A complementary DNA clone has been isolated that encodes a coxsackievirus and adenovirus receptor (CAR). When transfected with CAR complementary DNA, nonpermissive hamster cells became susceptible to coxsackie B virus attachment and infection. Furthermore, consistent with previous studies demonstrating that adenovirus infection depends on attachment of a viral fiber to the target cell, CAR-transfected hamster cells bound adenovirus in a fiber-dependent fashion and showed a 100-fold increase in susceptibility to virus-mediated gene transfer. Identification of CAR as a receptor for these two unrelated and structurally distinct viral pathogens is important for understanding viral pathogenesis and has implications for therapeutic gene delivery with adenovirus vectors.
The coxsackievirus and adenovirus receptor (CAR) mediates viral attachment and infection, but its physiologic functions have not been described. In nonpolarized cells, CAR localized to homotypic intercellular contacts, mediated homotypic cell aggregation, and recruited the tight junction protein ZO-1 to sites of cell-cell contact. In polarized epithelial cells, CAR and ZO-1 colocalized to tight junctions and could be coprecipitated from cell lysates. CAR expression led to reduced passage of macromolecules and ions across cell monolayers, and soluble CAR inhibited the formation of functional tight junctions. Virus entry into polarized epithelium required disruption of tight junctions. These results indicate that CAR is a component of the tight junction and of the functional barrier to paracellular solute movement. Sequestration of CAR in tight junctions may limit virus infection across epithelial surfaces.G roup B coxsackieviruses and a number of adenovirus serotypes initiate infection by binding to the coxsackievirus and adenovirus receptor (CAR) (1-3). CAR is a 46-kDa integral membrane protein with a typical transmembrane region, a long cytoplasmic domain, and an extracellular region composed of two Ig-like domains (1, 2). Both adenovirus (4) and coxsackievirus (5) interact with the N-terminal domain. Homologs of human CAR have been characterized in mice (2, 6), rats, pigs, dogs (7), and zebrafish (8). The murine and human proteins are very similar (91% amino acid identity within the extracellular domain, 77% within the transmembrane domain, and 95% identity within the cytoplasmic domain). Variant isoforms of CAR, which differ only at the C terminus and which most likely result from alternative splicing, have been identified in mice (6), humans, and rats (7). Despite evidence of its evolutionary conservation in mammals and nonmammalian vertebrates, the function of CAR is not known.Tight junctions are continuous circumferential intercellular contacts at the apical poles of lateral cell membranes, appearing in electron micrographs as a series of discrete contacts between the plasma membranes of adjacent cells (9). Tight junctions form a barrier that regulates the paracellular transit of water, solutes, and immune cells across an epithelium (10), and are essential for establishing cell polarity by separating the apical and basolateral domains of polarized epithelial cells (11). ZO-1, the first tight junction protein identified (12, 13), is an intracellular peripheral membrane scaffolding protein important for tight junction structure and assembly. In the present study, we found that in polarized epithelial cells CAR is expressed at the tight junction, where it associates with ZO-1 and functions in the barrier to the movement of macromolecules and ions. Materials and MethodsCell Culture. T-84, CALU-3, and 16HBE14o-cells were grown in 10% CO 2 in a 1:1 mixture of DMEM and Ham's F-12 medium with 10% FCS. To establish polarized monolayers, 5 ϫ 10 5 cells per well were plated on 12-mm diameter polyester filters with a ...
Group B coxsackieviruses (CVBs) must cross the epithelium as they initiate infection, but the mechanism by which this occurs remains uncertain. The coxsackievirus and adenovirus receptor (CAR) is a component of the tight junction and is inaccessible to virus approaching from the apical surface. Many CVBs also interact with the GPI-anchored protein decay-accelerating factor (DAF). Here, we report that virus attachment to DAF on the apical cell surface activates Abl kinase, triggering Rac-dependent actin rearrangements that permit virus movement to the tight junction. Within the junction, interaction with CAR promotes conformational changes in the virus capsid that are essential for virus entry and release of viral RNA. Interaction with DAF also activates Fyn kinase, an event that is required for the phosphorylation of caveolin and transport of virus into the cell within caveolar vesicles. CVBs thus exploit DAF-mediated signaling pathways to surmount the epithelial barrier.
Recent identification of two receptors for the adenovirus fiber protein, coxsackie B and adenovirus type 2 and 5 receptor (CAR), and the major histocompatibility complex (MHC) Class I ␣-2 domain allows the molecular basis of adenoviral infection to be investigated. Earlier work has shown that human airway epithelia are resistant to infection by adenovirus. Therefore, we examined the expression and localization of CAR and MHC Class I in an in vitro model of well differentiated, ciliated human airway epithelia. We found that airway epithelia express CAR and MHC Class I. However, neither receptor was present in the apical membrane; instead, both were polarized to the basolateral membrane. These findings explain the relative resistance to adenovirus infection from the apical surface. In contrast, when the virus was applied to the basolateral surface, gene transfer was much more efficient because of an interaction of adenovirus fiber with its receptors. In addition, when the integrity of the tight junctions was transiently disrupted, apically applied adenovirus gained access to the basolateral surface and enhanced gene transfer. These data suggest that the receptors required for efficient infection are not available on the apical surface, and interventions that allow access to the basolateral space where fiber receptors are located increase gene transfer efficiency.The mechanism of infection by type 2 and type 5 adenovirus has been extensively studied. However, most of the knowledge on adenoviral infection has been obtained from studies done on immortalized cell lines. The first steps in adenovirus infection are thought to involve primarily two proteins in the capsid, fiber and penton base (1-3). The fiber protein is important for binding to a high affinity fiber receptor. In a human oral epidermoid carcinoma cell line (KB cells), A549 cells, and HeLa cells, this receptor is thought to be present in the range of 3,000 -10,000 receptors/cell (4 -6). NIH 3T3 cells, which are resistant to adenovirus infection, have less than 100 receptors/ cell (7). After binding to the fiber receptor, penton base interaction with ␣ V  3 and ␣ V  5 integrins facilitates internalization via receptor-mediated endocytosis (2,8,9). The acidic pH the virus encounters in the endosome may trigger a conformational change that releases the virus into the cytoplasm (10 -12) and allows the adenovirus capsid to travel to the nucleus (2, 13). Then viral proteins and DNA bind to the nuclear pore complex, capsid disassembly continues, and DNA enters the nucleus accompanied by DNA-associated protein 7 (1, 2, 14). These studies have concluded that a high affinity fiber receptor is required for binding and infection and that an ␣ V  integrin acts as a co-receptor.We and others (15-22) have found infection of ciliated airway epithelia by adenovirus to be inefficient. In an in vitro model of human airway epithelia, we found that unlike infections of HeLa cells adenovirus infection of ciliated airway epithelia was quite limited and that which did occur w...
We have determined the high resolution crystal structure of the I domain from the ␣-subunit of the integrin ␣21, a cell surface adhesion receptor for collagen and the human pathogen echovirus-1. The domain, as expected, adopts the dinucleotide-binding fold, and contains a metal ion-dependent adhesion site motif with bound Mg 2؉ at the top of the -sheet. Comparison with the crystal structures of the leukocyte integrin I domains reveals a new helix (the C-helix) protruding from the metal ion-dependent adhesion site face of the domain which creates a groove centered on the magnesium ion. Modeling of a collagen triple helix into the groove suggests that a glutamic acid side chain from collagen can coordinate the metal ion, and that the Chelix insert is a major determinant of binding specificity. The binding site for echovirus-1 maps to a distinct surface of the ␣2-I domain (one edge of the -sheet), consistent with data showing that virus and collagen binding occur by different mechanisms. Comparison with the homologous von Willebrand factor A3 domain, which also binds collagen, suggests that the two domains bind collagen in different ways.The integrins are a family of plasma membrane proteins that transduce bidirectional signals between the cytoplasm and the extracellular matrix or other cells (1). The integrin ␣21 is expressed on a variety of cell types, serving as the collagen receptor on platelets and fibroblasts, and as both a collagen and laminin receptor on endothelial and epithelial cells (2, 3). It also acts as the receptor for the human pathogen echovirus-1 (4). In common with six other integrin ␣-chains (␣1, ␣D, ␣E, ␣L, ␣M, and ␣X) the ␣2 chain contains a 200-amino acid inserted domain, the I domain, that is homologous to the von Willebrand factor A domains (5). Recombinant ␣2-I domain recapitulates many of the ligand binding properties of the parent integrin (6 -8). It exhibits specific binding to various fibrillar collagens, and two groups have shown that, like collagen binding to the complete receptor (9, 10), binding to the I domain is cation-dependent, being supported by magnesium or manganese but not by calcium (7, 11). The triple-helical structure of collagen is required for recognition by ␣21, but specific collagen sequences have not been identified (for review, see Ref. 12).The first crystal structure of an integrin I domain, from ␣M2, showed that it adopts the dinucleotide-binding fold, with a central parallel -sheet surrounded on both sides by ␣-helices (13). In this class of fold, a functional surface of the domain always lies at the C-terminal end of the -sheet (14). In the I domain, a novel cation coordination sphere is located there, and in the ␣M-I domain crystal structure with bound Mg 2ϩ , a glutamate side chain from a neighboring I domain in the crystal lattice completes the octahedral coordination sphere of the metal. This led to the suggestion that the glutamate behaves as a ligand mimetic, as most integrin ligands possess a critical aspartate residue (or glutamate) as a key fe...
The major group B coxsackievirus (CVB) receptor is a component of the epithelial tight junction (TJ), a protein complex that regulates the selective passage of ions and molecules across the epithelium. CVB enters polarized epithelial cells from the TJ, causing a transient disruption of TJ integrity. Here we show that CVB does not induce major reorganization of the TJ, but stimulates the specific internalization of occludin-a TJ integral membrane component-within macropinosomes. Although occludin does not interact directly with virus, depletion of occludin prevents CVB entry into the cytoplasm and inhibits infection. Both occludin internalization and CVB entry require caveolin but not dynamin; both are blocked by inhibitors of macropinocytosis and require the activity of Rab34, Ras, and Rab5, GTPases known to regulate macropinocytosis. Thus, CVB entry depends on occludin and occurs by a process that combines aspects of caveolar endocytosis with features characteristic of macropinocytosis.
Echoviruses are human pathogens belonging to the picornavirus family. Decay-accelerating factor (DAF) is a glycosylphosphatidylhinostol (GPI)-anchored surface protein that protects cells from lysis by autologous complement. Anti-DAF monoclonal antibodies prevented echovirus 7 attachment to susceptible cells and protected cells from infection. HeLa cells specifically lost the capacity to bind echovirus 7 when treated with phosphatidylinositol-specific phospholipase C, an enzyme that releases GPI-anchored proteins from the cell surface, indicating that the virus receptor, like DAF, is a GPI-anchored protein. Although Chinese hamster ovary cells do not bind echovirus 7, transfectants expressing human DAF bound virus efficiently, and binding was prevented by pretreatment with an anti-DAF monoclonal antibody. Anti-DAF antibodies prevented infection by at least six echovirus seroypes. These results indicate that DAF is the receptor mediating attachment and infection by several echoviruses.
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