Spectrum of activity of soluble intercellular adhesion molecule-1 against rhinovirus reference strains and field isolates.

The antiviral potency of soluble intercellular adhesion molecule-1 (ICAM-1; the major receptor for human rhinoviruses) was determined for a subset of American Type Culture Collection reference serotypes and field isolates of rhinovirus. The results indicate that soluble ICAM-1 exhibits a broad spectrum of activity against rhinoviruses and that field isolates have a sensitivity indistinguishable from that of laboratory strains.

Formation of rhinovirus-soluble ICAM-1 complexes and conformational changes in the virion.

Viral receptors serve both to target viruses to specific cell types and to actively promote the entry of bound virus into cells. Human rhinoviruses (HRVs) can form complexes in vitro with a truncated soluble form of the HRV cell surface receptor, ICAM-1. These complexes appear to be stoichiometric, with approximately 60 ICAM molecules bound per virion or 1 ICAM-1 molecule per icosahedral face of the capsid. The complex can have two fates, either dissociating to yield free virus and free ICAM-1 or uncoating to break down to an 80S empty capsid which has released VP4, viral RNA, and ICAM-1. This uncoating in vitro mimics the uncoating of virus during infection of cells. The stability of the virus-receptor complex is dependent on temperature and the rhinovirus serotype. HRV serotype 14 (HRV14)-ICAM-1 complexes rapidly uncoat, HRV16 forms a stable virus-ICAM complex which does not uncoat detectably at 34 degrees C, and HRV3 has an intermediate phenotype. Rhinovirus can also uncoat after exposure to mildly acidic pH. The sensitivities of individual rhinovirus serotypes to ICAM-1-mediated virus uncoating do not correlate with uncoating promoted by incubation at low pH, suggesting that these two means of virus destabilization occur by different mechanisms. Soluble ICAM-1 and low pH do not act synergistically to promote uncoating. The rate of uncoating does appear to be inversely related to virus affinity for its receptor.

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.

Mechanisms of receptor-mediated rhinovirus neutralization defined by two soluble forms of ICAM-1.

The majority of human rhinoviruses use intercellular adhesion molecule 1 (ICAM-1) as a cell surface receptor. Two soluble forms of ICAM-1, one corresponding to the entire extracellular portion [tICAM(453)] and one corresponding to the two N-terminal immunoglobulin-like domains [tICAM(185)], have been produced, and their effects on virus-receptor binding, virus infectivity, and virus integrity have been examined. Results from competitive binding experiments indicate that the virus binding site is largely contained within the two N-terminal domains of ICAM-1. Virus infectivity studies indicate that tICAM(185) prevents infection by direct competition for receptor binding sites on virus, while tICAM(453) prevents infection at concentrations 10-fold lower than that needed to inhibit binding and apparently acts at the entry or uncoating steps. Neutralization by both forms of soluble ICAM-1 requires continual presence of ICAM-1 during the infection and is largely reversible. Both forms of soluble ICAM-1 can alter rhinovirus to yield subviral noninfectious particles lacking the viral subunit VP4 and the RNA genome, thus mimicking virus uncoating in vivo, although this irreversible modification of rhinovirus is not the major mechanism of virus neutralization.

Folding of influenza hemagglutinin in the endoplasmic reticulum.

The folding of influenza hemagglutinin (HA0) in the ER was analyzed in tissue culture cells by following the formation of intrachain disulfides after short (1 min) radioactive pulses. While some disulfide bonds were already formed on the nascent chains, the subunits acquired their final disulfide composition and antigenic epitopes posttranslationally. Two posttranslational folding intermediates were identified. In CHO cells constitutively expressing HA0, mature HA0 subunits were formed with a half time of 3 min and their folding reached completion at 22 min. The rate of folding was highly dependent on cell type and expression system, and thus regulated by factors other than the sequence of the protein alone. Exposure of cells to stress conditions increased the level of glucose regulated proteins, including BiP, and decreased the folding rate. The efficiency of folding and subsequent trimerization was not dependent on the rate of translation, nor on temperature between 37 and 15 degrees C; however, the rates of folding and trimerization decreased with decreasing temperature. Whereas the rate of folding was independent of expression level, trimerization was accelerated at higher levels of expression.

Interactions of misfolded influenza virus hemagglutinin with binding protein (BiP).

We have characterized the association between the binding protein, BiP (also known as GRP 78), and misfolded forms of the influenza virus hemagglutinin precursor, HA0. BiP is a heat-shock-related protein that binds to unassembled immunoglobulin heavy chain and to a variety of misfolded proteins in the lumen of the ER. A small fraction (5-10%) of newly synthesized HA0 in CV-1 cells was found to be misfolded and retained in the ER. When glycosylation was blocked with tunicamycin, all of the HA0 produced was similarly misfolded. The misfolded HA0 was retained as relatively small (9-25-S) complexes associated with BiP. In these complexes the top domains of HA0 were correctly folded judging by their reactivity with monoclonal antibodies, but the polypeptides were cross-linked via anomalous interchain disulfides. The association with BiP was non-covalent and easily broken by warming to 37 degrees C or by adding ATP to the lysate. Pulse-chase experiments showed that HA0's self-association into complexes occurred immediately after synthesis and was followed rapidly by BiP association. The misfolded, BiP-associated HA0 was not transported to the plasma membrane but persisted as complexes in the ER for a long period of time before degradation (t1/2 = 6 h). The results suggested that BiP may be part of a quality control system in the ER and that one of its functions is to detect and retain misfolded proteins.