Cell surface receptors for picornaviruses

Does enterovirus 71 urge for effective vaccine control strategies? Challenges and current opinion

Enterovirus 71 (EV71) is an infectious virus affecting all age groups of people around the world. It is one of the major aetiologic agents for HFMD (hand, foot and mouth disease) identified globally. It has led to many outbreaks and epidemics in Asian countries. Infection caused by this virus that can lead to serious psychological problems, heart diseases and respiratory issues in children younger than 10 years of age. Many studies are being carried out on the pathogenesis of the virus, but little is known. The host immune response and other molecular responses against the virus are also not clearly determined. This review deals with the interaction between the host and the EV71 virus. We discuss how the virus makes use of its proteins to affect the host's immunity and how the viral proteins help their replication. Additionally, we describe other useful resources that enable the virus to evade the host's immune responses. The knowledge of the viral structure and its interactions with host cells has led to the discovery of various drug targets for the treatment of the virus. Additionally, this review focusses on the antiviral drugs and vaccines developed by targeting various viral surface molecules during their infectious period. Furthermore, it is asserted that the improvement of prevailing vaccines will be the simplest method to manage EV71 infection swiftly. Therefore, we summarise numerous vaccines candidate for the EV71, such as the use of an inactivated complete virus, recombinant VP1 protein, artificial peptides, VLPs (viral-like particles) and live attenuated vaccines for combating the viral outbreaks promptly.

A nonpolio enterovirus with respiratory tropism causes poliomyelitis in intercellular adhesion molecule 1 transgenic mice

Coxsackievirus A21 (CAV21) is classified within the species Human enterovirus C (HEV-C) of the Enterovirus genus of picornaviruses. HEV-C share striking homology with the polioviruses (PV), their closest kin among the enteroviruses. Despite a high level of sequence identity, CAV21 and PV cause distinct clinical disease typically attributed to their differential use of host receptors. PV cause poliomyelitis, whereas CAV21 shares a receptor and a propensity to cause upper respiratory tract infections with the major group rhinoviruses. As a model for CAV21 infection, we have developed transgenic mice that express human intercellular adhesion molecule 1, the cell-surface receptor for CAV21. Surprisingly, CAV21 administered to these mice via the intramuscular route causes a paralytic condition consistent with poliomyelitis. The virus appears to invade the CNS by retrograde axonal transport, as has been demonstrated to occur in analogous PV infections. We detected human intercellular adhesion molecule 1 expression on both transgenic mouse and human spinal cord anterior horn motor neurons, indicating that members of HEV-C may share PV's potential to elicit poliomyelitis in humans.

Variation in enterovirus receptor genes

The increased incidence of a enterovirus infections observed in patients with type 1 diabetes preceding the development of the clinical disease could be partially explained by variation in the genes coding for enterovirus receptors. We carried out sequence analysis of the most common enterovirus receptor molecules in 21 diabetic children and 20 healthy adults. DNA was isolated from the leukocytes, and gene regions known to code for virus-recognizing domains in major enterovirus receptors were amplified and sequenced. Heterozygous single-nucleotide polymorphism (SNP), Ala 67 (GCG) --> Thr (ACG), was detected in the poliovirus receptor gene in four individuals in the diabetes group, but not in the control group. However, serological studies could not confirm that this substitution would convey different susceptibility to poliovirus infection. A heterozygous SNP, Lys 29 (AAG) --> Met (ATG), was found in the intracellular adhesion molecule-1 (ICAM-1) (receptor for rhinoviruses and some coxsackie A viruses) in one individual in both groups. A silent SNP in the alpha2 integrin subunit gene (echovirus 1 receptor) was frequently found in both groups, a silent heterozygotic SNP in coxsackievirus-adenovirus receptor (coxsackie B virus receptor) gene was seen in one individual in the diabetes group, whereas no variation was found in the DAF (echovirus receptor) and beta3 integrin subunit sequences (receptor for coxsackievirus A9) studied. In conclusion, both synonymous and nonsynonymous sequence variability of genes coding for enterovirus and rhinovirus receptors was shown to occur, but no pattern directly specific for type 1 diabetes was found. =

Molecular mechanisms of virus spread and virion components as tools of virulence. A review

Despite of differences in replication strategy among virus families, some basic principles have remained similar. Analogous mechanisms govern virus entry into cells and the use of enzymes which direct the replication of the virus genome. The function of many cell surface receptors (such as glycosoaminoglycans, glycoproteins, proteins) which interact with viral capsid proteins or envelope glycoproteins has recently been elucidated. The list of cellular receptors (Table I) is still far from being final. The capsid components, similarly as the envelope glycoproteins, may form specific pocket like sites, which interact with the cell surface receptors. Neutralizing antibodies usually react with antigenic domains adjacent to the receptor binding site(s) and hamper the close contact inevitable for virion attachment. In the case of more complex viruses, such as herpes simplex virus, different viral glycoproteins interact with several cellular receptors. At progressed phase of adsorption the virions are engulfed into endocytic vesicles and the virion fusion domain(s) become(s) activated. The outer capsid components of reoviruses which participate in adsorption and fusion may get activated already in the lumen of digestive tract, i.e. before their engulfment by resorptive epithelium cells. Activation of the hydrophobic fusion domain(s) is a further important step allowing to pass through the lipid bilayer when penetrating the cell membrane in order to reach the cytosol. Activation of the virion fusion domain is accomplished by a conformation change, which occurs at acid pH (influenza virus hemagglutinin, sigma 1 protein of the reovirus particle) and/or after protease treatment. The herpes simplex virus fusion factors (gD and gH) undergo conformation changes by a pH-independent mechanism triggered due to interaction with the cell surface receptor(s) and mediated by mutual interactions with the viral envelope glycoproteins. The virion capsid or envelope components participating in the entry and membrane fusion are not the only tools of virulence. The correct function of virus coded proteins, which participate in replication of the viral genome, and/or in the supply of necessary nucleotides, may be very essential. In the case of enteroviruses, which RNA interacts with ribosomes directly, the correct configuration of the non-coding viral RNA sequence is crucial for initiation of translation occurring in the absence of the classical "cap" structure.

Interaction of coxsackievirus A21 with its cellular receptor, ICAM-1

Coxsackievirus A21 (CAV21), like human rhinoviruses (HRVs), is a causative agent of the common cold. It uses the same cellular receptor, intercellular adhesion molecule 1 (ICAM-1), as does the major group of HRVs; unlike HRVs, however, it is stable at acid pH. The cryoelectron microscopy (cryoEM) image reconstruction of CAV21 is consistent with the highly homologous crystal structure of poliovirus 1; like other enteroviruses and HRVs, CAV21 has a canyon-like depression around each of the 12 fivefold vertices. A cryoEM reconstruction of CAV21 complexed with ICAM-1 shows all five domains of the extracellular component of ICAM-1. The known atomic structure of the ICAM-1 amino-terminal domains D1 and D2 has been fitted into the cryoEM density of the complex. The site of ICAM-1 binding within the canyon of CAV21 overlaps the site of receptor recognition utilized by rhinoviruses and polioviruses. Interactions within this common region may be essential for triggering viral destabilization after attachment to susceptible cells.

Mapping the binding domains on decay accelerating factor (DAF) for haemagglutinating enteroviruses: implications for the evolution of a DAF-binding phenotype

Decay accelerating factor (DAF) functions as a cell attachment receptor for a wide range of human enteroviruses, the interaction accounting for the haemagglutination phenotype exhibited by many members of this family. Haemagglutination inhibition assays using purified truncated soluble DAF (sDAF) receptors and short consensus repeat (SCR) domain-specific antibodies have been used to determine the domain(s) of DAF to which the viruses bind. Further sDAF-mediated virus neutralization and biosensor analysis have been used to confirm the virus-binding domains of DAF. Of the four distinct clusters of human enteroviruses, three contain representatives that bind DAF. The majority of DAF-binding enteroviruses occupy the 'CBV-like' cluster, and require SCR domains 2-4 for DAF binding. In contrast, the DAF-binding representatives of the 'ENV70-like' and 'PV-like' clusters require SCR1 for DAF interaction. These studies confirm that DAF binding is a widespread characteristic amongst phylogenetically divergent clusters within the enteroviruses and suggest that the ability to bind DAF may have evolved more than once within this group of viruses.

A review of the possible mechanisms for the persistence of foot-and-mouth disease virus

Foot-and-mouth disease (FMD) was the first animal disease to be attributed to a virus, and the second virus to be discovered [1]. It is a positive-sense, singlestranded RNA picornavirus and the sole member of the genus Aphthovirus. Each infectious virus particle contains a single strand of RNA approximately 8-5 kb long. This is translated into a single polypeptide which is then cleaved into the structural and non-structural virus proteins.

Identification and characterization of the cell surface 70-kilodalton sialoglycoprotein(s) as a candidate receptor for encephalomyocarditis virus on human nucleated cells

The attachment of encephalomyocarditis (EMC) virus to human nucleated cells susceptible to virus infection was examined with HeLa and K562 cell lines. Both cell types showed specific virus binding competitively blocked by unlabeled virions. The number of binding sites for EMC virus on HeLa and K562 cells were approximately 1.6 x 10(5) and 3.5 x 10(5) per cell, respectively, and dissociation binding constants were 1.1 and 2.7 nM, respectively. Treatment of cells with cycloheximide after pretreatment with trypsin eliminated EMC virus attachment, suggesting that the virus-binding moiety is proteinaceous in nature. Digestion of cells, cell membranes, and sodium deoxycholate-solubilized cell membranes with proteases or neuraminidases or treatment of cells with lectins demonstrated that the EMC virus-cell interaction is mediated by a sialoglycoprotein. Proteins with a molecular mass of 70 kDa were isolated from detergent-solubilized cell membranes of both HeLa and K562 cells by EMC virus affinity chromatography. The purified proteins, as well as their 70-kDa-molecular-mass equivalents detected in intact surface membranes of HeLa and K562 cells, specifically bound EMC virus in a virus overlay protein blot assay, whereas membranes from nonpermissive K562 D clone cells did not. Western immunoblot analysis with glycophorin A-specific antibody confirmed that the identified 70-kDa binding site on K562 cells is not glycophorin A, which is the EMC virus receptor molecule on virus-nonpermissive human erythrocytes (HeLa cells do not express glycophorin A). These results indicate that EMC virus attachment to permissive human cells is mediated by a cell surface sialoglycoprotein(s) with a molecular mass of 70 kDa.

Pathogenetic differences between coxsackie A and B virus infections in newborn mice

Coxsackieviruses are divided into A and B subgroups on the basis of their pathogenicity in newborn mice. Although used in the classification of these viruses, our understanding of the details of the infection is incomplete due to the lack of sensitive and specific techniques to localize the viruses in affected tissue. We have used in situ hybridization to detect coxsackievirus genomes in tissues of newborn mice after infection by five serotypes (A2, A9, A21, B3 and B4) through different administration routes. Our results indicate that coxsackie A viruses are able to affect both skeletal and heart muscle while the coxsackievirus B subgroup infects a wide range of tissues. In addition to striated muscle these include central nervous system, liver, exocrine pancreas and brown fat. This model will make it possible to analyze molecular factors determining tissue tropism.

Monoclonal anti-idiotypes induce neutralizing antibodies to enterovirus 70 conformational epitopes

Monoclonal antibodies (MAbs) directed against the prototype enterovirus 70 (EV-70) strain J670/71 were generated and characterized in order to produce anti-idiotypic MAbs (MAb2s) for use as surrogate immunogens. Western immunoblot and radioimmunoprecipitation assays suggested that all the MAbs recognize conformational epitopes on the virion surface. An EV-70-neutralizing antibody, MAb/ev-12 (MAb1), was selected for the production of MAb2s. Five MAb2s were selected for their capacities to inhibit the interaction of MAb/ev-12 with EV-70 in dot immunobinding inhibition and immunofluorescence assays. In addition, these five MAb2s inhibited virus neutralization mediated by MAb/ev-12, suggesting that they recognize paratope-associated idiotopes. In competition enzyme immunosorbent assays, none of the five MAb2s recognized other neutralizing and nonneutralizing EV-70-specific MAbs, demonstrating that the MAb2s were specific for private idiotopes. Immunization with each of the MAb2s was carried out for the production of anti-anti-idiotypic antibodies (Ab3). All five MAb2s induced an immune response. Moreover, results suggested that they share idiotopes, since MAb2-MAb/ev-12 binding could be inhibited by homologous as well as heterologous Ab3s. Ab3 sera were shown to possess antibodies capable of immunoprecipitating 35S-labeled viral proteins in the same manner as MAb/ev-12. Nine of 15 mice immunized with MAb2s demonstrated Ab3 neutralizing activity specific for the prototype EV-70 strain, J670/71. The potential application of MAb2s to serve as surrogate immunogens for conformational epitopes is substantiated by the results presented in this report.

Preliminary X-ray crystallographic analysis of intercellular adhesion molecule-1

Crystals of the two amino-terminal domains of intercellular adhesion molecule-1, the receptor for the major group of human rhinovirus serotypes, diffract to 3.0 A resolution. The crystals are trigonal in space group P3(1)21 or P3(2)21 with cell dimensions of a = b = 55.7 A, c = 166.3 A, with probably six molecules per unit cell.

Human-murine chimeras of ICAM-1 identify amino acid residues critical for rhinovirus and antibody binding

Human ICAM-1 is the cellular receptor for the major group of human rhinoviruses (HRVs). Previous studies have suggested that the N-terminal domain of ICAM-1 is critical for binding of the major group rhinoviruses. To further define the residues within domain 1 that are involved in virus binding, we constructed an extensive series of ICAM-1 cDNAs containing single and multiple amino acid residue substitutions. In each case, substitutions involved replacement of the human amino acids with those found in murine ICAM-1 to minimize conformational effects. To facilitate the mutagenesis process, a synthetic gene encompassing the first two domains of ICAM-1 was constructed which incorporated 27 additional restriction sites to allow mutagenesis by oligonucleotide replacement. Each of the new constructs was placed into a Rous sarcoma virus vector and expressed in primary chicken embryo fibroblast cells. Binding assays were performed with six major group HRVs, including one high-affinity binding mutant of HRV-14, and two monoclonal antibodies. Results indicated that different serotypes displayed a range of sensitivities to various amino acid substitutions. Amino acid residues of ICAM-1 showing the greatest effect on virus and antibody binding included Pro-28, Lys-29, Leu-30, Leu-37, Lys-40, Ser-67, and Pro-70.

Identification of monoclonal antibody epitopes and critical residues for rhinovirus binding in domain 1 of intercellular adhesion molecule 1

Intercellular adhesion molecule 1 (ICAM-1) is the cellular receptor for the major group of human rhinoviruses (HRVs) and the adhesion ligand of lymphocyte function-associated antigen 1. Analysis of a series of chimeric exchanges between human and murine ICAM-1 shows that two distinct epitopes recognized by monoclonal antibodies that block rhinovirus attachment and cell adhesion map to the N-terminal first domain of ICAM-1. Furthermore the specificity for HRV binding is entirely contained within the first 88 amino acids. Mutagenesis of the four sites of N-linked glycosylation within the second domain shows that carbohydrate is not involved in virus recognition. Homologue replacement mutagenesis localizes the epitopes for virus-blocking antibodies to two regions of domain 1 predicted to form beta strand D and the loop between the F and G strands of an immunoglobulin-fold structure. Analysis of virus binding to the mutants predicts a large surface of contact between HRV and ICAM-1 domain 1 but shows that the regions most important for virus binding are coincident with the monoclonal antibody epitopes.

Poliovirus can enter and infect mammalian cells by way of an intercellular adhesion molecule 1 pathway

Mouse fibroblast cell lines were transfected with truncated forms of the human poliovirus receptor (PVR) cDNA and tested for the expression of functional receptors for poliovirus. Several receptor constructs, all containing the coding region of the first 143 amino acids of PVR, were able to render mouse cells susceptible to poliovirus infection. A deletion of 65 amino acids in the first extracellular domain of PVR prevented virus attachment and infection. These data suggest that domain 1 is necessary and sufficient for the virus-receptor interaction. A PVR/intercellular adhesion molecule 1 hybrid receptor, expressing the PVR variable domain on a truncated receptor molecule for human rhinovirus 14, was shown to be a functional receptor for poliovirus. This observation indicates that, subsequent to attachment to the PVR-binding domain, poliovirus can use the same pathway as the major receptor group rhinoviruses to enter cells.

Antibodies that block rhinovirus attachment map to domain 1 of the major group receptor

The vast majority of human rhinovirus serotypes utilize the intercellular adhesion molecule 1 (ICAM-1) as the attachment site on susceptible cells. Twelve murine monoclonal antibodies were isolated and shown by competition binding studies to recognize three distinct, nonoverlapping epitopes on the ICAM-1 receptor. Titration of three antibodies representing each of the binding sites demonstrated that they were equally effective at blocking viral attachment. By using in vitro transcription and translation systems, a series of progressive C-terminal truncations of ICAM-1 molecules was generated. Immunoprecipitation of these fragments with each of the three antibodies indicated that all three epitopes reside within the first 82 amino acids of the receptor. Attempts to demonstrate specific binding of these in vitro-synthesized receptor fragments to virions were unsuccessful. The inability to show virion binding was most likely due to a failure of the lysates to properly glycosylate the receptor molecule, since native, unglycosylated receptor molecules isolated from cell membranes were also inactive in virus binding assays.

Crystal structure of human rhinovirus serotype 1A (HRV1A)

The structure of human rhinovirus 1A (HRV1A) has been determined to 3.2 A resolution using phase refinement and extension by symmetry averaging starting with phases at 5 A resolution calculated from the known human rhinovirus 14 (HRV14) structure. The polypeptide backbone structures of HRV1A and HRV14 are similar, but the exposed surfaces are rather different. Differential charge distribution of amino acid residues in the "canyon", the putative receptor binding site, provides a possible explanation for the difference in minor versus major receptor group specificities, represented by HRV1A and HRV14, respectively. The hydrophobic pocket in VP1, into which antiviral compounds bind, is in an "open" conformation similar to that observed in drug-bound HRV14. Drug binding in HRV1A does not induce extensive conformational changes, in contrast to the case of HRV14.

cDNA cloning reveals that the major group rhinovirus receptor on HeLa cells is intercellular adhesion molecule 1

A 90-kDa surface glycoprotein was previously isolated and shown to be required for infection by the "major" group of human rhinovirus (HRV) serotypes. In the present work, the amino acid sequence of the receptor protein was obtained from CNBr and tryptic peptides. Using degenerate oligonucleotides predicted from the peptide sequences, we identified four cDNA clones that encode a 3-kilobase mRNA. The clones were ligated, subcloned in a simian virus 40 expression vector, and used to transfect receptor-negative Vero (monkey) cells. Results showed that transfected cells expressed receptor molecules capable of binding HRV and a monoclonal antibody which recognizes the major group HRV receptor. The cloned receptor cDNA encoded a protein with a sequence nearly identical to that of the intercellular adhesion molecule 1 (ICAM-1), indicating that the two surface proteins are one and the same. Both proteins have identical mass, carbohydrate composition, and tissue distribution. In addition, major group receptors on HeLa cells could be induced with various cytokines in a manner similar to the ICAM-1 ligand. A similar induction of the HRV "minor" group receptor was not observed.

The canyon hypothesis

The three-dimensional structure of human rhinovirus 14 has a deep surface depression or "canyon" encircling each of the twelve fivefold vertices. The canyon's surface is inaccessible to the broad antigen binding region of antibodies, permitting conservation of residues that might be required for host cell receptor recognition without danger of attack by the host's immune system. In contrast, the exposed surface features, where neutralizing antibodies are known to bind, change rapidly under pressure from the host's immune system. It was, therefore, hypothesized that this depression was the site of receptor attachment. Similar, but smaller, depressions had been observed previously on both the hemagglutinin and neuraminidase spikes of influenza virus. These have also been shown to be the site of host cell interaction. Although support for the canyon hypothesis was only circumstantial in the first place, there are now extensive confirmatory data. These include site-specific mutations of residues in the canyon and conformational changes induced in the canyon by the binding of small organic molecules, all of which alter receptor attachment. The strategy used in human rhinovirus 14 to protect the viral receptor attachment site from immune surveillance may be utilized not only in other picornaviruses but also in many other types of viruses including human immunodeficiency virus.

Evidence for the direct involvement of the rhinovirus canyon in receptor binding

Evidence is presented that indicates a deep crevice located on the surface of human rhinovirus type 14 is involved in virion attachment to cellular receptors. By using mutagenesis of an infectious cDNA clone, 11 mutants were created by single amino acid substitutions or insertions at positions 103, 155, 220, 223, and 273 of the structural protein VP1. Seven of the recovered mutants had a small plaque phenotype and exhibited binding affinities significantly lower than wild-type virus. One mutant, in which glycine replaced proline at amino acid position 155, showed a greatly enhanced binding affinity. Single-cycle growth kinetics suggested that 5 of the mutants had delayed growth cycles due to intracellular deficiencies apart from receptor binding.