the band 3 dimer are clustered at the interface between subunits. We argue that derivatization or disulfide cross-linking of these cysteines can block ankyrin binding by both conformational and steric mechanisms.     

Ezrin Interacts with the SARS Coronavirus Spike Protein and Restrains Infection at the Entry Stage

Background

Entry of Severe Acute Respiratory Syndrome coronavirus (SARS-CoV) and its envelope fusion with host cell membrane are controlled by a series of complex molecular mechanisms, largely dependent on the viral envelope glycoprotein Spike (S). There are still many unknowns on the implication of cellular factors that regulate the entry process.

Methodology/Principal Findings

We performed a yeast two-hybrid screen using as bait the carboxy-terminal endodomain of S, which faces the cytosol during and after opening of the fusion pore at early stages of the virus life cycle. Here we show that the ezrin membrane-actin linker interacts with S endodomain through the F1 lobe of its FERM domain and that both the eight carboxy-terminal amino-acids and a membrane-proximal cysteine cluster of S endodomain are important for this interaction in vitro. Interestingly, we found that ezrin is present at the site of entry of S-pseudotyped lentiviral particles in Vero E6 cells. Targeting ezrin function by small interfering RNA increased S-mediated entry of pseudotyped particles in epithelial cells. Furthermore, deletion of the eight carboxy-terminal amino acids of S enhanced S-pseudotyped particles infection. Expression of the ezrin dominant negative FERM domain enhanced cell susceptibility to infection by SARS-CoV and S-pseudotyped particles and potentiated S-dependent membrane fusion.

Conclusions/Significance

Ezrin interacts with SARS-CoV S endodomain and limits virus entry and fusion. Our data present a novel mechanism involving a cellular factor in the regulation of S-dependent early events of infection.     

A Charged Second-Site Mutation in the Fusion Peptide Rescues Replication of a Mutant Avian Sarcoma and Leukosis Virus Lacking Critical Cysteine Residues Flanking the Internal Fusion Domain

The entry process of the avian sarcoma and leukosis virus (ASLV) family of retroviruses requires first a specific interaction between the viral surface (SU) glycoproteins and a receptor on the cell surface at a neutral pH, triggering conformational changes in the viral SU and transmembrane (TM) glycoproteins, followed by exposure to low pH to complete fusion. The ASLV TM glycoprotein has been proposed to adopt a structure similar to that of the Ebola virus GP2 protein: each contains an internal fusion peptide flanked by cysteine residues predicted to be in a disulfide bond. In a previous study, we concluded that the cysteines flanking the internal fusion peptide in ASLV TM are critical for efficient function of the ASLV viral glycoproteins in mediating entry. In this study, replication-competent ASLV mutant subgroup A [ASLV(A)] variants with these cysteine residues mutated were constructed and genetically selected for improved replication capacity in chicken fibroblasts. Viruses with single cysteine-to-serine mutations reverted to the wild-type sequence. However, viruses with both C9S and C45S (C9,45S) mutations retained both mutations and acquired a second-site mutation that significantly improved the infectivity of the genetically selected virus population. A charged-amino-acid second-site substitution in the TM internal fusion peptide at position 30 is preferred to rescue the C9,45S mutant ASLV(A). ASLV(A) envelope glycoproteins that contain the C9,45S and G30R mutations bind the Tva receptor at wild-type levels and have improved abilities to trigger conformational changes and to form stable TM oligomers compared to those of the C9,45S mutant glycoprotein.All retroviruses have envelope glycoproteins that interact with a receptor protein on the cell surface to initiate entry (18, 36). The viral glycoprotein is synthesized as a precursor polyprotein consisting of the surface (SU) glycoprotein, which contains the domains that bind with the cellular receptor, and the transmembrane (TM) glycoprotein, which tethers the protein to the viral surface and contains the domains responsible for fusion of the viral and cellular membranes (32). After synthesis, the precursor viral glycoproteins form trimers through the interaction of the TM domains. The SU and TM domains are then cleaved by a cellular protease, forming a mature, metastable complex capable of mediating viral entry. A specific receptor protein interaction with the SU domain of the mature Env is required to initiate a conformational change in the trimer, separating the globular SU domains to allow the TM glycoproteins to form a structure that projects the fusion peptide toward the target membrane. Two domains in TM, the N-terminal heptad repeat and the C-terminal heptad repeat, are critical for the formation of the extended structure (13, 31)}. The fusion peptide is thought to interact with a target membrane irreversibly, forming an extended prehairpin TM oligomer structure anchored in both the viral and target membranes (35). The cooperation of several of these extended prehairpin TM oligomer structures is most likely required to complete fusion. The viral and target membranes are brought into close proximity when the C-terminal heptad repeats fold back into grooves formed by the N-terminal heptad repeats, forming presumably the most stable TM structure, the six-helix bundle (6HB). Fusion of the membranes proceeds through the initial mixing of the outer lipid leaflets, hemifusion, followed by initial fusion pore formation, pore widening, and the completion of fusion. The 6HB may undergo some additional structural rearrangement in order to bring the fusion peptide and membrane-spanning domain of TM into close proximity to form the final trimeric hairpin structure (22, 24, 33).Until recently, the triggering of class I virus fusion proteins was thought to occur by one of two mechanisms (13, 35, 36). In one mechanism, the viral glycoproteins interact with receptors on the cell surface, resulting in the trafficking of the virion into an endocytic compartment, followed by the triggering of structural rearrangements in the viral glycoproteins to initiate fusion by exposure to low pH (e.g., influenza virus hemagglutinin [HA]). In a second entry mechanism, the interaction of the viral glycoproteins with receptors on the cell surface in a neutral pH environment triggers the structural rearrangements in the viral glycoproteins directly, initiating viral entry. Retroviruses predominately employ the second entry mechanism, although two cellular protein receptors may be required to complete the conformational changes in the viral glycoproteins necessary to complete entry (e.g., human immunodeficiency virus type 1). However, the entry process of the avian sarcoma and leukosis virus (ASLV) family of retroviruses demonstrates a third entry mechanism for the action of class I virus fusion proteins (25). ASLV entry requires both a specific interaction between the viral glycoproteins and receptors at the cell surface at neutral pH, triggering initial conformational changes in the viral glycoproteins, and a subsequent exposure to low pH to complete fusion (2, 3, 22-24).The fusion peptides of ASLVs are not at the N terminus of the cleaved TM, as in all other retroviral TM proteins, but in a proposed internal loop (TM residues 22 to 37) flanked by two cysteine residues (residues C9 and C45) (Fig. ​(Fig.1).1). The ASLV TM glycoprotein has been proposed to adopt a structure similar to that of the Ebola virus GP2 protein: both contain an internal fusion peptide flanked by cysteine residues predicted to be in a disulfide bond (10). Other viruses contain internal fusion peptides also predicted to be in looped structures (35). In a study to determine if the cysteines that flank the ASLV fusion peptide are required for function, mutant ASLV Env proteins were constructed with one or both of these cysteines changed to serine (C9S, C45S, or C9S C45S [C9,45S]) (8). The mutant subgroup A ASLV [ASLV(A)] Env proteins were expressed, processed, and incorporated into virions at levels similar to those of wild-type (WT) ASLV(A) Env. The mutant and WT ASLV(A) Env proteins bound the Tva receptor with similar affinities. However, murine leukemia virus (MLV) virions pseudotyped with the mutant Envs were ∼500-fold less infectious (titer, ∼2 × 10³ inclusion-forming units [IFU]/ml) than MLV virions pseudotyped with WT ASLV(A) Env (titer, ∼1 × 10⁶ IFU/ml). The ability of the mutant Envs to mediate cell fusion was also greatly impaired compared to that of WT ASLV(A) Env in a cell-cell fusion assay. We concluded that the cysteines flanking the internal fusion peptide in ASLV TM are critical for efficient function of the ASLV viral glycoproteins in mediating entry. In a recent study, the cysteines flanking the fusion peptide region were shown to be critical for the lipid mixing stage of fusion (6).Open in a separate windowFIG. 1.Schematic representations of the ASLV-based RCASBP retroviral vector and the major domains of the envelope glycoproteins. The RCASBP(A)AP replication-competent vector contains a subgroup A env and a reporter gene coding for heat-stable AP. The hypervariable domains (vr1, vr2, hr1, hr2, and vr3) of the SU glycoprotein, the proteolytic cleavage site, the putative fusion peptide region (shaded box), and the membrane-spanning domain (MSD) of the TM glycoprotein are shown schematically. The first 45 residues of the TM glycoprotein are shown for wild-type subgroup A Env (WT) and for the three mutants tested in this study, with either a substitution of serine for the cysteine at position 9 in TM (C9S), a substitution of serine for the cysteine at position 45 in TM (C45S), or both substitutions (C9,45S). The complete sequence of the ASLV(A) WT TM glycoprotein is shown, with the fusion peptide region, N-terminal and C-terminal heptad repeat regions (N-alpha-helix; C-alpha helix), and membrane-spanning domain indicated.Very little is known about the structures of fusion peptides in the context of full-length, trimeric, viral glycoproteins upon interaction with target membranes. Also, natural membrane targets contain a variety of lipid and protein compositions in an asymmetrical organization that is difficult to reproduce experimentally (27). In addition, little is known about how fusion proteins with internal fusion peptide regions interact with target membranes or the possible conformational changes that might be required to complete the fusion process (19, 20). In this study, replication-competent ASLV(A) viruses containing the C9S, C45S, or C9,45S mutations were constructed and genetically selected for improved replication in chicken fibroblasts in order to further explore the importance of these cysteines for proper TM function. Viruses with single cysteine-to-serine mutations reverted to the WT sequence. However, viruses with both the C9S and the C45S mutation retained both mutations and acquired a second-site mutation that significantly enhanced the infectivity of the genetically selected virus population. Unexpectedly, the selected second-site mutation was a charged residue located in the middle of the hydrophobic fusion peptide within TM.     

Only five of 10 strictly conserved disulfide bonds are essential for folding and eight for function of the HIV-1 envelope glycoprotein

Protein folding in the endoplasmic reticulum goes hand in hand with disulfide bond formation, and disulfide bonds are considered key structural elements for a protein's folding and function. We used the HIV-1 Envelope glycoprotein to examine in detail the importance of its 10 completely conserved disulfide bonds. We systematically mutated the cysteines in its ectodomain, assayed the mutants for oxidative folding, transport, and incorporation into the virus, and tested fitness of mutant viruses. We found that the protein was remarkably tolerant toward manipulation of its disulfide-bonded structure. Five of 10 disulfide bonds were dispensable for folding. Two of these were even expendable for viral replication in cell culture, indicating that the relevance of these disulfide bonds becomes manifest only during natural infection. Our findings refine old paradigms on the importance of disulfide bonds for proteins.     

Four cysteines of the membrane protein DsbB act in concert to oxidize its substrate DsbA

Protein disulfide bond formation in Escherichia coli is catalyzed by the periplasmic protein DsbA. A cytoplasmic membrane protein DsbB maintains DsbA in the oxidized state by transferring electrons from DsbA to quinones in the respiratory chain. Here we show that DsbB activity can be reconstituted by co-expression of N- and C-terminal fragments of the protein, each containing one of its redox-active disulfide bonds. This system has allowed us (i) to demonstrate that the two DsbB redox centers interact directly through a disulfide bond formed between the two DsbB domains and (ii) to identify the specific cysteine residues involved in this covalent interaction. Moreover, we are able to capture an intermediate in the process of electron transfer from one redox center to the other. These results lead us to propose a model that describes how the cysteines cooperate in the early stages of oxidation of DsbA. DsbB appears to adopt a novel mechanism to oxidize DsbA, using its two pairs of cysteines in a coordinated reaction to accept electrons from the active cysteines in DsbA.     

Simple, automated, high resolution mass spectrometry method to determine the disulfide bond and glycosylation patterns of a complex protein: subgroup A avian sarcoma and leukosis virus envelope glycoprotein

Enveloped viruses must fuse the viral and cellular membranes to enter the cell. Understanding how viral fusion proteins mediate entry will provide valuable information for antiviral intervention to combat associated disease. The avian sarcoma and leukosis virus envelope glycoproteins, trimers composed of surface (SU) and transmembrane heterodimers, break the fusion process into several steps. First, interactions between SU and a cell surface receptor at neutral pH trigger an initial conformational change in the viral glycoprotein trimer followed by exposure to low pH enabling additional conformational changes to complete the fusion of the viral and cellular membranes. Here, we describe the structural characterization of the extracellular region of the subgroup A avian sarcoma and leukosis viruses envelope glycoproteins, SUATM129 produced in chicken DF-1 cells. We developed a simple, automated method for acquiring high resolution mass spectrometry data using electron capture dissociation conditions that preferentially cleave the disulfide bond more readily than the peptide backbone amide bonds that enabled the identification of disulfide-linked peptides. Seven of nine disulfide bonds were definitively assigned; the remaining two bonds were assigned to an adjacent pair of cysteine residues. The first cysteine of surface and the last cysteine of the transmembrane form a disulfide bond linking the heterodimer. The surface glycoprotein contains a free cysteine at residue 38 previously reported to be critical for virus entry. Eleven of 13 possible SUATM129 N-linked glycosylation sites were modified with carbohydrate. This study demonstrates the utility of this simple yet powerful method for assigning disulfide bonds in a complex glycoprotein.     

囊膜病毒膜融合分子机制研究进展

囊膜病毒通过病毒与宿主细胞膜融合的方式感染宿主,病毒囊膜蛋白介导了膜融合过程。根据这些囊膜蛋白在病毒囊膜表面的排列、蛋白结构及其在融合肽中的位置不同,可将囊膜病毒分为三类,其利用这些囊膜特殊的蛋白分子与受体相互作用完成膜融合。在分子水平上研究这一过程有助于认识病毒侵染的本质和发现关键环节,达到预防与治疗病毒病的目的。