The mucin-type glycoprotein podoplanin is specifically expressed by lymphatic but not blood vascular endothelial cells in culture and in tumor-associated lymphangiogenesis, and podoplanin deficiency results in congenital lymphedema and impaired lymphatic vascular patterning. However, research into the biological importance of podoplanin has been hampered by the lack of a generally available antibody against the human protein, and its expression in normal tissues and in human malignancies has remained unclear. We generated a human podoplanin-Fc fusion protein and found that the commercially available mouse monoclonal antibody D2-40 specifically recognized human podoplanin, as assessed by enzyme-linked immunosorbent assay and Western blot analyses. We found that, in addition to lymphatic endothelium, podoplanin was also expressed by peritoneal mesothelial cells, osteocytes, glandular myoepithelial cells, ependymal cells, and by stromal reticular cells and follicular dendritic cells of lymphoid organs. These findings were confirmed in normal mouse tissues with anti-podoplanin antibody 8.1.1. Podoplanin was also strongly expressed by granulosa cells in normal ovarian follicles, and by ovarian dysgerminomas and granulosa cell tumors. Although podoplanin was primarily absent from normal human epidermis, its expression was strongly induced in 22 of 28 squamous cell carcinomas studied. These findings suggest a potential role of podoplanin in tumor progression, and they also identify the first commercially available antibody for the specific staining of a defined lymphatic marker in archival human tissue sections, thereby enabling more widespread studies of tumor lymphangiogenesis in human cancers.
In mammals, the lymphatic vascular system develops by budding of lymphatic progenitor endothelial cells from embryonic veins to form a distinct network of draining vessels with important functions in the immune response and in cancer metastasis. However, the lineage-specific molecular characteristics of blood vascular versus lymphatic endothelium have remained poorly defined. We isolated lymphatic endothelial cells (LECs) and blood vascular endothelial cells (BVECs) by immunomagnetic isolation directly from human skin. Cultured LECs but not BVECs expressed the lymphatic markers Prox1 and LYVE-1 and formed LYVE-1-positive vascular tubes after implantation in vivo. Transcriptional profiling studies revealed increased expression of several extracellular matrix and adhesion molecules in BVECs, including versican, collagens, laminin, and N-cadherin, and of the growth factor receptors endoglin and vascular endothelial growth factor receptor-1/Flt-1. Differential immunostains of human skin confirmed the blood vessel-specific expression of these genes. During embryonic development, endoglin expression was gradually down-regulated on lymphatic endothelium whereas vascular endothelial growth factor receptor-1 was absent from lymphatics. We also identified several genes with specific expression in LECs. These results demonstrate that some lineage-specific genes are only expressed during distinct developmental stages and they identify new molecular markers for blood vascular and lymphatic endothelium with im- The lymphatic system consists of a vascular network of thin-walled capillaries that drain protein-rich lymph from the extracellular spaces within most organs and that play major roles in the immune response and in tumor metastasis.1,2 Lymphatic vessels provide the conduit for antigen-presenting cells from the organ exposed to antigens to the regional lymph nodes, involving active recruitment of antigen-presenting cells by chemokines and other mediators secreted by lymphatic endothelium.3 Moreover, the early dissemination of malignant tumors frequently occurs via lymphatic vessels to regional lymph nodes, and the recent discovery of active tumor lymphangiogenesis and its role in cancer metastasis has drawn considerable attention to the molecular mechanisms that control activation and proliferation of lymphatic endothelium. 2,4
Vascular endothelial growth factor-A (VEGF-A) is strongly up-regulated in wounded cutaneous tissue and promotes repair-associated angiogenesis. However, little is known about its role in lymphatic regeneration of the healing skin. We studied wound healing in transgenic mice that overexpress VEGF-A specifically in the epidermis and in wild-type mice in the absence or presence of inhibitors of VEGF-A signaling. Surprisingly, transgenic overexpression of VEGF-A in the skin promoted lymphangiogenesis at the wound healing site, whereas systemic blockade of VEGFR-2 prevented lymphatic vessel formation. Studies in cultured lymphatic endothelial cells revealed that VEGF-A induced expression of the alpha1 and alpha2 integrins, which promoted their in vitro tube formation and their haptotactic migration toward type I collagen. VEGF-A-induced lymphatic endothelial cord formation and haptotactic migration were suppressed by anti-alpha1 and anti-alpha2 integrin blocking antibodies, and systemic blockade of the alpha1 and alpha2 integrins inhibited VEGF-A-driven lymphangiogenesis in vivo. We propose that VEGF-A promotes lymphatic vasculature formation via activation of VEGFR-2 and that lineage-specific differences of integrin receptor expression contribute to the distinct dynamics of wound-associated angiogenesis and lymphangiogenesis.
Fibroblast growth factors play important roles in angiogenesis, but their functions in lymphangiogenesis remain poorly understood. The homeodomain transcription factor Prox1 is essential for development of the lymphatic system by specifying lymphatic endothelial cell (LEC) fate. Here, we identify fibroblast growth factor (FGF) receptor (FGFR)-3 as a novel Prox1 target gene. Ectopic overexpression of Prox1 in blood vascular endothelial cells up-regulates FGFR-3. Prox1 induces the expression of the IIIc isoform, which we also found to be the major isoform of FGFR-3 expressed in LECs. This transcriptional activation is mediated by a direct binding of Prox1 to newly identified Prox1-response elements in the FGFR-3 promoter. Consistently, FGFR-3 is up-regulated in Prox1-positive newly formed lymphatic vessels during embryogenesis and its lymphatic-specific expression is maintained throughout development. We also found that FGF-1 and FGF-2 promote proliferation, migration, and survival of cultured LECs without involvement of vascular endothelial cell growth factor receptor-3. We show that FGF-2 binds to low-and high-affinity receptors on LECs and is efficiently internalized and processed. Moreover, functional inhibition of FGFR-3 using small interfering RNA represses LEC proliferation. Together, these results indicate that FGFR-3 is an initial target of Prox1 during the lymphatic cell fate specification and that FGF signaling may play an important role in lymphatic vessel development.
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