The Coronavirus Transmissible Gastroenteritis Virus Causes Infection after Receptor-Mediated Endocytosis and Acid-Dependent Fusion with an Intracellular Compartment

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J Virol, January 1998, p. 527-534, Vol. 72, No. 1
0022-538X/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.

The Coronavirus Transmissible Gastroenteritis Virus Causes Infection after Receptor-Mediated Endocytosis and Acid-Dependent Fusion with an Intracellular Compartment

G. H. Hansen,¹ B. Delmas,² L. Besnardeau,² L. K. Vogel,¹ H. Laude,² H. Sjöström,¹ and O. Norén¹^,^*

Biochemistry Laboratory C, Department of Medical Biochemistry and Genetics, The Panum Institute, DK-2200 Copenhagen N, Denmark,¹ and Unité de Virologie Immunologie Moléculaires, INRA, F-78350 Jouy-en-Josas, France²

Received 21 May 1997/Accepted 18 September 1997

	ABSTRACT

Top Abstract Introduction Materials & Methods Results Discussion References

Aminopeptidase N is a species-specific receptor for transmissible gastroenteritis virus (TGEV), which infects piglets, andfor the 229E virus, which infects humans. It is not known whetherthese coronaviruses are endocytosed before fusion with a membraneof the target cell, causing a productive infection, or whetherthey fuse directly with the plasma membrane. We have studied theinteraction between TGEV and a cell line (MDCK) stably expressingrecombinant pig aminopeptidase N (pAPN). By electron microscopyand flow cytometry, TGEV was found to be associated with the plasmamembrane after adsorption to the pAPN-MDCK cells. TGEV was alsoobserved in endocytic pits and apical vesicles after 3 to 10 minof incubation at 38°C. The number of pits and apical vesicleswas increased by the TGEV incubation, indicating an increase inendocytosis. After 10 min of incubation, a distinct TGEV-pAPN-containingpopulation of large intracellular vesicles, morphologically compatiblewith endosomes, was found. A higher density of pAPN receptorswas observed in the pits beneath the virus particles than in thesurrounding plasma membrane, indicating that TGEV recruits pAPNreceptors before endocytosis. Ammonium chloride and bafilomycinA₁ markedly inhibited the TGEV infection as judged from virusproduction and protein biosynthesis analyses but did so only whenadded early in the course of the infection, i.e., about 1 h afterthe start of endocytosis. Together our results point to an acidintracellular compartment as the site of fusion for TGEV.

	INTRODUCTION

Top Abstract Introduction Materials & Methods Results Discussion References

Coronaviruses cause a wide spectrum of diseases in humans and animals, among which respiratory and enteric diseases are themost commonly seen (for a review, see reference 19). Epithelialcells of the digestive and respiratory tracts are the primarysites of replication for many coronaviruses. It is of great interestto understand in detail how different genetic subsets of coronaviruses(11) gain entry into these cells and whether they use similaror different strategies for fusion and penetration. Substantialevidence has been provided that coronaviruses enter their targetcells by using different plasma membrane glycoproteins as receptors.Thus, several members of a family of carcinoembryonic antigensare known to act as receptors for mouse hepatitis virus (MHV)(12, 43). The class II membrane protein aminopeptidase N (APN)(26, 31) was demonstrated to be the major receptor for theporcine coronavirus transmissible gastroenteritis virus (TGEV)(8), the human coronavirus 229E (42), the feline coronavirus(2, 38), and the canine coronavirus (2, 38), all ofwhich belong to a genetic subset that differs from that of MHV(11). APN is apically expressed in epithelial cells, which hasthe consequence that these cells are preferably infected fromthe apical side (34). Studies on the biosynthesis and intracellulartransport of human APN in MDCK cells have shown that the majorityof the APN is transported directly from the trans-Golgi networkto the apical membrane (41).

The S glycoprotein of the coronavirus envelope plays a crucial role in the early steps of infection, since it carries functionsfor both receptor binding (15, 23, 25) and virus-cell membranefusion (6). A complete understanding of the infection mechanismsof the coronaviruses includes the identification of their siteof fusion. It is an unsettled matter whether penetration occursby fusion directly with the plasma membrane or whether the differentcoronaviruses are endocytosed before fusion and penetration (19,28). Until now most of the studies aimed at answering this questionhave focused on MHV. It has been shown that low pH is not a requirementfor MHV infection (13, 21). In addition, it has been reportedthat MHV internalization by endocytosis does not necessarily leadto a productive infection (1, 21). Furthermore, the pH optimumfor the cell-cell fusion activity of MHV is above 7.0 (35, 37).Taken together, these data make it most likely that fusion andpenetration of MHV take place at the plasma membrane level. Onthe other hand, it has been reported that MHV infection is delayedby ammonium chloride (29), which is known to prevent pH-dependentmembrane fusion in other virus systems (27, 28). This mightsuggest that endocytosis of MHV occurs prior to penetration (22,29). However, the observed retardation by ammonium chloridecould as well depend on unspecific cellular effects of the drug.

We have studied the early virus-cell interactions of TGEV in order to settle whether this virus fuses with intracellular membranesafter endocytosis of the TGEV-pig APN (TGEV-pAPN) complex or whetherfusion occurs directly after attachment to the primary receptorat the cell surface. For this purpose we used a transfected cellclone (pAPN-MDCK) of the polarized cell line MDCK which stablyexpresses recombinant wild-type pAPN at high levels (8). Thismakes it possible to monitor the TGEV-pAPN complexes and pAPNalone by immunoelectron microscopy. For some experiments analyzingthe importance of low endosomal pH for infection, the naturallyfully permissive ST cells (24) were used as well. A direct interactionbetween the TGEV receptor pAPN and TGEV at the plasma membranelevel was demonstrated, and the formation of this complex wasfound to increase endocytosis. After endocytosis, the TGEV-pAPNcomplexes were transported further to large intracellular vesiclesthat were morphologically compatible with endosomes. BafilomycinA₁ and ammonium chloride added before endocytosis inhibited infectionin pAPN-MDCK cells and inhibited productive infection in ST cells,demonstrating that acidity is important for infection. These findingsprovide biochemical evidence that the morphological observationsof endocytosis are related to the productive infection.

	MATERIALS AND METHODS

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Virus and cells. The cell-adapted Purdue-115 strain was used as a TGEV source. Virus suspensions were produced on the PD5 cell line, purifiedby centrifugation through a sucrose gradient (purified virus particlesuspension, 1.2 mg/ml), and then titrated on the ST cell lineas described earlier (24) (physical/infectious particle ratio,10 to 50) (23a). pAPN-MDCK cells (8) or transfected MDCK cellsexpressing tailless pAPN (TLpAPN-MDCK cells) (see below) weregrown in Eagle's minimal essential medium supplemented with 2mM L-glutamine, 10% fetal calf serum, 100 U of penicillin perml, and 100 µg of streptomycin per ml.

Tailless pAPN cDNA, encoding a membrane-bound form of pAPN in which the 9-amino-acid N-terminal cytoplasmic sequence is exchangedfor a Met-Ala-Arg sequence attached to the transmembrane partof the anchor, was constructed as previously described in detail(40). MDCK cells were transfected with 20 µg of pTej-4 (20),containing the cDNA coding for the tailless pAPN, and 2 µg ofpSV2-neo. G418-resistant clones were then isolated and subclonedas described previously (40). The expression of tailless pAPNwas analyzed by enzymatic measurements, and the correct molecularweight was assessed by sodium dodecyl sulfate (SDS) gel electrophoresisfollowed by Western blotting with a specific antibody directedagainst the denatured pAPN C subunit (36).

pAPN-MDCK or TLpAPN-MDCK cells (10⁵) were seeded into 6.2-mm-diameter 24-well (0.45-µm-pore-size) Transwell chambers (CostarEurope Ltd., Badhoevedorp, The Netherlands). Twenty-four-hour-oldconfluent monolayers were used. The tightness of the filter-grownmonolayers was assayed by filling the inner chamber to the brimand monitoring a constant fluid level after 5 h.

TGEV particles were adsorbed to tight filter-grown layers of pAPN-MDCK or TLpAPN-MDCK cells by adding 40 µl of purified virusparticle suspension in 0.4 ml of medium (4°C) to the apical side(10⁴ to 10⁵ virus particles per cell). After adsorption (60 min, 4°C), thevirus-containing solution was removed and the cells were rinsedonce and further incubated at 38°C for different lengths of time(0 to 60 min). The incubations were stopped by cooling to 4°C,and the filters were then washed three times with isotonic phosphate-bufferedsaline, pH 7.2.

Inhibition of infectivity. Ammonium chloride and bafilomycin A₁ (Sigma Chemical Co., St. Louis, Mo.) (3), both of which are known to neutralize low-pHorganelles, were used as inhibitors of virus penetration.

TGEV (50 PFU per well) was added to pAPN-MDCK cell monolayers in minimal essential medium containing newborn calf serum (5%).After 120 min at 4°C, unbound virus particles were removed byrinsing with the medium three times. Ammonium chloride (25 mMfinal concentration) was then added to the incubation mixturesat different time points before and after the temperature wasraised to 38°C (see Fig. 5). In all experiments the cells wereleft with ammonium chloride for 2 h. The cells were then washedfree of the drug with minimal essential MEM medium. The perturbationof productive infection was measured as a reduction of the cytopathiceffect on the cells. The cytopathic effect was measured as thereduction of the acetic acid-mediated release of crystal violetincorporated in cells surviving the cytopathic effect of TGEVafter fixation and staining, as previously described in detail(9). Similar experiments were also performed with ST cellsand 200 PFU per well, and the degree of perturbation was assayedby the reduction in plaque formation (24).

To further study the importance of organelle acidity for TGEV infection, the effects of bafilomycin A₁ and ammonium chlorideon the biosynthesis of viral proteins was studied by using thenaturally permissive ST cells (24). TGEV was adsorbed and endocytosiswas initiated as described above for the pAPN-MDCK cells. BafilomycinA₁ (5 µM) or ammonium chloride (25 mM) was added at differenttimes (0 to 180 min) after the start of endocytosis. Three hoursafter virus adsorption, the cultures were supplemented with 50µCi of [³⁵S]methionine per ml of medium and then incubated for 5 h for proteinlabelling. The cells were then solubilized by incubation (1 h,4°C) in 10 mM Tris-HCl (pH 8.0) containing 2% Triton X-100, 0.15M NaCl, 0.6 M KCl, and 0.5 mM MgCl₂, and 10³ U of aprotinin per ml was added. Undissolved material was removedby centrifugation (10,000 × g, 30 min, 4°C). TGEV proteins wereimmunoisolated and analyzed by SDS-polyacrylamide gel electrophoresisas described earlier (33).

Flow cytometry. pAPN- and human APN-expressing MDCK cells were released from the culture bottles by trypsination. The cells (5 × 10⁵) were incubated at 4°C for 1 h in the presence of TGEV (2 × 10⁸ PFU/ml). After being washed three times with cold staining medium(Dulbecco's modified Eagle's medium supplemented with 3% bovineserum albumin and 0.02% sodium azide), the cells were incubated(4°C, 1 h) in TGEV antibody solution produced in pigs (24) (diluted500 times). The washed cells were then incubated in an excessof fluorescein isothiocyanate-labelled affinity-purified rabbitimmunoglobulin G (IgG) against porcine IgG (Biosys, Compiègne,France). The cells were then washed, fixed in phosphate-bufferedparaformaldehyde (5%), and analyzed on a FACScan apparatus (BectonDickinson).

Ultrastructural analyses. The cells were fixed in 2.5% glutaraldehyde in 0.1 M phosphate buffer, pH 7.2 (PB), for 30 min. After fixation, the filterswere cut from their holders, washed in PB, and postfixed in 1%osmium tetroxide in PB for 15 min at 4°C. After treatment with1% uranyl acetate in water for 1 h at 20°C, the cells were dehydratedin a graded series of ethanol solutions and finally embedded inEpon. Ultrathin sections were cut on an Ultramicrotome III (LKB,Stockholm, Sweden), stained in lead citrate for 5 s, and examinedin a Zeiss EM 900 electron microscope operated at 80 kV. Apicalvesicles were counted as the vesicles present in the 20% apicalpart of the cells.

Immunogold staining. Immunogold labelling of pAPN was performed on filter-grown cells fixed and processed as described above. Ultrathin sections(approximately 100 nm) were etched in 1% hydrogen peroxide inwater for 5 min and washed in TBS (0.05 M Tris-HCl buffer, 0.15M NaCl, pH 7.4) containing 1% Triton X-100. To minimize nonspecificantibody adsorption, the sections were treated with 3% bovineserum albumin in gold buffer (0.02 M Tris-HCl, 0.15 M NaCl, 0.25%bovine serum albumin, and 1% Triton X-100, pH 8.2) for 30 minat 20°C. The sections were then incubated in a rabbit anti-pAPNIgG (diluted in gold buffer) directed against the denatured pAPNC subunit (36) for 20 h at 4°C and for 1 h at 20°C in a moistchamber. After three washes (10 min each) in gold buffer, thesections were incubated with centrifuged (5,000 rpm, 15 min; SS-34Sorvall centrifuge) sheep anti-rabbit IgG conjugated to 5-nm-diametergold particles (16) for 30 min at room temperature. The sectionswere rinsed three times (10 min each) in gold buffer, twice (5min each) in TBS, and twice (5 min each) in water. The sectionswere finally contrasted in lead citrate for 45 s before examinationin a Zeiss EM 900 electron microscope operated at 80 kV.

The quantitative evaluation of the density of pAPN in the plasma membrane beneath the virus particles and in the adjacentplasma membrane was performed directly on a monitor connectedto the electron microscope. The numbers of gold particles in theformed pits beneath the virus particles and in a correspondinglength of the adjacent plasma membrane were counted.

Statistics. Quantitative data are presented as means ± standard errors. For significance tests, Student's t test was used.

	RESULTS

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TGEV is endocytosed and transported to large vesicles in the target cells. pAPN-MDCK cells, which express pAPN at a high level, were incubated with TGEV at 4°C for 60 min from the apical side, followedby incubation at 38°C for different lengths of time (0 to 60 min).The cells were directly fixed at the end of the incubation andfurther processed for electron microscopy, and the morphologywas examined.

Initially a high number of virus particles were seen closely associated to the apical plasma membrane (Fig. 1A). Frequentlythe virus particles were seen in close proximity to pits (Fig.1B and C) formed by invagination of a thickened plasma membrane,indicating that the pits are protein coated. Infection of pAPN-MDCKcells with TGEV induced a significant (P $>=$ 0.98) increase of thenumber of pits observed per cell profile in comparison to thatin uninfected cells (Table 1). Similarly a significant (P $>=$ 0.95)increase in the number of pits was observed when TLpAPN-MDCK cellswere used in a similar experiment (Table 1).

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FIG. 1. Apical binding and endocytosis of TGEV by pAPN-MDCK cells. (A) A large number of TGEV particles are seen in close proximity to the apical membrane after initial adsorption (60 min, 4°C) and incubation at 38°C (3 min). (B and C) TGEV particles (arrows) are seen in pits with a thickened plasma membrane after adsorption and incubation at 38°C for 3 min. (D) TGEV particle in a smooth apical vesicle (arrow) after incubation at 38°C for 10 min. (E) The arrow points to a smooth transport vesicle containing a TGEV particle which is positioned close to a larger endosome-like vesicle (EN), indicating vesicle fusion. (F) TGEV particles in large intracellular vesicles after incubation at 38°C for 30 min. The arrow indicates putative continuity between viral and vesicle membranes, indicating fusion between the TGEV particle and the intracellular vesicle. Bars, 200 nm.

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TABLE 1. Number of pits in TGEV-infected and uninfected pAPN-MDCK and TLpAPN-MDCK cells^a

Approximately 20-nm-wide gaps between the plasma membrane of the coated pits and the viral membrane were observed (Fig. 1Band C). Frequently, electron-dense linear structures were observedin these gaps. This material most probably represents the viralspikes formed by S-protein trimers (7) interacting with theirmembrane receptors (pAPN). We have not observed any continuitybetween viral and plasma membranes, which is compatible with theview that fusion does not occur at the plasma membrane level.

After 10 min of incubation at 38°C, the apical cell surface was partially cleared from viral particles. TGEV particles werenow present in small vesicles beneath the apical plasma membrane,as illustrated by the electron micrographs in Fig. 1D and E. Thus,0.64 ± 0.08 (n = 150) apical vesicles per cell profile were foundin the TGEV-infected cells 10 min after the elevation of the temperatureto 38°C. This is a significantly (P $>=$ 0.99) higher value thanthat found for uninfected cells (0.36 ± 0.05; n = 150). Occasionally,TGEV-containing smooth vesicles were observed close to large vesicles(Fig. 1E), indicating fusion between these compartments. Largeintracellular vesicles (Fig. 1F) containing many TGEV particleswere often observed. In these large vesicles the virus particleswere seen associated with the cisternal face of the membrane ata distance of approximately 20 nm. The electron-dense materialbetween the TGEV particles and the membrane, which is assumedto represent the S-protein-pAPN complex, was also observed inthese vesicles. Morphologically, these vesicles are compatiblewith endosomes. Free, non-membrane-associated virus particleswere very infrequently observed. The TGEV-pAPN complexes are thusalso kept intact in these endosome-like structures, which arelikely to have an acidic pH promoting the dissociation of theligand-receptor complexes (5).

pAPN is specifically involved in TGEV-cell binding and in the internalization process. Flow cytometry shows that binding of TGEV to the cell surface is specifically dependent on the presence of pAPN. This is demonstratedby an analysis using the pAPN-MDCK cells and MDCK cells transfectedby human APN (39). Distinct TGEV binding was seen for the pAPN-MDCKcells (Fig. 2b), but no such binding was observed for the MDCKcells transfected with human APN (Fig. 2a).

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FIG. 2. Specific binding of TGEV to pAPN-MDCK cells. MDCK cells permanently expressing human APN (a) or pAPN-MDCK cells (b) were incubated with TGEV (solid lines) or mock incubated (dotted lines). Cellular binding of TGEV was monitored by flow cytometry after incubation with a porcine anti-TGEV serum followed by incubation with a fluorescein isothiocyanate-labelled rabbit IgG directed against porcine IgG.

Immunogold labelling of pAPN on the TGEV-infected pAPN-MDCK cells was seen in close proximity to the virions present in pits(Fig. 3A and B) after incubation at 38°C for 10 min after theviral adsorption. In the pits beneath the virus particles, 2.18± 0.14 (n = 348) gold particles were observed. This is significantlyhigher (P $>=$ 0.999) than the number (0.73 ± 0.08; n = 347) foundin corresponding lengths of the plasma membrane outside the pitsin the same cell. The corresponding values for TGEV-infected TLpAPN-MDCKcells are 2.8 ± 0.19 (n = 102) and 0.26 ± 0.05 (n = 101) in thecorresponding lengths of the plasma membrane outside the pits,again showing a significant (P $>=$ 0.999) increase in labellingof the pits after TGEV infection. Together the data clearly demonstratethat the interaction between TGEV and its receptor pAPN causesa clustering of pAPN molecules.

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FIG. 3. Colocalization of pAPN and TGEV. Localization of pAPN was carried out by immunogold labelling of pAPN-MDCK cells which were incubated with TGEV from the apical side (4°C, 1 h). The cells were then incubated at 38°C for 10 min. (A) Gold labelling demonstrating the presence of pAPN is seen just beneath the TGEV particle (arrow) and to a lesser extent in the rest of the plasma membrane. (B) Gold labelling of a TGEV-containing pit (arrow), demonstrating colocalization between TGEV and pAPN. (C) Labelling of a large intracellular vesicle. The gold particles are seen all over the membrane localized to the cisternal side beneath the TGEV particles, demonstrating the presence of pAPN in close proximity to TGEV. Bars, 200 nm.

In the pAPN-MDCK cells, two distinct populations of large intracellular vesicles were observed. One population carries TGEVparticles; another does not. The population containing TGEV particlesdisplayed a significantly higher (P $>=$ 0.999) gold labelling (12.27± 0.96 gold particles per organelle [64 organelles analyzed])than the vesicles that are free of TGEV (1.11 ± 0.21 gold particlesper organelle [90 organelles analyzed]) (Fig. 3C and 4), showingthat the majority of pAPN is present in the same organelles asthe endocytosed TGEV.

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FIG. 4. TGEV- and pAPN-free large intracellular vesicles. The cells and labelling are as in Fig. 3. The arrows indicate vesicles free of TGEV particles and pAPN labelling. The arrowhead indicates a pAPN-TGEV-containing vesicle. Bar, 200 nm.

TGEV membrane fusion and penetration occur in an acidic compartment. Biochemical studies using the lysosomotropic drug ammonium chloride (30) or the proton pump inhibitor bafilomycin A₁ (3)showed that these drugs have a significant inhibitory effect onthe TGEV infectivity. They completely blocked the effect of TGEVon ST cells and potently reduced the effect of TGEV on pAPN-MDCKcells when added during the first hour after the start of endocytosis.Ammonium chloride is known to raise the pH in intracellular organelles1 min after addition (30), making it possible to inhibit a low-pH-dependentfusion process at defined time points. The almost complete inhibitoryeffect of ammonium chloride on the infectivity of TGEV in thefully permissive ST cells is demonstrated in Fig. 5b. Ammoniumchloride does not influence the infectivity of TGEV later whenpresent exclusively during the adsorption phase at 4°C, a temperaturethat blocks endocytosis. This indicates that the drug does notinfluence the binding of TGEV to the plasma membrane, as almost100% infectivity is achieved after warming the system to 38°C,thereby allowing endocytosis.

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FIG. 5. Inhibitory effect of ammonium chloride on TGEV infectivity. Virions were bound to pAPN-MDCK cells (a) or ST cells (b) at 0°C for 120 min, and unbound virions were washed away. Ammonium chloride (25 mM final concentration) was added at the indicated times ( $open circle$ ) and was present during different 2-h periods as indicated by the horizontal bars. The ammonium chloride was washed out of the cells at the ends of these periods. (a) The cytopathic effect was quantified colorimetrically by measuring cellular crystal violet association as described in Materials and Methods. The means and standard errors from three experiments are shown. (b) The cells were overlaid with agar at 38°C and incubated for 48 h at this temperature for plaque formation. The means from two different experiments are shown.

Half-maximal inhibition occurred about 1 h after warming, suggesting that penetration occurs in late endosomes. Ammonium chloridealso had a significant inhibitory effect on viral protein synthesis(Fig. 6B) when added 0 to 40 min after initiation of endocytosis.

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FIG. 6. Inhibitory effect of bafilomycin A₁ (a) and ammonium chloride (b) on TGEV infectivity. Virions were bound to ST cells at 0°C for 120 min, unbound virions were washed away with ice-cold medium, and then warm medium (37°C) was added. Bafilomycin A₁ (5 µM final concentration) (a) or ammonium chloride (25 mM) (b) was added at the indicated times (minutes) after adsorption. For each time, duplicate infections were performed. At 3 h after adsorption, [³⁵S]methionine was added. After 5 h of further incubation, the cells were solubilized and the viral proteins were immunoisolated, separated by SDS-polyacrylamide gel electrophoresis, and visualized by autoradiography.

A significant half-maximal inhibition of infection (Fig. 5a) was observed when similar experiments were carried out with thepAPN-MDCK cells. In this type of experiment, the drug effect wasmeasured by an assay of reduction of cytopathic effect, as TGEVinfection does not cause plaques in this cell system (9). Inthis case also, half-maximal inhibition occurred about 1 h afterwarming, supporting the idea that penetration occurs in late endosomes.

In addition, the proton pump inhibitor bafilomycin A₁ was used to further study the importance of acidic compartments forthe TGEV infection. Addition of this drug at 0 to 40 min afteradsorption of TGEV to ST cells strongly inhibited the TGEV infectionas monitored by the complete inhibition of TGEV protein biosynthesis(Fig. 6A). The drug was without effect when added 80 min afteradsorption or later, indicating that the sensitive period forviral inhibition is about 1 h after the start of viral uptake.This is compatible with the view that penetration occurs by alow-pH-dependent mechanism. Invaginations with a diameter similarto that of the membrane of the virus particles were occasionallyobserved in the TGEV-containing large vesicles (Fig. 1F). Theseinvaginations may represent fusions between TGEV particles andthe vesicular membranes, thus providing morphological supportfor the conclusion that fusion and penetration of TGEV occur inintracellular vesicles morphologically compatible with endosomes.

	DISCUSSION

Top Abstract Introduction Materials & Methods Results Discussion References

pAPN has been shown to be the major receptor for TGEV (8). In this study we extend this information by use of immunoelectronmicroscopy. Thus, we demonstrate that TGEV particles initiallyare adsorbed to the plasma membrane of the pAPN-MDCK cells viaits receptor pAPN, as the immunogold labelling for pAPN is foundin close proximity to the TGEV particles after virus binding.During binding, the virus particles carrying many receptor (pAPN)binding sites recruit pAPN molecules, as a local high densityof pAPN molecules is observed beneath the virus particles. Thisphenomenon is not dependent on the cytoplasmic tail, as the taillesspAPN is concentrated in a similar way in the membrane. The formationof these pAPN-TGEV complexes in the plasma membrane seems to increasethe endocytosis rate, as indicated by the increase in the numberof pits and the number of apical vesicles in the infected cells.The virus particles seem to act as cross-linkers of pAPN, therebyinducing endocytosis in a way similar to that of antibodies againstsurface antigens (antibody-mediated endocytosis) (4). It isnot known whether endocytosis of TGEV occurs via the clathrin-or non-clathrin-dependent mechanism or via the combination ofboth. The thickening of the membrane below the adsorbed TGEV particlesobserved in many cases might, however, indicate the involvementof clathrin-coated pits.

After endocytosis, the pAPN-TGEV complexes are transported to (or form) a distinct population of vesicles rich in TGEV particlesand pAPN molecules. Morphologically, these vesicles are compatiblewith endosomes. The finding that neutralization of the acidicorganelles, as demonstrated by the use of ammonium chloride andbafilomycin A₁, has to occur not later than 1 h after initiationof endocytosis for a productive infection to occur suggests thata late endosomal population is the site for TGEV genome penetration.This notion is further supported by the electron microscopic observationof structures compatible with fusions between viral and the vesicularmembranes. Thus, both morphological and biochemical data are compatiblewith the view that an intracellular vesicular compartment is thesite of TGEV genome penetration. We never observed syncytium formationin any of the cell lines examined, even with a brief incubationof infected cells at a slightly acidic pH (unpublished data).This might argue against an acid mechanism for the virus-membranefusion, thereby excluding an intracellular vesicular compartmentlike endosomes as the site of TGEV fusion and penetration. However,it is known that the requirements for syncytium formation aremore stringent than those for fusion with membranes in targetorganelles (18). This weakens the importance of the absenceof syncytium formation in the discussion of the site of viralfusion. TGEV is an enteropathogenic virus for which it is wellestablished that natural infection in vivo is oronasal (32).Thus, exposure to the very low pH in the stomach does not leadto complete inactivation of the virus. TGEV infectivity has beenshown to be unaltered down to pH 3 (24), which is an unusualfeature among enveloped viruses. This could imply that a conformationalchange induced in the S protein is at least partially reversible,as has been described for the rabies virus (14). It might besuggested that exposure to acidic pH is not sufficient to induceand keep a putative fusion peptide in an exposed state but thatan additional interaction with a membrane component, for example,the receptor (pAPN), is required.

In contrast to our observations for TGEV, syncytium formation has been observed for the mouse coronavirus MHV. In this casea slightly alkaline pH has been found to be optimal for triggeringMHV fusion (22, 35, 37). For this virus, internalizationhas been proposed to be of no importance for productive infection(1, 21). Thus, there seems to be a discrepancy between TGEVand MHV, which belong to two different genetic subsets of coronaviruses(11), with respect to site of fusion and penetration.

The mechanism for uptake and penetration of TGEV might also be of relevance for other coronaviruses of the same genetic subset,like human coronavirus 229E, which usually do not cause syncytiumformation. The initial mechanism of infection for TGEV thus isvery similar to what has been found for many other groups of envelopedviruses (18, 27, 28).

Together, the data reported in this paper strongly reinforce the opinion that pAPN is a functional receptor for TGEV. To ourknowledge, our report is the first in which visualization of thecellular uptake of the virus-receptor complexes has been demonstrated.The model system presented in this paper constitutes a good systemfor further studies of the structural requirements of pAPN-TGEVinteraction and the uptake of the virus-receptor complex. As astarting point for such studies, the binding site of TGEV hasbeen mapped outside the catalytic site to the C-terminal partof pAPN (10). The identification of the structural parts ofpAPN involved in endocytosis is of high interest for the understandingof the uptake mechanism. In this paper evidence is presented thatpAPN-TGEV interaction stimulates endocytosis. How this is exertedis for the moment completely unknown. It might be speculated thatthe interaction stimulates protein kinase A-dependent phosphorylation,which has been demonstrated to increase endocytosis (17).

	ACKNOWLEDGMENTS

We thank L.-L. Niels-Christiansen, E. Thorsen, and J. Gelfi for skilful technical assistance.

We thank the Danish Cancer Society, the Danish Research Council of Health Sciences, and the Benzon Foundation for generousfinancial support. G.H.H., O.N., H.S., and L.K.V. were membersof the Biomembrane Research Center, Aarhus University.

	FOOTNOTES

^* Corresponding author. Mailing address: IMBG, Biochemistry Laboratory C, The Panum Institute, Blegdamsvej 3, DK-2200 CopenhagenN, Denmark. Phone: 45 3532 7793. Fax: 45 3536 7980. E-mail: noren{at}biobase.dk.

REFERENCES

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

1. Asanaka, M., and M. C. Lai. 1993. Cell fusion studies identified multiple cellular factors involved in mouse hepatitis virus entry. Virology 197:732-741[Medline].

2. Benbacer, L., E. Kut, L. Besnardeau, H. Laude, and B. Delmas. 1997. Interspecies aminopeptidase N chimeras reveal species-specific receptor recognition by canine coronavirus, feline infectious peritonitis virus, and transmissble gastroenteritis virus. J. Virol. 71:734-737[Abstract].

3. Bowman, E. J., A. Siebers, and K. Altendorf. 1988. Bafilomycins: a class of inhibitors of membrane ATPases from microorganisms, animal cells, and plant cells. Proc. Natl. Acad. Sci. USA 85:7972-7976[Abstract/Free Full Text].

4. Bretscher, M. S. 1984. Endocytosis: relation to capping and cell locomotion. Science 224:681-686[Abstract/Free Full Text].

5. Davis, C. G., J. L. Goldstein, T. C. Südhof, R. G. W. Anderson, D. W. Russell, and M. S. Brown. 1987. Acid-dependent ligand dissociation and recycling of LDL receptor mediated by growth factor homology region. Nature 326:760-765[Medline].

6. De Groot, R., R. W. Van Leen, M. J. M. Dalderup, H. Vennema, M. C. Horzinek, and W. J. M. Spaan. 1989. Stably expressed FIPV peplomer protein induces cell fusion and elicits neutralizing antibodies in mice. Virology 171:493-502[Medline].

7. Delmas, B., and H. Laude. 1990. Assembly of coronavirus spike proteins into trimers and its role in epitope expression. J. Virol. 64:5367-5375[Abstract/Free Full Text].

8. Delmas, B., J. Gelfi, R. L'Haridon, L. K. Vogel, H. Sjöström, O. Norén, and H. Laude. 1992. Aminopeptidase N is a major receptor for the enteropathogenic coronavirus TGEV. Nature 357:417-419[Medline].

9. Delmas, B., J. Gelfi, H. Sjöström, O. Norén, and H. Laude. 1993. Further characterization of aminopeptidase N as a receptor for coronaviruses, p. 293-298. In H. Laude, and J. F. Vautherot (ed.), Coronaviruses: molecular biology and virus-host interactions. Plenum Press, New York, N.Y.

10. Delmas, B., J. Gelfi, E. Kut, H. Sjöström, O. Norén, and H. Laude. 1994. Determinants essential for the transmissible gastroenteritis virus-receptor interaction reside within a domain of aminopeptidase N that is distinct from the enzymatic site. J. Virol. 68:5216-5224[Abstract/Free Full Text].

11. Duarte, M., J. Gelfi, P. Lambert, D. Rasschaert, and H. Laude. 1993. Genome organization of porcine epidemic diarrhoea virus, p. 55-60. In H. Laude, and J. F. Vautherot (ed.), Coronaviruses: molecular biology and virus-host interactions. Plenum Press, New York, N.Y.

12. Dveksler, G. S., C. W. Dieffenbach, C. B. Cardellichio, K. McCuaig, M. N. Pensiero, G. S. Jiang, N. Beauchemin, and K. V. Holmes. 1993. Several members of the mouse carcinoembryonic antigen-related glycoprotein family are functional receptors for the coronavirus mouse hepatitis virus A59. J. Virol. 67:1-8[Abstract/Free Full Text].

13. Gallagher, T., C. Escarmis, and M. J. Buchmeier. 1991. Alteration of the pH dependence of coronavirus-induced fusion: effect of mutations in the spike glycoprotein. J. Virol. 65:1916-1928[Abstract/Free Full Text].

14. Gaudin, Y., C. Tuffereau, D. Segretain, M. Knossow, and A. Flamand. 1991. Reversible conformational changes and fusion activity of rabies virus glycoprotein. J. Virol. 65:4853-4859[Abstract/Free Full Text].

15. Godet, M., J. Grosclaude, B. Delmas, and H. Laude. 1994. Major receptor-binding and neutralization determinants are located within the same domain of the transmissible gastroenteritis virus (coronavirus) spike protein. J. Virol. 68:8008-8016[Abstract/Free Full Text].

16. Hansen, G. H., L.-L. Wetterberg, H. Sjöström, and O. Norén. 1992. Immunogold labelling is a quantitative method as demonstrated by studies on aminopeptidase N in microvillar membrane vesicles. Histochem. J. 24:132-136[Medline].

17. Hansen, S. H., and J. E. Casanova. 1994. Gs alpha stimulates transcytosis and apical secretion in MDCK cells through cAMP and protein kinase A. J. Cell Biol. 126:677-687[Abstract/Free Full Text].

18. Hernandez, L. D., L. R. Hoffman, T. G. Wolfsberg, and J. M. White. 1996. Virus-cell and cell-cell fusion. Annu. Rev. Cell. Dev. Biol. 12:627-661. [Medline]

19. Holmes, K. V., and M. C. Lai. 1996. Coronaviridae: the viruses and their replication, p. 1075-1093. In N. Fields, D. M. Knipe, P. Howley, et al. (ed.), Fields virology, 3rd ed. Lippincott-Raven Publishers, Philadelphia, Pa.

20. Johansen, T. E., M. S. Schøller, S. Tolstoy, and T. W. Schwartz. 1990. Biosynthesis of peptide precursors and protease inhibitors using new constitutive and inducible eukaryotic expression vectors. FEBS Lett. 267:289-294[Medline].

21. Kooi, C., M. Cervin, and R. Anderson. 1991. Differentiation of acid-pH dependent and non-dependent entry pathways for mouse hepatitis virus. Virology 180:108-119[Medline].

22. Krzystyniak, K., and J. M. Dupuy. 1984. Entry of mouse hepatitis virus 3 into cells. J. Gen. Virol. 65:227-231[Abstract/Free Full Text].

23. Kubo, H., Y. Yamada, and F. Taguchi. 1994. Localization of neutralizing epitopes and the receptor-binding site within the amino-terminal 330 amino acids of the murine coronavirus spike protein. J. Virol. 68:5403-5410[Abstract/Free Full Text].

23a. Laude, H. Unpublished data.

24. Laude, H., J. Gelfi, and J. M. Aynaud. 1981. In vitro properties of low- and high-passage strains of transmissible gastroenteritis coronavirus of swine. Am. J. Vet. Res. 42:447-449[Medline].

25. Laude, H., J. M. Chapsal, J. Gelfi, S. Labiau, and J. Grosclaude. 1986. Antigenic structure of transmissible gastroenteritis virus. I. Properties of monoclonal antibodies directed against virion proteins. J. Gen. Virol. 67:119-130[Abstract/Free Full Text].

26. Look, T., R. A. Ashmun, L. H. Shapiro, and S. C. Peiper. 1989. Human myeloid plasma membrane glycoprotein CD13 (gp150) is identical to aminopeptidase N. J. Clin. Invest. 83:1299-1307.

27. Marsh, M., and A. Helenius. 1989. Virus entry into animal cells. Adv. Virus Res. 36:107-151[Medline].

28. Marsh, M., and A. Pelchen-Matthews. 1994. The endocytic pathway and virus entry, p. 215-240. In E. Wimmer (ed.), Cellular receptors for animal viruses. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.

29. Mizzen, L., A. Hilton, S. Cheley, and R. Anderson. 1985. Attenuation of murine coronavirus infection by ammonium chloride. Virology 142:378-388[Medline].

30. Okhuma, S., and B. Poole. 1978. Fluorescence probe measurements of the intralysosomal pH in living cells and the perturbation of pH by various agents. Proc. Natl. Acad. Sci. USA 75:3327-3331[Abstract/Free Full Text].

31. Olsen, J., G. M. Cowell, E. Kønigshøfer, E. M. Danielsen, J. Møller, L. Laustsen, O. Hansen, K. G. Welinder, J. Engberg, W. Hunziker, M. Spiess, H. Sjöström, and O. Norén. 1988. Complete amino acid sequence of human intestinal aminopeptidase N as deduced from cloned cDNA. FEBS Lett. 238:307-314[Medline].

32. Pensaert, M., P. Callebaut, and E. Cox. 1993. Enteric coronaviruses of animals, p. 627-696. In A. Z. Kapikian (ed.), Viral infections of the gastrointestinal tract, 2nd ed. Marcel Dekker, New York, N.Y.

33. Rasschaert, D., M. Duarte, and H. Laude. 1990. Porcine respiratory coronavirus differs from transmissible gastroenteritis virus by a few genomic deletions. J. Gen. Virol. 71:2599-2607[Abstract/Free Full Text].

34. Rossen, J. W. A., C. P. J. Bekker, W. F. Voorhout, G. J. A. M. Strous, A. Van der Ende, and P. J. M. Rottier. 1994. Entry and release of transmissible gastroenteritis coronavirus are restricted to apical surfaces of polarized epithelial cells. J. Virol. 68:7966-7973[Abstract/Free Full Text].

35. Sawicki, S. G., and D. Sawicki. 1986. Coronavirus minus strand RNA synthesis and effect of cycloheximide on coronavirus RNA synthesis. J. Virol. 57:328-334[Abstract/Free Full Text].

36. Sjöström, H., and O. Norén. 1982. Changes of the quaternary structure of microvillus aminopeptidase in the membrane. Eur. J. Biochem. 122:245-250[Medline].

37. Sturman, L. S., S. Richard, and K. V. Holmes. 1990. Conformational changes of the coronavirus peplomer glycoprotein at pH 8.0 and 37°C correlates with virus aggregation and virus-induced cell fusion. J. Virol. 64:3042-3050[Abstract/Free Full Text].

38. Tresnan, D. B., R. Levis, and K. V. Holmes. 1996. Feline aminopeptidase N serves as a receptor for feline, canaine, porcine, and human coronaviruses in serogroup I. J. Virol. 70:8669-8674[Abstract].

39. Vogel, L. K., M. Spiess, H. Sjöström, and O. Norén. 1992. Evidence for an apical sorting signal on the ectodomain of human aminopeptidase N. J. Biol. Chem. 267:2794-2797[Abstract/Free Full Text].

40. Vogel, L. K., O. Norén, and H. Sjöström. 1995. Transcytosis of aminopeptidase N in Caco-2 cells is mediated by a non-cytoplasmic signal J. Biol. Chem. 270:22933-22938. [Abstract/Free Full Text]

41. Wessels, H. P., G. H. Hansen, C. Fuhrer, A. T. Look, H. Sjöström, O. Norén, and M. Spiess. 1990. Aminopeptidase N is directly sorted to the apical domain in MDCK cells. J. Cell Biol. 111:2923-2930[Abstract/Free Full Text].

42. Yeager, C. L., R. A. Ashmun, R. K. Williams, C. B. Cardellichio, L. H. Shapiro, A. T. Look, and K. V. Holmes. 1992. Human aminopeptidase N is a receptor for human coronavirus 229E. Nature 357:420-422[Medline].

43. Yokomori, K. Y., and M. M. C. Lai. 1992. Mouse hepatitis virus utilizes two carcinoembryonic antigens as alternative receptors. J. Virol. 66:6194-6199[Abstract/Free Full Text].

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J. Bacteriol.	Mol. Cell. Biol.	Microbiol. Mol. Biol. Rev.

Clin. Vaccine Immunol.	ALL ASM JOURNALS

1.	Asanaka, M., and M. C. Lai. 1993. Cell fusion studies identified multiple cellular factors involved in mouse hepatitis virus entry. Virology 197:732-741[Medline].
2.	Benbacer, L., E. Kut, L. Besnardeau, H. Laude, and B. Delmas. 1997. Interspecies aminopeptidase N chimeras reveal species-specific receptor recognition by canine coronavirus, feline infectious peritonitis virus, and transmissble gastroenteritis virus. J. Virol. 71:734-737[Abstract].
3.	Bowman, E. J., A. Siebers, and K. Altendorf. 1988. Bafilomycins: a class of inhibitors of membrane ATPases from microorganisms, animal cells, and plant cells. Proc. Natl. Acad. Sci. USA 85:7972-7976[Abstract/Free Full Text].
4.	Bretscher, M. S. 1984. Endocytosis: relation to capping and cell locomotion. Science 224:681-686[Abstract/Free Full Text].
5.	Davis, C. G., J. L. Goldstein, T. C. Südhof, R. G. W. Anderson, D. W. Russell, and M. S. Brown. 1987. Acid-dependent ligand dissociation and recycling of LDL receptor mediated by growth factor homology region. Nature 326:760-765[Medline].
6.	De Groot, R., R. W. Van Leen, M. J. M. Dalderup, H. Vennema, M. C. Horzinek, and W. J. M. Spaan. 1989. Stably expressed FIPV peplomer protein induces cell fusion and elicits neutralizing antibodies in mice. Virology 171:493-502[Medline].
7.	Delmas, B., and H. Laude. 1990. Assembly of coronavirus spike proteins into trimers and its role in epitope expression. J. Virol. 64:5367-5375[Abstract/Free Full Text].
8.	Delmas, B., J. Gelfi, R. L'Haridon, L. K. Vogel, H. Sjöström, O. Norén, and H. Laude. 1992. Aminopeptidase N is a major receptor for the enteropathogenic coronavirus TGEV. Nature 357:417-419[Medline].
9.	Delmas, B., J. Gelfi, H. Sjöström, O. Norén, and H. Laude. 1993. Further characterization of aminopeptidase N as a receptor for coronaviruses, p. 293-298. In H. Laude, and J. F. Vautherot (ed.), Coronaviruses: molecular biology and virus-host interactions. Plenum Press, New York, N.Y.
10.	Delmas, B., J. Gelfi, E. Kut, H. Sjöström, O. Norén, and H. Laude. 1994. Determinants essential for the transmissible gastroenteritis virus-receptor interaction reside within a domain of aminopeptidase N that is distinct from the enzymatic site. J. Virol. 68:5216-5224[Abstract/Free Full Text].
11.	Duarte, M., J. Gelfi, P. Lambert, D. Rasschaert, and H. Laude. 1993. Genome organization of porcine epidemic diarrhoea virus, p. 55-60. In H. Laude, and J. F. Vautherot (ed.), Coronaviruses: molecular biology and virus-host interactions. Plenum Press, New York, N.Y.
12.	Dveksler, G. S., C. W. Dieffenbach, C. B. Cardellichio, K. McCuaig, M. N. Pensiero, G. S. Jiang, N. Beauchemin, and K. V. Holmes. 1993. Several members of the mouse carcinoembryonic antigen-related glycoprotein family are functional receptors for the coronavirus mouse hepatitis virus A59. J. Virol. 67:1-8[Abstract/Free Full Text].
13.	Gallagher, T., C. Escarmis, and M. J. Buchmeier. 1991. Alteration of the pH dependence of coronavirus-induced fusion: effect of mutations in the spike glycoprotein. J. Virol. 65:1916-1928[Abstract/Free Full Text].
14.	Gaudin, Y., C. Tuffereau, D. Segretain, M. Knossow, and A. Flamand. 1991. Reversible conformational changes and fusion activity of rabies virus glycoprotein. J. Virol. 65:4853-4859[Abstract/Free Full Text].
15.	Godet, M., J. Grosclaude, B. Delmas, and H. Laude. 1994. Major receptor-binding and neutralization determinants are located within the same domain of the transmissible gastroenteritis virus (coronavirus) spike protein. J. Virol. 68:8008-8016[Abstract/Free Full Text].
16.	Hansen, G. H., L.-L. Wetterberg, H. Sjöström, and O. Norén. 1992. Immunogold labelling is a quantitative method as demonstrated by studies on aminopeptidase N in microvillar membrane vesicles. Histochem. J. 24:132-136[Medline].
17.	Hansen, S. H., and J. E. Casanova. 1994. Gs alpha stimulates transcytosis and apical secretion in MDCK cells through cAMP and protein kinase A. J. Cell Biol. 126:677-687[Abstract/Free Full Text].
18.	Hernandez, L. D., L. R. Hoffman, T. G. Wolfsberg, and J. M. White. 1996. Virus-cell and cell-cell fusion. Annu. Rev. Cell. Dev. Biol. 12:627-661. [Medline]
19.	Holmes, K. V., and M. C. Lai. 1996. Coronaviridae: the viruses and their replication, p. 1075-1093. In N. Fields, D. M. Knipe, P. Howley, et al. (ed.), Fields virology, 3rd ed. Lippincott-Raven Publishers, Philadelphia, Pa.
20.	Johansen, T. E., M. S. Schøller, S. Tolstoy, and T. W. Schwartz. 1990. Biosynthesis of peptide precursors and protease inhibitors using new constitutive and inducible eukaryotic expression vectors. FEBS Lett. 267:289-294[Medline].
21.	Kooi, C., M. Cervin, and R. Anderson. 1991. Differentiation of acid-pH dependent and non-dependent entry pathways for mouse hepatitis virus. Virology 180:108-119[Medline].
22.	Krzystyniak, K., and J. M. Dupuy. 1984. Entry of mouse hepatitis virus 3 into cells. J. Gen. Virol. 65:227-231[Abstract/Free Full Text].
23.	Kubo, H., Y. Yamada, and F. Taguchi. 1994. Localization of neutralizing epitopes and the receptor-binding site within the amino-terminal 330 amino acids of the murine coronavirus spike protein. J. Virol. 68:5403-5410[Abstract/Free Full Text].
23a.	Laude, H. Unpublished data.
24.	Laude, H., J. Gelfi, and J. M. Aynaud. 1981. In vitro properties of low- and high-passage strains of transmissible gastroenteritis coronavirus of swine. Am. J. Vet. Res. 42:447-449[Medline].
25.	Laude, H., J. M. Chapsal, J. Gelfi, S. Labiau, and J. Grosclaude. 1986. Antigenic structure of transmissible gastroenteritis virus. I. Properties of monoclonal antibodies directed against virion proteins. J. Gen. Virol. 67:119-130[Abstract/Free Full Text].
26.	Look, T., R. A. Ashmun, L. H. Shapiro, and S. C. Peiper. 1989. Human myeloid plasma membrane glycoprotein CD13 (gp150) is identical to aminopeptidase N. J. Clin. Invest. 83:1299-1307.
27.	Marsh, M., and A. Helenius. 1989. Virus entry into animal cells. Adv. Virus Res. 36:107-151[Medline].
28.	Marsh, M., and A. Pelchen-Matthews. 1994. The endocytic pathway and virus entry, p. 215-240. In E. Wimmer (ed.), Cellular receptors for animal viruses. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.
29.	Mizzen, L., A. Hilton, S. Cheley, and R. Anderson. 1985. Attenuation of murine coronavirus infection by ammonium chloride. Virology 142:378-388[Medline].
30.	Okhuma, S., and B. Poole. 1978. Fluorescence probe measurements of the intralysosomal pH in living cells and the perturbation of pH by various agents. Proc. Natl. Acad. Sci. USA 75:3327-3331[Abstract/Free Full Text].
31.	Olsen, J., G. M. Cowell, E. Kønigshøfer, E. M. Danielsen, J. Møller, L. Laustsen, O. Hansen, K. G. Welinder, J. Engberg, W. Hunziker, M. Spiess, H. Sjöström, and O. Norén. 1988. Complete amino acid sequence of human intestinal aminopeptidase N as deduced from cloned cDNA. FEBS Lett. 238:307-314[Medline].
32.	Pensaert, M., P. Callebaut, and E. Cox. 1993. Enteric coronaviruses of animals, p. 627-696. In A. Z. Kapikian (ed.), Viral infections of the gastrointestinal tract, 2nd ed. Marcel Dekker, New York, N.Y.
33.	Rasschaert, D., M. Duarte, and H. Laude. 1990. Porcine respiratory coronavirus differs from transmissible gastroenteritis virus by a few genomic deletions. J. Gen. Virol. 71:2599-2607[Abstract/Free Full Text].
34.	Rossen, J. W. A., C. P. J. Bekker, W. F. Voorhout, G. J. A. M. Strous, A. Van der Ende, and P. J. M. Rottier. 1994. Entry and release of transmissible gastroenteritis coronavirus are restricted to apical surfaces of polarized epithelial cells. J. Virol. 68:7966-7973[Abstract/Free Full Text].
35.	Sawicki, S. G., and D. Sawicki. 1986. Coronavirus minus strand RNA synthesis and effect of cycloheximide on coronavirus RNA synthesis. J. Virol. 57:328-334[Abstract/Free Full Text].
36.	Sjöström, H., and O. Norén. 1982. Changes of the quaternary structure of microvillus aminopeptidase in the membrane. Eur. J. Biochem. 122:245-250[Medline].
37.	Sturman, L. S., S. Richard, and K. V. Holmes. 1990. Conformational changes of the coronavirus peplomer glycoprotein at pH 8.0 and 37°C correlates with virus aggregation and virus-induced cell fusion. J. Virol. 64:3042-3050[Abstract/Free Full Text].
38.	Tresnan, D. B., R. Levis, and K. V. Holmes. 1996. Feline aminopeptidase N serves as a receptor for feline, canaine, porcine, and human coronaviruses in serogroup I. J. Virol. 70:8669-8674[Abstract].
39.	Vogel, L. K., M. Spiess, H. Sjöström, and O. Norén. 1992. Evidence for an apical sorting signal on the ectodomain of human aminopeptidase N. J. Biol. Chem. 267:2794-2797[Abstract/Free Full Text].
40.	Vogel, L. K., O. Norén, and H. Sjöström. 1995. Transcytosis of aminopeptidase N in Caco-2 cells is mediated by a non-cytoplasmic signal J. Biol. Chem. 270:22933-22938. [Abstract/Free Full Text]
41.	Wessels, H. P., G. H. Hansen, C. Fuhrer, A. T. Look, H. Sjöström, O. Norén, and M. Spiess. 1990. Aminopeptidase N is directly sorted to the apical domain in MDCK cells. J. Cell Biol. 111:2923-2930[Abstract/Free Full Text].
42.	Yeager, C. L., R. A. Ashmun, R. K. Williams, C. B. Cardellichio, L. H. Shapiro, A. T. Look, and K. V. Holmes. 1992. Human aminopeptidase N is a receptor for human coronavirus 229E. Nature 357:420-422[Medline].
43.	Yokomori, K. Y., and M. M. C. Lai. 1992. Mouse hepatitis virus utilizes two carcinoembryonic antigens as alternative receptors. J. Virol. 66:6194-6199[Abstract/Free Full Text].