Decreased D2-40 immunoreactivity in stored paraffin sections and methods for preserving it

D2-40, a monoclonal antibody against podoplanin, is a selective marker of lymphatic endothelium and is widely used for research on and diagnosis of pathology of lymphatic vessels. We examined the relation between the duration of tissue section storage and changes in immunostaining by D2-40 antibody; we evaluated also the effects of preservation methods on changes in immunostaining during storage. Staining by D2-40 was attenuated by long-term preservation of scalp skin and lymph node sections at room temperature. The attenuation of D2-40 staining in stored sections was improved by preservation at low temperature, i.e., 4° or ? 30° C. We investigated also the immunostaining of preserved tissue sections using NZ-1 and Lyve-1, which are antibodies against lymphatic endothelium markers. Staining by NZ-1 or Lyve-1 antibody was detected clearly in sections that had been stored for 16 weeks. Our study suggests that either long-term storage of D2-40 immunostained tissue sections should be avoided or the section should be preserved at low temperature.     

Visualization of Intrapulmonary Lymph Vessels in Healthy and Inflamed Murine Lung Using CD90/Thy-1 as a Marker

Background

Lymphatic vessels play a pivotal role in fluid drainage and egress of immune cells from the lung. However, examining murine lung lymphatics is hampered by the expression of classical lymph endothelial markers on other cell types, which hinders the unambiguous identification of lymphatics. The expression of CD90/Thy-1 on lymph endothelium was recently described and we therefore examined its suitability to identify murine pulmonary lymph vessels under healthy and inflammatory conditions.

Methodology/Principal Findings

Immunohistochemistry with a monoclonal antibody against CD90.2/Thy-1.2 on 200 µm thick precision cut lung slices labeled a vascular network that was distinct from blood vessels. Preembedding immunostaining and electron microscopy verified that the anti-CD90.2/Thy-1.2 antibody labeled lymphatic endothelium. Absence of staining in CD90.1/Thy-1.1 expressing FVB mice indicated that CD90/Thy-1 was expressed on lymph endothelium and labeling was not due to antibody cross reactivity. Double-labeling immunohistochemistry for CD90/Thy-1 and α-smooth muscle actin identified two routes for lymph vessel exit from the murine lung. One started in the parenchyma or around veins and left via venous blood vessels. The other began in the space around airways or in the space between airways and pulmonary arteries and left via the main bronchi. As expected from the pulmonary distribution of lymph vessels, intranasal application of house dust mite led to accumulation of T cells around veins and in the connective tissue between airways and pulmonary arteries. Surprisingly, increased numbers of T cells were also detected around intraacinar arteries that lack lymph vessels. This arterial T cell sheath extended to the pulmonary arteries where lymph vessels were located.

Conclusions/Significance

These results indicate that CD90/Thy-1 is expressed on lymphatic endothelial cells and represents a suitable marker for murine lung lymph vessels. Combining CD90/Thy-1 labeling with precision cut lung slices allows visualizing the anatomy of the lymphatic system in normal and inflamed conditions.     

Intravital two-photon microscopy of lymphatic vessel development and function using a transgenic Prox1 promoter-directed mOrange2 reporter mouse

Lymphatic vessels, the second vascular system of higher vertebrates, are indispensable for fluid tissue homoeostasis, dietary fat resorption and immune surveillance. Not only are lymphatic vessels formed during fetal development, when the lymphatic endothelium differentiates and separates from blood endothelial cells, but also lymphangiogenesis occurs during adult life under conditions of inflammation, wound healing and tumour formation. Under all of these conditions, haemopoietic cells can exert instructive influences on lymph vessel growth and are essential for the vital separation of blood and lymphatic vessels. LECs (lymphatic endothelial cells) are characterized by expression of a number of unique genes that distinguish them from blood endothelium and can be utilized to drive reporter genes in a lymph endothelial-specific fashion. In the present paper, we describe the Prox1 (prospero homeobox protein 1) promoter-driven expression of the fluorescent protein mOrange2, which allows the specific intravital visualization of lymph vessel growth and behaviour during mouse fetal development and in adult mice.     

Distribution of lymphatic vessels in mouse thymus: immunofluorescence analysis

Thymic blood and lymphatic vessels in humans and laboratory animals have been investigated in morphological studies. However, occasionally a clear distinction between blood vessels and lymphatic vessels cannot be made from morphological characteristics of the vasculature. To visualize thymic lymphatics in normal adult BALB/c mice, we used antibodies against specific markers of lymphatic endothelial cells. Expression of vascular endothelial growth factor receptor–3 (VEGFR–3) was detected throughout the thymus, i.e., the capsule, cortex, and medulla. Most thymic lymphatics were present in capillaries of ~20 μm in caliber. The plexuses of lymphatic capillaries were occasionally detectable. Lymphatic vessels were frequently adjacent to CD31–positive blood vessels, and some lymphatic vessels were seen in the immediate vicinity of or within the perivascular spaces around postcapillary venules. The identity of VEGFR–3–positive vessels as lymphatics was further confirmed by staining with additional markers: LYVE–1, Prox–1, neuropilin–2, and secondary lymphoid tissue chemokine (SLC). The distributions of LYVE–1 were similar to those of VEGFR–3. Most lymphatic vessels were also identified by Prox–1. Neuropilin–2 was restricted to lymphatic vessels in the thymus. The most abundant expression of SLC in the thymus was in medullar epithelial cells; SLC was also expressed in lymphatic vessels and blood vessels. Thus, lymphatic endothelium in mouse thymus was characterized by positive staining with antibodies to VEGFR–3, LYVE–1, Prox–1, neuropilin–2, or SLC, but not with an antibody to CD31. Our results suggest the presence of lymphatic capillary networks throughout the thymus.     

Immunoelectron microscopic study of PECAM-1 expression on lymphatic endothelium of the human tongue

The expression of platelet-endothelial cell adhesion molecule-1 (PECAM-1) on lymphatic and blood vessels of the human tongue was examined with fluorescence and transmission electron microscopy (TEM). The study used anti-desmoplakins antiserum for light microscopic identification of the lymphatic vessels, plus a pre-embedding immunogold electron microscopic technique for TEM observations. Before making TEM observations, cryostat serial sections were immunostained with anti-desmoplakins or anti-PECAM-1 and then embedded. Semithin sections from each cryostat section were photographed under a light microscope and compared in order to identify the lymphatic vessels expressing PECAM-1. In fluorescence microscopy, PECAM-1 expression on lymphatic vessels was weaker than that on blood vessels. TEM observations showed that PECAM-1 expression on the blood vessels was observed only on the luminal surface of the endothelium. In lymphatic vessels, PECAM-1 expression was found both on the luminal and abluminal surfaces of the endothelium. The density of the PECAM-1 reaction products was lower in lymphatic vessels than in blood vessels. The density of PECAM-1 reaction products on the luminal surface of lymphatic vessels was higher than on the abluminal surfaces. The results suggest that blood vessels are more active than lymphatic vessels in leukocyte migration. The expression of PECAM-1 on the abluminal surface of lymphatic endothelium may allow leukocytes to adhere to the endothelium and interact in their migration from tissue into lymphatic vessels.     

Structure of lymphatic vessels in the rat thyroid gland

The lymphatic bed of the thyroid gland has been studied in 24 intact rats. Three techniques facilitating to reveal lymphatic vessels in the organ have been used: preparation of semithin sections, injection of the blood bed with methyl methacrylate with a successive chemical extraction of the preparations, injection of the blood bed with liquid solution of methyl methacrylate with a consecutive study of the preparations in the scanning electron microscope. Methods of electron histochemistry (revealing horseradish peroxidase) and kryofractography have been applied. Construction of the thyroid lymphatic bed, structure of the wall are described, fibroblastic membrane (F-membrane) is revealed and the signs are presented, that allow to differentiate F-membrane from endothelium of the lymphatic capillaries. The pathways of lymph outflow in the rat thyroid gland consist of the following links: interstitial space in the interlobular spaces of the gland, into them the tissue liquor (lymph) is filtered ; plates of the F-membrane regulating direction of excessive albumin-containing liquor in the lymphatic capillaries, surrounding groups of 5-11 follicles, embracing the microlobule of the gland and situating in the interlobular spaces, deferent lymphatic vessels.     

Expression of cys-cys chemokine ligand 21 on human gingival lymphatic vessels

The cys-cys (C-C) chemokine ligand 21 is a member of the C-C chemokines that constitute a group of heparin-binding cytokines with a pattern of four or six conserved cysteines. The CCL21 is known to be expressed in secondary lymphoid tissues, however it has rarely been reported for the expression on peripheral lymphatic vessels in somatic tissue. Here we investigated the expression of CCL21 on lymphatic vessels identified by anti-desmoplakin in uninflamed and inflamed human gingiva. In uninflamed tissue the expression of CCL21 was detected on lymphatic vessels in gingiva. In uninflamed gingiva the expression of CCL21 was detected on all lymphatic capillaries of the mucosal connective tissue papillae. There were two types of collecting lymphatic vessels in the lamina propria mucosae expressing CCL21 strongly or very weakly. In inflamed gingiva no expression of CCL21 was detected on lymphatic vessels. In all tissue sections no blood vessels expressing CCL21 were observed. These results may suggest that the expression of CCL21 is predominantly induced in the peripheral lymphatic endothelium of the uninflamed mucosal microcirculation, and that under inflamed conditions a reduction of CCL21 occurs in lymphatic endothelium.     

ENOS,ET-1 and ETB-R immunoreactivities in the porcine mesometrial lymphatics during the estrous cycle

Abstract: Immunohistochemical localization and distribution of nitric oxide synthase (eNOS), endothelin (ET-1) and endothelin beta receptor (ETB-R) were investigated in precollector and collector lymph vessels in the broad ligament of the uterus during different phases of the estrous cycle in pigs. The polyclonal antibody for ET-1 and ETB-R and monoclonal antibody for eNOS isoform were used to perform observations on the light microscopic level. Immunoreactivities to ET-1, ETB-R and eNOS were observed in the endothelium of precollector and collector lymphangions but not in smooth muscle cells of the lymphatics examined. The staining for eNOS in the endothelial cells of all studied lymphatic vessels was stronger comparing to ET-1 and ETB-R. During the estrous cycle, only eNOS showed the correlation with the particular phases of the estrous cycle. The differences between ET-1 and ETB-R immunoreactivities were very slight and rather independent of the size or type of the lymphatic lymphangions and estrous cycle. The highest immunoreactivity level for eNOS was displayed by collector lymphangions with widened lumen in the follicular phase comparing to the precollector ones. During the luteal phase, a slight decrease in the reaction intensity was observed. The immunoreactivities for ET-1 in the endothelium of the studied vessels was not comparable with the presence or with the reactivity level of ETB-R. Optically stronger immunoreaction for ETB-R was observed in the cytoplasm of collector lymphangions in the follicular phase. eNOS, ET-1 and ETB-R were also present in the cytoplasm of the lymphatic valves. These results suggest that ET-1 and eNOS can play a role in the mechanisms regulating the vascular contractile activity, promoting lymph flow during the estrous cycle in the porcine broad ligament.     

The multidrug-resistance P-glycoprotein (Pgp, MDR1) is an early marker of blood-brain barrier development in the microvessels of the developing human brain

 The multidrug-resistance P-glycoprotein (Pgp) was initially identified as an energy-dependent proton pump, which transports a variety of non-related compounds out of chemotherapy-resistant cancer cells. Molecular biological investigations using knockout mice for the mouse homologue of the human Pgp showed that these mice partially lack a functioning blood-brain barrier, indicating that Pgp has an important role in the blood-brain barrier as its normal function. The presence of Pgp expression in formalin-fixed and wax-processed tissue sections can be assessed using the monoclonal antibody, JSB-1. Since no data on the developmental expression of Pgp are available, we stained a developmental series of human brain sections with JSB-1. Our results indicate that Pgp expression in endothelia of brain microvessels occurs regularly in embryos of about 30-mm crown-rump length (CRL). Strong reactivity is seen in blood vessels of fetuses from 123-mm CRL. There is also reactivity in pial blood vessels but not in choroid plexus blood vessels known to be without a blood-brain barrier. Pgp expression is therefore an early marker of the blood-brain barrier in the developing human brain. Accepted: 20 May 1997     

Angiogenesis and the formation of lymphaticlike channels in cultures of thoracic duct

Summary Segments of rat thoracic duct cultured in plasma clot or in collagen gel produced microvascular and fibroblastic outgrowths. Lymphaticlike channels (LLC) with a highly attenuated endothelium, which was barely visible by light microscopy, were found in 8 out of 25 cultures (32%). Serial histologic sections revealed that the endothelium of the LLC was continuous with the intimal endothelium of the throacic duct and was therefore of lymphatic origin. In addition to the LLC, vascular channels lined by a thick endothelium with hump-shaped, cross-sectional profiles were found in 10 cultures (40%). These channels were indistinguishable from the microvessels of blood vascular origin that formed in parallel cultures of rat aorta or periductal adipose tissue and were termed hematiclike channels (HLC). Contrary to the LLC, the HLC did not originate from the lymphatic endothelium of the thoracic duct. The frequent association of the HLC with the adventitia of the thoracic duct and with the surrounding adipose tissue suggested that they probably developed from the hematic microvessels of the periductal soft tissues. This research was supported by grants from the National Cancer Institute, NIH, National Bladder Cancer Project (CA14137), and the W. W. Smith Charitable Trust.     

Generation and characterization of novel stromal specific antibodies

Rheumatoid synovial fibroblasts were used as an immunogen to produce monoclonal antibodies selected for their reactivity with stromal cell antigens. Mice were immunised with low passage whole cell preparations and the subsequent hybridomas were screened by immunohistochemistry on rheumatoid synovium and tonsil sections. The aim was to identify those antibodies that recognised antigens that were restricted to stromal cells and were not expressed on CD45 positive leucocytes. A significant number of antibodies detected antigen that identified endothelial cells. These antibodies were further characterised to determine whether the vessels identified by these antibodies were vascular or lymphatic. From five fusions clones were identified with predominant reactivity with： 1） fibroblasts and endothelial cells; or 2） broad stromal elements （fibroblast, endothelium, epithelium, follicular dendritic cells）. A fibroblast-specific antibody that did not also identify vessels was not generated. Examples of each reactivity pattern are discussed.     

Identification of smooth muscle-derived foam cells in the atherosclerotic plaque of human aorta with monoclonal antibody IIG10

We have developed a monoclonal antibody that specifically interacts with a surface antigen of human fibroblasts and smooth muscle cells. The antibody (antibody IIG10) recognizes a polypeptide of molecular mass 330,000, revealed by immunoblotting in fibroblast and smooth muscle cell extract, but not in vascular endothelial cells, peritoneal macrophages, peripheral blood lymphocytes nor hepatocytes. In tissue sections the antibody stained smooth muscle cells of myometrium, aorta and smaller blood vessels, and fibroblasts of connective tissue. Specificity of the antibody was further confirmed by double staining of aorta sections. Antibody IIG10 was used to identify smooth muscle-derived foam cells in the atherosclerotic plaque of human aorta.     

Morphological parameters of the angiogenic response in pancreatic ductal adenocarcinoma--correlation with histological grading and clinical data.

The aim of this study was to evaluate angiogenesis in tissue of the pancreatic ductal adenocarcinoma and to correlate it with histopathological data such as tumour differentiation, tumour size, lymph node metastasis and patients survival. Tumour samples obtained during surgery from 36 patients were immunostained for the presence of blood vessels with monoclonal antibody against the CD31 molecule. Evaluation of microvasculature was perfomed by counting the microvessel density (MVD) in selected areas under light microscope as well as by computer assisted image analysis (CAIA). In the latter, the following parameters were used for assessment of microvessels: mean number/field, mean area of the vessels, total area/field and total perimeter/field. MVD values obtained under optical microscope and with CAIA were highly correlated. All parameters characterising microvasculature in CAIA also revealed a significant correlation with the histological grading of tumours; generally the less differentiated tumours manifested more extensive vascular network. No significant relationship was found between the tumour size and any of the CAIA parameters. The area of vessels (both total and mean values) revealed a significant, inverse correlation with the incidence of lymph node metastases. The same type of correlation was also found between the mean vessel area and the postoperative survival period. The results show that CAIA of microvessels offers new parameters with some predictive value for the outcome of patients with pancreatic cancer.     

Ultrastructural localization of arginine vasopressin in coronary vessels of newborn rat

We report on the ultrastructural distribution of arginine-vasopressin (AVP) in the heart of newborn rats using pre-embedding peroxidase-antiperoxidase immunocytochemistry with a polyclonal AVP antibody for electron microscopy. Positive labelling for AVP was localized in endothelial cells of main coronary arteries and cardiac vessels of smaller diameter (microvessels). Examination of the right coronary artery showed that approximately 58% of the endothelial cells were positive for AVP. Immunoreactivity to AVP in the cytoplasm of arterial endothelium predominated in association with the membranes of granular endoplasmic reticulum and in subplasmalemmal areas. The endothelium of small vessels exhibits less endoplasmic reticulum, but still shows AVP immunoprecipitate in the cytoplasm. It is suggested that endothelial AVP may contribute to vasomotor control of the coronary circulation in the early stages of postnatal development. AVP antibody also labelled some fibroblast/fibroblast-like cells associated with the coronary arteries and microvessels; thus, these cells as well as the endothelium appear to be a source of AVP in the newborn rat heart. The functional significance of these findings is discussed.     

Lymphoid tissue- and inflammation-specific endothelial cell differentiation defined by monoclonal antibodies

Endothelial cells play an essential role in immune responses by regulating the entry of leukocytes into lymphoid tissues and sites of inflammation. As an initial approach to analyzing endothelial cell specialization in relation to such immune function, we have produced monoclonal antibodies (MAB) against mouse lymph node endothelium. Three antibodies were selected: MECA-20, recognizing the endothelium of all blood vessels in lymphoid as well as non-lymphoid organs; MECA-217, which stains the endothelium lining large elastic arteries, but among small vessels is specific for post-capillary venules within lymphoid organs and tissues exposed to exogenous antigen, such as skin and uterus; and MECA-325, an antibody that demonstrates specificity for the specialized high endothelial venules (HEV) that control lymphocyte homing into lymph nodes and Peyer's patches. MECA-325 failed to stain vessels in any non-lymphoid organs tested. Immunoperoxidase studies of HEV in lymph node frozen sections, and of isolated high endothelial cells in suspensions, demonstrated that the antigens recognized by all three antibodies are expressed at the cell surface; those defined by MECA-20 and MECA-325 are also present in the cytoplasm. To study the regulation of the antigens defined by these MAB in relation to extra-lymphoid immune reactions, we assessed their expression in induced s.c. granulomas as a model for chronic inflammation. Small vessels in the granulomas were already stained by MECA-217 in the first days of development. In contrast MECA-325 detected postcapillary venules (which frequently displayed the morphologic characteristics of HEV) only from approximately 1 wk, in parallel with the development of a persistent mononuclear cell infiltrate including numerous lymphocytes. The selective appearance of the MECA-325 antigen on vascular endothelium supporting lymphocyte traffic in both lymphoid and extra-lymphoid sites suggests that this antigen may play an important role in the process of lymphocyte extravasation. The demonstration of lymphoid organ- and inflammation-specific microvascular antigens offers direct evidence for a complex specialization of endothelium in relation to immune stimuli, and supports the concept that microvascular differentiation may play an important role in local immune responses.     

Investigations on the usefulness of CEACAMs as potential imaging targets for molecular imaging purposes

Members of the carcinoembryonic antigen cell adhesion molecules (CEACAMs) family are the prototype of tumour markers. Classically they are used as serum markers, however, CEACAMs could serve as targets for molecular imaging as well.In order to test the anti CEACAM monoclonal antibody T84.1 for imaging purposes, CEACAM expression was analysed using this antibody. Twelve human cancer cell lines from different entities were screened for their CEACAM expression using qPCR, Western Blot and FACS analysis. In addition, CEACAM expression was analyzed in primary tumour xenografts of these cells. Nine of 12 tumour cell lines expressed CEACAM mRNA and protein when grown in vitro. Pancreatic and colon cancer cell lines showed the highest expression levels with good correlation of mRNA and protein level. However, when grown in vivo, the CEACAM expression was generally downregulated except for the melanoma cell lines. As the CEACAM expression showed pronounced expression in FemX-1 primary tumours, this model system was used for further experiments. As the accessibility of the antibody after i.v. application is critical for its use in molecular imaging, the binding of the T84.1 monoclonal antibody was assessed after i.v. injection into SCID mice harbouring a FemX-1 primary tumour. When applied i.v., the CEACAM specific T84.1 antibody bound to tumour cells in the vicinity of blood vessels. This binding pattern was particularly pronounced in the periphery of the tumour xenograft, however, some antibody binding was also observed in the central areas of the tumour around blood vessels. Still, a general penetration of the tumour by i.v. application of the anti CEACAM antibody could not be achieved despite homogenous CEACAM expression of all melanoma cells when analysed in tissue sections. This lack of penetration is probably due to the increased interstitial fluid pressure in tumours caused by the absence of functional lymphatic vessels.     

Localization of factor VIII-related antigen in the endothelium of the chick embryo chorioallantoic membrane

In this study, by using a polyclonal antibody against factor VIII-related antigen (FVIII-RA), we have examined the expression of FVIII-RA in the blood and lymphatic vessels of the chick embryo chorioallantoic membrane (CAM). The antibody marked the endothelium of blood and lymphatic vessels starting from day 8 of incubation and the cytoplasm of the allantoic epithelial cells. The application of this antibody may be useful for quantifying neovascularization in response to various angiogenic stimuli applied to the CAM. Accepted: 12 October 1999     

The lymphatic vasculature in disease

Blood vessels form a closed circulatory system, whereas lymphatic vessels form a one-way conduit for tissue fluid and leukocytes. In most vertebrates, the main function of lymphatic vessels is to collect excess protein-rich fluid that has extravasated from blood vessels and transport it back into the blood circulation. Lymphatic vessels have an important immune surveillance function, as they import various antigens and activated antigen-presenting cells into the lymph nodes and export immune effector cells and humoral response factors into the blood circulation. Defects in lymphatic function can lead to lymph accumulation in tissues, dampened immune responses, connective tissue and fat accumulation, and tissue swelling known as lymphedema. This review highlights the most recent developments in lymphatic biology and how the lymphatic system contributes to the pathogenesis of various diseases involving immune and inflammatory responses and its role in disseminating tumor cells.     

Ontogeny of human fetal lymph nodes.

Developing lymph nodes from 30 human embryos and fetuses with crown-rump lengths (CRL) of 18 mm (5.6 wk) to 245 mm (26 wk) were examined by light microscopy. The nodes were embedded in araldite, and the sections examined were approximately 1 mu in thickness. The development of nodes was divided into three stages: 1. the lymphatic plexus and connective tissue invagination (30 mm to 67 mm CRL); 2. the early fetal lymph node (43 mm to ,5 mm CRL); and 3. the late fetal lymph node (CRL greater than 75 mm). The lymphatic plexus was formed by connective tissue invaginations and bridges which divided a lymph sac into a meshwork of channels and spaces. Connective tissue invaginations were endothelially-lined and were surrounded by lymphatic space. Reticular cells, macrophages, and blood vessels were found in these invaginations. Early fetal lymph nodes were formed from invaginations when the cellular density and lymphocyte content increased. The lymphatic space surrounding the early node was the developing subcapsular sinus. With further development the early node became packed with lymphocytes, increasing the cellular density and size of the node. The connective tissue surrounding the subcapsular sinus condensed to form the capsule. Afferent lymphatic vessels pierced the capsule. Capillaries, veins, postcapillary venules, and occasional arteries were found in early and late nodes.