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Lymphatic Vasculature (lymphatic + vasculature)

Distribution by Scientific Domains

Life Sciences	75%

Selected Abstracts

Immmunohistochemical Study of the Blood and Lymphatic Vasculature and the Innervation of Mouse Gut and Gut-Associated Lymphoid Tissue

ANATOMIA, HISTOLOGIA, EMBRYOLOGIA, Issue 1 2007
B. Ma
Summary The blood and lymphatic vascular system of the gut plays an important role in tissue fluid homeostasis, nutrient absorption and immune surveillance. To obtain a better understanding of the anatomic basis of these functions, the blood and lymphatic vasculature of the lower segment of mouse gut and several constituents of gut-associated lymphoid tissue (GALT) including Peyer's patch, specialized lymphoid nodules in the caecum, small lymphoid aggregates and lymphoid nodules in the colon were studied by using confocal microscopy. Additionally, the innervation and nerve/immune cell interactions in the gut and Peyer's patch were investigated by using cell surface marker PGP9.5 and Glial fibrillary acidic protein (GFAP). In the gut and Peyer's patch, the nerves have contact with B cell, T cell and B220CD3 double-positive cells. Dendritic cells, the most important antigen-presenting cells, were closely apposed to some nerves. Some dendritic cells formed membrane,membrane contact with nerve terminals and neuron cell body. Many fine nerve fibres, which are indirectly detected by GFAP, have contact with dendritic cells and other immune cells in the Peyer's patch. Furthermore, the expression of Muscarinic Acetylcholine receptor (subtype M2) was characterized on dendritic cells and other cell population. These findings are expected to provide a route to understand the anatomic basis of neuron-immune regulation/cross-talk and probably neuroinvasion of prion pathogens in the gut and GALT. [source]

Expression of the hyaluronan receptor LYVE-1 is not restricted to the lymphatic vasculature; LYVE-1 is also expressed on embryonic blood vessels

DEVELOPMENTAL DYNAMICS, Issue 7 2008
Emma J. Gordon
Abstract Expression of the hyaluronan receptor LYVE-1 is one of few available criteria used to discriminate lymphatic vessels from blood vessels. Until now, endothelial LYVE-1 expression was reported to be restricted to lymphatic vessels and to lymph node, liver, and spleen sinuses. Here, we provide the first evidence that LYVE-1 is expressed on blood vessels of the yolk sac during mouse embryogenesis. LYVE-1 is ubiquitously expressed in the yolk sac capillary plexus at E9.5, then becomes progressively down-regulated on arterial endothelium during vascular remodelling. LYVE-1 is also expressed on intra-embryonic arterial and venous endothelium at early embryonic stages and on endothelial cells of the lung and endocardium throughout embryogenesis. These findings have important implications for the use of LYVE-1 as a specific marker of the lymphatic vasculature during embryogenesis and neo-lymphangiogenesis. Our data are also the first demonstration, to our knowledge, that the mouse yolk sac is devoid of lymphatic vessels. Developmental Dynamics 237:1901,1909, 2008. © 2008 Wiley-Liss, Inc. [source]

Tumor metastasis and the lymphatic vasculature

INTERNATIONAL JOURNAL OF CANCER, Issue 12 2009
Jonathan P. Sleeman
Abstract Tumor-associated lymphatic vessels act as a conduit by which disseminating tumor cells access regional lymph nodes and form metastases there. Lymph node metastasis is of major prognostic significance for many types of cancer, although lymph node metastases are themselves rarely life-threatening. These observations focus our attention on understanding how tumor cells interact with the lymphatic vasculature, and why this interaction is so significant for prognosis. Tumors interact with the lymphatic vasculature in a number of ways, including vessel co-option, chemotactic migration and invasion into lymphatic vessels and induction of lymphangiogenesis. Tumor-induced lymphangiogenesis both locally and in regional lymph nodes has been correlatively and functionally associated with metastasis formation and poor prognosis. The investigation of the molecular regulation of lymphangiogenesis has identified ways of interfering with prolymphangiogenic signaling. Blockade of tumor-induced lymphangiogenesis in preclinical models inhibits metastasis formation in lymph nodes and often also in other organs, suggesting that blocking the lymphatic route of dissemination might suppress metastasis formation not only in lymph nodes but also in other organs. However, randomized clinical trials that have investigated the efficacy of therapeutic removal of lymph nodes have concluded that lymph node metastases act only as indicators that primary tumors have developed metastatic potential, and do not govern the further spread of metastatic cells. To reconcile these apparently paradoxical observations we suggest a model in which tumor-induced lymphangiogenesis and lymph node metastasis formation act as indicators that tumors are producing factors that can act systemically to promote metastasis formation in distant organs. © 2009 UICC [source]

Lymphatics at the crossroads of angiogenesis and lymphangiogenesis

JOURNAL OF ANATOMY, Issue 6 2004
Claudio Scavelli
Abstract The lymphatic system is implicated in interstitial fluid balance regulation, immune cell trafficking, oedema and cancer metastasis. However, the sequence of events that initiate and coordinate lymphatic vessel development (lymphangiogenesis) remains obscure. In effect, the understanding of physiological regulation of lymphatic vasculature has been overshadowed by the greater emphasis focused on angiogenesis, and delayed by a lack of specific markers, thereby limiting this field to no more than a descriptive characterization. Recently, new insights into lymphangiogenesis research have been due to the discovery of lymphatic-specific markers and growth factors of vascular endothelial growth factor (VEGF) family, such as VEGF-C and VEGF-D. Studies using transgenic mice overexpressing VEGF-C and VEGF-D have demonstrated a crucial role for these factors in tumour lymphangiogenesis. Knowledge of lymphatic development has now been redefined at the molecular level, providing an interesting target for innovative therapies. This review highlights the recent insights and advances into the field of lymphatic vascular research, outlining the most important aspects of the embryo development, structure, specific markers and methods applied for studying lymphangiogenesis. Finally, molecular mechanisms involved in the regulation of lymphangiogenesis are described. [source]

Expression of Lymphatic Markers During Avian and Mouse Cardiogenesis

THE ANATOMICAL RECORD : ADVANCES IN INTEGRATIVE ANATOMY AND EVOLUTIONARY BIOLOGY, Issue 2 2010
Ganga Karunamuni
Abstract The adult heart has been reported to have an extensive lymphatic system, yet the development of this important system during cardiogenesis is still largely unexplored. The nuclear-localized transcription factor Prox-1 identified a sheet of Prox-1-positive cells on the developing aorta and pulmonary trunk in avian and murine embryos just before septation of the four heart chambers. The cells coalesced into a branching lymphatic network that spread within the epicardium to cover the heart. These vessels eventually expressed the lymphatic markers LYVE-1, VEGFR-3, and podoplanin. Before the Prox-1-positive cells were detected in the mouse epicardium, LYVE-1, a homologue of the CD44 glycoprotein, was primarily expressed in individual epicardial cells. Similar staining patterns were observed for CD44 in avian embryos. The proximity of these LYVE-1/CD44-positive mesenchymal cells to Prox-1-positive vessels suggests that they may become incorporated into the lymphatics. Unexpectedly, we detected LYVE-1/PECAM/VEGFR-3-positive vessels within the embryonic and adult myocardium, which remained Prox-1/podoplanin-negative. Lymphatic markers were surprisingly found in adult rat and embryonic mouse epicardial cell lines, with Prox-1 also exhibiting nuclear-localized expression in primary cultures of embryonic avian epicardial cells. Our data identified three types of cells in the embryonic heart expressing lymphatic markers: (1) Prox-1-positive cells from an extracardiac source that migrate within the serosa of the outflow tract into the epicardium of the developing heart, (2) individual LYVE-1-positive cells in the epicardium that may be incorporated into the Prox-1-positive lymphatic vasculature, and (3) LYVE-1-positive cells/vessels in the myocardium that do not become Prox-1-positive even in the adult heart. Anat Rec, 2010. © 2009 Wiley-Liss, Inc. [source]