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Infection and Immunity, February 1999, p. 946-953, Vol. 67, No. 2
Department of Pediatrics, Harvard Medical
School, and Department of Medicine and GI Cell Biology Research
Laboratory, Children's Hospital, Boston, Massachusetts 02115
Received 25 June 1998/Returned for modification 16 October
1998/Accepted 24 November 1998
The biochemical features that distinguish human M cells from other
intestinal epithelial cell types are important for understanding microbial pathogenesis and for targeting vaccines to the mucosal immune
system. We applied a large panel of carbohydrate-specific monoclonal
antibodies and lectins to Peyer's patch and cecum biopsy specimens
from three normal individuals and a patient with inflammatory bowel
disease. The results show that human M-cell glycosylation patterns are
distinct from those of other species examined and that human M cells
preferentially display the sialyl Lewis A antigen. This carbohydrate
epitope is also present in a small subpopulation of enterocytes in the
follicle-associated epithelium and in goblet cell mucins.
The mucosal surface of the
gastrointestinal tract is lined by a single layer of epithelial cells
that serves as a delicate barrier to foreign antigens and microbial
pathogens in the intestinal lumen. An important component in protection
of this vulnerable surface is the mucosal immune system, an assembly of
cells in the lamina propria which responds to luminal antigens by
producing secretory antibodies and other local immune effectors
(37). Sampling of luminal antigens occurs at specialized
local inductive sites, the organized mucosa-associated lymphoid
tissues, that appear as single or aggregated mucosal lymphoid follicles
in the small intestine, cecum, appendix, colon, and rectum. Transport of antigens and microorganisms across the epithelial barrier at these
sites is accomplished by a specialized follicle-associated epithelium
(FAE). The FAE contains M cells, a unique, relatively rare epithelial
cell type specialized for transepithelial transport of macromolecules,
particles, and microorganisms (43). Because of their
importance in microbial pathogenesis and their potential in targeting
of vaccines to the mucosal immune system, there is great current
interest in elucidating the functional and biochemical features that
distinguish M cells from other intestinal epithelial cell types.
M cells in many species, including humans (15, 23, 44, 48),
can be identified by morphological features such as their flattened
apical surfaces and intraepithelial pockets containing lymphoid cells.
Immunocytochemical studies of experimental animals have revealed other
distinguishing M-cell features, including reduced surface expression of
brush border hydrolases (47, 55); expression of the
intermediate filament proteins vimentin, cytokeratin 8, and cytokeratin
18 in rabbit, rat, and pig M cells, respectively (16, 18, 25,
51); diffuse cytoplasmic distribution of the actin-bundling
protein villin (30); and apical expression of Although M cells generally lack the uniform thick glycocalyx seen on
enterocytes, their apical membranes do display abundant glycoconjugates
(3, 14, 41) that may serve as binding sites for
microorganisms. Recent lectin-binding studies have established that M
cells in experimental animals have glycosylation patterns that differ
from those of their epithelial neighbors. For example, in Peyer's
patches of BALB/c mice, lectins that recognize a range of carbohydrate
structures containing Panels of lectins and monoclonal antibodies have been extensively used
to survey epithelial and mucin glycoconjugate expression patterns in
human biopsy specimens. Such studies have demonstrated clear
differences between glycoconjugates of humans and other species
(34, 38, 64), between normal and neoplastic human mucosae
(4, 35, 52), and between normal mucosa and mucosa affected
by inflammatory bowel disease (IBD) (24, 50, 53, 65). A few
studies have applied lectins to normal human mucosa containing
organized lymphoid tissues but have failed to identify a marker for
human M cells in Peyer's patches (27, 56) or appendix
(2). These studies were limited by the fact that many lectins are capable of recognizing multiple related carbohydrate structures. In the present study, we applied a panel of monoclonal antibodies specific for single carbohydrate epitopes, as well as a
large panel of lectins, to intestinal biopsy specimens from both normal
individuals and one patient with IBD. We report here that human M cells
can indeed display glycosylation patterns that distinguish them from
other intestinal epithelial cell types.
Histochemistry of human intestinal tissue.
Biopsy specimens
were obtained from the Endoscopy Suite at Children's Hospital, Boston,
Mass., as part of endoscopic examinations. Ileal, cecal, and rectal
biopsies were typically taken from each individual. Peyer's patch
samples from normal individuals of blood group type O (age of
individual, 16 years) and type A (age, 13 years) as well as an
individual diagnosed with ulcerative colitis (UC) of blood group O
(age, 10 years) were analyzed. Cecal tissue from a type O normal
individual (age, 6 years) was also examined. The research protocol was
followed with prior approval by the Children's Hospital Committee on
Clinical Investigation and informed consent from patient guardians.
Pinch biopsies were immediately placed in 3% paraformaldehyde-0.1%
glutaraldehyde in 0.1 M cacodylate (pH 7.2) and fixed for 3 h at
4°C. Samples were processed, embedded in Epon-Araldite, and sectioned
at a 0.5-µm thickness as described previously (19).
0019-9567/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Human Intestinal M Cells Display the Sialyl Lewis
A Antigen
ABSTRACT
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1 integrin,
a protein that is basolateral on other epithelial cells (9,
36). With the possible exception of 1 integrin, however, none
of these components can serve to explain the selective binding of
certain pathogens to M-cell surfaces or can be exploited to target
antigens to these cells.
(1-2)-fucose selectively stained M cells in
the FAE (6, 11, 19). We observed such lectin binding sites
not only on M-cell apical membranes but also on intracellular vesicles
and basolateral membranes, including the pocket domain (19).
These fucose-containing carbohydrate structures have not proven to be
universal M-cell markers, however. Glycoconjugates expressed on M cells
in other intestinal regions (cecum, colon, and rectum) of BALB/c mice
(7, 19) and in other species such as rabbit (17,
26) were found to differ from those in BALB/c mouse Peyer's
patches. Despite these species and regional differences, the animal
data suggest that M-cell-specific glycoconjugates might also exist in humans.
TABLE 1.
Partial listing of lectins and antibodies used in
this studya
TABLE 2.
Lectin and antibody binding patterns in human Peyer's
patch and cecum
Glycoconjugates on normal human Peyer's patch M cells. The binding and cellular localizations of 31 lectins and 10 anticarbohydrate monoclonal antibodies were analyzed. In Peyer's patches of the two normal and the UC individual, cells displaying the morphological features of M cells represented only a small percentage (<5%) of FAE cells, consistent with the frequency reported by others (10, 33). M-cell morphology in Peyer's patches varied depending on the position of the M cells in the dome epithelia. M cells emerging from crypts and on the lateral portion of a dome were intact and contained several leukocytes within small intraepithelial pockets. M cells positioned closer to the dome apexes contained larger pockets with many immune cells and often displayed ruptured apical membranes, with cells extruding into the lumens. We did not observe M cells at or near the apexes of the domes, confirming previous observations (10) and suggesting that M-cell exfoliation occurs prior to this point.
Lectin and antibody binding revealed a more limited range of carbohydrate epitopes on M cells than on enterocytes in the FAE or on villi (Table 2). Many of the probes bound to enterocyte membranes, and binding sites were abundant in the highly glycosylated apical brush borders as expected. By contrast, fewer probes labeled M cells. For example, UEA-I lectin recognizes several carbohydrate structures containing(1-2) fucose and is a marker for BALB/c mouse Peyer's
patch M cells (6, 19). This lectin did not bind to M cells
in our human specimens but strongly bound to all enterocytes (Fig.
1A and B). While many probes showed
similar reactivities with epithelial cells from the two normal
individuals of distinct blood groups (A versus O), others showed clear
differences. For example, enterocyte binding by RCA I (Ricinus
communis type I), GS I-B4, and other probes was
observed in the type A specimen but was absent in the type O specimen.
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GalNAc being part of the blood group A determinant. In this specimen, however, the same lectins
stained FAE enterocytes more weakly. Since
(1-3)-N-acetylgalactosyltransferase is required to
synthesize this determinant on epithelial cells, endothelial cells, and
erythrocytes (45), the expression of this enzyme is probably
lower in the FAE than in the villus epithelium.
Glycoconjugate expression by normal cecal M cells. It is known that intestinal epithelial glycosylation patterns are distinct in different regions of the digestive tracts of animal and humans. For example, the transition from the small to the large intestine is accompanied by substantial changes in the profiles and abundance of glycoconjugates (reviewed in reference 61). Similarly, M cells exhibit glycosylation patterns specific to the small or large intestine in mice (7, 19) and rabbits (17, 26). Thus, we examined the glycosylation profile of epithelial cells in a cecal biopsy containing mucosal lymphoid tissue from a type O normal individual. The abundance of M cells as determined morphologically was higher in cecum than in Peyer's patch; in some areas identifiable M cells represented >50% of FAE cells. Cecal M cells were largely intact, with large intraepithelial pockets containing multiple leukocytes (Fig. 3A). Lectin- and antibody-binding assays revealed that cecal M cells displayed more abundant glycoconjugates with greater epitope diversity than M cells in the normal Peyer's patch tissues examined (Table 2). Most probes bound to both M cells and enterocytes, consistent with results obtained with human appendix (2). The intensity of labeling was often more varied on M-cell apical membranes than on enterocytes, however, perhaps reflecting variations in the thickness of the M-cell glycocalyx. In the cecum, as in Peyer's patch, only the anti-sialyl Lewis A monoclonal antibody was selective for M cells (Fig. 3B and C); however, only ~5% of M cells were labeled and binding was restricted to apical membranes.
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Glycoconjugate expression by Peyer's patch M cells in an IBD patient. Others have reported changes in intestinal epithelial cell glycosylation in IBD specimens (2, 24, 50, 53, 65). We therefore surveyed lectin and antibody binding on tissue biopsies from a patient diagnosed with UC, analyzing in detail a Peyer's patch specimen from an area unaffected by the disease. The numbers of M cells in the FAE were comparable to those in normal tissue, unlike the findings for specimens from adults with spondylarthropathy reported previously (10). We observed that Peyer's patch M cells from this colitis patient displayed more diverse and abundant oligosaccharide epitopes than those from the two normal individuals tested, irrespective of blood group (Table 2). In particular, many lectin probes recognizing terminal fucose- or galactose-containing glycoconjugates showed binding to M cells in this specimen but not in the normal samples tested. Nevertheless, we again observed that expression of sialyl Lewis A antigen was largely restricted to M cells (Fig. 4). In summary, the sialyl Lewis A antigen is selectively expressed by M cells in both small and large intestines of normal individuals of distinct blood groups and in small intestine of a patient with IBD.
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M-cell glycosylation in microbial pathogenesis and mucosal immunity. The expression of distinct glycoconjugates by M cells in various tissues and species suggests an important role for carbohydrate epitopes in the function of this unique cell type. The structural modifications of the M-cell apical surface and the display of particular oligosaccharides together would allow M cells to present a conspicuously unique biochemical face to the lumen which might facilitate adherence, uptake, and immunological sampling of microorganisms. The transepithelial transport of microbes from the external environment as part of routine mucosal immune surveillance renders the host vulnerable to invasive pathogens, however, and the tropism that many pathogens demonstrate for M cells (42, 59) supports this concept.
Our results also raise the possibility that M cell-specific glycoconjugates can be exploited to enhance delivery of mucosal vaccines in humans. M-cell-specific glycoconjugates have been shown to be capable of mediating delivery to organized mucosal lymphoid tissues in mice and hamsters. Incubation of M-cell-selective lectins in mouse ligated intestinal loops containing Peyer's patches (8, 19) or feeding of lectin intragastically (unpublished results) resulted in M-cell adherence and transcytosis into Peyer's patch lymphoid follicles, and an M-cell-selective lectin given intranasally to hamsters targeted M cells overlying nasal lymphoid tissue (20). M-cell-selective lectins have also been used to target particles such as polymerized liposomes (5) and latex beads (13) to mouse small-intestinal M cells. The results from the two normal individuals studied here indicate that human Peyer's patch M cells display a more restricted array of carbohydrate epitopes than do enterocytes, suggesting that under normal conditions, expression of certain glycosyltransferases is reduced in M cells. In contrast, a previous lectin-binding survey of human Peyer's patch tissue (56) found that more lectins recognized M-cell glycoconjugates than did lectins in the present study. Whether this discrepancy reflects normal variation in the human population cannot be resolved with the limited specimens available to us. It should be noted that the specimens examined in the previous study were taken from colon carcinoma patients and that epithelial glycosylation patterns in the gut are known to be altered in colon cancer (4, 35, 52). Analysis of a larger number of normal tissue specimens will be required to define the diversity of glycoconjugate expression in human M cells. Consistent findings in this study were that the sialyl Lewis A antigen was largely restricted to M cells but that the Lewis A antigen was ubiquitous on epithelial cell surfaces. The monosialyl Lewis A antigen, defined as Neu5Ac(2-3)Gal(1-3)GlcNAc[Fuc(1-4)], differs from
the Lewis A antigen only by the presence of a single (2-3)-linked
sialic acid residue. The sialyl Lewis A antigen has been identified as
a ligand for selectins expressed by lymphocytes and endothelial cells
(reviewed in reference 63). Lymphocytes selectively
enter the M-cell intraepithelial pocket to interact closely with the
basolateral M-cell membrane, and we have observed that luminal
lymphocytes can interact with M-cell apical surfaces in experimental
animals (66). It is tempting to propose a role for sialyl
Lewis A in the observed interactions of lymphocytes with M cells.
Indeed, B and T lymphocytes within M-cell pockets were shown to express
L-selectin in human biopsies (12), supporting this
hypothesis. Further studies will be needed to comprehensively define
the oligosaccharide repertoire on human M cells and to elucidate their
role in the biology of this unique epithelial cell type.
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ACKNOWLEDGMENTS |
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This work was supported by NIH research grants HD17557 and AI34757 and NIH center grant DK-34854 to the Harvard Digestive Diseases Center.
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FOOTNOTES |
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* Corresponding author. Mailing address: GI Cell Biology, Enders 1220, Children's Hospital, 300 Longwood Ave., Boston, MA 02115. Phone: (617) 355-6229. Fax: (617) 730-0404. E-mail: neutra_m{at}a1.tch.harvard.edu.
Present address: OraVax Inc., Cambridge, MA 02139.
Editor: P. J. Sansonetti
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