Optimization and regeneration kinetics of lymphatic-specific photodynamic therapy in the mouse dermis

Lymphatic vessels transport fluid, antigens, and immune cells to the lymph nodes to orchestrate adaptive immunity and maintain peripheral tolerance. Lymphangiogenesis has been associated with inflammation, cancer metastasis, autoimmunity, tolerance and transplant rejection, and thus, targeted lymphatic ablation is a potential therapeutic strategy for treating or preventing such events. Here we define conditions that lead to specific and local closure of the lymphatic vasculature using photodynamic therapy (PDT). Lymphatic-specific PDT was performed by irradiation of the photosensitizer verteporfin that effectively accumulates within collecting lymphatic vessels after local intradermal injection. We found that anti-lymphatic PDT induced necrosis of endothelial cells and pericytes, which preceded the functional occlusion of lymphatic collectors. This was specific to lymphatic vessels at low verteporfin dose, while higher doses also affected local blood vessels. In contrast, light dose (fluence) did not affect blood vessel perfusion, but did affect regeneration time of occluded lymphatic vessels. Lymphatic vessels eventually regenerated by recanalization of blocked collectors, with a characteristic hyperplasia of peri-lymphatic smooth muscle cells. The restoration of lymphatic function occurred with minimal remodeling of non-lymphatic tissue. Thus, anti-lymphatic PDT allows control of lymphatic ablation and regeneration by alteration of light fluence and photosensitizer dose.     

Lymphatic vessels: new targets for the treatment of inflammatory diseases

The lymphatic system plays an important role in the physiological control of the tissue fluid balance and in the initiation of immune responses. Recent studies have shown that lymphangiogenesis, the growth of new lymphatic vessels and/or the expansion of existing lymphatic vessels, is a characteristic feature of acute inflammatory reactions and of chronic inflammatory diseases. In these conditions, lymphatic vessel expansion occurs at the tissue level but also within the draining lymph nodes. Surprisingly, activation of lymphatic vessel function by delivery of vascular endothelial growth factor-C exerts anti-inflammatory effects in several models of cutaneous and joint inflammation. These effects are likely mediated by enhanced drainage of extravasated fluid and inflammatory cells, but also by lymphatic vessel-mediated modulation of immune responses. Although some of the underlying mechanisms are just beginning to be identified, lymphatic vessels have emerged as important targets for the development of new therapeutic strategies to treat inflammatory conditions. In this context, it is of great interest that some of the currently used anti-inflammatory drugs also potently activate lymphatic vessels.     

Differences in lymphatic and blood capillary permeability: ultrastructural-functional correlations

The major structural features of lymphatic capillaries, as they contrast with blood capillaries and as they pertain to endothelial permeability, are reviewed briefly with special emphasis on intrarenal vessels. The most characteristic structural feature of lymphatic endothelium is the discontinuity of the basal lamina. Basal laminae of blood vessels, such as renal glomerular capillaries, are prominent and are known to play a role in preventing extravasation of plasma proteins. By analogy, the lack of a basal lamina around lymphatic capillaries can be considered to be of major functional importance in facilitating access of interstitial macromolecules to the abluminal surface of endothelial cells and thus to the transport pathways that provide entry to the lymph. Tracer studies with horseradish peroxidase, for example, reveal that the protein enters the intraendothelial cytoplasmic vesicular system suggesting that this system may provide a transport pathway. Tracer is also seen between adjacent endothelial cells but in the kidney, liver and thyroid these intercellular channels comprise relatively narrow spaces of about 20 nanometers or less and do not form prominent gaps such as are seen in lymphatics of the diaphragm and skin. Evidence that macromolecular transport across endothelial cells may be asymmetric, favoring movement from interstitium to lymph, is derived from 1) studies using isolated perfused lymphatics, 2) differential luminal and abluminal membrane staining with cationic stains, 3) the presence of charged microdomains on lymphatic endothelial cell surfaces revealed with macromolecules of different charges, and 4) studies on cultured monolayers of porcine arterial endothelial cells.(ABSTRACT TRUNCATED AT 250 WORDS)     

Potential therapeutic strategies for lymphatic metastasis

Physiologically, the lymphatic system regulates fluid volume in the interstitium and provides a conduit for immune cells to travel to lymph nodes, but pathologically, the lymphatic system serves as a primary escape route for cancer cells. Lymphatic capillaries have a thin discontinuous basement membrane, lack pericyte coverage and often contain endothelial cell gaps that can be invaded by immune cells (or tumor cells). In addition, tumor cells and stromal cells in the tumor microenvironment secrete factors that stimulate lymphangiogenesis, the growth of lymphatic endothelial cells and the sprouting of lymphatic capillaries. As a result, many tumors are surrounded by large, hyperplastic, peri-tumoral lymphatic vessels and less frequently are invaded by intra-tumoral lymphatic vessels. Carcinoma cells commonly metastasize through these lymphatic vessels to regional lymph nodes. The presence of metastatic cells in the sentinel lymph node is a prognostic indicator for many types of cancer, and the degree of dissemination determines the therapeutic course of action. Lymphangiogenesis is currently at the frontier of metastasis research. Recent strides in this field have uncovered numerous signaling pathways specific for lymphatic endothelial cells and vascular endothelial cells. This review will provide an overview of tumor lymphangiogenesis and current strategies aimed at inhibiting lymphatic metastasis. Novel therapeutic approaches that target the tumor cells as well as the vascular and lymphatic endothelial compartments are discussed.     

Potential therapeutic strategies for lymphatic metastasis

Physiologically, the lymphatic system regulates fluid volume in the interstitium and provides a conduit for immune cells to travel to lymph nodes, but pathologically, the lymphatic system serves as a primary escape route for cancer cells. Lymphatic capillaries have a thin discontinuous basement membrane, lack pericyte coverage and often contain endothelial cell gaps that can be invaded by immune cells (or tumor cells). In addition, tumor cells and stromal cells in the tumor microenvironment secrete factors that stimulate lymphangiogenesis, the growth of lymphatic endothelial cells and the sprouting of lymphatic capillaries. As a result, many tumors are surrounded by large, hyperplastic, peri-tumoral lymphatic vessels and less frequently are invaded by intra-tumoral lymphatic vessels. Carcinoma cells commonly metastasize through these lymphatic vessels to regional lymph nodes. The presence of metastatic cells in the sentinel lymph node is a prognostic indicator for many types of cancer, and the degree of dissemination determines the therapeutic course of action. Lymphangiogenesis is currently at the frontier of metastasis research. Recent strides in this field have uncovered numerous signaling pathways specific for lymphatic endothelial cells and vascular endothelial cells. This review will provide an overview of tumor lymphangiogenesis and current strategies aimed at inhibiting lymphatic metastasis. Novel therapeutic approaches that target the tumor cells as well as the vascular and lymphatic endothelial compartments are discussed.     

淋巴管:干预动脉粥样硬化发生发展的潜在途径

动脉粥样硬化是一种慢性炎症性疾病,是血管壁对各种损伤的异常反应。虽然影响动脉粥样硬化的因素很多,但淋巴管在动脉粥样硬化中的作用一直被忽视。传统上认为淋巴管是将间质液回流至血液循环的通道。在早期的研究中,发现动脉粥样硬化周围存在大量淋巴管,但两者之间的关系一直不清楚。近期研究发现淋巴管不仅参与动脉炎症的起始和消退,在胆固醇逆转运中也发挥着积极作用。此外,改善淋巴功能或促进局部淋巴管生成似乎可以减轻动脉粥样硬化的进展。因此,研究淋巴管与动脉粥样硬化的关系对干预动脉粥样硬化的发生发展具有重要意义。文章介绍了淋巴管与动脉粥样硬化发生发展相关的炎症、胆固醇逆转运以及免疫等因素的关系,以期为动脉粥样硬化干预策略的研究提供新的视角。     

Characterization of a transformed ovine lymphatic endothelial cell line

OBJECTIVE: To develop a non-tumor-derived stable lymphatic endothelial cell line that exhibits rapid growth rate without serum and exogenous growth factors, while still maintaining key features characteristics of the non-transformed lymphatic endothelium. METHODS: Lymphatic endothelial cells were isolated from ovine mesenteric lymphatic vessels, grown to confluence and transfected with SV40 DNA using the calcium phosphate method. The resulting cell line was characterized using morphological, immunocytochemical, flow cytometric analysis, and immunoprecipatitation and Western blotting methods. RESULTS: The resulting cell line (sheep lymphatic endothelial transformed cell line, SLET-1) underwent rapid proliferation in the absence of growth factors and reduced concentrations of serum. In addition, key morphological and functional properties of the non-transformed lymphatic endothelium were retained. These include the ability to form confluent monolayer cultures, the expression of the lymphatic endothelial-specific VEGFR-3, FLT-4) tyrosine kinase receptor, the biosynthesis and secretion of von Willebrand factor and plasminogen activators. In addition, SLET-1 cells express cell surface antigens found on LEC that may act as antibody targets in various immune reactions. Monolayer cultures of the SLET-1 cells incubated with endothelial cell-growth factor formed tubular structures, indicating the retention of the capacity to differentiate. CONCLUSION: The SLET-1 cell line retained key morphological and functional properties characteristic of the non-transformed lymphatic endothelium. The ability to form capillary-like tubular structures provides an important cell line for defining the role of specific proteins that are involved in the lymphagiogenic (formation of new lymphatic vessels) process. Thus, this transformed lymphatic endothelial cell line provides an in citro model that may have widespread utility in studying regulatory mechanisms of lymphatic endothelial cell function and differentiation.     

Topography and ultrastructure of kidney lymphatics in some hibernating bats

The kidney lymphatic system of some bats consists of intraparenchymal (interlobar, arcuate, and interlobular) and extraparenchymal vessels (capsular and prehilar connective). These vessels drain lymph via precollecting and prenodal collecting lymphatics into a hilar lymph node. There are no lymphatics in the renal medulla. The lymphatic vasculature (precollecting vessels excluded) is characterized by an endothelial wall lacking basal lamina and fenestrations. The endothelial cells, mostly rectangular in shape, are joined together by overlapping, end-to-end, and complex interdigitating junctions. Cytoplasmic expansions profile and thickness, intercellular junctions and particularly the different categories of uncoated vesicles (free or opened on luminal or abluminal surface) show qualitative and quantitative seasonal variations. Luminal and abluminal cytoplasmic processes appear (when analyzed in tridimensional reconstructions) as "intraendothelial channels." The increased number of these structures during summer characterizes them as dynamic elements and supports the concept of an active role played by them in transendothelial transport. Nevertheless, the main functional role is still ascribed (in addition to membrane transport mechanisms) to the vesicular system, also defined as the "vesicular route." We did not find any open intercellular junctions.     

Lymphatic biology and the microcirculation: past, present and future

Because of the role that lymphatics have in fluid and macromolecular exchange, lymphatic function has been tightly tied to the study of the microcirculation for decades. Despite this, our understanding of many basic tenets of lymphatic function is far behind that of the blood vascular system. This is in part due to the difficulty inherent in working in small, thin-walled, clear lymphatic vessels and the relative lack of lymphatic specific molecular/cellular markers. The application of cellular and molecular tools to the field of lymphatic biology has recently produced some significant developments in lymphatic endothelial cell biology. These have propelled our understanding of lymphangiogenesis and related fields forward. Whereas the use of some of these techniques in lymphatic muscle biology has somewhat lagged behind those in the endothelium, recent developments in lymphatic muscle contractile and electrical physiology have also led to advances in our understanding of lymphatic transport function, particularly in the regulation of the intrinsic lymph pump. However, much work remains to be done. This paper reviews significant developments in lymphatic biology and discusses areas where further development of lymphatic biology via classical, cellular, and molecular approaches is needed to significantly advance our understanding of lymphatic physiology.     

Investigating lymphangiogenesis in vitro and in vivo using engineered human lymphatic vessel networks

The lymphatic system is involved in various biological processes, including fluid transport from the interstitium into the venous circulation, lipid absorption, and immune cell trafficking. Despite its critical role in homeostasis, lymphangiogenesis (lymphatic vessel formation) is less widely studied than its counterpart, angiogenesis (blood vessel formation). Although the incorporation of lymphatic vasculature in engineered tissues or organoids would enable more precise mimicry of native tissue, few studies have focused on creating engineered tissues containing lymphatic vessels. Here, we populated thick collagen sheets with human lymphatic endothelial cells, combined with supporting cells and blood endothelial cells, and examined lymphangiogenesis within the resulting constructs. Our model required just a few days to develop a functional lymphatic vessel network, in contrast to other reported models requiring several weeks. Coculture of lymphatic endothelial cells with the appropriate supporting cells and intact PDGFR-β signaling proved essential for the lymphangiogenesis process. Additionally, subjecting the constructs to cyclic stretch enabled the creation of complex muscle tissue aligned with the lymphatic and blood vessel networks, more precisely biomimicking native tissue. Interestingly, the response of developing lymphatic vessels to tensile forces was different from that of blood vessels; while blood vessels oriented perpendicularly to the stretch direction, lymphatic vessels mostly oriented in parallel to the stretch direction. Implantation of the engineered lymphatic constructs into a mouse abdominal wall muscle resulted in anastomosis between host and implant lymphatic vasculatures, demonstrating the engineered construct''s potential functionality in vivo. Overall, this model provides a potential platform for investigating lymphangiogenesis and lymphatic disease mechanisms.

The lymphatic and blood vascular systems are two distinct vessel network systems that work in synchrony to maintain tissue homeostasis. Blood vessels transport oxygen and nutrients around the body, while lymphatic vessels collect leaked fluid and macromolecules from the interstitial space and return them to the blood circulation, maintaining interstitial fluid homeostasis (1). Furthermore, the lymphatic system plays a central role in immune responses, inflammation regulation, and lipid absorption (2). While many in vitro models have been created to study angiogenesis, fewer attempts have been made to engineer an in vitro platform to study lymphangiogenesis. Such engineered models are critical for both fundamental research and the development of clinically implantable tissue to treat various diseases involving the lymphatic system. One such disease is lymphedema, a chronic condition that affects 200 million people worldwide (3). Lymphedema is characterized by tissue swelling resulting from a compromised lymphatic system. The condition is mainly caused by complications during cancer treatment but may also develop due to genetic disorders. The condition is progressive and incurable, with a high risk of infection. Implantation of engineered lymphatic tissue can serve as a treatment for such disease (4).Lymph flow is primarily driven by pressures generated by lymphatic contractions of the smooth muscle cells surrounding the vessels (5). Impaired contractility thus reduces lymph flow and may cause lymphedema. Previous computational studies have investigated the correlation between lymphatic vessel contractility and mechanical stimulation, such as mechanical loading, pressure gradients, and shear stress amplitudes (6, 7). Furthermore, studies have investigated lymphatic vessel capacity to distend under mechanical loading conditions. In addition, the microenvironment composition has been shown to play an important role in enabling lymphatic vessel functionality (4).Thus far, several groups have been able to engineer lymphatic tissues. Marino et al. created dermo-epidermal skin grafts with lymphatic and blood vessels embedded in a fibrin-collagen gel (8). Others created a lymphatic vessel network within multilayered fibroblast sheets (9, 10). Another study demonstrated that different hydrogel compositions are required for the optimal growth and development of blood and lymphatic endothelial cells (BECs and LECs, respectively) (11). However, no studies have investigated the influence of the supporting cells, the secreted extracellular matrix (ECM), and the mechanical environment on the forming lymphatic vessels. Since lymphatic pathologies are known to correlate with mechanically impaired lymphatic vessels (4), it is important to create lymphatic models with a biomimetic microenvironment.In this study, lymphatic vessel networks were engineered to investigate fundamental questions concerning lymphangiogenesis, including the influence of different supporting cells on the formation of lymphatic vessels and the role of PDGFR-β, an important receptor associated with support cells recruitment, in vessel formation. In addition, a complex tissue designed to better mimic native tissue was generated and lymphatic and blood vessel development along with muscle formation were monitored. In addition, the impact of the application of cyclic stretch on the organization and alignment of lymphatic-blood-vessel-muscle tissue was assessed. Finally, the penetration and anastomosis of the engineered lymphatic vessels were monitored following their implantation into mice.     

淋巴管生成的分子机制与恶性肿瘤的转移

长期以来一直认为淋巴管是恶性肿瘤转移的有效途径;但是,关于淋巴管内皮细胞的特异性标记物缺乏一致的资料,而且,恶性肿瘤内是否存在新生淋巴管也一直有争议。直到最近,发现了新的淋巴管内皮细胞标记物,在肿瘤的动物模型以及人类肿瘤中均发现了新生淋巴管,对于VEGF-C、D／VEGFR-3信号途径的深入了解,因此淋巴管生成在肿瘤转移中的相关研究得以深入进行。越来越多的研究资料表明,淋巴管生成同肿瘤的转移播散、肿瘤患者的预后等直接相关。现将淋巴管生成的分子机制以及其与肿瘤转移的相关研究进展综述。     

Immunohistochemical analysis of VEGF-C/VEGFR-3 system and lymphatic vessel extent in normal and adenomatous human pituitary tissues.

The angiogenic growth factor Vascular Endothelial Growth Factor-C (VEGF-C) and its receptor VEGFR-3 are also known to be implicated in the development of lymphatic vessels. We assessed the expression of VEGF-C and VEGFR-3, together with blood and lymphatic vessel extents and proliferation index (PI) values, by immunohistochemistry (IHC) in 6 normal human pituitary glands and 53 pituitary adenomas of different tumour grade, on consecutive tissue sections. VEGF-C was detected in around 10% of the endocrine cells in normal pituitary tissue, while this gland was devoid of lymphatic vascularization and showed very few vessels positive for VEGFR-3. Concerning tumour tissue, most of the adenomas showing VEGF-C immunoreactivity (21/47) were positive in 60% of the tumour cells and the ones positive for VEGFR-3 showed a number of immunostained vessels higher than those observed in the normal pituitary. Most of the tumours positive for VEGFR-3 did not show any LYVE-1 positive vessels (18/53), suggesting that at least in these cases, VEGFR-3 is expressed on blood vessels. Nevertheless, we observed a significant association between low expression of VEGFR-3 and low lymphatic vessel number, suggesting that VEGFR-3 might be involved in the starting of DE NOVO lymphangiogenesis in this tumour type. Moreover, tumours bearing lymphatic vessels showed the tendency to shift towards a more aggressive behaviour (high tumour grade and high PI). In conclusion, the VEGF-C/VEGFR-3 system might be involved in controlling tumour angiogenesis in the pituitary adenomas lacking lymphatic vessels, but may also play a role in starting the process of tumour lymphangiogenesis.     

Prox1-GFP/Flt1-DsRed transgenic mice: an animal model for simultaneous live imaging of angiogenesis and lymphangiogenesis

The roles of angiogenesis in development, health, and disease have been studied extensively; however, the studies related to lymphatic system are limited due to the difficulty in observing colorless lymphatic vessels. But recently, with the improved technique, the relative importance of the lymphatic system is just being revealed. We bred transgenic mice in which lymphatic endothelial cells express GFP (Prox1-GFP) with mice in which vascular endothelial cells express DsRed (Flt1-DsRed) to generate Prox1-GFP/Flt1-DsRed (PGFD) mice. The inherent fluorescence of blood and lymphatic vessels allows for direct visualization of blood and lymphatic vessels in various organs via confocal and two-photon microscopy and the formation, branching, and regression of both vessel types in the same live mouse cornea throughout an experimental time course. PGFD mice were bred with CDh5CreERT2 and VEGFR2lox knockout mice to examine specific knockouts. These studies showed a novel role for vascular endothelial cell VEGFR2 in regulating VEGFC-induced corneal lymphangiogenesis. Conditional deletion of vascular endothelial VEGFR2 abolished VEGFA- and VEGFC-induced corneal lymphangiogenesis. These results demonstrate the potential use of the PGFD mouse as a powerful animal model for studying angiogenesis and lymphangiogenesis.     

Focal adhesion molecules expression and fibrillin deposition by lymphatic and blood vessel endothelial cells in culture

The microfibrils of anchoring filaments, a typical ultrastructural feature of initial lymphatic vessels, consist mainly of fibrillin and are similar to the microfibrils of elastic fibers. As we previously demonstrated, they radiate from focal adhesions of lymphatic endothelium to the perivascular elastic network. Although present in large blood vessels, fibrillin microfibrils have never been detected in blood capillaries. Here we report immunohistochemical evidence that cultured bovine aortic and lymphatic endothelial cells express fibrillin microfibrils. These microfibrils form an irregular web in lymphatic endothelial cells, whereas in blood vessel endothelial cells they are arranged in a honeycomb pattern. Cultured lymphatic and blood vessel endothelial cells also produce focal adhesion molecules: focal adhesion kinase, vinculin, talin, and cytoskeletal beta-actin. Our data suggest that anchoring filaments of initial lymphatic vessels in vivo may be produced by endothelium. Through their connection with focal adhesions, they may form a mechanical anchorage for the thin wall of initial lymphatic vessels and a transduction device for mechanical signals from the extracellular matrix into biochemical signals in endothelial cells. The complex anchoring filaments-focal adhesions may control the permeability of lymphatic endothelium and finely adjust lymph formation to the physiological conditions of the extracellular matrix. The different deposition of fibrillin microfibrils in blood vessel endothelial cells may be related to the necessity of withstanding shear forces. Thus, in our opinion, differences in fibrillin deposition imply a different role of fibrillin in blood vessel and lymphatic endothelium.     

Mechanical forces and lymphatic transport

This review examines the current understanding of how the lymphatic vessel network can optimize lymph flow in response to various mechanical forces. Lymphatics are organized as a vascular tree, with blind-ended initial lymphatics, precollectors, prenodal collecting lymphatics, lymph nodes, postnodal collecting lymphatics and the larger trunks (thoracic duct and right lymph duct) that connect to the subclavian veins. The formation of lymph from interstitial fluid depends heavily on oscillating pressure gradients to drive fluid into initial lymphatics. Collecting lymphatics are segmented vessels with unidirectional valves, with each segment, called a lymphangion, possessing an intrinsic pumping mechanism. The lymphangions propel lymph forward against a hydrostatic pressure gradient. Fluid is returned to the central circulation both at lymph nodes and via the larger lymphatic trunks. Several recent developments are discussed, including evidence for the active role of endothelial cells in lymph formation; recent developments on how inflow pressure, outflow pressure, and shear stress affect the pump function of the lymphangion; lymphatic valve gating mechanisms; collecting lymphatic permeability; and current interpretations of the molecular mechanisms within lymphatic endothelial cells and smooth muscle. An improved understanding of the physiological mechanisms by which lymphatic vessels sense mechanical stimuli, integrate the information, and generate the appropriate response is key for determining the pathogenesis of lymphatic insufficiency and developing treatments for lymphedema.     

Impaired lymphatic contraction associated with immunosuppression

To trigger an effective immune response, antigen and antigen-presenting cells travel to the lymph nodes via collecting lymphatic vessels. However, our understanding of the regulation of collecting lymphatic vessel function and lymph transport is limited. To dissect the molecular control of lymphatic function, we developed a unique mouse model that allows intravital imaging of autonomous lymphatic vessel contraction. Using this method, we demonstrated that endothelial nitric oxide synthase (eNOS) in lymphatic endothelial cells is required for robust lymphatic contractions under physiological conditions. By contrast, under inflammatory conditions, inducible NOS (iNOS)-expressing CD11b(+)Gr-1(+) cells attenuate lymphatic contraction. This inhibition of lymphatic contraction was associated with a reduction in the response to antigen in a model of immune-induced multiple sclerosis. These results suggest the suppression of lymphatic function by the CD11b(+)Gr-1(+) cells as a potential mechanism of self-protection from autoreactive responses during on-going inflammation. The central role for nitric oxide also suggests that other diseases such as cancer and infection may also mediate lymphatic contraction and thus immune response. Our unique method allows the study of lymphatic function and its molecular regulation during inflammation, lymphedema, and lymphatic metastasis.     

Lack of functioning lymphatics and accumulation of tissue fluid/lymph in interstitial "lakes" in colon cancer tissue

There is controversy as to whether intratumoral or peritumoral lymphatics play a dominant role in the metastatic process. The knowledge of how and where exactly tumor cells enter lymphatics is important for therapeutic targeting either the tumor core or peritumoral tissue with drugs or radiation. The basic questions remain: what is the morphological structure of intra- and peritumoral interstitium and lymphatics; what is their hydraulic conductivity?; and do these local physical conditions allow detached tumor cells to migrate to lymphatics? Identification of lymphatics has been based on immunohistochemical staining of lymphatic endothelial cells. This method does not, however, show the tissue fluid filled interstitial space and the shape of minute lymphatic vessels in tumors. We visualized the interstitial space and lymphatics in the central and peripheral regions of tumors using our original method of color stereoscopic lymphography in translucent tissue fragments and simultaneously with immunohistochemical staining of lymphatic and blood endothelial cells. The density of open and compressed lymphatic and blood vessels was measured in the intratumoral "hot spots" and at tumor edge. Moreover, the intratumoral tissue hydraulic conductivity was measured to define force necessary for propelling tissue fluid to peritumoral lymphatics. We found very few rudimentary minor blind lymphatics in the tumor core and numerous minor fluid "lakes" in the interstitium with no visible connection to the peritumoral lymphatics. Lining of "lakes" did not express molecular markers specific for lymphatic endothelial cells. Ninety-five percent of structures of what looked like lymphatics had compressed lumen and the hydraulic conductivity was 3 powers of magnitude lower than in the adjacent non-tumoral tissue. It can be concluded that lack of functioning lymphatics in tumor foci manifested by accumulation of tissue fluid in "lakes," low fluid conductivity and compression of lymphatics by tumor cells, and proliferating connective tissue may hamper escape of tumor cells. The most favorable site of entry of tumor cells to lymphatics seems to be the interface of the tumor and surrounding tissue with open lymphatics.     

Vascular endothelial cell specification in health and disease

There are two vascular networks in mammals that coordinately function as the main supply and drainage systems of the body. The blood vasculature carries oxygen, nutrients, circulating cells, and soluble factors to and from every tissue. The lymphatic vasculature maintains interstitial fluid homeostasis, transports hematopoietic cells for immune surveillance, and absorbs fat from the gastrointestinal tract. These vascular systems consist of highly organized networks of specialized vessels including arteries, veins, capillaries, and lymphatic vessels that exhibit different structures and cellular composition enabling distinct functions. All vessels are composed of an inner layer of endothelial cells that are in direct contact with the circulating fluid; therefore, they are the first responders to circulating factors. However, endothelial cells are not homogenous; rather, they are a heterogenous population of specialized cells perfectly designed for the physiological demands of the vessel they constitute. This review provides an overview of the current knowledge of the specification of arterial, venous, capillary, and lymphatic endothelial cell identities during vascular development. We also discuss how the dysregulation of these processes can lead to vascular malformations, and therapeutic approaches that have been developed for their treatment.

     

Light and electron microscopy of the structural organization of the tissue-lymphatic fluid drainage system in the mesentery: an experimental study

Supplementing vital microscopy and histophysiology, we examined using combined light and electron microscopy the tissue fluid-lymphatic drainage system of the mesentery isolated from guinea pigs, rabbits, and tree shrews. In silver impregnated tissue, different types of lymphatics and blood vessels were able to be distinguished along with argyrophilic and argyrophobic structures in the connective tissue. Some initial lymphatic pathways were interrupted by non-endothelialized tissue zones thus forming separate but discrete vascular "islands". After carbon labeling of the lymphatic collectors, carbon particles were seen to escape from the initial lymphatic lumen at various sites. Electron microscopy revealed wide apertures in the lymphatic endothelial cells of these microvessels. These morphological findings support the concept of an "open" prelymphatic-lymphatic system in the mesentery. The special histometrical features exhibited by a flat membranous organ like the mesentery are discussed in terms of physiologic function of mesenteric tissue fluid transport.