Construction of a poliovirus type 1/type 2 antigenic hybrid by manipulation of neutralization antigenic site II.

There are three serotypes of poliovirus, poliovirus type 1 (PV-1), PV-2, and PV-3. These viruses each display four distinct neutralization antigenic sites, designated N-AgI, N-AgII, N-AgIIIA, and N-AgIIIB. It has been demonstrated previously that part of N-AgI can be replaced with heterogeneous amino acid sequences, resulting in hybrid viruses expressing heterogeneous antigenic determinants. To study whether hybrid viruses could be constructed by modifying another antigenic site, a part of N-AgII (amino acids 158 to 173 of VP2) of PV-1(Mahoney) was replaced with the equivalent sequence from PV-2(Lansing). The resulting hybrid was viable and expressed both PV-1 and PV-2 antigenic determinants. When inoculated into rabbits, the hybrid induced neutralizing antibodies against both PV-1 and PV-2, showing that amino acids 158 to 173 of VP2 are able to function as an antigenic site independent of the rest of N-AgII. Manipulation of N-AgII represents a useful alternative method for the production of hybrid polioviruses.     

Identification of a T-cell epitope adjacent to neutralization antigenic site 1 of poliovirus type 1.

Proliferative T-cell responses to poliovirus in various strains of mice have been analyzed by using either killed purified virus or capsid protein VP1 synthetic peptides. Following immunization of mice with inactivated poliovirus type 1 (PV1), a specific proliferative response of their lymph node CD4+ T cells was obtained after in vitro stimulation with purified virus. In mice immunized with PV1, PV2, or PV3, a strong cross-reactivity of the T-cell responses was observed after in vitro stimulation with heterologous viruses. By using various strategies, a dominant T-cell epitope was identified in the amino acid 103 to 115 region of capsid polypeptide VP1, close by the C3 neutralization epitope. The T-cell response to VP1 amino acids 103 to 115 is H-2 restricted: H-2d mice are responders, whereas H-2k and H-2b mice do not respond to this T-cell epitope. Immunization of BALB/c (H-2d) mice with the uncoupled p86-115 peptide, which represents VP1 amino acids 86 to 115 and contains both the T-cell epitope and the C3 neutralization epitope, induced poliovirus-specific B- and T-cell responses. Moreover, these mice developed poliovirus neutralizing antibodies.     

Identification of a new neutralization antigenic site on poliovirus coat protein VP2

Major neutralization antigenic sites have been previously mapped by us on VP1, the largest capsid protein of poliovirus type 1. Here we report the first identification of the primary sequence of a neutralization antigenic site on capsid protein VP2. Inspection of the amino acid sequence of VP2 led to the selection and synthesis of a peptide (n = 12) that, after linking to a carrier protein, induced an antiviral neutralizing antibody response in rabbits. The response was augmented by a single subsequent inoculation of intact virus; thus, the peptide was also capable of priming the production of neutralizing antibodies. These antibodies were directed only against the site specified by the synthetic peptide. Although the VP2-specific neutralization antigenic site appears not to be strongly immunogenic in the intact virion, it can nevertheless contribute to neutralization of poliovirus. This observation may be important for the development of peptide vaccines.     

The antigenic structure of poliovirus

We have solved the structure of the Mahoney strain of type 1 and the Sabin (attenuated vaccine) strain of type 3 poliovirus by X-ray crystallographic methods. By providing a three-dimensional framework for the interpretation of a wealth of experimental data, the structures have yielded insight into the architecture and assembly of the virus particle, have provided information regarding the entry of virus into susceptible cells, and defined the sites on the virus particle that are recognized by neutralizing monoclonal antibodies. Thus locating mutations in variants selected for resistance to neutralizing monoclonal antibodies has defined three antigenic sites of the surface of the virion, and provided clues as to the mechanisms by which viruses escape neutralization. Finally, comparison of the structures of the two strains, together with analysis of sequences of many poliovirus strains, have begun to define the structural changes associated with serotypic differences between polioviruses.     

Correlation between poliovirus type 1 Mahoney replication in blood cells and neurovirulence.

Poliovirus (PV) is not often described as a monocyte- or macrophage-tropic virus; however, previous work indicated that neurovirulent PV type 1 Mahoney [PV(1)Mahoney] can productively infect primary human monocytes. To determine whether this replication has a functional role in pathogenesis, primary human mononuclear blood cells were infected with pairs of attenuated and neurovirulent strains of PV. Two neurovirulent strains of PV, PV(1)Mahoney and PV(2)MEF-1, replicated faster and to higher titers than attenuated counterparts PV(1)Sabin and PV(2)W-2, respectively, in primary human monocytes, suggesting that this replication may contribute to pathogenesis. PV(3)Leon grew weakly, while PV(3)Sabin, PV(2)Sabin, and PV(2) P712 did not replicate in these cells, perhaps because of their slow replication cycle. In U937 cells, a monocytelike cell line, PV(1)Mahoney replicated but PV(1)Sabin did not, while both grew well in HeLa cells. When molecular recombinants of PV(1)Mahoney and PV(1)Sabin were assessed, a correlation between neurovirulence and the ability to replicate in primary human mononuclear blood cells was found. Surprisingly, infectious centers assays with primary human mononuclear blood cells and U937 cells indicated that despite the lower overall viral yield, more cells are initially infected with the attenuated viruses. These results indicate that there are virulence-specific differences in the ability of PV(1)Mahoney to replicate in monocytes and suggest that there may be factors in monocytes that virulent strains of PV require.     

Three-dimensional structure of a mouse-adapted type 2/type 1 poliovirus chimera.

The crystal structure of V510, a chimeric type 2/type 1 poliovirus, has been determined at 2.6 A resolution. Unlike the parental Mahoney strain of type 1 poliovirus, V510 is able to replicate in the mouse central nervous system, due entirely to the replacement of six amino acids in the exposed BC loop of capsid protein VP1. Significant structural differences between the two strains cluster in a major antigenic site of the virus, located at the apex of the radial projection which surrounds the viral five-fold axis. Residues implicated in the mouse-virulence of poliovirus by genetic studies are located in this area, and include the residues which are responsible for stabilizing the conformation of the BC loop in V510. Despite evidence that this area is not involved in receptor binding in cultured primate cells, the genetic and structural observations suggest that this area plays a critical role in receptor interactions in the mouse central nervous system. These results provide a structural framework for further investigation of the molecular determinants of host and tissue tropism in viruses.     

Mutations conferring resistance to neutralization with monoclonal antibodies in type 1 poliovirus can be located outside or inside the antibody-binding site.

Antigenic variants resistant to eight neutralizing monoclonal antibodies were selected from wild (Mahoney) and attenuated (Sabin) type 1 infectious poliovirions. Cross-immunoprecipitation revealed interrelationships between epitopes which were not detected by cross-neutralization. Operational analysis of antigenic variants showed that seven of eight neutralization epitopes studied were interrelated. Only one neutralization epitope, named Kc, varied independently from all the others. This latter, recognized by C3 neutralizing monoclonal antibody, was present not only on infectious virions but also on heat-denatured (C-antigenic) particles and on isolated capsid protein VP1. Loss of the neutralization function of an epitope did not necessary result from the loss of its antibody-binding capacity. Such potential, but not functional, neutralization epitopes exist naturally on Mahoney and Sabin 1 viruses. Their antibody-binding property could be disrupted by isolating antigenic variants in the presence of the nonneutralizing monoclonal antibody and anti-mouse immunoglobulin antibodies. Single-point mutations responsible for the acquisition of resistance to neutralization in the antigenic variants were located by sequence analyses of their genomes. Mutants selected in the presence of C3 neutralizing monoclonal antibody always had the mutation located inside the antibody-binding site (residues 93 through 103 of VP1) at the amino acid position 100 of VP1. On the contrary, antigenic variants selected in the presence of neutralizing monoclonal antibodies reacting only with D-antigenic particles had mutations situated in VP3, outside the antibody-binding site (residues 93 through 103 of VP1). The complete conversion of the Mahoney to the Sabin 1 epitope map resulted from a threonine-to-lysine substitution at position 60 of VP3.     

Molecular basis for linkage of a continuous and discontinuous neutralization epitope on the structural polypeptide VP2 of poliovirus type 1.

We obtained neutralizing monoclonal antibodies against a continuous neutralization epitope on VP2 of poliovirus type 1 strain Mahoney by using a combined in vivo-in vitro immunization procedure. The antibody-binding site was mapped to amino acid residues within the peptide segment (residues 164 through 170) of VP2 by competition with synthetic peptide and sequencing of resistant mutants. Cross-neutralization of these mutants with another neutralizing monoclonal antibody revealed a linkage of the continuous epitope and a discontinuous neutralization epitope involving both loops of the double-loop structure of VP2 at the twofold axis on the surface of the virion.     

Comparative sensitivities of Sabin and Mahoney poliovirus type 1 prototype strains and two recent isolates to low concentrations of glutaraldehyde.

Significant intratypic differences in the glutaraldehyde (GTA) sensitivity of echovirus isolates have been shown. While exploring ways to optimize the study of GTA sensitivity of enteroviruses, we also observed intratypic differences in poliovirus type 1 isolates collected in France. A suspension procedure was used for assessing the virucidal effect of GTA at low concentrations (< or = 0.10%) against purified viruses. Two recent isolates of poliovirus type 1 tested were first fully characterized by the PCR restriction fragment length polymorphism (RFLP) test. The RFLP pattern of clinical isolate 5617 was similar to that of poliovirus type 1 LS-c, 2ab (Sabin strain), confirming the vaccine origin of strain 5617. The RFLP pattern of strain 5915 recovered from sewage was different from that of the Mahoney strain, suggesting a genetic variation in this wild isolate. We then analyzed under the same controlled conditions the GTA sensitivities of both isolates and their respective prototype strains. The wild Mahoney and 5915 strains exhibited significantly lower sensitivities to GTA than did the vaccine Sabin and 5617 strains. The inactivation rates of clinical isolates 5617 and 5915 were very similar to those of their corresponding reference Sabin and Mahoney strains. Both the conformational structure of the capsid of each strain and the amino acid constitution of structural polypeptides could be involved in the variations observed. The relevance of our comparative sensitivity studies to standardization of virucidal tests is discussed.     

The nucleotide sequence of poliovirus type 3 leon 12 a1b: comparison with poliovirus type 1.

The complete nucleotide sequence of the genome of the Sabin vaccine strain of poliovirus type 3 (P3/Leon 12 a1 b) has been determined from cDNA cloned in E. coli. The genome comprises a 5' non-coding region of 742 nucleotides, a large open reading frame of 6618 nucleotides (89% of the sequence) and a 3' non-coding region of 72 nucleotides. There is 77.4% base-sequence homology and 89.6% predicted amino-acid homology between types 1 and 3. Conservation of all glutamine-glycine and tyrosine-glycine cleavage sites suggests a mechanism of polyprotein processing similar to that established for poliovirus type 1.     

The EM structure of a type I interferon-receptor complex reveals a novel mechanism for cytokine signaling

Type I interferons (IFNs) have pleiotropic effects, including antiviral, antiproliferative, and immunomodulatory responses. All type I IFNs bind to a shared receptor consisting of the two transmembrane proteins ifnar1 and ifnar2. We used negative stain electron microscopy to calculate a three-dimensional reconstruction of the ternary complex formed by a triple mutant IFN α2 with the ectodomains of ifnar1 and ifnar2. We present a model of the complex obtained by placing atomic models of subunits into the density map of the complex. The complex of IFN α2 with its receptor (a class II cytokine receptor) shows structural similarities to the complexes formed by growth hormone and erythropoietin with their receptors (members of the class I cytokine receptor family). Despite different assembly mechanisms, class I and class II cytokine receptors thus appear to initiate signaling through similar arrangements of the receptors induced by the binding of their respective ligands.     

Evidence for local inflammation in complex regional pain syndrome type 1

BACKGROUND: The pathophysiology of complex regional pain syndrome type 1 (CRPS 1) is still a matter of debate. Peripheral afferent, efferent and central mechanisms are supposed. Based on clinical signs and symptoms (e.g. oedema, local temperature changes and chronic pain) local inflammation is suspected. AIM: To determine the involvement of neuropetides, cytokines and eicosanoids as locally formed mediators of inflammation. METHODS: In this study, nine patients with proven CRPS 1 were included. Disease activity and impairment was determined by means of a Visual Analogue Scale, the McGill Pain Questionnaire, the difference in volume and temperature between involved and uninvolved extremities, and the reduction in active range of motion of the involved extremity. Venous blood was sampled from and suction blisters made on the involved and uninvolved extremities for measurement of cytokines interleukin (IL)-6, II-1beta and tumour necrosis factor-alpha (TNF-alpha), the neuropetides NPY and CRGP, and prostaglandin E2RESULTS: The patients included in this study did have a moderate to serious disease activity and impairment. In plasma, no changes of mediators of inflammation were observed. In blister fluid, however, significantly higher levels of IL-6 and TNF-alpha in the involved extremity were observed in comparison with the uninvolved extremity. CONCLUSIONS: This is the first time that involvement of mediators of inflammation in CRPS 1 has been so clearly and directly demonstrated. This observation opens new approaches for the succesful use and development of immunosuppressives in CRPS 1.     

Subunit structure of a high-affinity receptor for type beta-transforming growth factor. Evidence for a disulfide-linked glycosylated receptor complex

The structure of high-affinity receptors for type beta-transforming growth factor (beta TGF) has been examined by affinity labeling with 125I-beta TGF and disuccinimidyl suberate. The major receptor component labeled by 125I-beta TGF in mouse, rat, and chick fibroblasts migrated as a 280-290-kilodalton species on dodecyl sulfate-polyacrylamide electrophoresis gels in the presence of reductant, dithiothreitol. A larger (330-kilodalton) species was labeled in human fibroblasts, but comparative peptide mapping indicated a close structural relationship with receptors from mouse fibroblasts. In the absence of reductant, the affinity-labeled beta TGF receptor migrated in the gels as a larger disulfide-linked complex. The molecular mass calculated from the hydrodynamic properties of native nonreduced beta TGF receptors was 565 (mouse) or 615 kilodaltons (human). Other molecular parameters for the beta TGF receptor were: Stokes radius, 8.3-8.5 nm; sedimentation coefficient, 12.7-13.0 S; and frictional ratio, f/f0 = 1.4. The beta TGF receptor was solubilized under conditions in which the structural and ligand-binding properties of the native state were retained. beta TGF receptors solubilized from human, mouse, and chick cells interacted specifically with immobilized wheat germ agglutinin. These data suggest that the high affinity receptor for beta TGF in human, rodent, and avian fibroblasts is a disulfide-linked glycosylated 565-615-kilodalton complex with a 280-330-kilodalton subunit that contains the ligand-binding site. The oligomeric structure of the beta TGF receptor does not appear to be induced by receptor occupancy with the ligand.     

Demonstration of an immunodominant neutralization site by analysis of antigenic variants of SA11 rotavirus

Serotype-specific monoclonal antibodies were used to select mutants of SA11 rotavirus that were resistant to neutralization. The antigenic characteristics of these mutants were studied with with a panel of monoclonal antibodies. We isolated one type of mutant which showed a dramatic increase (greater than 10-fold) in resistance to neutralization by hyperimmune antiserum, and this together with other data indicates the presence on the rotavirus major outer shell glycoprotein of an immunodominant antigenic site involved in virus neutralization. The mutants were also useful in classifying neutralizing monoclonal antibodies.     

A poliovirus type 1 neutralization epitope is located within amino acid residues 93 to 104 of viral capsid polypeptide VP1.

Using nuclease Bal31, deletions were generated within the poliovirus type 1 cDNA sequences, coding for capsid polypeptide VP1, within plasmid pCW119. The fusion proteins expressed in Escherichia coli by the deleted plasmids reacted with rabbit immune sera directed against poliovirus capsid polypeptide VP1 (alpha VP1 antibodies). They also reacted with a poliovirus type 1 neutralizing monoclonal antibody C3, but reactivity was lost when the deletion extended up to VP1 amino acids 90-104. Computer analysis of the protein revealed a high local density of hydrophilic amino acid residues in the region of VP1 amino acids 93-103. A peptide representing the sequence of this region was chemically synthesized. Once coupled to keyhole limpet hemocyanin, this peptide was specifically immunoprecipitated by C3 antibodies. The peptide also inhibited the neutralization of poliovirus type 1 by C3 antibodies. We thus conclude that the neutralization epitope recognized by C3 is located within the region of amino acids 93-104 of capsid polypeptide VP1.     

Folding and processing of the capsid protein precursor P1 is kinetically retarded in neutralization site 3B mutants of poliovirus.

Poliovirus mutants in neutralizing antigenic site 3B were constructed by replacing the glutamic acid residue at amino acid 74 of capsid protein VP2 (VP2074E), using site-specific mutagenesis methods. All viable mutants display small-plaque phenotypes. Characterization of these mutants indicates that capsid assembly is perturbed. Although the defect in capsid assembly reduces the yield of mutant virus particles per cell, the resultant assembled particle is wild-type-like in structure and infectivity. Analyses of capsid assembly intermediates show a transient accumulation of the unprocessed capsid protein precursor, P1, indicating that cleavage of the mutant P1 by the 3CD protease is retarded. The mutant VP0-VP3-VP1 complex generated upon P1 cleavage appears assembly competent, forming pentamer and empty capsid assembly intermediates and infectious virion particles. Although the structure of the infectious mutant virus is virtually identical with that of the wild-type virus, the thermal stability of the mutant virus is dramatically increased over that of the wild-type virus. Thus, mutations at this residue are pleiotropic, altering the kinetics of capsid assembly and generating a virus that is more thermostable and more resistant to neutralization by the site 3B monoclonal antibodies.     

The herpes simplex virus type I DNA polymerase. Polypeptide structure and antigenic domains

Polyclonal antibodies responding specifically to the N-terminal, central and C-terminal polypeptide domains of the herpes simplex virus type I (HSV-1) DNA polymerase of strain Angelotti were generated. Each of the five different rabbit antisera reacted specifically with a viral 132 +/- 5-kDa polypeptide as shown by immunoblot analysis. Enzyme binding and inhibition studies revealed that antibodies raised to the central and the C-terminal domains of the protein inhibited the polymerizing activity by 70-90%, respectively, which is well in line with the proposed site of the catalytic center of the enzyme and with the possible involvement of these polypeptide chains in DNA-protein interactions. In agreement with this, antibodies directed towards the N-terminal domain bound to the enzyme without effecting the enzymatic activity. The strong binding but low inhibitory properties of antibodies directed to the polypeptide region between residues 1072 and 1146 confirms previous suggestions that these C-terminal sequences, which share no homology to the Epstein-Barr virus DNA polymerase, are less likely involved in the building of the polymerase catalytic site. Antibodies, raised to the very C terminus of the polymerase (EX3), were successfully used to identify a single 132 +/- 5-kDa polypeptide, which coeluted with the HSV DNA polymerase activity during DEAE-cellulose chromatography, and were further shown to precipitate a major viral polypeptide of identical size. From the presented data it can be concluded that the native enzyme consists of a single polypeptide with a size predicted from the long open reading frame of the HSV-1 DNA polymerase gene.