Physical and metabolic requirements for early interaction of poliovirus and human rhinovirus with HeLa cells

Productive entry pathways of human rhinoviruses

Currently, complete or partial genome sequences of more than 150 human rhinovirus (HRV) isolates are known. Twelve species A use members of the low-density lipoprotein receptor family for cell entry, whereas the remaining HRV-A and all HRV-B bind ICAM-1. HRV-Cs exploit an unknown receptor. At least all A and B type viruses depend on receptor-mediated endocytosis for infection. In HeLa cells, they are internalized mainly by a clathrin- and dynamin-dependent mechanism. Upon uptake into acidic compartments, the icosahedral HRV capsid expands by ~4% and holes open at the 2-fold axes, close to the pseudo-3-fold axes and at the base of the star-shaped dome protruding at the vertices. RNA-protein interactions are broken and new ones are established, the small internal myristoylated capsid protein VP4 is expelled, and amphipathic N-terminal sequences of VP1 become exposed. The now hydrophobic subviral particle attaches to the inner surface of endosomes and transfers its genomic (+) ssRNA into the cytosol. The RNA leaves the virus starting with the poly(A) tail at its 3′-end and passes through a membrane pore contiguous with one of the holes in the capsid wall. Alternatively, the endosome is disrupted and the RNA freely diffuses into the cytoplasm.

Multiple receptors involved in human rhinovirus attachment to live cells

Minor group human rhinoviruses (HRVs) attach to members of the low-density lipoprotein receptor family and are internalized via receptor-mediated endocytosis. The attachment of HRV2 to the cell surface, the first step in infection, was characterized at the single-molecule level by atomic force spectroscopy. Sequential binding of multiple receptors was evident from recordings of characteristic quantized force spectra, which suggests that multiple receptors bound to the virus in a timely manner. Unbinding forces required to detach the virus from the cell membrane increased within a time frame of several hundred milliseconds. The number of receptors involved in virus binding was determined, and estimates for on-rate, off-rate, and equilibrium binding constant of the interaction between HRV2 and plasma membrane-anchored receptors were obtained.

Inhibition of polyprotein processing and RNA replication of human rhinovirus by pyrrolidine dithiocarbamate involves metal ions

Pyrrolidine dithiocarbamate (PDTC) is an antiviral compound that was shown to inhibit the replication of human rhinoviruses (HRVs), poliovirus, and influenza virus. To elucidate the mechanism of PDTC, the effects on the individual steps of the infection cycle of HRV were investigated. PDTC did not interfere with receptor binding or internalization by receptor mediated endocytosis of HRV2 particles into HeLa cells. But we demonstrate that the processing of the viral polyprotein was prevented by PDTC treatment in HeLa cells infected with HRV2. Furthermore, PDTC inhibited the replication of the viral RNA, even when added four hours post infection. As PDTC is described as a metal ion binding agent, we investigated the effect of other metal chelators on the multiplication of HRV2. We show that EDTA, omicron-phenanthroline, and bathocuproine disulfonic acid do not exhibit any antiviral properties. Surprisingly, these substances, coadministered with PDTC, abolished the antiviral effect of PDTC, suggesting that metal ions play a pivotal role in the inhibition of virus multiplication. These results suggest that PDTC inhibits the activity of the viral proteases in a metal ion dependent way.

Visualization of single receptor molecules bound to human rhinovirus under physiological conditions

Dynamic force microscopy (DFM) was used to image human rhinovirus HRV2 alone and complexed with single receptor molecules under near physiological conditions. Specific and site-directed immobilization of HRV2 on a model cell membrane resulted in a crystalline arrangement of virus particles with hexagonal symmetry and 35 nm spacing. High-resolution imaging of the virus capsid revealed about 20 resolvable structural features with 3 nm diameters; this finding is in agreement with protrusions seen by cryo-electron microscopy. Binding of receptor molecules to individual virus particles was observed after injection of soluble receptors into the liquid cell. Virus-receptor complexes with zero, one, two, or three attached receptor molecules were resolved. The number of receptor molecules associated to virions increased over time. Occasionally, dissociation of single receptor molecules from viral particles was also observed.

Opening of size-selective pores in endosomes during human rhinovirus serotype 2 in vivo uncoating monitored by single-organelle flow analysis

The effect of virus uncoating on endosome integrity during the early steps in viral infection was investigated. Using fluid-phase uptake of 10- and 70-kDa dextrans labeled with a pH-dependent fluorophore (fluorescein isothiocyanate [FITC]) and a pH-independent fluorophore (cyanine 5 [Cy5]), we determined the pHs of labeled compartments in intact HeLa cells by fluorescence-activated cell sorting analysis. Subsequently, the number and pH of fluorescent endosomes in cell homogenates were determined by single-organelle flow analysis. Cointernalization of adenovirus and 70-kDa FITC- and Cy5-labeled dextran (FITC/Cy5-dextran) led to virus-induced endosomal rupture, resulting in the release of the marker from the low-pH environment into the neutral cytosol. Consequently, in the presence of adenovirus, the number of fluorescent endosomes was reduced by 40% compared to that in the control. When human rhinovirus serotype 2 (HRV2) was cointernalized with 10-and 70-kDa FITC/Cy5-dextrans, the 10-kDa dextran was released, whereas the 70-kDa dextran remained within the endosomes, which also maintained their low pH. These data demonstrate that pores are generated in the membrane during HRV2 uncoating and RNA penetration into the cytosol without gross damage of the endosomes; 10-kDa dextran can access the cytosol through these pores. Whereas rhinovirus-mediated pore formation was prevented by the vacuolar ATPase inhibitor bafilomycin A1, adenovirus-mediated endosomal rupture also occurred in the presence of the inhibitor. This finding is in keeping with the low-pH requirement of HRV2 infection; for adenovirus, no pH dependence for endosomal escape was found with this drug.

Human rhinovirus type 2-antibody complexes enter and infect cells via Fc-gamma receptor IIB1

HeLa cells were stably transfected with a cDNA clone encoding the B1 isoform of the mouse FcgammaRII receptor (hereafter referred to as HeLa-FcRII cells). The receptor was expressed at high level at the plasma membrane in about 90% of the cells. These cells bound and internalized mouse monoclonal virus-neutralizing antibodies 8F5 and 3B10 of the subtype immunoglobulin G2a (IgG2a) and IgG1, respectively. Binding of the minor-group human rhinovirus type 2 (HRV2) to its natural receptors, members of the low-density lipoprotein receptor family, is dependent on the presence of Ca(2+) ions. Thus, chelating Ca(2+) ions with EDTA prevented HRV2 binding, entry, and infection. However, upon complex formation of (35)S-labeled HRV2 with 8F5 or 3B10, virus was bound, internalized, and degraded in HeLa-FcRII cells. Furthermore, challenge of these cells with HRV2-8F5 or HRV2-3B10 complexes resulted in de novo synthesis of viral proteins, as shown by indirect immunofluorescence microscopy. These data demonstrate that minor-group receptors can be replaced by surrogate receptors to mediate HRV2 cell entry, delivery into endosomal compartments, and productive uncoating. Consequently, the conformational change and uncoating of HRV2 appears to be solely triggered by the low-pH (pH </= 5.6) environment in these compartments.

Molecular basis of pathogenesis of FMDV

Current understanding of the molecular basis of pathogenesis of foot-and-mouth disease (FMD) has been achieved through over 100 years of study into the biology of the etiologic agent, FMDV. Over the last 40 years, classical biochemical and physical analyses of FMDV grown in cell culture have helped to reveal the structure and function of the viral proteins, while knowledge gained by the study of the virus' genetic diversity has helped define structures that are essential for replication and production of disease. More recently, the availability of genetic engineering methodology has permitted the direct testing of hypotheses formulated concerning the role of individual RNA structures, coding regions and polypeptides in viral replication and disease. All of these approaches have been aided by the simultaneous study of other picornavirus pathogens of animals and man, most notably poliovirus. Although many questions of how FMDV causes its devastating disease remain, the following review provides a summary of the current state of knowledge into the molecular basis of the virus' interaction with its host that produces one of the most contagious and frightening diseases of animals or man.

Inhibition of clathrin-dependent endocytosis has multiple effects on human rhinovirus serotype 2 cell entry

Minor group human rhinoviruses (exemplified by human rhinovirus serotype 2 (HRV2)) use members of the low density lipoprotein receptor family for cell entry; all these receptors possess clathrin-coated pit localization signals. Viral infection should thus be inhibited under conditions of impaired clathrin-mediated endocytosis. However, Madshus et al. reported an increase in the cytopathic effect of HRV2 infection in HEp-2 cells upon suppression of clathrin-dependent endocytosis by hypotonic shock and potassium depletion (Madshus, I. H., Sandvig, K., Olsnes, S., and van Deurs, B. (1987) J. Cell. Physiol. 131, 14-22.) To resolve this apparent contradiction, we investigated the binding, internalization, conformational changes, and productive uncoating of HRV2 in HeLa cells subjected to hypotonic shock and potassium depletion. This treatment led to an increase in HRV2 binding, with internalization being barely affected. The generation of C-antigenic particles requiring pH </=5.6 was strongly reduced due to an elevation of the pH in endosomal compartments. However, K(+) depletion only slightly affected de novo viral protein synthesis, suggesting that productivity of viral RNA in the cytoplasm is enhanced and thus compensates for the reduction in C-antigenic particles. The distinct steps in the entry pathway of HRV2 are thus differently influenced by potassium depletion. Viral internalization under conditions of inhibited clathrin-dependent endocytosis without the need to disturb the ionic milieu was confirmed in HeLa cells overexpressing the nonfunctional dynamin-1 mutant K44A. Unexpectedly, overexpression of dynamin-1 K44A resulted in elevated endosomal pH compared with overexpression of wild-type dynamin.

Structure of human rhinovirus serotype 2 (HRV2)

Human rhinoviruses are classified into a major and a minor group based on their binding to ICAM-1 or to members of the LDL-receptor family, respectively. They can also be divided into groups A and B, according to their sensitivity towards a panel of antiviral compounds. The structure of human rhinovirus 2 (HRV2), which uses the LDL receptor for cell attachment and is included in antiviral group B, has been solved and refined at 2.6 A resolution by X-ray crystallography to gain information on the peculiarities of rhinoviruses, in particular from the minor receptor group. The main structural differences between HRV2 and other rhinoviruses, including the minor receptor group serotype HRV1A, are located at the internal protein shell surface and at the external antigenic sites. In the interior, the N termini of VP1 and VP4 form a three-stranded beta-sheet in an arrangement similar to that present in poliovirus, although myristate was not visible at the amino terminus of VP4 in the HRV2 structure. The betaE-betaF loop of VP2, a linear epitope within antigenic site B recognized by monoclonal antibody 8F5, adopts a conformation considerably different from that found in the complex of 8F5 with a synthetic peptide of the same sequence. This either points to considerable structural changes impinged on this loop upon antibody binding, or to the existence of more than one single conformation of the loop when the virus is in solution. The hydrophobic pocket of VP1 was found to be occupied by a pocket factor apparently identical with that present in the major receptor group virus HRV16. Electron density, consistent with the presence of a viral RNA fragment, is seen stacked against a conserved tryptophan residue.

Poliovirus and its cellular receptor: a molecular genetic dissection of a virus/receptor affinity interaction

The ability of a virus to attach to a susceptible host cell is of utmost importance for the initiation of viral life cycle. Cell surface proteins called viral receptors mediate the initial steps of virus attachment and uptake. Poliovirus (PV) is one of the most studied animal viruses and its interaction with its cellular receptor, the human poliovirus receptor (hPVR) has been well characterized. This review will present our current understanding of the PV/hPVR interaction at the genetic and biochemical level. In addition, we will also discuss the implications of the PV/hPVR interaction on PV tissue tropism and the evolution of the three PV serotypes.

Major and minor receptor group human rhinoviruses penetrate from endosomes by different mechanisms

Intercellular adhesion molecule 1 and the low-density lipoprotein receptor are used for cell entry by major and minor receptor group human rhinoviruses (HRVs), respectively. Whereas minor-group viruses, exemplified by HRV2, transfer their genomic RNA to the cytoplasm through a pore in the endosomal membrane (E. Prchla, C. Plank, E. Wagner, D. Blaas, and R. Fuchs, J. Cell Biol. 131:111-123, 1995), the mechanism of in vivo uncoating of major-group HRVs has not been elucidated so far. Using free-flow electrophoresis, we performed a comparative analysis of cell entry by HRV2 and the major group rhinovirus HRV14. Here we demonstrate that this technique allows the separation of free viral particles from those associated with early endosomes, late endosomes, and plasma membranes. Upon free-flow electrophoretic separation of microsomes, HRV14 was recovered from endosomes under conditions which prevent uncoating, whereas the proportion of free viral particles increased with time under conditions which promote uncoating. The remaining virus eluted within numerous fractions corresponding to membraneous material, with no clear endosomal peaks being discernible. This suggests that uncoating of HRV14 results in lysis of the endosomal membrane and release of subviral 135S and 80S particles into the cytoplasm.

Use of free-flow electrophoresis for the analysis of cellular uptake of picornaviruses

Free-flow electrophoresis is a powerful tool to separate subcellular vesicles such as early and late endosomes from plasma membranes. Using this technique, the intracellular distribution of poliovirus type 2 Sabin (PV2) and its derived subviral particles was analyzed upon infection of HeLa cells. Comparison of various infection conditions showed that maximally 30% of total cell associated PV2 was found in endosomal compartments with the remainder being associated with plasma membrane fractions; 2% of viral label was recovered from the cytoplasm in form of free virions. Sucrose gradient centrifugation analysis of the viral material recovered from the respective fractions revealed that intracellular virus was exclusively in its native conformation. This is in sharp contrast to human rhinovirus serotype 2 (HRV2), which is rapidly modified to RNA-free subviral particles upon accumulation in endosomes. The data suggest that productive poliovirus uncoating can occur at the plasma membrane whereas internalized virus is most probably aborted.

Interaction between echovirus 7 and its receptor, decay-accelerating factor (CD55): evidence for a secondary cellular factor in A-particle formation

Soluble forms of decay-accelerating factor (DAF) (CD55), the receptor for echovirus 7, were synthesized in the yeast Pichia pastoris. Purified recombinant protein containing SCR domains 2, 3, and 4, but lacking the serine/threonine rich region, was shown to block infection of susceptible cells by echovirus 7. In contrast to the situation with poliovirus and its receptor, the neutralization of echovirus 7 by soluble DAF was completely reversible and did not lead to the formation of 135S A-particles. Binding of virus to susceptible cells, by contrast, did lead to the formation of A particles, mainly from virus that had been internalized. The data suggest that a secondary factor(s) may contribute to A-particle formation and uncoating of echovirus 7.

Cold-adapted poliovirus mutants bypass a postentry replication block

In the current model of poliovirus entry, the initial interaction of the native virion with its cellular receptor is followed by a transition to an altered form, which then acts as an intermediate in viral entry. While the native virion sediments at 160S in a sucrose gradient, the altered particle sediments at 135S, has lost the coat protein VP4, and has become more hydrophobic. Altered particles can be found both associated with cells and in the culture medium. It has been hypothesized that the cell-associated 135S particle releases the viral genome into the cell cytoplasm and that nonproductive transitions to the 135S form are responsible for the high particle-to-PFU ratio observed for polioviruses. At 25 degrees C, a temperature at which the transition to 135S particles does not occur, the P1/Mahoney strain of poliovirus was unable to replicate, and cold-adapted (ca) mutants were selected from the population. These mutants have not gained the ability to convert to 135S particles at 25 degrees C, and the block to wild-type (wt) infection at low temperatures is not at the level of cellular entry. The particle-to-PFU ratio of poliovirus does not change at 25 degrees C in the absence of alteration. Three independent amino acid changes in the 2C coding region were identified in ca mutants, at positions 218 (Val to Ile), 241 (Arg to Ala), and 309 (Met to Val). Introduction of any of these mutations individually into wt poliovirus by site-directed mutagenesis confers the ca phenotype. All three serotypes of the Sabin vaccine strains and the P3/Leon strain of poliovirus also exhibit the ca phenotype. These results do not support a model of poliovirus entry into cells that includes an obligatory transition to the 135S particle.

Poliovirus infection without accumulation of eclipse particles

Poliovirus type 1 (Mahoney) was treated with the capsid-binding pyridazinamine R 78206, followed by dialysis to remove free compound. Upon infection of HeLa cells by R 78206-pretreated virus, the formation of intra- and extracellular modified particles was completely inhibited, except for a small amount of empty capsids. The synthesis of viral proteins and first cycle progeny virus was delayed by 1 h. The results suggest that poliovirus infection does not require intracellular accumulation of 135 S eclipse particles.

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.

Uncoating of human rhinovirus serotype 2 from late endosomes

The internalization pathway and mechanism of uncoating of human rhinovirus serotype 2 (HRV2), a minor-group human rhinovirus, were investigated. Kinetic analysis revealed a late endosomal compartment as the site of capsid modification from D to C antigenicity. The conformational change as well as the infection was prevented by the specific V-ATPase inhibitor bafilomycin A1. A requirement for ATP was also demonstrated with purified endosomes in vitro. Capsid modifications occurred at a pH of 5.5 regardless of whether the virus was entrapped in isolated endosomes or free in solution. These findings suggest that the receptor is not directly involved in the structural modification of HRV2. Viral particles found in purified endosomes of infected cells were mostly devoid of RNA. This supports the hypothesis that uncoating of HRV2 occurs in intact endosomes rather than by a mechanism involving endosomal disruption with subsequent release of the RNA into the cytoplasm.

Early interaction of feline calicivirus with cells in culture

The kinetics and biochemical properties of feline calicivirus (FCV) attachment to Crandell-Reese feline kidney cells were determined. Maximum binding was observed at pH 6.5. Cells in suspension at 4 degrees C bound virus more efficiently than cells in monolayers at 4 degrees C or 37 degrees C. High initial binding rate was observed in monolayers or cells in suspension and proceeded to a maximum at 90 min, although half maximal binding was observed as early as 15 min. Binding was specific and competitively blocked by serotypically homologous or heterologous FCV as well as by San Miguel sea lion virus. Treatment of cells with proteases increased FCV binding, whereas phospholipase had no effect on virus attachment. Conversely, cells treated with neuraminidase followed by O-glycanase treatment showed a decreased binding ability. Cells of feline origin bound FCV very efficiently, and non-permissive cells showed a poor binding ability. Following transfection of viral RNA, infectious virus could be recovered from all non-permissive cells, except from Madin-Darby canine kidney cells. These results suggest that FCV binds to a receptor in which carbohydrates may be an important component and that FCV replication in non-permissive cells is primarily restricted by the absence of appropriate receptors on the cell surface.

Influence of polyions on the early steps of enterovirus infection

The influence of electric charged molecules on the early phases of enterovirus infection was studied in order to select antiviral compounds able to prevent viral attachment. The effect of different polyelectrolytes on the multiplication of coxsackie virus B3, echovirus 6 and hepatitis A virus was investigated in susceptible cells by adding the drug before, during or after the viral adsorption period. Among polyanions, the polysaccharides heparin and dextran sulfate inhibited viral infectivity, dextran sulfate being the most effective mainly towards hepatitis A virus infection. DEAE-dextran and protamine sulfate, generally recognized as enhancers of infectivity of naked and enveloped viruses, exhibited an inhibitory effect towards the three picornaviruses tested. Only in the case of hepatitis A did DEAE-dextran slightly improve viral antigen synthesis. The inhibitory effect shown by compounds belonging to positive and negative polyions suggests that the electric charge is not sufficient by itself to explain the antiviral activity of these drugs.

Comparison of the binding characteristics to BHK-21 cells of viruses representing the two Theiler's virus neurovirulence groups

The binding characteristics of the highly virulent GDVII and less virulent BeAn strains of Theiler's murine encephalomyelitis viruses (TMEV) to whole BHK-21 cells were determined using a direct viral binding assay. The overall rates of association and dissociation of BeAn and GDVII viruses were similar. Using a saturation binding assay intended for multivalent ligands, such as picornaviruses, the number of binding sites per cell was calculated as 1.6 x 10(5). Competitive binding assays with both viruses showed one-way blocking. In addition, treatment of cell monolayers with neuraminidase reduced binding of BeAn virus by 90% but did not affect GDVII binding. Wheat germ agglutinin, a lectin which blocks binding to sialic acid and N-acetylglucosamine residues, substantially reduced binding of radiolabeled GDVII and BeAn viruses. Treatment of asialylated cells with O-glycanase further reduced the binding of BeAn virus, suggesting that O-linked oligosaccharides are involved in viral binding. These results suggest members of the two TMEV virulence groups share a common receptor but bind it differently.

Kinetics of poliovirus uncoating in HeLa cells in a nonacidic environment

Lysis of HeLa cells infected with poliovirus revealed intact virus; 135S particles, devoid of VP4 but containing the viral RNA; and 80S empty capsids. During infection the kinetics of poliovirus uncoating showed a continuous decrease of intact virus, while the number of 135S particles and empty shells increased. After 1.5 h of infection conformational transition to altered particles resulted in complete disappearance of intact virions. To investigate the mechanism of poliovirus uncoating, which has been suggested to depend on low pH in endosomal compartments of cells, we used lysosomotropic amines to raise the pH in these vesicles. In the presence of ammonium chloride, however, the kinetics of uncoating were similar to those for untreated cells, whereas in cells treated with methylamine, monensin, or chloroquine, uncoating was merely delayed by about 30 min. This effect could be attributed to a delay of virus entry into cells after treatment with methylamine and monensin, whereas chloroquine stabilized the viral capsid itself. Thus, elevation of endosomal pH did not affect virus uncoating. We therefore propose a mechanism of poliovirus uncoating which is independent of low pH.

Human cytomegalovirus binding to fibroblasts is receptor mediated

The binding of radiolabeled human cytomegalovirus (HCMV) strain AD169 to human lymphocytes, lymphoblastoid cell lines, monocytes, and fibroblasts varied over a 20-fold range. Since maximum binding was observed with human foreskin fibroblasts (HFF), interactions of radiolabeled HCMV with this cell type were analyzed quantitatively. Binding of HCMV to HFF at 4 degrees C was specific and saturable; at low viral inputs specific binding averaged 16.4% of input and nonspecific binding was less than 1% of input. Binding curves yielded single-component linear Scatchard plots indicating an average Kd of 1.1 nM and 5,262 available virus-binding sites per cell. A two-component Scatchard curve was obtained at 37 degrees C and reflected viral internalization, since it could be converted to a single-component curve by the use of paraformaldehyde-fixed cells. HCMV strain Towne was found to bind to the receptor used by HCMV strain AD169 with similar affinity. HCMV failed to bind to protease-treated HFF or to HFF grown in the presence of inhibitors of glycosylation. Sialic acid residues, however, were not found to be important in binding. These data indicate that a single type of molecule, likely a glycoprotein, on the surface of HFF serves as a specific receptor for the virus.

Characterization of human rhinoviruses displaced by an anti-receptor monoclonal antibody

The attachment of rhinoviruses to cellular receptors was studied by displacing bound virus particles with an anti-receptor monoclonal antibody. The two serotypes studied differed significantly with respect to the temperature dependence of displacement and the nature of the particles displaced. Binding was shown to be a two-step process, the first of which is reversible and is seen when viruses are bound either to isolated cell membranes or to cells at lower than physiological temperatures. Second-stage binding was seen with serotype 14 when bound to intact cells. Viral particles released from such cells by incubation at 37 degrees C or by anti-receptor antibody exhibited altered physical changes in the capsid and a loss of infectivity. In contrast, serotype 67 bound efficiently to cells at 37 degrees C and did not elute spontaneously but could be displaced by anti-receptor antibody to produce complete, infectious particles. Rhinoviruses labeled with [3H]myristic acid or with [35S]methionine were displaced similarly from cells or membranes by anti-receptor antibody, indicating that the majority of VP4 of rhinoviruses does not enter or remain attached to cells during either the first or second stage of virus binding. These data support the conclusion that the myristic acid moiety of VP4 is not involved in the initial viral interaction with cellular receptors.

Characteristics of the minor group receptor of human rhinoviruses

The receptor for the minor group of human rhinoviruses was solubilized from HeLa cell membranes with various detergents. Virus binding activity was determined in a filter binding assay using 35S-labeled human rhinovirus 2 (HRV2) as a probe. The receptor protein was enriched on Lens culinaris lectin columns and the active fractions were further purified by gel permeation and anion exchange chromatography. The receptor has an apparent molecular weight of 450 kDa in the presence of detergent. The binding activity is sensitive to trypsin, sulfhydryl modifying agents, but insensitive to neuraminidase. Divalent cations are essential for virus binding.

Mechanism of entry of human rhinovirus 2 into HeLa cells

Internalized human rhinovirus 2 (HRV2) undergoes a rapid conformational change leading to recognition by the C-determinant-specific monoclonal antibody 2G2. In the presence of the ionophore monensin, the virus accumulates in the cells in its native conformation and infection is strongly inhibited. At 20 degrees but not at 34 degrees the inhibitory effect of monensin can be overcome by a short incubation of the infected cells at low pH as late as 2 hr after inoculation. Incubation of infected cells at 20 degrees prior to addition of monensin permits virus synthesis to occur, depending on the time of preincubation.

Comparison of the three-dimensional structure of two human rhinoviruses (HRV2 and HRV14)

An attempt has been made to build a model of human rhinovirus 2 (HRV2) based on the known human rhinovirus 14 (HRV14) structure. HRV2 was selected because its amino acid sequence is known and because it belongs to the minor rhinovirus receptor class as compared to HRV14, which belongs to the major class. Initial alignment of HRV2 with HRV14 based on the primary sequence and the knowledge of the three-dimensional structure of HRV14 showed that the most probable position of the majority of insertions and deletions occurred in the vicinity of the neutralizing immunogenic sites (NIm). Out of a total of 855 amino acids present in one copy of each of the capsid proteins VP1 through VP4 of HRV14, 411 are different between the two viruses. There are also 6 amino acid residues inserted and 14 residues deleted in HRV2 relative to HRV14. Examination of amino acid interactions showed several cases of conservation of function, e.g., salt bridges or the filling of restricted space. The largest variation amongst the residues lining the canyon, the putative receptor binding site, was in the carboxy-terminal residues of VP1.

Type 1 human poliovirus binds to human synaptosomes

Poliovirus is a neurotropic virus that selectively infects human motoneurons in vivo. The basis for the specificity of this infection is not fully understood. It has been suggested that this tropism occurs because motoneurons are the only neurons to express poliovirus receptors. We have examined this hypothesis by measuring the binding of 125I-labeled poliovirus type 1 to neural tissues. With this assay we have detected highly specific binding sites in human but not rodent neural tissue. Regional assays of binding in human central nervous system homogenates demonstrate that binding sites are not confined to motoneurons. Rather, they are widely distributed throughout the human neuraxis. Particularly in the forebrain, binding is more abundant in gray than white matter. For this reason, we performed tissue fractionation studies which indicate that poliovirus binding sites are enriched in synaptosomes, the subfraction of central nervous system gray matter tissue rich in synaptic endings. The preferential expression of poliovirus binding sites in synaptic endings may be an important factor in the motor tropism of this virus, inasmuch as the major category of neurons with synaptic endings outside the central nervous system are motoneurons; thus, particles of virus may preferentially bind to this cell type during poliovirus viremia.

Protein kinase in nondiabetogenic coxsackievirus B4

Alkali-dissociated, purified preparations of prototype coxsackievirus B4 release a protein kinase that catalyzes the incorporation of gamma-phosphate from 32P-labeled ATP into three virus capsid proteins (VP1, VP3, VP4), several additional proteins of the particle, and exogenous acceptor proteins. Using protamine sulfate as an acceptor protein, we detected nearly 20-fold more enzyme activity in membrane-bound virions (MBV) than in virions of the virus. The activity in the MBV is cyclic nucleotide-independent, divalent cation-dependent, and has a pH optimum of 8.0. Phosphoserine is labeled with 32P. The enzyme activity sediments at about 5S and is separated into at least two peaks of heterogeneous proteins by ion-exchange chromatography. The patterns of phosphorylation by these enzyme peaks are somewhat similar. Coxsackievirus-associated protein kinase appears to be located internally in the virus and may be host-cell-coded. The enzyme appears to be lacking in a variant of the virus that produced diabetes in mice.

Early interactions between animal viruses and the host cell: relevance to viral vaccines

Viral recognition of specific receptors in the host cell plasma membrane is the first step in virus infection. Attachment is followed by a redistribution or capping of virus particles on the cell surface which may play a role in the uptake process. Certain viruses penetrate the plasma membrane directly but many, both enveloped and non-enveloped viruses, are endocytosed at coated pits and subsequently pass into endosomes. The low pH environment of the endosome facilitates passage of the viral genome into the cytoplasm. For some viruses the mechanism of membrane penetration is now known to be linked to a pH-mediated conformational change in external virion proteins. As a consequence of infection there are alterations in the permeability of the plasma membrane which may contribute to cellular damage. Recent advances in the understanding of these processes are reviewed and their relevance to the development of new strategies for vaccines emphasised.

Adsorption, purification, and growth characteristics of hepatitis A virus strain HAS-15 propagated in fetal rhesus monkey kidney cells

A human fecal isolate of hepatitis A virus strain HAS-15 was adapted to rapid growth in FRhK-4 cells by more than 20 7-day passages. A cell culture-derived inoculum of strain HAS-15 was used at a multiplicity of infection of 80 radioimmunofocus-forming units per cell, and a one-step growth curve was determined. Both intracellular production and supernatant release of infectious virions were evaluated. Detection of virus release into the medium directly corresponded to intracellular production of infectious virions. A classical eclipse period was not observed during the growth curve determinations; however, detectable infectious virion production was absent for approximately 20 h after infection. This 20-h period was immediately followed by a 4-day logarithmic phase of virus production. A maximum intracellular virus titer of 10(9) radioimmunofocus-forming units per ml was achieved, and this level remained essentially constant for up to 14 days after infection. The infectious virus and viral antigen produced during the growth cycle were ascertained by a radioimmunofocus assay and by a radioimmunoassay, respectively. Cell culture supernatants were negative for viral antigen as determined by the radioimmunoassay, even though as many as 10(8) hepatitis A virus radioimmunofocus-forming units per ml were found. An adsorption study was also performed with strain HAS-15 by using FRhK-4 cells. More than 99.9% of the infectious virus was adsorbed at 25 degrees C in less than 20 min.

Different pH requirements for entry of the two picornaviruses, human rhinovirus 2 and murine encephalomyocarditis virus

The entry into cells of human rhinovirus 2 (HRV 2) and murine encephalomyocarditis (EMC) virus was studied by the use of light-sensitive virus grown in the presence of acridine orange (HRV 2) and neutral red (EMC). HeLa cells were protected against infection with HRV 2 by NH4Cl, monensin, and other compounds known to increase the pH of intracellular vesicles. Preincubation of the cells with the same compounds reduced the ability of the cells to bind [35S]methionine-labeled HRV 2, apparently due to inhibition of recycling of endocytosed receptors back to the cell surface. The cells were also protected against infection when HRV 2 was bound to cells on ice and the cells were then incubated at 37 degrees with the different compounds. This indicates that low pH is also necessary for some event in the entry process taking place after the virus is bound to the cells. In contrast, compounds which increase the pH in acidic intracellular compartments did not protect mouse L-cells against infection with EMC-virus, and the entry of the virus was inhibited by low pH in the medium. This inhibition was partly overcome by the presence of the ionophore monensin, which elevates the pH in endosomes and lysosomes. Possibly, EMC virus enters the cytosol from vesicles with neutral or slightly alkaline pH.

Mechanism of entry into the cytosol of poliovirus type 1: requirement for low pH

The effect of a number of drugs and culture conditions on the entry into cells of a strain of poliovirus 1 (Brunende) was tested. The cells were exposed in the dark to light-sensitive, neutral red-containing virus, in the presence of the drug to be tested. Then the cells were exposed to light, transferred to normal medium, and incubated overnight. Cytopathogenic effect was measured as inhibition of [3H]leucine incorporation. Compounds that dissipate proton gradients across membranes, like monensin, protonophores, and amines, and compounds that inhibit the acidification process, such as N,N'-dicyclohexylcarbodiimide (DCCD) and tributyltin, inhibited the entry of virus, but not virus binding. This was also the case with metabolic inhibitors that deplete cells for ATP. The same compounds also inhibited the cell-induced alteration of the virus particles. When cells with surface-bound virus were exposed to low pH, the virus entered efficiently, even in the presence of monensin and DCCD. The results indicate that acidification somehow facilitates the entry of the virus RNA into the cytosol and that under normal conditions the entry occurs from intracellular acidic vesicles.

Altered receptor specificity of coxsackievirus B3 after growth in rhabdomyosarcoma cells

Serial "blind" passages in human rhabdomyosarcoma (RD) cells of prototype viruses from each of the six immunotypes of the group B coxsackieviruses (CB) resulted in the isolation of intratypic variants of CB1, CB3, CB5, and CB6. Each variant virus strain acquired the capacity to agglutinate human erythrocytes and produce small plaques on HeLa cells, although their serological specificity remained unchanged. An alteration in VP1 mobility in sodium dodecyl sulfate-polyacrylamide gel electrophoresis was noted for CB3-RD. The CB3-RD variant was plaque purified on RD cells and studied for receptor interactions on both HeLa and RD cells. An attachment restriction appeared to exist for prototype CB3 on RD cells, whereas CB3-RD attached well to both cells. In attachment interference assays, HeLa cells saturated with CB3-RD blocked the attachment of CB3. In contrast, saturation of cells with CB1 (which shares a common receptor with parental CB3) failed to block the attachment of CB3-RD. This unidirectional receptor blockade suggested that a second site for the attachment of virions to receptors was acquired by the CB3-RD variant. Thus, more than one virus receptor specificity may be operative in the selection of host range virus mutants. The implications of this phenomenon as they may relate to pathogenesis are discussed.

Binding of 125I-labeled reovirus to cell surface receptors

Quantitative studies of 125I-labeled reovirus binding at equilibrium to several cell types was studied, including (1) murine L cell fibroblasts; (2) murine splenic T lymphocytes; (3) YAC cells, a murine lymphoma cell line; and (4) R1.1 cells, a murine thymoma cell line. Competition and saturation studies demonstrated (1) specific, saturable, high-affinity binding of reovirus types 1 and 3 to nonidentical receptors on L cell fibroblasts; (2) high-affinity binding of type 3 reovirus to murine splenic lymphocytes and R1.1 cells; (3) low-affinity binding of reovirus type 1 to lymphocytes and R1.1 cells; and (4) no significant binding of either serotype to YAC cells. Differences in the binding characteristics of the two reovirus serotypes to L cell fibroblasts were found to be a property of the viral hemagglutinin, as demonstrated using a recombinant viral clone. The equilibrium dissociation constant (Kd) for viral binding was of extremely high affinity (Kd in the range of 0.5 nM), and was slowly reversible. Experiments demonstrated temperature and pH dependence of reovirus binding and receptor modification studies using pronase, neuraminidase, and various sugars confirmed previous studies that reovirus receptors are predominantly protein in structure. The reovirus receptor site density was in the range of 2-8 X 10(4) sites/cell. These studies demonstrate that the pseudo-first-order kinetic model for ligand-receptor interactions provides a useful model for studying interactions of viral particles with membrane viral receptors. They also suggest that one cell may have distinct receptor sites for two serotypes of the same virus, and that one viral serotype may bind with different kinetics depending on the cell type.

Virus receptor interaction in the adenovirus system. II. Capping and cooperative binding of virions on HeLa cells

Adenovirus type 2 attachment to HeLa cells was analyzed under controlled conditions. The temperature-dependent attachment kinetics revealed an inflection point at around 20 degrees C, and above this temperature the increase of the rate was doubled. In multiplicity dependence experiments, the attachment exhibited positive cooperative binding at 37 degrees C. This binding pattern was inhibited by low temperatures and prefixation of cells with 0.015% glutaraldehyde. Attachment of rhodamine-labeled virions revealed capping of the particles on 15% of the cells at 37 degrees C. Capping was inhibited by low temperatures, glutaraldehyde fixation of cells, and treatment with cytochalasin B, azide, and 2-deoxyglucose. Consequently, we propose that the adenovirus type 2 attachment to cells leads to rearrangements in the plasma membrane, resulting in cooperative binding and capping of the virus particles.

Uncoating-like modification of poliovirus capsid resulting from the cooperative effects of subfreezing temperature and submolar concentrations of urea

Inactivation of poliovirus at subfreezing temperature in the presence of unusually low concentrations of urea (less than or equal to 0.5 M) was investigated. Whereas serotypes 1 and 2 are very sensitive, type 3 is resistant. Inactivation cannot be attributed to concentration of solutes since temperature must be reduced below -13 degrees C for loss of infectivity. Characteristics of the inactivated virion are similar to those of virions in the early stages of uncoating in HeLa cells, viz., loss of infectivity, sensitivity to proteases and detergents, change in isoelectric point, retention of intact genome, and in some instances, loss of VP4. The molecular basis for inactivation is considered to be dissociation of water bound to capsid proteins thereby causing irreversible denaturation of native tertiary structure. The results of this study are discussed in terms of their relevance to the early stages of uncoating in vivo.

Interaction of viruses with cell surface receptors

This chapter discusses the interaction of viruses with cell surface receptors. The rigorous characterizations of receptor–ligand interactions have been derived from binding studies of radiolabeled ligands in neuropharmacology and endocrinology. The definition of viral recognition sites as receptors involves three major criteria that are derived from models of ligand–receptor interactions: saturability, specificity, and competition. A variety of approaches have been used to study the interaction of viral particles with cell surface receptors or reception sites. A rigorous study of viral–receptor interactions requires the use of more than one technique as different approaches provide complementary information about viral binding. The chapter discusses membrane components that interact with viruses. The identification of the subviral components that are responsible for the binding of viruses to cell surfaces has preceded the structural understanding of the cellular receptors themselves. The chapter summarizes current data concerning the viral attachment protein (VAP) of selected viruses.

Application of Arrhenius kinetic theory to viral eclipse: selection of bacteriophage phi X174 mutants

Analysis of the bacteriophage phi X174 eclipse period in terms of Arrhenius kinetic theory suggests the following hypothesis: mutants should exist with two concomitant physiological characteristics as their phenotype. These are an eclipse rate lower than that of the wild type at permissive temperatures for plaque formation and an eclipse rate too low at lower temperatures to permit plaque development. Thus, enrichment of a mutagenized virus population for mutants that fail to eclipse during a short period at permissive temperatures should yield eclipse mutants with the cold-sensitive (cs; nonpermissive temperature, 25 degrees C), and not the temperature-sensitive (ts; nonpermissive temperature, 42 degrees C), plaque phenotype. In several trials, the frequency of the cs phenotype in the population increased from less than 0.2% to between 2 and 4% after the enrichment step, whereas the frequency of the ts phenotype remained unchanged (less than 0.2%). Moreover, 80% of these cs mutants have eclipse rates that are 3- to 40-fold lower than that of the wild type at both 37 degrees C and 25 degrees C. The successful application of the Arrhenius theory to phi X eclipse may provide insights into the molecular mechanism whereby the phi X174 genome is delivered into the host cell. Since the eclipse kinetics of other nonenveloped viruses are similar to those of phi X174, kinetic theory may be broadly applicable in the selection and characterization of viral eclipse mutants.

Replacement of mouse LM fibroblast choline by a sulfonium analog. Effects on membrane properties as determined by virus probes

A sulfonium analog of choline ('sulfocholine', a natural phospholipid constituent of diatoms) was metabolically incorporated into mouse LM fibroblasts cultured in serum-free medium. Subconfluent cultures of LM cells were able to utilize sulfocholine as sole choline source and to increase in cell number for 3 days of incubation; thereafter a decrease in cell number was observed. In contrast, cultures of LM cells seeded to confluency showed no decrease in cell number up to at least 10 days when maintained, with daily medium changes, in medium containing either choline or the sulfonium analog. Such confluent cultures, maintained for 7 days in sulfocholine-containing medium, showed virtually complete replacement of cellular phosphatidylcholine and greater than 50% replacement of cellular sphingomyelin by their respective sulfonium analogs. The functional exchangeability of natural phosphatidylcholine and sphingomyelin with their sulfonium analogs to participate in normal cell membrane-mediated activities was demonstrated by comparatively assaying the abilities of sulfocholine- and choline-maintained cells to incorporate and replicate certain animal viruses known to possess membrane-dependent steps in various phases of their replication cycles. No difference was detected between the abilities of sulfocholine- and choline-maintained cells to take up vesicular stomatitis virus or mengo virus, or to replicate vesicular stomatitis virus, mengo virus or mouse hepatitis virus.