Monoclonal antibody #3-9-16 recognizes one of the two isoforms of rabies virus matrix protein that exposes its N-terminus on the virion surface

We investigated behaviors of the rabies virus matrix (M) protein using a monoclonal antibody (mAb), #3-9-16, that recognized a linear epitope located at the N-terminus of the protein. Based on the reactivity with this mAb, M proteins could be divided into at least two isoforms; an ordinary major form (Malpha) whose 3-9-16 epitope is hidden, and an N-terminal-exposed epitope-positive form (Mbeta). The Mbeta protein accounted for about 25-30% of the total M proteins in the virion, while its content in the cell ranged from 10 to 15% of total M protein. Fluorescent antibody (FA) staining showed that the Mbeta antigen distributed in the Golgi area where the colocalized viral glycoprotein antigen was also detected. Mbeta antigen was shown to be exposed on the surface of infected cells by both immunoprecipitation and FA staining with the mAb, whereby the cells might have become sensitive to the mAb-dependent complement-mediated cytolysis. Similarly, the Mbeta antigen was shown to be exposed on the virion surface, and the infectivity of the virus was destroyed by the mAb in the presence of a complement. Together with these results, we think that the M protein molecule takes either of two conformations, one (Mbeta) of which exposes the 3-9-16 epitope located in the N-terminal region of the M protein, that are also exposed on the surface of the virion and infected cells, whereby it might play a certain important role(s) in the virus replication process differently from the other form (Malpha), probably through its intimate association with the Golgi area and/or the cell membrane.     

Two different conformations of rabies virus glycoprotein taken under neutral pH conditions

We previously reported that the rabies virus glycoprotein (G) takes either of two different conformations (referred to as B and C forms) under neutral pH conditions, that could be differentiated by their reactivity to a monoclonal antibody (mAb), #1-30-44, that recognizes the acid-sensitive conformational epitope, and the formation taken is dependent on two separate regions containing Lys-202 and Asn-336 of the protein (Kankanamge et al., Microbiol. Immunol., 47, 507-519, 2003). Semi-quantitative antibody-binding assays demonstrated that only one-third to one-fourth of mature G proteins on the cell surface were taking the 1-30-44 epitope-positive B form even at pH 7.4. The ratio of B to C varied, depending on the environmental pH, but did not decrease to zero even at pH 5.8-6.2, preserving a certain content (about 15-20%) of B form. Immunoprecipitation studies demonstrated that a portion of G proteins were intimately associated with a dimer form of matrix (M) protein in terms of resistance to treatment with a mixture of 1% deoxycholate and 1% Nonidet P-40, and seemed to preserve the B form even at lower pHs. Similar results were also obtained with the virion-associated G proteins, including the intimate association of a portion of the G proteins with the M protein dimer. From these results, we assume that a certain portion of the rabies virion-associated G proteins are associated with a dimer form of M protein, keeping the 1-30-44 epitope-positive B conformation under various pH conditions, which might possibly assure the virion's recognition of host cell receptor molecules in the body.     

Characterization of a slow-migrating component of the rabies virus matrix protein strongly associated with the viral glycoprotein

We investigated multiple forms of rabies virus matrix (M) protein. Under non-reducing electrophoretic conditions, we detected, in addition to major bands of monomer forms (23- and 24-kDa) of M protein, an M antigen-positive slow-migrating minor band (about 54 kDa) in both the virion and infected cells. Relative contents of the 54-kDa and monomer components in the virion were about 20-30% and 70-80% of the whole M protein, respectively, while the content of the 54-kDa component was smaller (about 10-20% of the total M protein) in the cell than in the virion. The 54-kDa components could be extracted from the infected cells with sodium deoxycholate, but they were quite resistant to extraction with 1% nonionic detergents by which most monomer components were solubilized. The 54-kDa component was precipitated more efficiently than the monomer by a monoclonal antibody (mAb; #3-9-16), which recognized a linear epitope located at the N-terminal of the M protein. The mAb #3-9-16 coprecipitated the viral glycoprotein (G), which was demonstrated to be due to strong association between the G and 54-kDa component of the M protein. Monomers and the 54-kDa polypeptide migrated to the same isoelectric point (pI) in twodimensional (2-D) gel electrophoresis, implicating that the 54-kDa component was composed of component(s) of the same pI as that of the M protein monomers. From these results, we conclude that the M antigen-positive 54-kDa polypeptide is a homodimer of M protein, taking an N-terminal-exposed conformation, and is strongly associated with the viral glycoprotein. Possible association with a membrane microdomain of the cell will be discussed.     

Further studies on the mechanism of rabies virus neutralization by a viral glycoprotein-specific monoclonal antibody, #1-46-12

We previously reported that a conformational epitope-specific monoclonal antibody (mAb; #1-46-12) neutralized the rabies virus by binding only a small number (less than 20) of the antibody molecules per virion, while a linear epitope-specific mAb (#7-1-9) required more than 250 IgG molecules for the neutralization. We also isolated both the epitope-negative (R-31) and-positive (R-61) escape mutants that resisted mAb #1-46-12. Co-infection studies with wild type (wt) and R-61 mutant have shown that although the infectivity of R-61 mutant was not affected by the binding of about 300 IgG molecules per virion, incorporation of a small number of wt G protein into the R-61 virion resulted in dramatic loss of the resistance. In this study, we further investigated properties of the mutant G proteins. The R-61 G protein lost reactivity to the mAb when solubilized, even keeping a trimer form, suggesting that membrane-anchorage is essential for the maintenance of its epitope-positive conformation. On the other hand, incorporation of wt G proteins into the R-31 virions did not affect their resistance to the mAb very much. Although we have not so far found the presumed conformational changes induced by the mAb-binding, we think that these results are not inconsistent with our previously proposed novel model (referred to as a domino effect model) for the virus neutralization by mAb #1-46-12 other than a classical spike-blocking model, which implicates successive spreading of the postulated antibody-induced conformational changes of G protein to the neighboring spikes until abolishing the host cell-binding ability of the virion.     

Intracellular behavior of rabies virus matrix protein (M) is determined by the viral glycoprotein (G).

To investigate the nature and intracellular behavior of the matrix (M) protein of an avirulent strain (HEP-Flury) of rabies virus, we cloned and sequenced the cDNA of the protein. Using expression vectors pZIP-NeoSV(X)1 and pCDM8, the cDNA was transfected to animal cells (BHK-21 and COS-7) with or without coexpression of viral glycoprotein (G). When M protein alone was expressed in the cells, it displayed homogeneous distribution in the whole cell including the nucleus. In contrast, coexpression with G protein resulted in the abolishment of nuclear distribution of M antigen, and both of the antigens displayed a colocalized distribution in the cell, especially at the cellular membrane as seen in the virus-infected cells, while the distribution of G antigen was not affected by coexpressed M antigen. Immunoprecipitation studies revealed that M protein was coprecipitated with G protein by anti-G antibody, and vice versa, although cross-linking with dithiobis(succinimidyl propionate) was necessary for coprecipitation because of their easier dissociation in the presence of sodium deoxycholate. These results suggest that M protein intimately associates with G protein, which may affect or regulate the behavior (e.g., intracellular localization) of M protein. Studies with deletion mutants of M protein indicate that an internal region around the amino acids from 115 to 151 is essential for the M protein to preserve its binding ability to G protein.     

Studies on the conditions required for structural and functional maturation of rabies virus glycoprotein (G) in G cDNA-transfected cells

When the rabies virus G cDNA was expressed with the help of T7 RNA polymerase provided by a recombinant vaccinia virus (RVV-T7), functional G proteins were produced in terms of their ability to induce low pH-dependent syncytium formation and the formation of conformational epitopes, including the acid-sensitive epitope recognized by mAb #1-30-44. Such an ability and the 1-30-44 epitope formation, however, were not associated with the G gene products when G cDNA was expressed without the help of RVV-T7 using a tetracycline-regulated expression vector (pTet-G), although they were normally transported to the surface of established G protein-producing BHK-21 (G-BHK) cells. But, when the G-BHK cells were treated with 2.5 m M sodium butyrate (NaB) after the removal of tetracycline, we could observe not only a much increased frequency of G protein-producing cells, but also the greatly enhanced maturation of the protein. Another short acylate, sodium propionate (NaP), similarly induced increased G protein synthesis at a concentration of 2.5 m M as NaB; however, such proteins were mostly not endowed with the fusion activity nor the 1-30-44 epitope, while NaP at a higher concentration as 5.0 m M did induce similarly the increased production and enhanced maturation of G protein, including the 1-30-44 epitope formation. From these results, we conclude that functional maturation of G protein to acquire fusogenic activity is correlated with 1-30-44 epitope formation, and 2.5 m M NaB not only stimulates G protein production, but also provides such cellular conditions as are required for the structural and functional maturation of the protein.     

Further studies on the hyperphosphorylated form (p40) of the rabies virus nominal phosphoprotein (P)

We investigated possible mechanisms involved in production of a hyperphosphorylated form (p40) of rabies virus P protein, to which two dimensional (2-D) gel electrophoresis was applied. The P gene products produced in Escherichia coli cells could be detected as a single spot of unphosphorylated 37-kDa form (termed as p37-0) in a 2-D gel. The 37-kDa proteins in the virus-infected cells are composed of some phosphorylated forms, including a major p37-1 and more phosphorylated minor forms (e.g., p37-2, p37-3, etc.), but little p37-0 is detected (Eriguchi et al., 2002). When the E. coli -produced P protein analogues were incubated with BHK-21 cell lysates, heparin-sensitive phosphorylation occurred as described previously (Takamatsu et al., 1998), giving an additional 40-kDa spot. However, such a p40-like derivative displayed a little more basic pI value than that of the authentic p40 produced in the infected cells; hence, the former was termed p40-0 (pI=4.78), while the latter, p40-1 (pI=4.73). In contrast, p40 produced in the P cDNAtransfected animal cell was detected at the p40-1 position. In addition, staurosporine did not affect the p40-1 production in virus-infected nor the P cDNA-transfected animal cells, while the agent reduced production of hyperphosphorylated forms of p37, resulting in accumulation of p37-1, but not of p37-0. These results suggest that, although p37-0 may become a substrate for the heparin-sensitive protein kinase (PK) in vitro, only p37-1 is a substrate for p40 production catalyzed by heparin-sensitive PK in animal cells, and staurosporine-sensitive PK is involved in the production of more phosphorylated forms of p37, but not in p37-1 production from p37-0.     

Structural difference recognized by a monoclonal antibody #404-11 between the rabies virus nucleocapsid (NC) produced in virus infected cells and the NC-like structures produced in the nucleoprotein (N) cDNA-transfected cells

We investigated structural changes in the rabies virus (HEP-Flury strain) nucleocapsid (NC) during the virus replication, for which we used two anti-nucleoprotein (N) monoclonal antibodies (mAbs), #404-11 (specific for a conformation-dependently exposed linear epitope) and #1-7-11 (specific for a conformational epitope which is exposed after the nucleocapsid formation). Both mAbs recognized the N protein of the viral NC, but not of the RNA-free N-P complex. The 1-7-11 and 404-11 epitopes could be mapped to the N-terminal and the C-terminal regions of N protein, respectively. Immunoprecipitation studies demonstrated that treatment of the NC either with the alkaline phosphatase or sodium deoxycholate (DOC) resulted in dissociation of most P proteins from the NC and in the reduced reactivity to mAb #404-11, but not to mAb #1-7-11. NC-like structures produced in the N cDNA-transfected cells displayed strong reactivity to mAb #1-7-11; however, reactivity to mAb #404-11 was very weak. And, coexpression with viral phosphoprotein (P) resulted in little increase in reactivity to mAb #404-11 of the NC-like structures, while the reactivity was significantly increased by cotransfection with P and the viral minigenome whose 3'- and 5'-end structures were derived from the viral genome. From these results, we assume that, although the 404-11 epitope is a linear one, the epitope-containing region is exposed only when N proteins encapsidate properly the viral RNA in collaboration with the P protein. Further, exposure of the 404-11 epitope region might be function-related, and be regulated by association and dissociation of the P protein.     

Mapping of the low pH-sensitive conformational epitope of rabies virus glycoprotein recognized by a monoclonal antibody #1-30-44

Monoclonal antibody (mAb) #1-30-44 recognized an acid-sensitive conformational epitope of rabies virus glycoprotein (G). The antigenicity of G protein exposed on the cell surface was lost when the infected cells were exposed to pH 5.8. By comparing the deduced amino acid sequence of G protein between the HEP-Flury strain and the epitope-negative CVS strain as well as the mAb-resistant escape mutants, two distant sites that contained Lys-202 and Asn-336 were shown to be involved in the epitope formation. Lys-202 is located in the so-called neurotoxin-like sequence, while Asn-336 is included in antigenic site III and is very near the amino acid at position 333, which is known to affect greatly the neuropathogenicity of rabies virus when changed. Consistent with this finding, antigenicity of a neurovirulent revertant of the HEP-Flury strain, in which Gln-333 of G protein was replaced by Arg, was also affected as shown by its greatly decreased reactivity with mAb #1-30-44 compared to that of the original avirulent HEP virus. Based on these results, we hypothesize that the neurotoxin-like domain and some amino acids in antigenic site III come into contact with each other to form a conformational epitope for mAb #1-30-44, and such a configuration would be lost when exposed to acidic conditions to perform a certain low pH-dependent function of G protein.     

Studies on the rabies virus RNA polymerase: 3. Two-dimensional electrophoretic analysis of the multiplicity of non-catalytic subunit (P protein)

We described previously (Takamatsu et al., 1998. Microbiol. Immunol. 42: 761-771) the rabies virus P protein as being composed of several components of different sizes, among which the full-sized major components were termed as p40 and p37 according to their electrophoretic mobilities, and radiolabeling studies with [32P]phosphate implied that p40 was a hyperphosphorylated form. We further examined here these proteins by two-dimensional (2-D) gel electrophoresis and immunoblotting, showing that a major component, p37, was composed of multiply modified subcomponents of different pIs (termed p37-1, p37-2, p37-3, etc., based on their acidity) in the virion and infected cells, but the unmodified precursor (termed p37-0) was little in amount. The viral nucleocapsid (NC)-bound P proteins were composed of multiple forms of p37 (the major one was p37-1) and also a minor component, p40-1. P proteins which were bound to newly synthesized free N proteins were mostly composed of p37-1, indicating that hyperphosphorylation of P proteins occurred after their being used for the encapsidation. Treatment of the infected cells with okadaic acid induced accumulation of the more acidic forms of P proteins, suggesting that heterogeneity in the full-sized P proteins is a reflection of their dynamic aspects of multiple cycles of phosphorylations and dephosphorylations in the cell. Two-D gel analyses demonstrated also that p40 was not so acidic as we expected, and implied that our previous data of apparent hyperphosphorylation of p40 was due to very frequently recycled utilization of the protein, and preformed non-labeled P proteins were also 32P-phosphorylated in a radiolabeling period and were converted to the p40.     

Studies on the escape mutants of rabies virus which are resistant to neutralization by a highly conserved conformational epitope-specific monoclonal antibody #1-46-12

We investigated a virus-neutralizing conformational epitope of the rabies virus glycoprotein (G) that is recognized by an anti-G monoclonal antibody (mAb; #1-46-12) and shared by most of the laboratory strains of the virus. To investigate the epitope structure, we isolated escape mutants from the HEP-Flury virus (wild-type; wt) after repeated passages in culture in the presence of the mAb. Immunofluorescence studies indicated that the mutants could be classified into two groups; the Group I lacked the epitope, while Group II preserved the epitope. The latter was dominant under the passage conditions, since Group I disappeared during the continuous passages. G proteins showed different electrophoretic mobilities; G protein of Group I migrated at the same rate as wt G protein, while that of Group II migrated at a slower rate, which was shown to be due to acquisition of an additional oligosaccharide side chain. Nucleotide sequencing of the G gene strongly suggested that amino acid substitutions at Thr-36 by Pro and Ser-39 by Thr of the G protein are responsible for the escape mutations of Groups I and II, respectively. The latter is a unique mutation of the rabies virus that allows the G protein to be glycosylated additionally at Asn-37, a potential glycosylation site that is not glycosylated in the parent virus, in preserving the epitope-positive conformation. These results suggest that to keep the 1-46-12 epitope structure is of greater survival advantage for the virus to escape the neutralization than to destroy it, which could be achieved by acquiring an additional oligosaccharide chain at Asn-37.     

Further characterization of the rabies virus glycoproteins produced by virus-infected and G cDNA-transfected cells using a monoclonal antibody, #1-30-44, which recognizes an acid-sensitive epitope

Expression of rabies virus glycoprotein (G) by G cDNA-transfected mammalian cells resulted in the production of only a fusion-negative form. Low pH-dependent fusion activity, however, was seen when the expression was done under control of the T7 promoter with the help of recombinant vaccinia virus (RVV-T7) that provided T7 RNA polymerase. Fusion-inactive G proteins were transported to the cell surface as being detected by a conformational epitope-specific monoclonal antibody (mAb; #1-46-12). The fusion-inactive G proteins were recognized by most of our 13 conformation-specific mAbs, except for one mAb, #1-30-44, that recognized the low pH-sensitive conformational epitope. When the G gene expression was done with the help of RVV-T7, although most G proteins remained in the epitope-negative form, a small fraction of G gene products were 1-30-44 epitope-positive, and cell fusion activity could be seen when cells were exposed to low pH conditions. From these results, we conclude that acquisition of low pH-dependent fusion activity is closely related to structural maturation of the G protein to form the low pH-sensitive 1-30-44 epitope. Such maturation seems to be dependent on certain rabies virus-induced cellular conditions or functions, which might also be provided in part by the vaccinia virus infection. We further assume that expression of G cDNA alone mostly results in the production of mis-folded and/or differently folded forms of G protein, and only a small fraction is correctly folded even under RVV-T7-mediated expression conditions.     

Association of rabies virus nominal phosphoprotein (P) with viral nucleocapsid (NC) is enhanced by phosphorylation of the viral nucleoprotein (N)

We investigated possible role(s) of N protein phosphorylation in the rabies virus replication process. A large amount of P proteins are associated with the viral nucleocapsid (NC) in the infected cell, the amount which was greatly decreased by phosphatase-treatment of the isolated NC, indicating that the phosphate group of N and/or P proteins is essential for their stable association with the NC. Immunoprecipitation studies were performed on the coexpressed normal N or phosphorylation deficient N(S389A) and P proteins, demonstrating that the P protein associated with phosphorylation-deficient NC-like structures was much less in amount than that associated with the wild type NC. Similar results were also obtained with a mutant P protein, PDeltaN19, which lacked the N-terminal 19 amino acids and was capable of binding to the NC-like structures but incapable of forming the RNA-free N-P complexes. Immunoprecipitation studies with mAb #402-13 further suggested that the NC-specific linear 402-13 epitope was exposed even on the P proteins which were associated with the phosphorylation-deficient NC-like structures, but such association was very weak as demonstrated by greatly decreased amounts of coprecipitated NC-like structures. From these results, we assume that the phosphorylation of N protein enhances the association between the 402-13 epitope-positive P protein and the NC probably by stabilizing such P-NC binding.     

Role of glycosylation in structure and stability of Erythrina corallodendron lectin (EcorL): a molecular dynamics study

The effect of glycosylation on structure and stability of glycoproteins has been a topic of considerable interest. In this work, we have investigated the solution conformation of the oligosaccharide and its effect on the structure and stability of the glycoprotein by carrying out a series of long Molecular dynamics (MD) simulations on glycosylated Erythrina corallodendron lectin (EcorL) and nonglycosylated recombinant Erythrina corallodendron lectin (rEcorL). Our results indicate that, despite the similarity in overall three dimensional structures, glycosylated EcorL has lesser nonpolar solvent accessible surface area compared to nonglycosylated EcorL. This might explain the experimental observation of higher thermodynamic stability for glycosylated EcorL compared to nonglycosylated EcorL. Analysis of the simulation results indicates that, dynamic view of interactions between protein residues and oligosaccharide is entirely different from the static picture seen in the crystal structure. The oligosaccharide moiety had dynamically stable interactions with Lys 55 and Tyr 53, both of which are separated in sequence from the site of glycosylation, Asn 17. It is possible that glycosylation helps in forming long-range contacts between amino acids, which are separated in sequence and thus provides a folding nucleus. Thus our simulations not only reveal the conformations sampled by the oligosaccharide, but also provide novel insights into possible molecular mechanisms by which glycosylation can help in folding of the glycoprotein by formation of folding nucleus involving specific contacts with the oligosaccharide moiety.     

Effect of the infectious laryngotracheitis virus (ILTV) glycoprotein G on virus attachment,penetration, growth curve and direct cell-to-cell spread

The secreted alphaherpesvirus glycoprotein G (gG) works differently from other proteins. Analysis of the role of ILTV gG in virus attachment, penetration, direct cell-to-cell spread (CTCS) and the growth curve showed that gG or its antibody had no effect on ILTV attachment and penetration and that the gG antibody reduced the virus plaque size and the one-step growth curve on chicken embryo liver (CEL) cells, but gG did not affect the virus plaque size or the one-step growth curve on CEL cells. Laser scanning confocal microscopy (LSCM) detection showed that ILTV gG is located in the perinuclear region and the membrane of the CEL cells. These results suggested that ILTV gG might contribute to direct cell-to-cell transmission.     

Effect of the infectious laryngotracheitis virus (ILTV) glycoprotein G on virus attachment, penetration, growth curve and direct cell-to-cell spread

Glycoprotein G plays many important roles in al-phaherpesvirus except for the varicella-zoster virus (VZV), from which gG is absent[1]. The gG of most alphaherpesviruses is secreted after proteolytic proc-essing, as occurs in the herpes simplex virus 2 (HSV- 2)[2―4], bovine herpesvirus 1 (BHV-1)[5―7], bovine herpesvirus 5 (BHV-5)[8], equine herpesvirus 1 (EHV- 1)[9], equine herpesvirus 3 (EHV-3)[10], equine herpes-virus 4 (EHV-4)[11], feline herpesvirus 1 (FHV-1)[12], infectious la…     

Immunochemical and single molecule force spectroscopy studies of specific interaction between the laminin binding protein and the West Nile virus surface glycoprotein E domain II

ELISA and Western blot immunochemical data attest an effective and highly specific interaction of the surface glycoprotein E domain II (DII) of the tick born encephalitis and Dengue viruses with the laminin binding protein (LBP). Based on a highly conservative structure of the DII in different flaviviruses we propose a similarly effective interaction between the LBP and the DII of the surface glycoprotein E of the West Nile virus. We report the results of studies of this interaction by immunochemical and single molecule force spectroscopy methods. The specific binding between these species is confirmed by both methods.     

Effect of phospholipids on conformational structure of bovine pancreatic trypsin inhibitor (BPTI) and its thermolabile mutants

The effects of negatively charged phosphatidylserine-prepared membranes (PS) and neutral phosphatidylcholine-prepared membranes (PC) on the structure of wild-type and mutant bovine pancreatic trypsin inhibitor (BPTI) at neutral pH were investigated. The presence of PC did not have any effect on the protein structure while PS induced a non-native structure in three mutant BPTI proteins. However, the negatively charged membrane did not have any effect on wild-type BPTI. The findings revealed that (i) elimination of some disulphide bonds results in dramatic change in protein structure, and, (ii) that this biochemical interaction is surface-driven and electrostatic interactions may play a very strong role in influencing the fore-stated changes in protein structure. Of further interest were the results obtained from investigating the possible role of PS fluidity and concentration in altering mutant. When the value of Gibbs free-energy change of unfolding (DeltaG(U)) was positive, various non-native structures were formed in a concentration-dependent manner. However, when the value of DeltaG(U) was negative, only two types of non-native structures were formed: one with high beta structure content at low PS fluidity state, and the other with a high alpha-helical content at high PS fluidity state. Our study reveals how particular combinations of phospholipid:protein interactions can induce a protein conformation transition from a native to a non-native one at neutral pH, especially when the native structure is predestabilized by amino acid substitutions. This revelation may open up opportunities to explore alternative ways in which phospholipids may play a role in protein mis-folding and the related pathologies.