key: cord-0000554-fvfl0bn1
authors: Shen, Ching-I; Wang, Ching-Ho; Shen, Shih-Cheng; Lee, Hsiu-Chin; Liao, Jiunn-Wang; Su, Hong-Lin
title: The Infection of Chicken Tracheal Epithelial Cells with a H6N1 Avian Influenza Virus
date: 2011-05-06
journal: PLoS One
DOI: 10.1371/journal.pone.0018894
sha: aae339db3ebacca2632136e51dac48f209a952f6
doc_id: 554
cord_uid: fvfl0bn1

Sialic acids (SAs) linked to galactose (Gal) in α2,3- and α2,6-configurations are the receptors for avian and human influenza viruses, respectively. We demonstrate that chicken tracheal ciliated cells express α2,3-linked SA, while goblet cells mainly express α2,6-linked SA. In addition, the plant lectin MAL-II, but not MAA/MAL-I, is bound to the surface of goblet cells, suggesting that SA2,3-linked oligosaccharides with Galβ1–3GalNAc subterminal residues are specifically present on the goblet cells. Moreover, both α2,3- and α2,6-linked SAs are detected on single tracheal basal cells. At a low multiplicity of infection (MOI) avian influenza virus H6N1 is exclusively detected in the ciliated cells, suggesting that the ciliated cell is the major target cell of the H6N1 virus. At a MOI of 1, ciliated, goblet and basal cells are all permissive to the AIV infection. This result clearly elucidates the receptor distribution for the avian influenza virus among chicken tracheal epithelial cells and illustrates a primary cell model for evaluating the cell tropisms of respiratory viruses in poultry.

Sialic acids (SAs), consisting of a core of nine-carbon monosaccharide, are usually linked to the outermost capping position of glycans that are conjugated to cell-surface glycoproteins or glycolipids [1] . Sialyltransferase adds SA to the terminal sugar residues, such as galactose (Gal), N-acetylglucosamine (GlcNAc) or N-acetylgalactosamine (GalNAc) [1] . The conjugation between Gal and SA can be either in the form of an a2,3 or an a2,6 glycosidic linkage. In mammals, N-acetylneuraminic acid (Neu5Ac) and Nglycolylneuraminic acid (Neu5Gc) are the two most common types of SA, but Neu5Ac is the major type of SA in birds [2] .

Plant lectins extracted from Maackia amurensis (M. amurensis leukoagglutinin, MAL) and Sambucus nigra (S. nigra agglutinin, SNA) are usually applied for the detection of Neu5Aca2-3Gal (SAa2-3Gal) and SAa2-6Gal glycans in tissues, respectively [3] . Two types of M. amurensis lectins were discovered: one that can agglutinate erythrocytes (hemagglutinin) (MAH, also known as MAL-II) and one that can agglutinate leukocytes (MAL, also known as MAM, MAA, MAL-I). Although both MAL-I and MAL-II recognize the SAa2-3Gal glycan, previous studies [4] and recent glycan microarray data [5] demonstrated that subterminal sugars affect their binding affinity to these two lectins. For example, MAL-I, rather than MAL-II, showed the highest affinity to the SAa2-3Galb1-4GalNAc and did not bind to this oligosaccharide when the subterminal b1,4-linkage was replaced by a b1,3-linkage [6] .

Cell entry by influenza virus depends on the recognition of a terminal SA-capped glycosylated molecules by the viral hemag-glutinin (HA) protein [3] . Generally, human influenza viruses preferentially bind to cell surface oligosaccharides that have the SAa2-6Gal linkage, while avian influenza viruses (AIVs) prefer SAa2-3Gal [3] . Especially, the glycans containing the SAa2-3Galb1-4GalNAc or SAa2-3Galb1-4(6OSO3)GalNAc, show a high affinity to MAA/MAL-I [4] and AIVs [7, 8] . Tracheal/ bronchial epithelium, mainly consisting of ciliated cells, goblet cells and basal cells, is the initially attacked tissue by the invading influenza viruses. The infected chicken trachea shows necrosis and detachment of ciliated cells, suggesting that ciliated cell is one of the cells targeted by AIV [9] . Previous analyses of the expression of SAs in chicken have revealed that a2,3-linked SA was localized on tracheal ciliated cells and a2,6-linked SAs was also present in the tracheal tissues [10, 11, 12] . However, the detailed distribution of SAs among chicken tracheal epithelial (CTE) cells remains unclear. Clarification of the distribution and the expression intensity of influenza receptor on CTE cells will help us to understand the viral tropism, viral spreading and the pathogenesis of avian influenza viruses. Here, the SA distribution on CTE cells were identified by the staining of biotin-labeled plant lectins. A Taiwan-isolated AIV H6N1 was applied to characterize the cell tropism of AIV and the correlation of the cell tropism of AIV to the SA distribution on CTE cells was also explored.

The SAa2-3Gal expression of primary CTE cells

The distribution of SAa2-3Gal expression on the primary CTE cells was determined by the staining with a plant lectin, MAA (EY Laboratories). The ciliated cells were revealed by the intense fluorescent microvilli, labeled by the b-tubulin specific antibody [13] . Mucin 5AC glycoprotein and cytokeratin-14 (K14) were the specific markers for the goblet and basal cells, respectively [14, 15] . Immunocytochemistry (ICC) staining illustrated that most btubulin + cells expressed SAa2-3Gal terminal glycan (ratio of MAA + /b-tubulin + cells, 0.8760.06, n = 317) (Fig. 1A) . In a high magnification field, the intense spots of MAA signal were surrounded by cilia bundles on the ciliated cells (Fig. 1B) . In addition, MAA lectin could also be detected on the primary K14 + basal cells (ratio of MAA + /K14 + cells, 0.4660.12, n = 267) (Fig. 1G) .

Interestingly, the MAA signals did not colocalized with the mucin-expressing cells (ratio of MAA + /mucin + cells, 0.00760.01, n = 223) (Fig. 1D) , indicating that goblet cells may not express the SAa2-3Gal glycans which show high affinity to the MAA lectin. However, for the immunohistochemistry in tissue sections, the distribution of SAa2-3Gal expression may show inconsistent distribution when different MAA/MALs were applied or the same lectins were from different providers [16, 17] . To further address the SA expression on goblet cells, MAL-I, same as MAA, was given by Vector Laboratories and applied to stain the CTE cells. We found that abundant MAL-I was detected on the b-tubulin + cells (ratio of MAL-1 + /b-tubulin + cells, 0.8260.10, n = 301) (Fig. S1), rather than the mucin + cells (ratio of MAL-1 + /mucin + cells, 0.0260.02, n = 201) (Fig. 1E ), similar to the result for MAA.

Subtypes of SAa2-3Gal glycans with different subterminal sugars present varied affinity to MAA/MAL-I and MAL-II. Whether the SAa2-3Gal glycan is not expressed on goblet cells was further evaluated by MAL-II (Vector Laboratories). Surprisingly, 0.3760.12 mucin + cells (n = 594) were double-stained with MAL-II (Fig. 1F ), indicating that a glycan subtype that shows a high affinity for MAL-II only, was expressed on the goblet cells. We also found that only 0.3360.09 b-tubulin + cells (n = 230) can be labeled with MAL-II (Fig. 1C ). In addition, about half basal cells were MAL-II positive (0.5360.12, n = 265) (Fig. 1H ).

The SAa2-6Gal expression of primary CTE cells

The distribution of SAa2-6Gal on the CTE cells was determined by staining with SNA (Vector Laboratories). In contrast to the finding for MAA/MAL-I, abundant SNA signals were mainly restricted to the mucin + cells (ratio of SNA + /mucin + cells, 0.8560.09, n = 368) ( Fig. 2A) , indicating that the goblet cells expressed SAa2-6Gal terminal glycan. In addition, SNA lectin can also be detected in a one-third proportion of K14 + cells (ratio of SNA + /K14 + cells, 0.3660.09, n = 284) (Fig. 2B) .

Especially, the SNA signal did not localize on the b-tubulin + cells (ratio of MAA + /b-tubulin + cells, 0.0160.01, n = 237) (Fig. 2C ). Testing the SNA-I, which was provided by EY Laboratories, showed no difference to the result of SNA, evidenced by the undetectable binding by SNA-I on the ciliated cells (Fig. 2D ).

The SAa2-3Gal and SAa2-6Gal expression on basal cells

Although both MAA and SNA bound to the surfaces of a subpopulation of the K14 + cells ( Fig. 1G and Fig. 2B ), their detected signals were relatively weak (Figs. S2A and S2B). To determine whether a single basal cells can express both SAa2-3Gal and SAa2-6Gal, CTE cells were triple-stained with K14 primary antibody (Cy5-2u Ab, purple), FITC-conjugated MAA (green) and biotin-labeled SNA (detected by Cy3-Streptovidin, red) (Figs. 3A, 3B and 3C). Their cell nuclei were revealed by DAPI staining (blue). When viewed in the same field under a confocal microscope, the ICC result indicated that MAA and SNA can be co-expressed on single K14 + cells (indicated by the arrows).

The distribution and relative expression levels of SAa2-3Gal and SAa2-6Gal are summarized in Table 1 . It should be noted that because the relative affinities of the lectins to their targeted glycans may differ, comparing the intensity of staining between the MAA and SNA cannot be used as a quantitative comparison of the relative SAa2-3Gal and SAa2-6Gal expressions. In addition, the H6N1 viral antigens detected in the infected cells at a MOI of 0.1 were mostly restricted to the b-tubulin + cells at 6 h.p.i. (Fig. 5A ). Few H6N1 antigens were detected in the goblet cells or basal cells, possibly due to the low expression of AIV receptors (Figs. 5B and 5C). These results indicate that the ciliated cell, rather than the goblet or the basal cells, is the primary target cell for the AIV. In addition, these data also illustrate that the distribution of SAa2-3Gal expression among cells determines the cell tropism of the AIV H6N1 virus (as summarized in Fig. 6 and Table 1 ).

The infectivity of H6N1 in CTE cells was further characterized at a MOI of 1. ICC results showed that the ciliated cells (Fig. 5D ), goblet and basal cells were all susceptible to infection by H6N1 as measured at 6 h.p.i. (Figs. 5E and 5F ). Although SAa2-3Gal expression was relatively low in goblet and basal cells, still 21.360.05% of goblet cells and 51.1610.9% of basal cells were infected. We speculated that the low infection of goblet cells by influenza virus at a high MOI might mediate through the binding to MAL-II specific SA or through a SA-independent pathway [18] . However, this hypothesis still requires the support from further experiments.

In the human tracheal/bronchial epithelium, ciliated cells display mainly a2,3linked SAs and goblet cells express a2,6linked SAs [19] . About one third of ciliated cells also display the a2,6-linked SAs and goblet cells also express the a2,3-linked SAs at a low degree [19, 20] . The distribution of the a2,3and a2,6-linked glycans was primarily on the apical surface of both ciliated and goblet cells, respectively [19, 20] . As revealed by specific lectins and ICC staining in the primary CTE cells, our results clearly illustrate that all three types of CTE cells express SAa2-3Gal in a varied degree. SAa2-3Gal showed abundant expression on chicken ciliated cells but only a detectable level on basal cells ( Fig. 6 and Table 1 ).

Revealing the distribution and the expression intensity of influenza virus receptor on the tracheal basal cells will help us to understand the cell tropism of influenza virus and the pathogenesis of AIV infected tissues. Our previous study indicated that the replication of infectious bronchitis virus (IBV) is restricted to ciliated cells and goblet cells, but not basal cells [21] . The tracheal/bronchial basal cells, assumed as multipotent stem cells, are responsible for epithelial recovery and reestablish normal respiratory function after desquamation of the ciliated and goblet cells [14, 15] . In an uncomplicated IBV-infected chick, clinical signs persist for only 1 week and the unaffected basal cells may be responsible for epithelial reconstruction of the injured respiratory tract [22] . In contrast, basal cells are susceptible to the infection of avian influenza virus at a MOI of 1. The susceptibility of basal cells to AIV infection suggests that infection with AIV alone may cause the cell death of basal cells, and consequently affect basal membrane integrity and severe inflammation in the AIV infected trachea.

Interestingly, MAA/MAL-1 did not bind to the surface of goblet cells, suggesting that certain SAa2-3Gal glycans that show high affinity for MAA/MAL-I lectins, such as SAa2-3Galb1-4GlcNAcb and SAa2-3Galb1-4(6OSO3)GlcNAcb [4, 5] , are not present to a significant extent on the cell membranes of goblet cells. However, one-third of the goblet cells showed strong MAL-II staining, suggesting that the MAL-II specific glycans, such as SAa2-3Galb1-3(SAa2-6)GalNAca and SAa2-3Galb1-3(6OSO3)-GalNAca are highly expressed on goblet cells [4, 5, 6, 23] .

The expression profiles of SAs on CTE cells exhibits distributions that are distinct from those of human. In chickens, MAL-I bind to the surface of ciliated cells and basal cells, but not goblet cells. The goblet cells express a MAL-II specific SAa2-3Gal glycan. In addition, both SNA and SNA-I failed to label the btubulin + cells, indicating that SAa2-6Gal is exclusively expressed on non-ciliated cells. In humans, by contrast, both ciliated and goblet cells can be labeled with MAA/MAL-I and SNA [19, 20] , indicating that these two epithelial cells have both types of influenza viral receptors. Moreover, both ciliated and goblet cells cells are permissive to infection by human influenza viruses [19, 20] . Interestingly, using duck influenza A viruses to infect human airway epithelial cells, the viral antigen could only be detected in the ciliated cells, but not in the goblet cells, possibly due to the low SAa2-3Gal expression on the surface of goblet cells and a low MOI infection [19, 20] .

Although the SAa2-6Gal glycans was detected in human tracheal/bronchial goblet cells [19, 20] and was capped on mucin protein [24] , it was also proposed that tracheal mucin in the airway contains SAa2-3Gal [25] (Fig. 6A) . Especially, this secreted mucin was shown to prevent infection by influenza viruses with a SAa2-3Gal preference in the airway [26] . This false-receptor effect may mask the HA of the AIV, disable the viral access to the goblet cells and also account, at least in part, for the hindrance of AIV infection to human goblet cell [26] . In chicken trachea, goblet cells exhibit high affinity for SNA, suggesting that the mucin may contain SAa2-6Gal glycans. The viral neutralization effect of mucin in humans may be recapitulated in chickens to aid the clearance of the invading influenza viruses with a SAa2-6Gal preference.

In addition to the SA2,6-linkage glycan, SA2,3-linked oligosaccharides with Galb1-3GalNAc subterminal residues, which show a MAL-II preference, may be present in the goblet cells (Table 1) [4, 5, 6, 23] . Notably, although AIVs can bind to the terminal SAa2-3Gal, duck and chicken influenza viruses exhibit different affinities for glycans with different subterminal residues [7, 8] . For example, duck influenza viruses prefer Galb1-3GlcNAc or Galb1-3GalNAc, but chicken influenza viruses prefer Galb1-4GlcNAc or Galb1-4(6OSO3)GlcNAc [7, 8] . Our study suggests that SAa2,3-capped oligosaccharides following a Galb1,3-linkage [6] are candidate sugars conjugated to the chicken tracheal mucin protein. Determining the SA composites of chicken mucin protein and the neutralizing effect of chicken mucin on duck influenza viruses will be an interesting task that will provide important information about the innate defense mechanisms in the chicken trachea and about the interspecies transmission of influenza viruses between ducks and chickens.

Both the hindrance of the mucin barrier and the limited number of proper receptors on the epithelial cells of the host restrict cross-species infection by influenza viruses [6, 20] . Nevertheless, genetic mutations or recombinations in the HA of an influenza virus can render interspecies transmission by altering the receptor tropism [27, 28, 29] . The 226 and 228 residues in the HA of the influenza H3 and H2 viruses are particular important for determining the receptor specificity and host range restrictions [30, 31] . The Ser-to-Gly mutation at HA position 228 and the Leuto-Gln mutation at HA position 226 shift the receptor preference from SAa2-6Gal to SAa2-3Gal and enhance the infectivity of human influenza virus in duck intestinal cells [31] .

The HA of the chicken H6N1 virus we applied possesses the GQRSRI sequence, which corresponds to the 225 to 230 positions in H3 HA [32] . We showed that most MAA + cells, but few SNA + cells, were permissive to infection by the H6N1 virus. In addition, at a low MOI, most H6N1 proteins were detected in the SAa2-3Gal-rich ciliated cells, and few in the goblet and basal cells. These results indicate that the chicken H6N1 virus, even with a Ser228 (using H3 HA numbering) in its HA, still possesses a SAa2-3Gal preference. Similarly, the HA 226 residue, critical to cell tropism in human H3 and H9N2, has been shown to be an insufficient binding site for determining the receptor tropism of the human H1, H2, H5 and the avian H6, H9 and H5N1 viruses [4, 33, 34, 35] . These results emphasize that receptor tropism is determined by several critical residues in the HA proteins, but these sites in HA are not highly conserved among different influenza viruses.

A Taiwan AIV H 6 N 1 strain, 2838V (virulent), was obtained by serial inoculation of an original field isolate, H 6 N 1 2838, into specific pathogen free (SPF) chickens [36] . The virus was further amplified by passage into the amnion of SPF eggs. Cell debris in the collected fluid was clarified by centrifuging at 1000 rpm for 10 min and passing through a 0.45 mm filter. The viral titer (50% of the egg infectious dose, EID 50 ) of 2838V was 1610 8 /ml.

Tracheas were obtained from one-day-old SPF chicks (Animal Health Research Institute, Tansui, Taipei, Taiwan) and rinsed in a DMEM medium (Invitrogen, Carlsbad, CA, USA) under a sterile condition. The procedure for removing epithelial sheets from the tracheas and the detailed culture conditions for the CTE cells have been described previously [21] . Briefly, tracheas were digested with dispase I solution (2.5 U/ml dispase I, Roche) for 2 h at 37uC. The detached cell sheets of tracheal epithelium from the tracheal lumen were harvested and further digested with collagenase I (1 mg/ml, Roche) for 5 min at 37uC. The disrupted tracheal epithelial sheets were gently pippeted and homogenized into small cell clumps. The cell pellets were resuspended in a CTE medium [21] and were seeded on 2% matrigel-coated 24-well plates (Corning). The cells were cultured at 37uC with 5% CO 2 for 3 days. The animal use protocol in this study had been reviewed and approved by Institutional Animal Care and Use Committee in National Chung Hsing University. The approval number is 99-09.

The tested lectins for the SAa2-3Gal capped glycan were MAA (EY Laboratories, San Mateo, CA, USA), MAL-I (Vector Laboratories, Burlingame, CA, USA) and MAL-II (Vector Laboratories). The lectins for the SAa2-6Gal were SNA (Vector Laboratories) and SNA-I (EY Laboratories). The MAA lectins were conjugated with biotin or a green fluorescent dye, fluorescein isothiocyanate (FITC). The signal of the biotin-labeled lectins was enhanced and visualized by staining with a red-fluorescent Cy3conjugated streptavidin (Rockland, Gilbertsville, PA, USA).

The CTE cells were fixed in 4% cold paraformaldehyde and blocked using the Carbo-free TM blocking solution (Vector Laboratories). Immunocytochemistry (ICC) was performed using the biotin-labeled lectins (MAA, MAL I, MAL II, SNA and SNA I, 1:500) or the FITC-conjugated MAA (1:50, EY Laboratories). The used primary antibodies were b-tubulin (1:500, Sigma-Aldrich, St. Louis, MO, USA), mucin 5AC (1:100, Sigma-Aldrich) and cytokeratin 14 (K14, 1:100, Convance, Princeton, NJ, USA). The specificity of the anti-AIV 2838 polyclonal antibodies (1:500, from infected chickens) has been evaluated in our previous report [37] . Appropriate fluorescence-tagged secondary antibodies (2u Ab, Jackson ImmunoResearch, West Grove, PA, USA) and Cy3conjugated streptavidin (Rockland) were used for visualization.

Blue 49,6-Diamidino-2-phenylindole (DAPI) was used for nuclear staining. The number of ICC-staining positive cells in a 24-well plate was manually counted from five individual fields. Images of the immunostaining were captured using a confocal microscope (LSM510 Meta, Zeiss). For comparing the expression intensity of SA among CTE cells, the images were collected with the same setting and same objective (406) under the confocal microscope. Figure S1 The SAa2-3Gal expression of ciliated cells (btubulin + ) was characterized by the double-staining of biotin-labeled MAL-1 (Vector laboratories, 1:500). Scale bar, 50 mm. (EPS) Figure S2 Expression levels of SAa2-3Gal (labeled by MAA)(A) and SAa2-6Gal (labeled by SNA)(B) in tracheal basal cell (K14 + ) were shown by immunocytostaining. The arrows in A and B indicate cells with high-intensity MAA and SNA staining, respectively. The cell nuclei were stained with DAPI (blue). Scale bar, 50 mm. (EPS)

Structural insights into sialic acid enzymology

Low incidence of N-glycolylneuraminic acid in birds and reptiles and its absence in the platypus

Glycans as receptors for influenza pathogenesis

Evolving complexities of influenza virus and its receptors

Functional glycomics research website

Characterization of the carbohydrate binding specificity of the leukoagglutinating lectin from Maackia amurensis. Comparison with other sialic acid-specific lectins

Differences between influenza virus receptors on target cells of duck and chicken and receptor specificity of the 1997 H5N1 chicken and human influenza viruses from Hong Kong

H5N1 chicken influenza viruses display a high binding affinity for Neu5Acalpha2-3Galbeta1-4(6-HSO3)GlcNAc-containing receptors

Comparative pathology of chickens experimentally inoculated with avian influenza viruses of low and high pathogenicity

Differences between influenza virus receptors on target cells of duck and chicken

Species and age related differences in the type and distribution of influenza virus receptors in different tissues of chickens, ducks and turkeys

Quail carry sialic acid receptors compatible with binding of avian and human influenza viruses

Differentiated cultures of primary hamster tracheal airway epithelial cells

Basal cells are a multipotent progenitor capable of renewing the bronchial epithelium

In vivo differentiation potential of tracheal basal cells: evidence for multipotent and unipotent subpopulations

Effects of sialic acid substitutions on recognition by Sambucus nigra agglutinin and Maackia amurensis hemagglutinin

Sialic acid receptor detection in the human respiratory tract: evidence for widespread distribution of potential binding sites for human and avian influenza viruses

Effective replication of human influenza viruses in mice lacking a major alpha2,6 sialyltransferase

Human and avian influenza viruses target different cell types in cultures of human airway epithelium

Infection of human airway epithelium by human and avian strains of influenza a virus

The infection of primary avian tracheal epithelial cells with infectious bronchitis virus

Coronavirus avian infectious bronchitis virus

Strong affinity of Maackia amurensis hemagglutinin (MAH) for sialic acid-containing Ser/Thrlinked carbohydrate chains of N-terminal octapeptides from human glycophorin A

Characterization of exosome-like vesicles released from human tracheobronchial ciliated epithelium: a possible role in innate defense

Primary structure determination of five sialylated oligosaccharides derived from bronchial mucus glycoproteins of patients suffering from cystic fibrosis. The occurrence of the NeuAc alpha(2-3)Gal beta(1-4)

Influenza virus strains selectively recognize sialyloligosaccharides on human respiratory epithelium; the role of the host cell in selection of hemagglutinin receptor specificity

Single amino acid substitutions in influenza haemagglutinin change receptor binding specificity

Mutations in the hemagglutinin receptor-binding site can change the biological properties of an influenza virus

Single-amino-acid substitution in an antigenic site of influenza virus hemagglutinin can alter the specificity of binding to cell membrane-associated gangliosides

Receptor specificity in human, avian, and equine H2 and H3 influenza virus isolates

The role of influenza A virus hemagglutinin residues 226 and 228 in receptor specificity and host range restriction

Sequence comparison between two quasi strains of H6N1 with different pathogenicity from a single parental isolate

Human influenza A H5N1 virus related to a highly pathogenic avian influenza virus

The surface glycoproteins of H5 influenza viruses isolated from humans, chickens, and wild aquatic birds have distinguishable properties

Comparison of complete amino acid sequences and receptor-binding properties among 13 serotypes of hemagglutinins of influenza A viruses

Experimental selection of virus derivatives with variations in virulence from a single low-pathogenicity H6N1 avian influenza virus field isolate

Detection of H6 influenza antibody by blocking enzyme-linked immunosorbent assay

We thank Dr. Yi-Ling Lin at the Institute of Biomedical Sciences in Academia Sinica for critical reading of this manuscript and valuable comments.