血管内皮生长因子D在小鼠碱烧伤后角膜的表达及其作用

目的观察血管内皮生长因子D(VEGF-D)在小鼠角膜碱烧伤后不同时间角膜组织内的表达,探讨VEGF-D在小鼠角膜碱烧伤后新生淋巴管形成过程中的作用。方法制作小鼠角膜碱烧伤模型,分别于碱烧伤后1d、3d、5d、7d、12d和18d取材。应用免疫组化SP法观察VEGF-D在正常角膜和碱烧伤后不同时间角膜内的表达,应用淋巴管内皮透明质酸受体1(LYVE-1)标记淋巴管,观察小鼠碱烧伤角膜内新生淋巴管的形成情况。结果碱烧伤后1d、3d、5d,角膜内VEGF-D表达水平明显高于正常角膜(P<0.01),于碱烧伤后3d,表达达到高峰。碱烧伤后7d,VEGF-D的表达下降至正常水平。在碱烧伤角膜内,可见阳性表达LYVE-1的新生淋巴管。结论 VEGF-D过表达可能参与小鼠角膜碱烧伤后新生淋巴管形成过程。     

Lymphangiogenesis of normal endometrium and endometrial adenocarcinoma

BACKGROUND: Information about lymphatics and lymphangiogenesis in the human endometrium is limited. We investigated the distribution of endometrial lymphatic vessels during the normal menstrual cycle and in association with endometrial adenocarcinoma and investigated the expression of lymphangiogenic growth factors, vascular endothelial growth factor (VEGF)-C, VEGF-D and VEGF receptor-3 (VEGF-R3). METHODS AND RESULTS: Full thickness uterine samples (n = 23 proliferative; n = 23 secretory) and endometrial adenocarcinoma samples (n = 7 grade I; n = 10 grade III) were collected for the study and analysed by immunohistochemistry and western blotting. Lymphatic vessels of the functionalis were significantly reduced compared with basalis (P = 0.001) across the menstrual cycle with lymphatics of the basalis sometimes intimately associated with spiral arterioles. Lymphatic vessels of endometrial adenocarcinomas were located intra-tumoural and peri-tumoural with significant increases in the peri-tumoural lymphatic vessels compared with normal basalis (P = 0.02). Interestingly, high-grade adenocarcinoma vessels containing tumour emboli demonstrated a mixed blood/lymphatic endothelial cell phenotype. VEGF-C and VEGF-D were immunolocalized in glandular epithelium and some stromal cells with the staining intensity of this localization increasing in endometrial adenocarcinoma. Protein analysis identified VEGF-C (58, 41, 31 and 21 kD) and VEGF-D (56, 41, 31 and 21 kD) and VEGF-R3 (148 and 65 kD) peptides in normal endometrium, with significant increases in several of these peptides for VEGF-C and VEGF-D and no changes in protein expression for VEGF-R3 in endometrial adenocarcinoma. CONCLUSION: Endometrial lymphatics are significantly reduced in the functionalis, and increases in endometrial adenocarcinoma peri-tumoural lymphatics are associated with increases in VEGF-C and VEGF-D peptides.     

The angiogenic and lymphangiogenic factor vascular endothelial growth factor-D exhibits a paracrine mode of action in cancer

Vascular endothelial growth factor-D (VEGF-D) promotes angiogenesis, lymphangiogenesis and metastatic spread via the lymphatics, however, the mode of VEGF-D action (e.g. paracrine vs. autocrine) was unknown. We analyzed VEGF-D action in human tumors and a mouse model of metastasis. VEGF-D was localized in tumor cells and endothelium in human non-small cell lung carcinoma and breast ductal carcinoma in situ. Tumor vessels positive for VEGF-D were also positive for its receptors, VEGF receptor-2 (VEGFR-2) and/or VEGFR-3 but negative for VEGF-D mRNA, indicating that VEGF-D is secreted by tumor cells and subsequently associates with endothelium via receptor-mediated uptake. The mature form of VEGF-D was detected in tumors demonstrating that VEGF-D is proteolytically processed and bioactive. In a mouse model of metastasis, VEGF-D synthesized in tumor cells became localized on the endothelium and thereby promoted metastatic spread. These data indicate that VEGF-D promotes tumor angiogenesis, lymphangiogenesis and metastatic spread by a paracrine mechanism.     

VEGFR-3 in adult angiogenesis.

Vascular endothelial growth factor receptor 3 (VEGFR-3, Flt-4), the receptor for vascular endothelial growth factors (VEGFs) C and D, is expressed on lymphatic endothelium and may play a role in lymphangiogenesis. In embryonic life, VEGFR-3 is essential for blood vessel development. The purpose of this study was to investigate whether VEGFR-3 is also involved in blood vessel angiogenesis in the adult. This was studied in human tissues showing angiogenesis and in a model of VEGF-A-induced iris neovascularization in the monkey eye, by the use of immunohistochemistry at the light and electron microscopic level. VEGFR-3 was expressed on endothelium of proliferating blood vessels in tumours. In granulation tissue, staining was observed in the proliferative superficial zone in plump blood vessel sprouts, in the intermediate zone in blood vessels and long lymphatic sprouts, and in the deeper fibrous zone in large lymphatics, in a pattern demonstrating that lymphangiogenesis follows behind blood vessel angiogenesis in granulation tissue formation. At the ultrastructural level, VEGFR-3 was localized in the cytoplasm and on the cell membrane of endothelial cells of sprouting blood vessels and sprouting lymphatics. In monkey eyes injected with VEGF-A, blood vessel sprouts on the anterior iris surface and pre-existing blood vessels in the iris expressed VEGFR-3. In conclusion, these results support a role for VEGFR-3 and its ligands VEGF-C and/or VEGF-D in cell-to-cell signalling in adult blood vessel angiogenesis. The expression of VEGFR-3 in VEGF-A-induced iris neovascularization and in pre-existing blood vessels exposed to VEGF-A suggests that this receptor and possibly its ligands are recruited in VEGF-A-driven angiogenesis.     

The Angiogenic and Lymphangiogenic Factor Vascular Endothelial Growth Factor-D Exhibits a Paracrine Mode of Action in Cancer

Vascular endothelial growth factor-D (VEGF-D) promotes angiogenesis, lymphangiogenesis and metastatic spread via the lymphatics, however, the mode of VEGF-D action (e.g. paracrine vs. autocrine) was unknown. We analyzed VEGF-D action in human tumors and a mouse model of metastasis. VEGF-D was localized in tumor cells and endothelium in human non-small cell lung carcinoma and breast ductal carcinoma in situ. Tumor vessels positive for VEGF-D were also positive for its receptors, VEGF receptor-2 (VEGFR-2) and/or VEGFR-3 but negative for VEGF-D mRNA, indicating that VEGF-D is secreted by tumor cells and subsequently associates with endothelium via receptor-mediated uptake. The mature form of VEGF-D was detected in tumors demonstrating that VEGF-D is proteolytically processed and bioactive. In a mouse model of metastasis, VEGF-D synthesized in tumor cells became localized on the endothelium and thereby promoted metastatic spread. These data indicate that VEGF-D promotes tumor angiogenesis, lymphangiogenesis and metastatic spread by a paracrine mechanism.     

LYVE-1 immunohistochemical assessment of lymphangiogenesis in endometrial and lung cancer

AIMS/METHODS: Normal and malignant pulmonary and endometrial tissues were analysed for lymphatic vessels to assess the process of lymphangiogenesis and its role at these sites, using specific immunostaining for LYVE-1 and the panendothelial marker CD31. RESULTS: Lymphatics were clearly demonstrated in some normal tissues (myometrium, bronchial submucosa, and intestinal submucosa), but not in others (endometrium and alveolar tissue). LYVE-1 positive lymphatic vessels were detected at the tumour periphery of endometrial and lung carcinomas, but not within the main tumour mass. Double staining for LYVE-1 and the MIB1 proliferation marker revealed a higher proliferation index in lymphatic endothelial cells at the invading front of endometrial carcinomas, compared with myometrial areas distal to the tumour. Lung and endometrial carcinomas did not have an intratumorous lymphatic network. CONCLUSIONS: Although lymphangiogenesis may occur at the invading tumour front, incorporated lymphatics do not survive. Therefore, the dissemination of cancer cells through the lymphatics may occur by invasion of peripheral cancer cells into the adjacent normal lymphatics, or through shunts eventually produced at the invading tumour front as a consequence of active angiogenesis and lymphangiogenesis.     

Expression of vascular endothelial growth factor (VEGF) and its two receptors (VEGF-R1-Flt1 and VEGF-R2-Flk1/KDR) in non-small cell lung carcinomas (NSCLCs): correlation with angiogenesis and survival

The formation of new vessels (angiogenesis) is essential for primary tumour growth and metastasis and is induced by several angiogenic factors, including vascular endothelial growth factor (VEGF). The microvascular density (MVD) in tumours was assessed and the expression of VEGF and its receptors VEGF-R1-Flt1 and VEGF-R2-KDR/Flk1 was investigated in the different cellular compartments in vivo, in order to establish their interrelationship and their prognostic influence. Immunohistochemical study of 69 stage I–II non-small cell lung carcinomas (NSCLCs) was performed on paraffin sections with CD34 antibody to estimate MVD, using a Chalkley eye-piece graticule and VEGF, VEGF-R1, and VEGF-R2 antibodies. There was strong expression of VEGF and its receptors in tumour cells, endothelial cells, and stromal fibroblasts. In tumour cells, the level of VEGF was correlated with that of VEGF-R1 ( p = 0·018) but not that of VEGF-R2. In fibroblasts, high expression of VEGF was correlated with that of VEGF-R1 ( p = 0·0001) and VEGF-R2 ( p = 0·0001). In endothelial cells, expression of VEGF was correlated with that of VEGF-R1 ( p < 0·0001) and VEGF-R2 ( p = 0·04). The level of VEGF in fibroblasts was correlated with that of VEGF-R1 ( p = 0·0028) and VEGF-R2 ( p = 0·01) in endothelial cells. There was no correlation between the level of MVD and that of VEGF or VEGF-R1 or VEGF-R2. Neither the level of MVD, nor the level of expression of VEGF and VEGF receptors in any compartment influenced the patient's survival. In conclusion, although angiogenesis is essential for tumour growth, this study failed to demonstrate that MVD, VEGF, VEGF-R1, and VEGF-R2 are prognostic markers for stage I–II NSCLC. VEGF, however, might act as a direct autocrine growth factor for tumour cells via VEGF-R1 and angiogenesis could be promoted in a paracrine loop, where VEGF is produced by fibroblasts and tumour cells and then binds to endothelial cells via induced VEGF receptors. VEGF and its receptors thus appear as relevant therapeutic targets in NSCLC. Copyright © 1999 John Wiley & Sons, Ltd.     

Granulocyte colony-stimulating factor promotes tumor angiogenesis via increasing circulating endothelial progenitor cells and Gr1+CD11b+ cells in cancer animal models

Recombinant granulocyte colony-stimulating factor (G-CSF) is used for cancer patients with myelosuppression induced by chemotherapy. G-CSF has been reported to progress tumor growth and angiogenesis, but the precise mechanism of tumor angiogenesis activated by G-CSF has not been fully clarified. N-terminal-mutated recombinant human G-CSF administration increased WBCs and neutrophils in peripheral blood and reduced bone marrow stromal cell-derived factor-1 in mice, indicating its biological relevance. Mice were inoculated with Lewis lung carcinoma cells (LLCs) or KLN205 cells and treated with G-CSF. G-CSF accelerated tumor growth and intratumoral vessel density, while it did not accelerate proliferation of LLCs, KLN205 cells or human umbilical vein endothelial cells in vitro. In the absence of tumors, G-CSF did not increase circulating cells that displayed phenotypic characteristics of endothelial progenitor cells (EPCs). In the presence of tumors, G-CSF increased circulating EPCs. In addition, G-CSF treatment increased immune suppressor and endothelial cell-differentiating Gr1+CD11b+ cells in tumor-bearing mice. We conclude that G-CSF promotes tumor growth by activating tumor angiogenesis via increasing circulating EPCs and Gr1+CD11b+ cells in cancer animal models.     

人脑胶质瘤中COX-2表达及其与血管新生关系

目的 检测COX-2、VEGF和CD34在人脑胶质瘤中的表达,探讨COX-2、VEGF与胶质瘤微血管密度及血管新生之间的关系及意义.方法 用免疫组化SP法检测80例胶质瘤及10例正常脑组织中COX-2、VEGF和CD34的表达.结果COX-2与VEGF阳性细胞在坏死区周围及血管密集的区域分布密集,80例胶质瘤中二者表达的阳性率分别为68.8%和72.5%,正常脑组织中无表达;COX-2、VEGF的表达与MVD之间成正相关(r=0.927,r=0.939,P<0.05),COX-2与VEGF的表达成正相关(r=0.885,P<0.05),胶质瘤病理级别与COX-2、VEGF、MVD之间均成正相关(r=0.894,r=0.927,r=0.865,P<0.05).结论 COX-2和VEGF在胶质瘤的生长和进展过程中发挥重要作用,与其恶性度关系密切;COX-2可能通过上调VEGF的表达促进肿瘤组织血管新生.     

Alterations of endothelin-converting enzyme expression in early and advanced stages of human coronary atherosclerosis

Endothelin-1 is a potent vasoconstrictor and exhibits a mitogenic activity on vascular smooth muscle cells (SMCs). Endothelin-converting enzyme (ECE) is the final key enzyme of endothelin-1 processing. We studied the immunolocalization of ECE in human coronary atherosclerotic lesions with different disease stages. Frozen sections of normal coronary arteries with diffuse intimal thickening (n=13) and those of coronary arteries with early (n=10) or advanced atherosclerotic plaques (n=13) were studied. Monoclonal antibodies used were directed against SMCs, macrophages, endothelial cells, and ECE. For the identification of cell types that express ECE, double immunostaining analysis was also used. In normal coronary arteries, ECE immunoreactivity was observed in luminal endothelial cells and medial SMCs. Early atherosclerotic plaques, which consisted predominantly of SMCs, showed enhanced ECE expression in luminal endothelial cells and intimal SMCs. In advanced atherosclerotic plaques, distinct ECE expression was found in accumulated macrophages and in endothelial cells of intraplaque microvessels, while luminal endothelial cells showed relatively weak immunoreactivity for ECE. In conclusion, the present study demonstrates that the major cell types expressing ECE within the plaques are different between early and advanced stages of human coronary atherosclerosis. Enhanced ECE expression and possible endothelin-1 generation may contribute to SMC proliferation and vasoconstriction in early atherosclerotic stages, and may promote plaque destabilization in advanced atherosclerotic stages.     

Angiogenesis is involved in the pathogenesis of nonrheumatic aortic valve stenosis

Angiogenesis is an essential biological process not only in embryogenesis, but also in the progression of several major diseases, including cancer, diabetes, and inflammation. Excessive vascularization can also contribute to some cardiovascular pathologies, such as atherosclerosis, but contradictory reports still prevail regarding its impact on aortic stenosis. Using immunohistochemical techniques, we assessed the vascular density and distribution of angiogenesis (FVIII) and vascular endothelial growth factor (VEGF) expression as well as the expression of 2 VEGF receptors, Flt-1 and Flk-1, in 55 nonrheumatic and 6 control aortic valves. In the light of the fact that the angiogenic effect of VEGF is mediated by sustained formation of nitric oxide, the samples were also immunostained with 3 nitric oxide synthase (eNOS, iNOS, and nNOS) antibodies. The immunohistochemical findings of VEGF and its receptors were verified by immunoblotting techniques. Vascular density was highest in the cases with moderate valve stenosis, and the mean number of FVIII-positive blood vessels was 1.7 +/- 1.9 vessels/mm(2) in the diseased valves, whereas the normal valves contained no blood vessels. Vascular density was significantly higher in the cases showing chronic inflammation (P = 0.007). Interestingly, the patients receiving statin therapy had significantly lower vascular densities than those not receiving such therapy (P = 0.001). Diseased valves showed distinct VEGF, Flt-1, Flk-1, and eNOS positivity of activated endothelial, stromal fusiform myofibroblastic, and histocytic cells. In contrast, immunoreactivity for iNOS and nNOS was seen only in nonendothelial stromal cells, and their expression was weaker. Enhanced vascular density was significantly associated with increased expression of Flk-1 (P = 0.028 for endothelial and P = 0.009 for stromal cells) and with endothelial eNOS expression (P = 0.024). A similar tendency was also observed for VEGF, but not for Flt-1. Our results show a distinct angiogenic response and the presence of angiogenic factors in nonrheumatic aortic valve stenosis, suggesting that angiogenesis may influence on the evolution of this disease.     

Angiogenesis in craniopharyngiomas: Microvascular density and tissue expression of the vascular endothelial growth factor (VEGF) and endostatin

Craniopharyngiomas are benign tumors of the sellar region generally associated with endocrine abnormality and often locally aggressive. Several studies have demonstrated that angiogenesis or neovascularization plays an important role in tumoral growth. The microvascular density (MVD) of craniopharyngiomas was determined in tumor tissue samples from a reference neurosurgery center located in southern Brazil using immunohistochemical methods for two endothelial markers, CD34 and CD105 (endoglin). In addition, tissue expression was determined for an angiogenesis stimulatory factor and for one of its inhibitors, the vascular endothelial growth factor (VEGF) and endostatin, respectively. Endothelial cell immunoreactivity for CD34 and CD105 was observed scattered within the stroma. MVD determined using CD105 antigen was significantly lower than the results obtained by using CD34 antigen. There was no association between the two endothelial markers and tumor extension. The epithelial component showed different degrees of immunoreactivity for VEGF and endostatin in all samples analyzed. We were not able to establish a relationship between angiogenesis in craniopharyngiomas and tumor extension with the endothelial markers used in this study. The investigated vascularization stimulatory and inhibitory factors showed no relation with MVD. We believe that CD105 antigen can be a more specific endothelial marker for tumor angiogenesis than CD34 antigen.     

Lymphangiogenesis in myocardial remodelling after infarction

AIMS: The lymphatic system is involved in fluid homeostasis of the cardiac interstitium, but lymphangiogenesis in myocardial remodelling has not previously been examined histopathologically. The aim was to investigate by D2-40 immunohistochemistry the sequential changes in lymphatic distribution in the process of myocardial remodelling after myocardial infarction (MI). METHODS AND RESULTS: Myocardial tissues in various phases of healing after MI were obtained from 40 autopsied hearts. D2-40+ lymphatic vessel density (LD) and CD34+ blood vessel density (BD) in the lesion were determined. BD decreased with advance of myocardial necrosis, subsequently increased at the early stage of granulation and thereafter decreased with the progression of scar formation. In contrast, lymphatic vessels were not detected in lesions with coagulation necrosis, and newly formed lymphatics first appeared in the early stages of granulation. A subsequent increase in LD was demonstrated in the late stages of granulation, and lymphatics remained up to the scar phase. Vascular endothelial growth factor-C was consistently expressed in viable cardiomyocytes around the lesion in all of these stages. CONCLUSION: In myocardial remodelling after MI, lymphangiogenesis lags behind blood vessel angiogenesis; newly formed lymphatics may be involved mainly in the maturation of fibrosis and scar formation through the drainage of excessive proteins and fluid.     

Localization of vascular endothelial growth factor-D in malignant melanoma suggests a role in tumour angiogenesis

Expression of angiogenic and lymphangiogenic factors by tumours may influence the route of metastatic spread. Vascular endothelial growth factor (VEGF) is a regulator of tumour angiogenesis, but studies of the inhibition of solid tumour growth by neutralizing anti-VEGF antibodies indicated that other angiogenic factors may be involved. VEGF-D may be an alternative regulator because like VEGF it is angiogenic and it activates VEGF receptor-2 (VEGFR-2), an endothelial cell receptor which is a key signalling molecule in tumour angiogenesis. This study reports the generation of monoclonal antibodies to the receptor-binding domain of VEGF-D and the use of these antibodies to localize VEGF-D in malignant melanoma. VEGF-D was detected in tumour cells and in vessels adjacent to immunopositive tumour cells, but not in vessels distant from the tumours. These findings are consistent with a model in which VEGF-D, secreted by tumour cells, activates endothelial cell receptors and thereby contributes to the regulation of tumour angiogenesis and possibly lymphangiogenesis. In addition, VEGF-D was detected in the vascular smooth muscle, but not the endothelium, of vessels in adult colon. The endothelium of these vessels was negative for VEGFR-2 and VEGFR-3. As VEGF receptors can be up-regulated on endothelium in response to vessel damage and ischaemia, these findings of a specific localization of VEGF-D in smooth muscle of the blood vessels suggest that VEGF-D produced by vascular smooth muscle could play a role in vascular repair by stimulating the proliferation of endothelial cells.     

Lymphatic endothelium-specific hyaluronan receptor LYVE-1 is expressed by stabilin-1+, F4/80+, CD11b+ macrophages in malignant tumours and wound healing tissue in vivo and in bone marrow cultures in vitro: implications for the assessment of lymphangiogenesis

Lymphangiogenesis is a novel prognostic parameter for several cancers that is preferentially quantified by immunohistochemistry of the lymphatic endothelium-specific hyaluronan receptor LYVE-1. Recently, the specificity of LYVE-1 was challenged by serendipitous observations of LYVE-1 expression in rare tissue macrophages. As expression of the hyaluronan receptor-like molecule stabilin-1 is shared by sinusoidal endothelium and macrophages, a thorough analysis of LYVE-1 expression was performed using macrophage-specific markers in vivo and in vitro. In murine tumour models and excisional wound healing, LYVE-1 expression occurred in a subset of CD11b(+), F4/80(+) tissue macrophages that preferentially co-expressed stabilin-1. Upon comparison of single- and double-labelling immunofluorescence, it became apparent that LYVE-1(+) macrophages mimic sprouting and collapsed lymphatic vessels. In vitro, LYVE-1 expression was induced in 25-40% of murine bone marrow-derived macrophages upon exposure to B16F1 melanoma-conditioned medium and IL-4/dexamethasone. By FACS analysis, 11.5% of bone marrow-derived macrophages were LYVE-1(+), stabilin-1(+) double-positive, while 9.9% were LYVE-1(+), stabilin-1(-) and 33.5% were LYVE-1(-), stabilin-1(+). Northern and western analyses confirmed expression of LYVE-1 mRNA and protein in bone marrow-derived macrophages. In the light of the current debate about true endothelial trans-differentiation versus endothelial mimicry of monocytes/macrophages, LYVE-1(+), stabilin-1(+) non-continuous endothelial-like macrophages will require further developmental and functional analyses. In conclusion, the findings imply that LYVE-1 staining must be supplemented by double labelling with macrophage markers in order to differentiate clearly between LYVE-1(+) lymphatics and LYVE-1(+) tumour-infiltrating macrophages. This improved approach will help to clarify the prognostic significance of lymphangiogenesis in malignant tumours.     

人喉癌组织中VEGF-C、VEGF-D及其受体3的表达及意义

目的 探讨喉癌组织中VEGF—C、D和受体VEGFR-3的表达及其在喉癌进展中的作用。方法 取人喉癌标本12例,正常及良性病变喉组织10例,免疫组化法观察VEGF—C、VEGF—D、VEGFR-3以及LYVE-1的表达。结果 VEGF—C和VEGF—D主要表达于喉癌细胞胞浆内,喉癌组织中VEGF—C和VEGF—D表达的阳性率明显高于正常及良性病变喉组织（P〈0．05）;VEGFR-3主要表达于基底层的癌细胞,在喉癌组织中VEGFR-3表达的阳性率明显高于正常和良性病变组织中（P〈0．01）,并且VEGFR-3的表达与VEGF—C、VEGF—D的表达显著正相关（P〈0．01）。LYVE—1仅见表达于淋巴管内皮细胞。结论 喉癌组织中VEGF—C、VEGP-D的表达明显增高,推测可能通过与VEGFR-3的结合促进喉癌组织中淋巴管的生成;LYVE-1是淋巴管内皮细胞较特异的标记物。     

血管内皮生长因子的生物学及其在临床的初步应用

血管内皮生长因子(VEGF)是内皮细胞特异性的有丝分裂原。它诱导内皮细胞增殖、促进内皮细胞迁移，并抑制内皮细胞凋亡，在调节血管和淋巴管新生中起重要作用。VEGF也是胚胎发育、软骨内骨形成、女性生殖系统、以及肿瘤和眼球内血管新生所必需的。另外，VEGF也可诱导血小板粘附于血管内皮细胞而出现高凝状态。目前，有许多临床实验正在评价VEGF在血管新生依赖性疾病的促血管新生作用和抗血管新生药物用于治疗的效果。     

LYVE-1, the lymphatic system and tumor lymphangiogenesis

Previous research into hyaluronan (HA) has focused on the role of this abundant tissue glycosaminoglycan in promoting cell migration through interactions with its transmembrane receptor CD44 on inflammatory leukocytes and tumor cells. The recent discovery of a new HA receptor, LYVE-1 (lymphatic vessel endothelial HA receptor), expressed predominantly in lymphatic vessels, highlights another aspect of HA biology: its continuous transit through the lymphatic system and its potential involvement in lymph node homing by CD44+ leukocytes and tumor cells. The functional role of LYVE-1 in lymphatic vessels and its application as a marker to study tumor lymphangiogenesis are important areas of investigation.     

Lymphangiogenesis and expression of specific molecules as lymphatic endothelial cell markers

In recent years, several functional molecules specifically expressed and localized in lymphatic endothelial cells, such as 5'-nucleotidase, lymphatic vessel endothelial receptor-1, vascular endothelial growth factor receptor-3, podoplanin and Prox-1, have been identified. The discovery of the lymphatic endothelial cell markers facilitated detailed analysis of the nature and structural organization of the lymphatic vessels and their growth (lymphangiogenesis). As a result, over the past few years, advances have been made in understanding the cellular and molecular aspects of physiological lymphangiogenesis and tumor-induced lymphangiogenesis. The biology of lymphangiogenesis, particularly the mechanism of its regulation, is very important in understanding the formation of the lymphatic system as a biological regulation system transporting tissue fluid and wandering cells, including lymphocytes, and disease involving lymphangiogenesis. The understanding of the molecular mechanism of lymphangiogenesis and the elucidation of the development of normal and pathological tissues are expected to lead to the development of therapy for intractable diseases, such as malignant tumors and lymphedema.