Differential expression of the HECA-452 antigen (cutaneous lymphocyte associated antigen, CLA) in cutaneous and non-cutaneous T-cell lymphomas

The monoclonal antibody HECA-452 identifies an antigen that is primarily expressed on high endothelial venules, the preferred site of lymphocyte extravasation in lymphoid tissues, and also on a subpopulation of myelomonocytic cells and some T-cells. We investigated the expression of the HECA-452 antigen, also called the cutaneous lymphocyte associated antigen, in primary cutaneous and primary non-cutaneous T-cell non-Hodgkin's lymphomas. The tumour cells of cutaneous T-cell non-Hodgkin's lymphomas were positive in 53% of cases, while only 5% of the non-cutaneous lymphomas were positive. These differences were also present in morphologically identical tumours. Thus, the tumour cells in six out of 10 primary cutaneous anaplastic large cell T-cell lymphomas were positive, while they were positive in none of 24 primary non-cutaneous anaplastic large cell T-cell lymphomas. In general, primary cutaneous and primary nasal T-cell non-Hodgkin's lymphomas were devoid of HECA-452 positive high endothelial venules, whereas most nodal T-cell non-Hodgkin's lymphomas contained HECA-452 positive high endothelial venules. These observations suggest that the HECA-452 antigen might be related to a skin-associated type of lymphoid tissue and to lymphomas originating in the skin. However, the results of HECA-452 expression in secondary sites, and the clinical data of the primary cutaneous large cell lymphomas did not support the concept that HECA-452 is functionally involved in homing to the skin, or that loss of the HECA-452 antigen is related to tumour progression of primary cutaneous T-cell lymphomas.(ABSTRACT TRUNCATED AT 250 WORDS)     

The ontogeny of human lymphocyte recirculation: high endothelial cell antigen (HECA-452) and CD44 homing receptor expression in the development of the immune system

In the present report we have studied the expression of a lymphocyte homing receptor, the CD44 antigen, and of HECA-452, a high endothelial-specific antigen, during the development of the human immune system. We found that prothymocyte immigrants of the thymus already expressed the CD44 antigen. Similarly, the first peripheral T lymphocytes in fetal lymph nodes, tonsils and gut-associated lymphoid tissue were also CD44+. Cortical thymocytes and germinal center cells were CD44-. CD44 antigen expression was, thus, not limited to mature recirculating lymphocytes. This suggests that CD44 may not only be involved in recirculation of mature lymphocytes but also in the migration of prothymocytes to their site of maturation, i.e. the thymus. High endothelial venules (HEV) were not demonstrable at the early onset of lymphocyte immigration into the developing lymphoid organs. However, when large-scale influx of lymphocytes occurred, it paralleled HEV development. HECA-452 antigen expression preceded the morphological transformation of endothelium into a HEV phenotype. Expression of this antigen therefore, independently reflected the specialized nature of high endothelium. In a patient with complete DiGeorge's syndrome normal HEV developed, indicating that the presence of T lymphocytes is not a requirement for HEV development. Interestingly, a subpopulation of venules located in the thymic medulla near the cortico-medullary junction expressed the HECA-452 antigen. These vessels, which had flat or intermediately high endothelium, are probably involved in lymphocyte migration to the thymus.     

High endothelial venules (HEVs): specialized endothelium for lymphocyte migration

High endothelial venules (HEVs) are specialized postcapillary venules found in lymphoid tissues that support high levels of lymphocyte extravasation from the blood. Here, Jean-Philippe Girard and Timothy Springer highlight the unique properties of HEV endothelium, discuss the molecular mechanisms controlling HEV specialization and review evidence suggesting that HEVs could play an important role in the pathogenesis of chronic inflammatory diseases.     

Anti-high endothelial venule monoclonal antibody HECA-452 recognizes plasmacytoid T cells and delineates an ”extranodular“ compartment in the reactive lymph node

So-called plasmacytoid T cells represent a subset of monocyte related cells, which share with endothelium the CD36⁺CD11b⁻ (OKM5⁺OKM1⁻) phenotype. The reactivity of plasmacytoid T cells with rat monoclonal antibody HECA-452, highly specific for high endothelial venules, was analyzed in reactive lymph nodes. In all cases, HECA-452 not only labelled the endothelium of high endothelial venules, but also strongly reacted with singular and clustered plasmacytoid T cells. The HECA-452 positivity for high endothelial venules and plasmacytoid T cells visualized a lymph node compartment extending from the subcapsular sinus to the corticomedullary junction. This compartment surrounded the composite nodule and was designated the ”extranodular“ compartment. The cooccurrence of plasmacytoid T cells and high endothelial venules in this extranodular compartment, together with their immunophenotypical similarities, may be indicative of functional co-operations.     

Functional evidence that the HECA-452 antigen is involved in the adhesion of human neutrophils and lymphocytes to tumour necrosis factor-alpha-stimulated endothelial cells.

The migration of leucocytes into tissues is a process mediated by leucocyte endothelial interactions, in which adhesion receptors play a crucial role. Recently, it was found that 80-90% of T cells in inflammatory skin diseases were reactive to the monoclonal antibody (mAb) HECA-452+ in contrast to inflamed non-cutaneous tissues. It was suggested that the HECA-452 antigen is a homing receptor for lymphocyte migration into skin. This receptor was designated cutaneous lymphocyte-associated antigen or CLA and subsequently identified as a group of related sugar moieties. E-selectin, formerly known as ELAM-1 expressed by the endothelium has been implicated to be a counter-receptor for CLA. In this study, we investigated the adhesion of HECA-452+ leucocytes, i.e. freshly isolated neutrophils and B-cell line BV173 to tumour necrosis factor-alpha (TNF-alpha)-stimulated (E-selectin+) endothelial cells. We found that the adhesion of these cells could be inhibited significantly by mAb HECA-452, in a similar fashion to CSLEX1, a mAb specific for E-selectin ligand sialyl Lewisx. This inhibiting effect of both mAb on the adhesion of polymorphonuclear leucocytes (PMN) and BV173 could only be demonstrated when the assay was performed at 4 degrees, but not at 37 degrees. Furthermore, using immunohistochemical analysis we found that the mAb HECA-452-reactive epitope is different from that recognized by CSLEX1. The present results give direct evidence that the antigen recognized by HECA-452 is involved in the adhesion of leucocytes to endothelial cells, although this antigenic epitope is different from that reactive to CSLEX1.     

Identical expression of ELAM-1, VCAM-1, and ICAM-1 in sarcoidosis and usual interstitial pneumonitis

Extravasation of leucocytes in tissues is mediated by leucocyte—endothelial cell interactions in which adhesion molecules play an important role. Until now, two pathways have been unravelled, i.e., the LFA-1/ICAM-1 and the VLA-4/VCAM-1 pathways. ELAM-1 has been shown to be involved in granulocyte accumulation and recently also in lymphocyte migration. The role of HECA-452 is under investigation. In this study we have investigated the expression of the above-mentioned adhesion molecules in lung tissue of patients with pulmonary sarcoidosis and usual interstitial pneumonitis (UIP), and in mediastinal lymph nodes of patients with sarcoidosis. ICAM-1 (CD54) was broadly distributed on the endothelium of all the vessels found in sarcoidosis and UIP. VCAM-1 was present on the endothelium of the venules, capillaries, and arterioles in both sarcoidosis and UIP. ELAM-1 reacted with endothelial cells lining venules and capillaries in chronic progressive sarcoidosis and in the active phase of UIP but not in the stationary phases of both diseases. HECA-452 activity could be detected only on high endothelial venules within sarcoid lymph nodes. In lung tissues, macrophages bearing the ICAM-1 antigen were present in sarcoid tissue but not in the interstitium and alveolar space of UIP. LFA-1 (CD11a/CD18) and VLA-4 (CD49d/CD29) were present on all leucocytes found but seemed to be more highly expressed on lymphocytes in sarcoidosis. These findings suggest that the LFA-1/ICAM-1 and VLA-4/VCAM-1 pathways are involved in leucocyte migration in both types of lung disease, while in the active phases of sarcoidosis and UIP, ELAM-1 is also involved.     

High endothelial-like venules in chronically inflamed periodontal tissues exchange polymorphs

A survey of 58 gingival biopsies revealed the presence of periodontal high endothelial-like venules (PHELVs) in chronically inflamed gingival tissues. PHELVs were found to exchange polymorphonuclear cells (PMNs) almost exclusively in advanced periodontitis, with PMNs greatly exceeding the number of mononuclear cells found in PHELVs (P less than 0.001). Electron microscopy confirmed the emigration of PMNs from these vessels. The enzyme histochemical and ultrastructural features as well as the 35SO4 uptake properties of PHELVs were similar to those of the well-characterized high endothelial venules (HEVs) of rat lymph nodes. It is generally accepted that HEVs in lymphoid tissues and inflammatory sites are specially adapted to assist in the emigration of lymphocytes. However, the observation of preferential PMN emigration in the apparent absence of lymphocyte exchange from PHELVs compels further investigation of other possible functions for HEVs. In relation to this, endothelial cells are capable of producing potent cytokines and inflammatory mediators which may contribute to the development of lesions, and the possibility is discussed that high endothelial cells are functionally adapted to enhance the production of such factors.     

Endothelial cell phenotypic diversity. In situ demonstration of immunologic and enzymatic heterogeneity that correlates with specific morphologic subtypes

Some endothelial cells share functional and phenotypic properties with cells of monocyte/macrophage lineage. The authors have performed frozen-section immunologic stains and plastic section enzyme histochemical stains on various human tissues to examine endothelial cell phenotypic properties in situ. They found that endothelial cells express heterogeneous phenotypes that correlate with vessel type. Several endothelial cell subsets were identified. These included arterioles, capillaries, and venules (HLA-ABC+, HLA-DR+, Factor VIII RA+, monocyte-, alkaline phosphatase+, ATPase+); high endothelial venules of lymphoid tissues and hepatic sinusoidal lining cells (HLA-ABC+, HLA-DR+, Factor VIII RA+, monocyte+); lymphatics and glomerular capillaries (HLA-ABC+, HLA-DR+/-, Factor VIII RA-, monocyte-, 5'nucleotidase+); splenic sinusoidal lining cells (HLA-ABC+, Leu-2+, HLA-DR+, Factor VIII RAweak+, monocyte-, alpha naphthyl acetate esterase+); umbilical cord vessels (Factor VIII RA+, HLA-ABCweak+, HLA-DR-, monocyte-). The expression of monocyte-related antigens by some endothelial cells appears to be acquired in extranodal inflammatory infiltrates and is probably modulated by lymphokines.     

Immunohistochemical study of stromal and vascular components of tonsillar polyps: high endothelial venules as participants of the polyp's lymphoid tissue

Tonsillar polyps are nonneoplastic lesions usually composed of variable amounts of lymphoid and vascular and connective tissues. All of them are generally assumed to be hamartomatous proliferations, but the profile of vascular and connective components has yet to be explored. The vascular system of the tonsils is complex and includes highly specialized structures (i.e., high endothelial venules (HEVs)) involved in lymphocyte homing into lymphoid tissues. In 14 tonsillar polyps and 26 control tonsils, an immunohistochemical study was performed using CD34 (blood vessels and HEVs), MECA-79 (HEVs), D2-40 (lymphatic vessels), Ki-67, collagens I and III, fibronectin, and tenascin-C. The polyps showed increased total lymphatic area, whereas the number of blood vessels and lymphatics and the blood vascular area did not differ significantly from those of control tonsils. Rare Ki-67+ endothelial cells were found. In the polyps, we detected, possibly for the first time, HEVs amid lymphoid tissue, and that the amount of the latter correlated positively with HEV density. The polyps also presented lesser amounts of fibronectin and collagens I and III than in normal tonsils, which were distributed in a disorganized fashion. Tenascin-C expression was uncommon in the polyps and control tonsils. Tonsillar polyps are composed of disorganized connective tissue and lymphatic channels which can be considered hamartomatous proliferations. However, the lymphoid component is possibly reactive due to its relationship with the HEVs. The highly differentiated phenotype of the HEVs and their complex biology are not in agreement with what would be expected for a component of hamartomatous nature.     

A unique phenotype of skin-associated lymphocytes in humans. Preferential expression of the HECA-452 epitope by benign and malignant T cells at cutaneous sites.

It has been proposed that the skin is a functionally unique compartment of the immune system, although little direct evidence supporting this hypothesis has been presented. Here we show that lymphocyte populations at cutaneous sites can be differentiated from otherwise similar populations at noncutaneous sites by their preferential expression of an epitope defined by the MAb HECA-452. This MAb recognizes a predominantly 200-kd cell-surface glycoprotein present on about 16% of peripheral blood T cells, including both CD4+ and CD8+ T cells (17% and 11% HECA-452+, respectively), as well as TCR-delta-bearing T cells (32%+). Most thymocytes (99%) lacked HECA-452 antigen expression, and essentially all the HECA-452+ peripheral blood T cells were found in the adhesion molecule high, CD45R low putative memory cell subset, findings suggesting that HECA-452 expression develops peripherally as a consequence of antigenic stimulation. However, the HECA-452 antigen is not a conventional activation antigen because it was not upregulated with mitogen stimulation of peripheral blood T cells. Most significantly, among 54 diverse specimens of normal/reactive lymphoid tissues and sites of chronic inflammation, there was a clear association of lymphocyte HECA-452 expression and cutaneous location. In extracutaneous sites (n = 38) only about 5% of lymphocytes within the T-cell areas of these tissues expressed this antigen, whereas in inflammatory skin lesions (n = 16), 85% were HECA-452+. The association of HECA-452 expression and cutaneous location was also seen in a series of T-cell lymphomas. The malignant cells of 16 of 18 cases of epidermotropic (patch/plaque) stage mycosis fungoides were HECA-452+, as well as 2 of 7 nonmycosis fungoides peripheral T-cell lymphomas in skin. In contrast, this antigen was not expressed in thymic (lymphoblastic) lymphomas (n = 14), nonepidermotropic (tumor) stage mycosis fungoides (n = 5), and noncutaneous peripheral T-cell lymphomas (n = 15). Among lymphocytes, the preferential expression of the HECA-452 determinant by cutaneous T cells supports the hypothesis that the skin constitutes a immunologically unique lymphoid tissue and suggests that this molecule may play a role in either lymphocyte homing to skin or in lymphocyte interactions with the epidermis.     

Adventitial infiltrates associated with advanced atherosclerotic plaques: structural organization suggests generation of local humoral immune responses

Advanced atherosclerotic lesions often contain adventitial lymphoid infiltrates, which occasionally contain nodular aggregates resembling lymphoid follicles. The structural organization suggests that local maturation of B cells may take place at these sites, as described for the mucosa-associated lymphoid tissue (MALT). This concept was evaluated by studying the micro-anatomy and cellular composition of adventitial infiltrates associated with advanced atherosclerosis of the aorta. Sections of 22 atherosclerotic aortas were stained immunohistochemically for cellular markers characteristic for lymphoid follicles, such as HECA-452-positive endothelial cells, CD20-positive B cells, CD21-positive follicular dendritic cells, and CD68-positive macrophages. Ki-67 was used as a proliferation marker. The TUNEL technique was used to study the presence of apoptotic cells. Specimens containing MALT served as comparison and positive controls. Seven of the 22 atherosclerotic aortas contained adventitial infiltrates resembling lymphoid follicles. The organized nodular centres were composed of CD45RA+ B cells, follicular dendritic cells (CD21+), a few T lymphocytes (CD3+) and 'tingible body' macrophages (CD68+). A large number of cells were Ki-67-positive; apoptotic bodies were numerous and phagocytosed by macrophages. The parafollicular area contained CD45RO-positive T cells and HECA-452-positive vessels. Vessels elsewhere were always HECA-452-negative. Specimens with MALT showed similar features. This study reveals a close resemblance between adventitial lymphoid infiltrates in advanced atherosclerotic aortic disease and MALT, suggesting local generation of a humoral immune response, likely to be initiated by antigens released during a process of long-standing tissue injury and inflammation as part of advanced atherosclerosis.     

Expression of sialyl-Lewis X, an E-selectin ligand, in inflammation, immune processes, and lymphoid tissues.

The carbohydrate structure sialyl-Lewis X (SLex) can function as a ligand for E-selectin, formerly known as endothelial leukocyte adhesion molecule-1 (ELAM-1). This study was performed to analyze the expression of SLex by leukocytes and other cell types in the context of inflammatory and immune processes. Human peripheral blood cells were examined by flow cytometry using monoclonal antibody CSLEX1 directed against SLex. Cell surface SLex was found in abundance on nearly all isolated polymorphonuclear leukocytes (PMN) and monocytes, and at low levels on a substantial portion (up to 40%) of natural killer cells. This moiety was expressed also on approximately 10% of peripheral blood T cells. Immunohistochemistry was performed on various human tissues involved in inflammatory or immune processes and on secondary lymphoid tissues. In acute appendicitis, endothelial cells of postcapillary venules expressed E-selectin, and most PMN, both within vessels and extravasated, expressed SLex. A substantial number of monocytes/macrophages in inflamed appendiceal, synovial, and dermal tissues also reacted with antibody CSLEX1; however, only rare tissue macrophages in uninflamed nonlymphoid sites showed expression of SLex. These observations are consistent with the concept that SLex on circulating PMN and monocytes functions as a ligand for endothelial E-selectin in the development of inflammatory reactions. SLex-positive lymphocytes also were seen, notably, T lymphocytes in inflamed skin. An unexpected finding was that the CSLEX1 antibody also reacted with venular endothelium in certain lymphoid tissues and in inflamed appendix, but not with endothelium in normal appendix. Whether the SLex antigen identified on endothelium represents de novo expression or passive adsorption remains to be determined.     

Augmented expression of secondary lymphoid tissue chemokine and EBI1 ligand chemokine in Crohn's disease

BACKGROUND: A dominant T helper type 1 (Th1) immune response is thought to be involved in Crohn's disease (CD). SLC/CCL21 and ELC/CCL19, chemokines that regulate T cell homing and promote recirculating T and dendritic cell (DC) interactions, help control antigen specific T cell responses. AIMS: To investigate the Th1 response and SLC and ELC in CD pathogenesis. METHODS: Surgically resected intestine and mesenteric lymph nodes (MLNs) from controls and patients with CD and ulcerative colitis (UC) were investigated. CD3, CD83, HECA452, VEGFR3, SLC, ELC, and CCR7 expression was studied immunohistochemically. CCR7 mRNA was quantified using real time RT-PCR. RESULTS: ELC was almost undetectable in intestinal samples. SLC was found sporadically in lymphoid follicles, lymphoid aggregate venules, and lymphatic vessels. In MLNs, SLC was highly expressed in high endothelial venules (HEVs), lymphatic vessels, and stromal DCs, predominantly in T cell areas. ELC was highly expressed in mature DCs. There were significantly more SLC positive HEVs and ELC positive mature DCs, important components of T cell areas, in CD. SLC, ELC, and CCR7 mRNA was significantly higher in CD MLNs compared with UC. CD MLNs had increased expression of SLC and ELC, mainly in HEVs, mature DCs, and lymphatic vessels, inducing T cell hyperplasia. CCR7 mRNA was increased in T cell areas. CONCLUSION: The dominant Th1 immune response is facilitated by interaction of SLC positive HEVs/lymphatic vessels, ELC positive mature DCs, and CCR7 positive T cells in hyperplastic T cell areas. In CD, memory T cells and mature DCs may home to MLN.     

Helicobacter-induced chronic active lymphoid aggregates have characteristics of tertiary lymphoid tissue

Susceptible strains of mice that are naturally or experimentally infected with murine intestinal helicobacter species develop hepatic inflammatory lesions that have previously been described as chronic active hepatitis. The inflammatory infiltrates in some models of chronic autoimmunity or inflammation resemble tertiary lymphoid organs hypothesized to arise by a process termed lymphoid organ neogenesis. To determine whether hepatic inflammation caused by infection with helicobacter could give rise to tertiary lymphoid organs, we used fluorescence-activated cell sorting, immunohistochemistry, and in situ hybridization techniques to identify specific components characteristic of lymphoid organs in liver tissue sections and liver cell suspensions from helicobacter-infected mice. Small venules (high endothelial venules [HEVs]) in inflammatory lesions in Helicobacter species-infected livers were positive for peripheral node addressin. Mucosal addressin cell adhesion molecule also stained HEVs and cells with a staining pattern consistent with scattered stromal cells. The chemokines SLC (CCL 21) and BLC (CXCL13) were present, as were B220-positive B cells and T cells. The latter included a na?ve (CD45lo-CD62Lhi) population. These findings suggest that helicobacter-induced chronic active hepatitis arises through the process of lymphoid organ neogenesis.     

Cutaneous angiolymphoid hyperplasia with high endothelial venules is characterized by endothelial expression of cutaneous lymphocyte antigen

Two cases in which the presence of cutaneous lesions with a characteristic admixture of lymphoid hyperplasia and vascular proliferation lead to the diagnosis of so-called acral pseudolymphomatous angiokeratoma (APA) of children are reported. Owing to the prominence of its blood vessels, so striking as to be reminiscent of high endothelial venules (HEVs), APA was initially interpreted as a vascular lesion rather than a pseudolymphoma. This resemblance is further compounded by our finding that cutaneous lymphocyte antigen (CLA), an HEV marker, is also expressed in APA epithelioid blood vessels. Consequently, we believe that "cutaneous angiolymphoid hyperplasia with high endothelial venules" (ALH-HEV), which alludes to the dual nature of proliferating elements and the HEV-like phenotype of the vascular component, would be a better denomination for this entity. Additionally, we speculate that ALH-HEV lymphoid hyperplasia self-perpetuates through the transformation of dermal capillaries into HEVs, which would bind non-skin homing lymphocytes expressing L-selectin and promote their local recruitment and recirculation.     

Fine-tuning immune surveillance by fever-range thermal stress

An effectively orchestrated immune response to infection and disease depends on efficient trafficking of lymphocytes across vascular beds at distinct tissue sites. Local inflammation and systemic fever increase immune surveillance to immune-relevant sites throughout the body. During the initiation phase of inflammation, this tightly regulated process improves leukocyte trafficking to the secondary lymphoid organs where they undergo activation and expansion in response to cognate antigen. In the resolution phase following the clearance of the invading pathogen, lymphocyte entry is rapidly returned to baseline conditions. Specialized blood vessels termed high endothelial venules (HEVs) have emerged as critical ‘hotspots’ controlling the rate of lymphocyte entry into lymphoid organs during both phases of inflammation. In this review, we will examine the remarkably tight regulation of lymphocyte trafficking across HEVs conferred by inflammatory cues associated with the thermal element of fever. These studies have revealed a novel role for interleukin-6 (IL-6) trans-signaling in eliciting systemic effects on lymphocyte trafficking patterns to fine-tune immune surveillance.     

Monoclonal antibody H3/5-47 recognizes an inducible cell surface antigen expressed differently in endothelium of normal and diseased tissues and in vitro.

Monoclonal antibody H3/5-47 was raised against a human melanoma metastasis and recognizes an antigen expressed in the endothelial cells of all normal human organs as assessed by immunohistochemistry. Antigen expression is higher in venous than in capillary or arterial endothelia; capillary endothelia of different microvascular beds, such as skin, lung, gut or liver, may express varying amounts of this antigen. H3/5-47 antigen expression in the endothelia of diseased tissues (inflammatory diseases, neoplasias) largely reflects its expression pattern in normal tissues. As might be anticipated, the highest expression of H3/5-47 antigen is found in resting adult cutaneous and hepatic cavernous venous hemangiomas. In contrast, psoriatic vessels, characterized by hypertrophy and fenestrations, tend to express H3/5-47 antigen at a much lower density. In human umbilical vein endothelial cells, half the single donor cases show no expression of H3/5-47 antigen, while the rest express the antigen at relatively low densities in about half the cells. Treatment with interferon-gamma or thrombin, but not interleukin-1, lipopolysaccharide, endothelial cell growth factor or phorbolester, either enhances or induces de novo expression in cultured human umbilical vein endothelial cells within 24h; maximum expression of H3/5-47 antigen is induced by interferon-gamma within 72 h. H3/5-47 antigen is not similar to other antigens inducible in human umbilical vein endothelial cells such as HLA-DR, ICAM-1, HECA-452, Leu13, MCP-1 or gamma-IP-10. It is not specifically expressed in the endothelium as it may also recognize certain epithelia, peripheral nervous tissue and bone marrow-derived cell populations.(ABSTRACT TRUNCATED AT 250 WORDS)     

Lymphocyte ‘homing’ and chronic inflammation

Chronic inflammation is a response to prolonged exposure to injurious stimuli that harm and destroy tissues and promote lymphocyte infiltration into inflamed sites. Following progressive accumulation of lymphocytes, the histology of inflamed tissue begins to resemble that of peripheral lymphoid organs, which can be referred to as lymphoid neogenesis or formation of tertiary lymphoid tissues. Lymphocyte recruitment to inflamed tissues is also reminiscent of lymphocyte homing to peripheral lymphoid organs. In the latter, under physiological conditions, homing receptors expressed on lymphocytes adhere to vascular addressin expressed on high endothelial venules (HEVs), initiating a lymphocyte migration process composed of sequential adhesive interactions. Intriguingly, in chronic inflammation, HEV‐like vessels are induced de novo, despite the fact that the inflamed site is not originally lymphoid tissue, and these vessels contribute to lymphocyte recruitment in a manner similar to physiological lymphocyte homing. In this review, we first describe physiological lymphocyte homing mechanisms focusing on vascular addressins. We then describe HEV‐like vessel‐mediated pathogenesis seen in various chronic inflammatory disorders such as Helicobacter pylori gastritis, inflammatory bowel disease (IBD), autoimmune pancreatitis and sclerosing sialadenitis, as well as chronic inflammatory cell neoplasm MALT lymphoma, with reference to our work and that of others.     

Endothelial sulfated sialyl Lewis x glycans, putative L-selectin ligands, are preferentially expressed in bronchial asthma but not in other chronic inflammatory lung diseases

Lymphocyte infiltrate is a hallmark of inflammatory responses. We have previously shown that de novo-induced endothelial sialyl Lewis x (sLex) expression guides lymphocytes in an L-selectin-dependent manner to sites of acute organ transplant rejections. In this research, we have analyzed five groups of chronic lung inflammations to determine the presence of properly glycosylated, i.e., sulfated, sLex-decorated, L-selectin ligands. Two anti-sLex (2F3 and HECA-452) and one anti-6- and/or 6'-sulfated and/or 6,6'-bisulfated (MECA-79) monoclonal antibodies (mAbs) were used. The control lung specimens did not express L-selectin ligands on endothelium. In contrast, the endothelial staining intensity and the number of positive peribronchial venules and capillaries with mAbs 2F3, HECA-452, and MECA-79 were significantly greater in bronchial biopsies from patients with asthma compared with normal specimens (P<0.003). However, no significant increase of peribronchial endothelial reactivity with these antibodies was observed in adult respiratory distress syndrome, chronic bronchitis, fibrosing alveolitis, and granulomatous inflammation compared with controls. These data suggest that sulfated sLex glycans, acting putatively as ligands for L-selectin, could be instrumental in lymphocyte extravasation into human peribronchial lung tissue during asthma, but not so important in several other inflammatory lung diseases.     

Structure, lymphatic vascularization and lymphocyte migration in mucosa-associated lymphoid tissue

Summary: In this review, we consider the morphological aspects and topographical arrangement of gut‐associated lymphoid tissue (GALT) (solitary and aggregate lymph nodules or Peyer's patches) and of vermiform appendix in the human child and in some mammals. The spatial arrangement of the vessels belonging to apparatus lymphaticus periphericus absorbens (ALPA) and of blood vessels within each lymphoid follicle as well as the ultrastructural characteristics of the lymphatic endothelium with high absorption capacity are considered. Particular attention is also paid to the morphological and biomolecular mechanisms inducing lymphocyte transendothelial migration to the bloodstream by means of lymphatic vessels as well as their passage from blood into lymphoid tissue through the high endothelial venules (HEVs). The preferential transendothelial passage of lymphocytes and polymorphonuclear neutrophils within ALPA vessels of the interfollicular area does not occur following the opening of intercellular contacts, but rather it occurs by means of ‘intraendothelial channels’. In HEVs, on the contrary, the hypothesis is plausible that lymphocyte transendothelial migration into lymphoid tissue occurs through a channel‐shaped endothelial invagination entirely independent of interendothelial contacts. The lymph of ALPA vessels of the single Peyer's patch is conveyed into precollector lymphatic vessels and into prelymph nodal collectors, totally independent of the ALPA vessels of the gut segments devoid of lymphoid tissue. The quantitative distribution of T lymphocytes in the lymph of mucosal ALPA vessels suggests a prevalent function of fluid uptake, whereas a reservoir and supply function is implicated for the vessels of interfollicular area. The precollector lymphatic vessels and prelymph nodal collectors are considered to be vessels with low absorption capacity, whose main function is lymph conduction and flow.