I. INTRODUCTION TO ANGIOGENESIS AND LYMPHANGIOGENESIS

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Embryonic vascular development involves a complex series of events during which the endothelial cells differentiate, proliferate, migrate, and undergo maturation into an organized network of vessels (176, 177). The first step in the development of the blood vessels is called vasculogenesis, which is the process where endothelial cells are generated from their mesenchymal precursors and spontaneously assemble into tubules that fuse to form the primary vascular plexus of the embryo. Remodeling and expansion of these primary vessels into arteries, veins, and capillaries of different sizes is called angiogenesis. Although, by definition, vasculogenesis precedes angiogenesis, in practice the two processes continue in parallel during early development. Tissues that are vascularized by vasculogenesis are generally of endodermal origin (lung, pancreas, spleen, heart, and large blood vessels), while tissues of ectodermal and mesodermal derivation (such as the kidney and the brain) are vascularized primarily via angiogenesis.

The oxygen and nutrients supplied by the vascular system are crucial for cell function and survival. In fact, the cardiovascular system is the first organ system to develop in embryos, supplying oxygen and nutrients to the growing tissues. During organogenesis, the proximity of growing cells to the circulation is ensured by the coordinated growth of blood vessels and organ parenchyma. At the same time that the blood vessels form, the precardiac myoblasts develop by differentiating from the mesothelial cells and form the heart (179). On day 9 of mouse embryonic development (E9), the heart starts to beat and blood starts to circulate through the newly formed network of vessels (147). In the yolk sac blood islands, mesenchymal cells give rise to both endothelial and hematopoietic cells (37). These cells organize into clusters consisting of future endothelial cells in the outer layer surrounding hematopoietic cells. The endothelial cells then coalesce with those of the neighboring blood islands to form a primitive honeycomb-like blood vessel network, and the hematopoietic cells differentiate into erythrocytes. Later, hematopoiesis resumes in the embryo in the para-aortic region (AGM region) and in the fetal liver and finally in the bone marrow.

A complex orchestration of molecular regulators is needed for the blood vessels to grow. The vasculature begins as a plexus of primitive capillary tubes that are subsequently modified to generate the more complex vascular network of adults. Sprouting of new vessels from preexisting ones is the most frequent mechanism of angiogenesis in embryos, and it involves several sequential steps (223). First, the extracellular matrix components surrounding the endothelial cells are degraded locally by proteases produced by the endothelial cells. This allows the chemotactic migration of endothelial cells toward angiogenic stimuli. Subsequently, the endothelial cells in the midsection of the new vessels proliferate and form a lumen, and adjacent sprouts anastomose and form loops, which become perfused with circulating blood. The loops between the vessels can also form by another mechanism called intussusceptive growth, a form of angiogenesis involving the in situ remodeling of the vessels by protruding interstitial tissue columns. In this process, a large sinusoidal capillary can be divided into smaller capillaries, which then grow separately (176).

Although endothelial cells initiate angiogenesis, they cannot complete the process. Newly formed capillary sprouts are fragile and remain susceptible to remodeling as long as they lack appropriate perivascular structures. The maturation of new blood vessels into stable and functional vessels requires the accumulation of a basal lamina and recruitment of pericytes and smooth muscle cells to cover tightly the abluminal side of the vessel (Fig. 1) (93). The smooth muscle cells provide structural support to the larger vessels protecting the vessels against rupture and are important regulators of blood flow and pressure by their contractile abilities (22). Pericytes are absent or only loosely attached to vessels undergoing angiogenesis, suggesting that the mural cells stabilize nascent vessels by inhibiting endothelial cell proliferation and migration and by stimulating extracellular matrix production (19). Under certain conditions the pericytes support endothelial cell survival, for example, in the neonatal retina during hyperoxia-induced regression of the retinal vessels, where associated pericytes spare some of the vascular branches (19).

View larger version (33K): [in this window] [in a new window]   Fig. 1. Receptor binding specificity of vascular endothelial growth factors (VEGFs). VEGFR-1 and VEGFR-2 mediate growth factor signals for blood vascular endothelial cells, whereas VEGFR-3 mainly regulates lymphatic endothelial cells. Neuropilin (NRP)-2 has recently been shown to be coexpressed with VEGFR-3 in the lymphatic endothelium, and VEGFR-2 has occasionally been detected in lymphatic endothelial cells. The permeability of blood vessels is tightly controlled, whereas lymphatic vessels have interendothelial openings that allow relatively free import of fluid and macromolecules. Note that the lymphatic vessels are attached to the interstitial matrix via specific anchoring filaments (af). PlGF, placenta growth factor.

Smooth muscle cells are separated from the endothelial cells by a basement membrane and thus are not in direct contact with the endothelium. In contrast, the pericytes share their basement membrane with the endothelial cells and make direct contact with them through holes in the basement membrane. In sites where selective filtration is required, like in the kidney glomeruli and lung parenchyma, pericytes are selectively positioned to allow the fluid or gas exchange. Pericytes and smooth muscle cells may be derived from the mesenchyme variously by in situ differentiation, trans-differentiation from endothelial cells, from bone-marrow precursors or macrophages, soon after the endothelial cells have formed tubes. Like the endothelial cells, they proliferate and migrate in parallel to the growth of the vascular plexus (19, 37).

The vascular system is a highly heterogeneous and nonuniform organ system. It consists of an arterial and a venous system that differ structurally and functionally. It has been proposed that establishment of the identities of the arterial and venous vasculatures is under the control of related but distinct genetic programs (75, 218, 230). Endothelial cells differ considerably in the arterial, capillary, and venous compartments, and there is further heterogeneity in the different organs (47). Recent molecular probing of the endothelial cell surface by phage display library panning in vivo has revealed striking molecular specificity for the availability of molecular determinants in different vascular endothelia (182). Endothelial cells in different vessels have distinct characteristics, such as fenestrations, cell junctions, enzymes, and carrier systems. For example, fenestrated endothelia are seen in places where extensive molecular exchange occurs across the blood vessel wall, such as in endocrine glands, choroid plexus, and kidney. Differentiation of endothelial cells is dependent on interactions with local parenchymal cells in the target tissues. Although it is not always known which cell type induces the organotypic differentiation of endothelial cells, the existence of such cell-cell interactions seems to be widely accepted.

Angiogenesis is also required for the maintenance of the functional and structural integrity of tissues during postnatal life. Vasculogenesis is mainly restricted to early development, while new vessels in adults appear to be formed by angiogenesis (37). However, adults are apparently able to mobilize bone marrow-derived endothelial precursor cells for angiogenesis (174). In healthy adults, the endothelial cell turnover is usually very low, and the vascular endothelia are maintained in quiescence by a balance of positive and negative regulators of angiogenesis. Angiogenesis is limited to sites where the metabolic demands of the tissue are such that new blood vessels are needed. In wound healing, fracture repair, inflammation, folliculogenesis, and ovulation during the menstrual cycle, as well as in situations of ischemia, the positive regulators predominate, leading to the activation of angiogenic mechanisms (67). Cells suffering from hypoxia start to release angiogenic factors to establish better contact with the circulating blood. Metabolic stimuli, including hypoglycemia and low pH, also participate in the induction of vessel growth, but these mechanisms are less well known. In contrast to developmental angiogenesis, angiogenesis in adults originates mostly in mature blood vessels. In embryos, endothelial cells are loosely connected and actively growing, whereas in adults they are quiescent and encapsulated by a thick mural coat. Therefore, the blood vessels must first become destabilized to allow new growth. A carefully orchestrated activation of several signaling molecules is needed, which may differ in different tissues (37). In contrast to angiogenesis in embryos, there is often inflammation associated with adult angiogenesis, attracting monocytes/macrophages, platelets, mast cells, and other leukocytes.

Angiogenesis results in a higher capillary density, but also the larger vessels are modified by the lack of an adequate oxygen supply. In the case of acute or chronic occlusion of a major artery (coronary, femoral artery), preexisting arteriolar connections can be recruited by arteriogenic mechanisms to bypass the site of occlusion (37). Arteriogenesis produces rapid circumferential growth in the preexisting collateral vessels, which are less perfused with blood under normal flow conditions. These vessels have the ability to dramatically increase their lumen by proliferation of endothelial and smooth muscle cells (33). Recent findings suggest that endothelial precursors in the adult bone marrow also contribute to the expansion of preexisting collaterals (40). As a result of the increased collateral flow, endothelial cells recruit monocytes, which are capable of remodeling the media of the vessel wall. Activated endothelial cells then induce the regrowth of smooth muscle cells in the vessel wall. The smooth muscle cells synthesize a new elastic lamina to the enlarged collaterals. Once the mural cells have been recruited into the vessels, they further muscularize the nascent vasculature by sprouting or by migrating longitudinally along preexisting vessels. After a couple of months the new collateral artery is almost indistinguishable from a normal artery (37). Arteriogenesis differs from angiogenesis in several aspects, but the two processes also share certain mechanisms. For example, angiogenic factors, like fibroblast growth factor (FGF), can activate both mechanisms, but angiogenesis is induced by hypoxia whereas main driving force in arteriogenesis is inflammation (33). Arteriogenesis can counteract the damage in ischemic tissues, such as heart, brain, or limbs, and growth factors that are involved in the arteriogenesis hold great promise for treatment of patients with ischemic diseases, especially those that are poor candidates for mechanical revascularization or bypass surgery.

One of the most extensively studied forms of pathological angiogenesis is tumor angiogenesis (68). Like normal cells, tumor cells need to be located at a close distance from the blood vessels serving the metabolic demands of the growing tumor. The stage in tumor development when a solid tumor grows beyond a few millimeters in diameter and starts to generate its own microcirculation is called the angiogenic switch (70). It means the transition of an avascular tumor to a tumor with its own blood supply. At this stage the endothelial cells transit from a quiescent into an angiogenic state; the positive regulators are induced. Negative regulators can also decrease; for example, trombospondin levels decrease in tumors upon loss of the p53 tumor suppressor gene (28, 91).

Tumor blood vessels are leaky and immature, at least partly because the pericytes and smooth muscle cells are usually poorly recruited to the tumors. The vessels are multilayered, protrude extensions bridging and splitting vessels, contain intercellular and transcellular holes, show relatively uncontrolled permeability, and undergo constant remodeling (68). These vessels resemble angiogenic vessels in other settings, such as in wound healing, with the exception that tumor vessels do not mature properly. Tumor angiogenesis is said to resemble a physiological response that is initiated but not terminated and is considerably more chaotic (53). Occasionally some of the endothelial cells in the tumor vessels are replaced by tumor cells, forming so-called mosaic blood vessels (44). Angiogenesis also takes place in other pathological conditions such as proliferative retinopathy, rheumatoid arthritis, psoriasis, and juvenile hemangioma (67).

Lymphatic vessels are also part of the vascular circulatory system. The lymphatic system is made up of an extensive network of capillaries, collecting vessels, and ducts that permeate most of the organs (183). Unlike the blood vasculature which forms a continuous loop, the lymphatic system is an open ended, one-way transit system. These vessels collect the extravasated protein-rich fluid and lymphocytes from the tissues and transport them back into the circulation. From the lymphatic capillaries, the fluid is transferred to the collecting lymphatic vessels and ultimately into the venous circulation via the thoracic duct. Larger lymphatic vessels are surrounded by a muscular layer that contracts automatically when the vessel becomes stretched with fluid. In addition, external factors such as skeletal muscle contractions or arterial pulsation compresses the vessels and increases the efficiency of fluid transport.

In tissue sections, lymphatics resemble blood vessels but are generally thinner walled and more irregular. Lymphatics have a low intraluminal pressure and contain a bloodless fluid called lymph, which consists of interstitial tissue fluid, macromolecules, and cells (227). The lymphatic vessels were discovered in 1627 by Gasparo Asellius (11), at about the same time that the blood circulation was described by William Harvey (89). However, compared with blood vascular studies, the lymphatic system has remained relatively neglected until the present day. This has been partly due to the difficulties in recognizing these vessels in tissues, due to a lack of specific markers. The only way of differentiating the lymphatic vessels has been based on morphology in histological samples and infusions of colored dyes, contrast agents, or macromolecules into the tissues. However, within the past few years molecules expressed specifically in the lymphatic endothelial cells have been found.

The lymphatic vessels also form part of the immune system by continuously transporting the white blood cells within the lymphoid organs (spleen, tonsils, thymus, Peyer patches, and lymph nodes) and bone marrow and transporting antigen-presenting cells. Mononuclear phagocytes and also lymphocytes patroling the tissues enter the afferent lymph vessels and the lymph nodes to elicit primary immune responses before reentering the vasculature. Endothelial receptors and binding proteins are involved in this trafficking of specific lymphatic cell populations.

Lymphatic vessels start to develop in embryos around midgestation, in parallel with the development of blood vessels and most of the organs. When the embryo grows, these vessels are needed for the regulation of the interstitial tissue pressure. The origin of the lymphatic vessels has long been controversial. Historically, the best accepted view of lymphatic development is the one proposed by Sabin (184, 185). On the basis of the findings from her injection experiments, Sabin proposed that early in fetal development, isolated primitive lymph sacs originate by endothelial cell budding from embryonic veins. The two jugular lymph sacs develop from the junction of the subclavian and anterior cardinal veins. Later in the development, the rest of the lymph sacs originate from the mesonephric veins, the veins of the Wolffian bodies, the primitive inferior vena cava and the junctions of the primitive iliac veins and the posterior cardinal veins. Sabin's model proposes that the peripherial lymphatic system then spreads from these primary lymph sacs by endothelial sprouting into the surrounding tissues and organs where local lymphatic capillaries form.

An alternative model has suggested that the initial lymph sacs arise in the mesenchyme from precursor cells ("lymphangioblasts"), independent of the veins and secondarily establish venous connections (97). Although recent reports about the development of the lymphatic vessels support Sabin's theory (52, 222), the existence of primitive lymphangioblasts, which can be recruited by the developing lymphatic vessels, has been shown at least in avian species (189). One should thus note that a combination of the two mechanisms is possible, whereby centrifugally sprouting lymphatic vessels anastomose with lymphatics developing from lymphangioblasts in tissues.

The lymphatic vessels differ in many ways from the blood vessels, but they also share many properties. Both vascular systems are lined by the endothelium, and the larger vessels are supported by a smooth muscle framework, particularly around luminal valves, which are present in the veins and in the large lymphatics (227). Both have vasa vasorum, the blood vessel network providing nutrition for the vessel wall. The smooth muscle layer in blood vessels controls the contractile tone of the vessels in response to vasoactive substances. Blood vessels have a continuous or fenestrated basement membrane and tight interendothelial junctions, which make the vessel wall selectively permeable to cells, fluids, and molecules, whereas lymphatic vessels have a relatively free import for interstitial fluid. Lymphatic endothelial cells have complex overlapping intercellular junctions and specialized anchoring filaments, which hold the vessel open as tissue pressure rises (227). It has been suggested that these properties provide the lymphatics a second valvular function, which permits fluid to enter from the interstitium into the initial lymph channels but prevents escape back out into the tissue (210). Liquid, macromolecules, and migrating cells pass through the blood capillary endothelia, enter the tissues, and are gradually absorbed into the lymphatic system. The fluid is transported via the lymphatic capillaries into the collecting vessels and through the lymph nodes, returning eventually to the circulation.

The blood vascular endothelium is a relatively leak-proof, nonthrombogenic surface, with tightly regulated flow and intraluminal pressure, whereas the lymphatics in contrast are a low flow, a low-pressure system in close contact with the extracellular matrix. Lymph fluid does not contain red blood cells or platelets and is therefore much less coagulable than blood. The large lymphatic vessels with their smooth muscle have intrinsic contractility, which serves as a critical pumping force transporting lymph centrally toward the great veins. Compared with blood capillaries, the lymphatic capillaries send out fewer sprouts, anastomose less frequently, and show much less tendency to retract than undergo changes in size or form (227).

After the discovery of specific molecules regulating the lymphatic vessels, their role in certain pathological conditions has been extensively studied. Abnormal function of the lymphatic vessels is implicated in diseases such as lymphedema, inflammation, infectious and immune diseases, fibrosis, ascites, and tumors such as Kaposi's sarcoma and lymphangioma/lymphangiomatosis. Perhaps most importantly, the lymphatic vessels are involved in tumor metastasis (reviewed in Refs. 110, 167). The identification of factors that promote tumor lymphangiogenesis and may promote the growth and spread of tumors via the lymphatic system is important for the development of new, effective treatments for cancer (108, 110, 145, 197, 201).

	II. MOLECULAR REGULATION OF BLOOD AND LYMPHATIC VESSELS

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Intercellular signaling mechanisms that govern the formation of blood and lymphatic vessels have emerged relatively recently. The complexity of endothelial cell development indicates that its regulation must involve many developmental and tissue-specific differentiation factors. Angiogenic signals are mediated by a number of growth factors and cytokines, and the balance between the positive and negative regulators maintains the adult vessels in a quiescent state (reviewed in Ref. 87). Whenever the balance is disturbed, the vessels react either by activating the angiogenic responses or regress by apoptosis when sufficient growth signals are not present. Interaction of angiogenic growth factors with their target cells triggers a cascade of steps, leading to the formation of blood vessels. Less is known about the regulation of the lymphatic vessels, although similar mechanisms seem to be involved.

Blood vessel development depends on members of the vascular endothelial growth factor (VEGF) family of proteins (Fig. 1). This family consists of VEGF, VEGF-B, VEGF-C, VEGF-D, VEGF-E, and placenta growth factor (PlGF), which bind and activate cell surface receptor tyrosine kinases. Key signals regulating embryonic cell growth and differentiation, as well as remodeling and regulation of adult tissues, are mediated by the tyrosine kinase receptors (75, 109). The VEGF receptor (VEGFR) family includes VEGFR-1 (also known as Flt-1), VEGFR-2 (Flk-1), and VEGFR-3 (Flt4). Neuropilins 1 and 2 (NRP-1/-2) are another class of high-affinity nontyrosine kinase receptors for VEGFs on endothelial and neuronal cell surfaces (157, 169). Recently, additional molecules similar to VEGF and capable of increasing capillary permeability were found in snake venom, suggesting that the family may be even larger (79, 120). The receptors have partly overlapping but independent roles in the vascular development and maintenance, and the expression level of these genes modulates the abundance of different types of vessels in tissues. Other factors that are involved in the regulation of blood and lymphatic vessels are the angiopoietins and Tie-receptors, ephrins, and platelet-derived growth factors (PDGFs), which all act together in a coordinated manner during vessel formation (23, 37, 75). Interestingly, certain highly differentiated endothelia may have additional structurally unrelated regulators, such as EG-VEGF (127).

The regulation of blood vessels has been studied extensively over the past 10 years, but the molecular mechanisms behind lymphatic vessel growth have only been studied since 1995, when VEGFR-3, the first specific growth factor receptor of the lymphatic vessels, was found (105). Thereafter, a wealth of new information about the regulation of the growth of the lymphatics has been gained, and the factors known to regulate blood vessels have also been shown to be involved in the biology of the lymphatic vessels. Angiogenesis and lymphangiogenesis are thought to occur in parallel during embryonic development, and both may be important in adult physiological and pathological conditions. It is thus essential to understand the development and regulation of blood vessels to understand the biology of the lymphatic vessels. One must also consider blood and lymphatic vessels as collaborating parts of the circulatory system.

VEGF, discovered in 1989, is a major mediator of both vasculogenesis and angiogenesis (reviewed in Ref. 61). In endothelial cells, VEGF mediates mitogenic signals by activating VEGFR-1 and VEGFR-2 (62). VEGF is expressed as several isoforms consisting of polypeptides of different sizes (121, 145, 165, 183, 189 and 206 amino acid residues), which are all formed from the same gene by alternative splicing and differ in their ability to interact with extracellular matrix components and with NRP-1 (114, 130, 199, 209). These isoforms are thought to have distinct but overlapping functions in angiogenesis. VEGF is also known as vascular permeability factor, as it promotes the extravasation of fluid and plasma proteins, including fibrin, from the blood vessels (54, 190). The increase in microvascular permeability and tissue deposition of fibrin is considered to enhance the migration of endothelial cells in the extracellular matrix (55).

Two independent studies have shown that VEGF is essential for embryonic vasculogenesis and angiogenesis. Inactivation of only a single VEGF allele in mice resulted in embryonic lethality due to defective angiogenesis (38, 64). Also a reduced number of hematopoietic cells was observed. In mutant mice lacking the 164 and 188 amino acid isoforms of VEGF, one-half of the mice did not survive due to defects in, for example, postnatal angiogenesis in the myocardium, suggesting that the other forms of VEGF cannot completely replace the action of the others (42). Further studies suggest that in particular the heparin binding VEGF isoforms are required for efficient angiogenic sprouting and vascular morphogenesis (D. Shima, personal communication). Partial inhibition of VEGF by a soluble extracellular form of VEGFR-1 resulted in increased mortality and impaired organ development in the early postnatal period (81). It was shown that in addition to proliferation VEGF is also required for the survival of endothelial cells. Consistent with this, other studies have also shown that VEGF supports the survival in endothelial cells and induces the expression of antiapoptotic proteins in endothelial cells (7, 18, 82).

VEGF is a major regulator of abnormal angiogenesis (reviewed in Ref. 61). Consistent with this, the expression of VEGF is potentiated in response to hypoxia and by activated oncogenes as well as by a variety of cytokines (85, 175, 193). VEGF is important in the etiology of several diseases characterized by pathological angiogenesis such as psoriasis, rheumatoid arthritis, and proliferative retinopathy. Deregulated VEGF expression contributes to the development of solid tumors by promoting tumor angiogenesis (67). Tumor inhibition studies with neutralizing anti-VEGF antibodies suggest that other angiogenic factors may also be involved (117). However, the VEGF signaling pathway is currently considered to be one of the most promising targets for the inhibition of tumor angiogenesis.

VEGF-B is structurally closely related to VEGF and binds one of its receptors, VEGFR-1 (155). It has two splice variants of which the 167 amino acid form binds to heparan sulfates and NRP-1, while the other, of 186 amino acid residues, is a freely secreted, soluble, and O-glycosylated product (143). If the 186 amino acid form is proteolytically cleaved, NRP-1 binding epitopes are exposed in this isoform as well. Both VEGF-B isoforms are able to form heterodimers with VEGF, and perhaps with other growth factors. This adds diversity to their biological roles by allowing a variety of combinations for cellular signal transduction. During development, VEGF-B may modulate the biological activities of VEGF, either by forming heterodimers or by controlling the bioavailability of VEGF (156).

VEGF-B is produced in large quantities by the developing myocardium and by muscle, bone, pancreas, adrenal gland, and the smooth muscle cell layer of several large vessels, but not by endothelial cells (1). VEGF-B is likely to act in a paracrine fashion as its receptor is almost exclusively located on endothelial cells. VEGF-B is a very weak endothelial cell mitogen when produced in mammalian cells (155), but otherwise its biological role is still unclear. It is possible that some of the biological activity of VEGF-B produced in mammalian cells can be attributed to VEGF/VEGF-B heterodimers.

Mice lacking a functional VEGF-B gene are healthy and fertile, but depending on the genetic background may have a first degree heart block (conduction defect) or reduced heart size (2, 17). The knockout mice display a striking vascular dysfunction after coronary occlusion, and they show impaired recovery from experimentally induced myocardial ischemia (17). Considering such results, it is interesting to note that while VEGFR-1 and VEGFR-2 were expressed rather uniformly in the developing vasculature, only VEGFR-1 was prominently expressed in the human fetal coronary endothelium (166). These results suggest a role for VEGF-B in the coronary vasculature and potential clinical use in therapeutic angiogenesis.

PlGF was discovered in the human placenta, and it is ~50% homologous to VEGF (139). Three splice isoforms of PlGF have been published, and PlGF-2 at least competes with VEGF₁₆₅ for binding to VEGFR-1 (35, 140, 163). This is considered to increase the proportion of VEGF available to activate VEGFR-2, thereby potentiating the angiogenic properties of VEGF (163). A lack of PlGF has no effect on embryonic development, even in combination with a loss of VEGF-B (41). However, loss of PlGF impairs angiogenesis associated with tumors, ischemia, myocardial infarcts, and experimental retinopathy and leads to prolonged healing of incisional skin wounds (41). During collateral growth after ligation of the femoral artery, PlGF was found to be essential for plasma extravasation, monocyte recruitment, and the growth of endothelial and smooth muscle cells. These results indicate that PlGF activates membrane-bound VEGFR-1 and specifically potentiates the angiogenic response to VEGF. In contrast to the essential role of VEGF in physiological and pathological angiogenesis, the role of PlGF is restricted to pathological vessel formation and is therefore a possible target for therapy.

PlGF is not needed to enhance VEGF signaling in embryonic vascular development. This is probably because VEGF is upregulated in response to a lack of PlGF. This suggests that PlGF serves as an inert regulator of the VEGF activity during development. The need for amplification of VEGF responses in adult pathological angiogenesis might be explained by the requirement of stronger responses to VEGF than in embryonic angiogenesis (41). When new blood vessels form in adults, endothelial cells may become more responsive to VEGF by upregulating PlGF and VEGFR-1. PlGF and VEGFR-1 are minimally expressed in normal quiescent adult vasculature, but both are markedly upregulated in pathological conditions. Also, the membrane localization of VEGFR-1 is increased in pathological angiogenesis compared with embryonic angiogenesis. PlGF is also a chemoattractant for inflammatory cells, which are hallmarks of pathological angiogenesis and collateral growth. PlGF may contribute to vessel growth in adults by mobilizing bone marrow-derived mononuclear cells. There may also be a synergism between PlGF and VEGF-B in pathological angiogenesis.

VEGF-C was cloned from human prostate carcinoma cells, and its mature form consisting of the VEGF homology domain is 30% identical to VEGF₁₆₅ (101). VEGF-C is synthesized as a preproprotein and from which a stepwise proteolytic processing generates several forms, with sequentially increasing binding and activity for its receptors, VEGFR-2 and VEGFR-3 (102). Like VEGF, VEGF-C stimulates the migration of endothelial cells and increases vascular permeability and endothelial cell proliferation but at higher concentrations than VEGF. These signals for endothelial cells are probably mediated through VEGFR-2 in blood vascular endothelial cells, and generally via VEGFR-3 in the lymphatic endothelial cells (102, 105). Unlike VEGF, the expression of VEGF-C does not appear to be regulated by hypoxia (58) but is increased in response to proinflammatory cytokines, suggesting a role in inflammatory responses (178). VEGF-C, along with VEGFR-3, is also prominently expressed by activated macrophages (196; S. Mustjoki, personal communication). The pattern of VEGF-C expression in embryos suggests that it plays a role in the development of the lymphatic vessels, since a paracrine expression pattern is seen between VEGF-C and VEGFR-3 at sites where the first lymphatic sprouts occur (123). Conversely, VEGF-C is already expressed before the emergence of the lymphatics, which also suggests its involvement in vasculogenesis/angiogenesis during early development.

VEGF-C can regulate physiological and pathological blood vessel growth in vivo. It is able to stimulate angiogenesis in the mouse cornea and in the hindlimb ischemia model (36, 228). On the other hand, VEGF-C has been shown to regulate the growth of lymphatic vessels in various experimental models. Overexpression of VEGF-C in skin keratinocytes leads to dermal lymphatic vessel hyperplasia (Fig. 2, A and B) (100). Signaling via VEGFR-3 alone was shown to be sufficient for the hyperplasia, since transgenic mice overexpressing a mutant form of VEGF-C, which has lost its capacity to bind VEGFR-2 and only binds and activates VEGFR-3 (VEGF-C156S), was able to induce a similar phenotype (216). VEGF-C was also studied in the mature, differentiated chorioallantoic membrane (CAM), which contains lymphatic vessels mainly around arterioles and veins (154). In this assay, VEGF-C acts as a highly specific lymphangiogenic factor. However, when VEGF-C was applied to the early CAM, where the lymphatics have not yet developed, it promoted angiogenesis. The angiogenic versus lymphangiogenic responses to VEGF-C may depend on the degree of proteolytic processing of its precursor and on the expression of it receptors in the blood versus lymphatic endothelial cells of the target tissue. VEGF-C also has synergistic effects with VEGF, during the induction of angiogenesis, and this effect is more prominent in cells expressing both of its receptors (168). In addition, VEGF-C can compete with VEGF in binding to VEGFR-2.

View larger version (107K): [in this window] [in a new window]   Fig. 2. Lymphatic vessels in adult tissues. Overexpression of VEGF-C in the skin keratinocytes in K14-VEGF-C transgenic mice leads to hyperplasia of lymphatic vessels around the hair follicles (hf) (A), compared with the skin of wild-type mice (B). The lymphatic endothelium is visualized by immunohistochemical staining for VEGFR-3 (arrows). Lymphatic vessels in the skin (C) and pericardium (D) of the VEGFR-3-LacZ mice are shown. Lectin perfusion-stained blood vessels appear brown in C. Scale bar in D is for A-D; A and B, 50 µm; C, 30 µm; D, 600 µm.

VEGF-D (also known as c-fos-induced growth factor or FIGF) is the most recently discovered member of the mammalian VEGF family (3). It shares 61% sequence identity with VEGF-C, and these two growth factors bind to the same receptors on human endothelial cells. VEGF-D is proteolytically processed similarly to VEGF-C, and the proteolytic processing also appears to regulate VEGF-D biological activity and receptor specificity (202). Interestingly, in mice, VEGF-D binds only to VEGFR-3, suggesting that VEGF-D may have a somewhat different function in mouse and human (12). This is uncommon within the VEGF family as these homologous and evolutionary conserved growth factors are assumed to exhibit similar receptor binding characteristics in different species.

VEGF-D has been shown to be able to stimulate the proliferation of endothelial cells, and it shows angiogenic properties in vitro and in vivo (146). Like VEGF-C, it was also shown to be lymphangiogenic when overexpressed in skin keratinocytes (216). Little is known about the expression of VEGF-D in physiological conditions, but its mRNA has been observed in the developing melanocytes and fibroblasts, lung mesenchyme, and the adult vascular wall (4).

The exact roles of VEGF-C and VEGF-D during embryonic vascular development are still unknown due to the lack of gene deletion studies. In adults, VEGF-C and VEGF-D may regulate the responses of the lymphatic vessels in inflammatory processes and in the regeneration of tissues after trauma, but they may also have important roles in physiological and pathological angiogenesis in various conditions. VEGF-C and VEGF-D may also affect the fluid dynamics in lymphatic vessels and be involved in the formation of valves and recruitment of smooth muscle cells to the developing lymphatic collecting vessels. Unpublished data indicate that VEGF-C and VEGF-D can heterodimerize (M. Jeltsch, personal communication), as has been reported for PlGF and VEGF as well as VEGF-B and VEGF, making their biological properties even more diverse (34, 156).

A VEGF homolog, VEGF-E, was recently discovered in the genome of the parapoxvirus, Orf virus, that infects sheep, goats, and occasionally humans (138). Infection by this virus causes proliferative skin lesions in which extensive capillary proliferation and dilation are prominent histological features. Several strains of the virus encode different VEGF-E variants, which bind specifically to VEGFR-2 and NRP-1 and are able to stimulate endothelial cell mitogenesis and vascular permeability (153, 225). VEGF-E is not essential for viral replication but rather plays an important role in modulating the host environment during infection.

All VEGFRs are characterized by seven extracellular immunoglobulin homology domains (Ig) (Fig. 1), of which the second and third are critical for ligand binding and the first three domains are necessary for establishment of full binding affinity (15, 49, 73, 142). In VEGFR-3, the fifth Ig homology domain is proteolytically cleaved, but the fragments remain together via disulfide bonds. These receptors control many aspects of vascular growth and have partially overlapping expression patterns in the developing vasculature in embryos but show a more restricted expression in adults.

VEGFR-1 and VEGFR-2 are important in blood vascular endothelial cell proliferation, migration, and survival. Mice carrying a homozygous disruption in either of the two VEGF receptors die during early development due to defects in both vasculogenesis and angiogenesis. Embryos lacking functional VEGFR-2 die without mature endothelial or hematopoietic cells (191). Primitive hematopoietic and endothelial progenitors arise normally within the yolk sac blood islands from precursors cells that express VEGFR-2. In contrast, VEGFR-1-deficient mice have normal hematopoietic progenitor cells and endothelial cells that migrate and proliferate but do not assemble into tubes and functional vessels (71). More recent studies have shown that an excessive proliferation of endothelial progenitors is the main factor leading to this disorganization (72). This supports the view that VEGFR-1 is a negative regulator of VEGF-induced vasculogenesis in embryos.

Although VEGFR-1 alone has been shown to induce weak mitogenic signals in vitro (125), it is thought that VEGFR-2 is the major receptor transducing the effects of VEGF in endothelial cells. For example, VEGF-E and site-directed mutants of VEGF, which bind only to VEGFR-2, stimulate endothelial cells similarly to VEGF (82, 116, 148, 225). VEGF also provides survival signals for endothelial cells via VEGFR-2 (82). Outside of the vascular system, VEGFR-1 is expressed in monocytes and macrophages, placental throphoblasts and renal mesangial cells, and VEGFR-2 in hematopoietic stem cells, megakaryocytes, and platelets and retinal progenitor cells (14, 45, 46, 112, 232). Despite the importance of these receptors during embryonic blood vessel development, VEGFR-1 and VEGFR-2 appear to be downregulated in the quiescent adult endothelium.

VEGFR-3 was cloned from a human leukemia cell line and human placenta (76, 161). Two isoforms of VEGFR-3 have been described, designated VEGFR-3s (short) and VEGFR-3l (long), which differ as a result of alternative splicing. The long form is the predominant form in most tissues. An endogenous retroviral genome appears responsible for the short isoform in humans, but this form is missing from mice (96). In adults, the expression of VEGFR-3 is mainly restricted to lymphatic endothelial cells and in hematopoietic cells of monocytic lineage, where it serves as a molecular marker for these vessels (Fig. 2, C and D) (103, 105). In embryos VEGFR-3 is initially expressed in all vasculature, but during development its expression in blood vessels decreases and becomes restricted to the developing lymphatic vessels (Fig. 3) (105). VEGFR-3-deficient embryos die as a result of a defect in the remodeling of the primary vascular network and cardiovascular failure at midgestation, before the lymphatic vessels start to develop (52). Interestingly, the differentiation of endothelial cells, the formation of the primary vascular plexus, and vascular sprouting were not disturbed by the absence of VEGFR-3 signaling, but the embryos had severe anemia due to impaired yolk sac hematopoiesis (86). These results suggest that VEGFR-3 plays a dual role, in embryos in cardiovascular development before the emergence of the lymphatic vessels and in adults in the regulation of the lymphatic vessels.

View larger version (70K): [in this window] [in a new window]   Fig. 3. VEGFR-3 expression during the development of the lymphatic vessels. Blood vascular and lymphatic vessels can be visualized in stained sections from VEGFR-3 knock-out heterozygous embryos (VEGFR-3-LacZ), in which the marker gene reveals sites of VEGFR-3 expression (blue). Early in mouse development (embryonic day 9.5, E9.5) VEGFR-3 is expressed uniformly in the whole developing vasculature (A). After the blood vessels have been established, the VEGFR-3-positive lymphatic vessels (arrow) start to sprout from preexisting veins (B). Later, VEGFR-3 expression is further downregulated in the blood vessels (arrowhead in C) and becomes restricted to the lymphatic vessels (arrow in C). The lymphatic vessel network in the skin of E15.5 mouse embryo is shown in whole mount staining (D). Scale bar in D is for A-D; A, 30 µm; B, 100 µm; C, 125 µm; D, 80 µm.

The majority of blood vessel endothelial cell populations around midgestation are positive for both VEGFR-2 and VEGFR-3, suggesting that these receptors have essential roles in angiogenesis (86). Also, VEGFR-1 is seen in the developing vasculature at this stage (71). Endothelial cells are apparently activated by both VEGF and VEGF-C at this stage, but it is not known whether these receptors transduce similar signals. The VEGF/VEGFR-2 system appears to be responsible for most of the growth signals for vascular endothelial cells, but it has also been proposed that VEGF-C induces proliferation of embryonic vascular endothelial cells through VEGFR-2. VEGF-C signaling through VEGFR-2 and VEGFR-3 may thus have distinct roles in embryogenic vasculogenesis (86). In addition, in VEGF-deficient mice, some endothelial cells survive, and this may be promoted by VEGF-C.

In adults, VEGFR-3 is expressed in a subset of capillary endothelia, although it is absent in endothelia of all large blood vessels (165). Although lymphatic vessels develop from large veins in the embryonic jugular, retroperitoneal, and perimesonephric regions, only a few adult tissues retain VEGFR-3 expression in the venous endothelia. Such endothelia are seen in the veins of the cartilage channels, vertebral bodies, venous canals of the adrenal medulla, and the splenic venous sinuses (165). Differences in VEGFR-3 expression are also seen between continuous and discontinuous endothelia, the former being negative and the latter positive for VEGFR-3, suggesting that this receptor plays a role in the endothelial transport functions in fenestrated capillaries. VEGFR-2 is also present in the fenestrated endothelia, and it is possible that VEGF-C and VEGF-D secreted by the neuroendocrine cells signal via both receptors in this specific subtype of capillaries in endocrine organs. VEGFR-3 is seen also in endothelia at sites of hematopoiesis or blood cell trafficking, such as in the sinusoids of liver, spleen, and bone marrow, suggesting that it has a regulatory role in the transendothelial translocation of hematopoietic cells (165). Also some nonendothelial expression of VEGFR-3 has been observed in embryonic notochordal cells and in the trophoblasts of the placenta (165, 224).

VEGFR-3 is activated in the blood vessel endothelium in certain pathological conditions, and upregulation of VEGF-C/VEGF-D ligands may accompany this (4, 186, 214). Similarly, VEGFR-2 can be expressed by both blood vascular and lymphatic endothelia (166). During wound healing, acute inflammation is followed by the deposition of fibrin and connective tissue and the growth of blood vessels into the granulation tissue. Most blood vessels then regress as the wound is remodeled into scar tissue. VEGFR-3-positive lymphatic vessels have been observed to sprout from preexisting lymphatics and grow into the granulation tissue in healing skin wounds (160). These lymphatic vessels persisted in the wound for some time but regressed as the healing proceeded. This suggests that transient lymphangiogenesis is needed during wound healing, in parallel with angiogenesis, and it is possible that inflammatory cells such as macrophages secrete relevant lymphangiogenic factors. On the other hand, no lymphatic vessels were seen in chronic human wounds (160). The absence of lymphatic vessels may contribute to the impaired healing in these conditions. The angiogenic vessels in wound healing remained negative for VEGFR-3, suggesting that there are differences in the regulation of angiogenesis in various pathological conditions.

Little is known about the characteristic features of lymphatic endothelial cells, mainly because isolated lymphatic endothelial cells have not been available for molecular studies. Recently, primary cultures of human dermal endothelial cells were shown to consist of distinct lines of blood vascular and lymphatic endothelial cells (Fig. 4) (121, 144). Cells of the lymphatic lineage could be isolated by antibodies against VEGFR-3 or podoplanin, another marker for lymphatic endothelium. Signaling via VEGFR-3 was shown to be critical for growth, migration, and survival of the isolated lymphatic endothelial cells (144). Also, VEGFR-2 was detected in the lymphatic endothelial cells, suggesting that activation of both VEGF-C receptors may be required for their maximal survival (144, 166). The isolation and culturing of lymphatic endothelial cells now allow more detailed studies of the molecular properties of these interesting cells.

View larger version (42K): [in this window] [in a new window]   Fig. 4. Cultured microvascular endothelium consists of blood vascular and lymphatic endothelial cells. A subpopulation of cultured human primary microvascular endothelial cells was positive for the lymphatic endothelial cell markers VEGFR-3 (A) and podoplanin (B). The cells were also stained for nuclear DNA using the Hoechst33258 fluorochrome (C). The specific lymphatic cell surface antigens allow the isolation and culturing of stable lineages of lymphatic and blood vascular endothelial cell populations and further studies of the molecular properties of these cells (144). Scale bar in C is for A-C, 160 µm.

NRP-1 and NRP-2 are transmembrane receptor proteins that are required for axon guidance and, according to recent discoveries, also for the regulation of angiogenesis (83, 198, 199). Both neuropilins bind certain isoforms of VEGF, VEGF-E, PlGF-2, and VEGF-B (143, 149, 199, 225). NRP-1 is expressed in the tips of actively growing axons of particular classes of neurons (74), but also in the blood vascular endothelial cells and in certain tumor cells (198, 199). NRP-1 enhances VEGF₁₆₅ binding to VEGFR-2 and VEGF-mediated chemotaxis. Embryos lacking functional NRP-1 die due to defects in VEGF-mediated angiogenesis and subsequent cardiovascular failure (113), and ectopic overexpression of NRP-1 leads to an excess of dilated blood vessels and hemorrhage, apparently due to inappropriate VEGF activity (119). Recently, NRP-2 has been shown to bind VEGF-C and to be expressed together with VEGFR-3 in the endothelial cells of a subpopulation of the lymphatic vessels (106).

Tie-1 and Tie-2 (Tek) are expressed in endothelial cells throughout embryonic development as well as in hematopoietic progenitor cells (50). Gene targeting experiments indicate that Tie-1 and Tie-2 are essential to the angiogenic expansion of the vasculature during development. In mouse embryos lacking the Tie-2 receptor, endothelial cells are present in slightly reduced numbers and are assembled into tubes, but the vessels remain immature, lacking branching networks and proper organization into a hierarchy of large and small vessels (51, 187). The vessels lack intimate encapsulation by periendothelial support cells, and the endocardium is only loosely attached to the myocardium. Thus Tie-2 appears to control the capability of endothelial cells to recruit stromal cells, which stabilize the vessel structure and modulate the function of blood vessels (87). Tie-1 is required cell autonomously for endothelial cell survival and extension of the vascular network during the later part of embryogenesis (173, 187). Vasculogenesis proceeds normally in embryos lacking both Tie-1 and Tie-2, since the angioblasts differentiate normally (172). It appears that one of the earliest critical functions of these receptors concerns endocardial development but that rescue of the embryos is possible if one bypasses the critical period using transgenic expression of Tie-2 (D. Dumont, personal communication).

Angiopoietin (Ang)-1 and Ang-2 bind to Tie-2 with similar affinities, but only Ang-1 can activate the receptor directly. Ang-2 is capable of inhibiting the effects of Ang-1 in endothelial cells in short-term experiments. However, if endothelial cells of human umbilical vein are stimulated with Ang-2 for longer periods, activation of the Tie-2 receptor is obtained (206). Ang-2 is also capable of stimulating Tie-2 in transfected nonendothelial cells. Thus Ang-2 has both agonistic and antagonistic properties, which may relate to its ability to dimerize or oligomerize less efficiently than Ang-1, or to binding to an inhibitor that needs to be downregulated.

Ang-1 is widely expressed in both embryonic and adult tissues (205). Ang-2 is also expressed in embryos around large vessels, but in adults the expression pattern is restricted to sites of physiological angiogenesis, where vascular remodeling occurs (141). Transgenic overexpression of Ang-2 under the Tie-2 promoter in the embryonic endothelium indicates that Ang-2 inhibits the recruitment of supporting perivascular cells, resulting in a phenotype similar to that of the Ang-1 knockout embryos (205). In adults, Ang-2 allows vascular remodeling, which otherwise is restricted by encapsulation by the basement membrane and periendothelial support cells. When the expression of Ang-1 overcomes that of Ang-2, such remodeling ceases and vessels stabilize (reviewed in Ref. 75).

Several lines of evidence indicate that there is significant collaboration between VEGF, Ang-2, and Ang-1 in angiogenic processes. Vascular regression is associated with very high levels of Ang-2 in the absence of activating survival signals from VEGF. In the skin of transgenic mice, VEGF increases the number of capillaries, whereas Ang-1 causes a massive enlargement of postcapillary venules (208). Interestingly, Ang-1 was able to prevent the permeability effects of VEGF (207). Coexpression of both factors was required to obtain an increased number of large vessels in transgenic mice. Surprisingly, a combinatorial function of Ang-1 and Tie-1 was critical for the development of the right-side venous system, but not for the left-side venous system (135). Identification of the ligand(s) for the Tie-1 receptor should provide further insights into the mechanistic basis for this asymmetric regulation of vascular development. Ang-2 may also be involved in the regulation of lymphatic vessels, since knock-out mice lacking functional Ang-2 have chylous ascites with a disorganized and leaky lymphatic vasculature (G. Thurston and G. Yancopoulos, personal communication).

The PDGF family consists of homodimers or heterodimers made from the pairwise assembly of the related PDGF polypeptide chains (reviewed in Ref. 92). These effects of the PDGFs depend on the target cell type, in particular on the cell's repertoire of PDGF receptors. The dimeric, active receptors consist of - and -subtypes of the PDGF tyrosine kinase receptor. The -receptor can bind PDGF-A, PDGF-B, and PDGF-C chains, whereas the -receptor is selective for the PDGF-B and PDGF-D chains (21, 23, 132). On the basis of the gene-deficient studies, both receptors are essential for embryonic development. PDGF-A and PDGFR- are prominently expressed at sites of epithelium-mesenchyme interaction, whereas PDGF-B takes part in blood vessel development (94, 133, 159). PDGF-D is the first known PDGFR--specific ligand, and its unique receptor specificity indicates that it may be important in the development and pathophysiology of several organs. The expression of PDGF-C and PDGF-D in the arterial wall and cultured vascular cells suggests that they can transduce proliferation/migration signals to pericytes and smooth muscle cells (213). The expression patterns of PDGF-A and PDGF-C are compatible with overlapping functions, but the situation with PDGF-B and PDGF-D is not that well characterized yet.

The association of supporting smooth muscle cells or pericytes with angiogenic vessels has been suggested to regulate endothelial proliferation, survival, sprouting, and differentiation. During blood vessel development, PDGF-B is expressed in endothelial cells, while pericytes and smooth muscle cells covering the blood vessels express PDGFR-, indicating paracrine signaling between these two cell types (94, 133). Targeted gene deletion studies of PDGF-B or PDGFR- gave similar phenotypes. In both mouse strains, blood vessel development was deficient because of the inability of blood vessels to attract pericytes (93, 94, 133). Also the development of the renal and hematopoietic systems was affected (131, 200). Lack of pericytes in embryonic angiogenesis led to hyperplasia of endothelial cells, supporting the notion that pericytes inhibit endothelial cell proliferation (93).

Smooth muscle cell proliferation in response to the release of growth factors from neighboring cells is one mechanism postulated to account for the development of atherosclerotic lesions. PDGFs may be involved in initiation and progression of atherosclerotic changes in arterial intima by promoting proliferation of smooth muscle cells of the vascular wall (24, 150). These molecules may also have an important role in tumor biology, since expression of the mRNA of the receptors and ligands A and B has been observed in a wide variety of human tumors (92).

Before the heart starts to beat and circulate blood, the vascular hierarchy must be organized and arteries and veins must be ready to properly transport blood. In studies of the ephrin family of molecules it has become obvious that the fate of the endothelial cell is already marked in early embryonic development when the whole endothelium is still rather uniform in nature (reviewed in Ref. 230). Unlike ligands for other receptor tyrosine kinases, the ephrins cannot act as soluble mediators but are membrane bound to activate their receptors. The Eph receptor family consists of at least 14 members. The receptors, and their ligands, can be divided into two subclasses, A and B (230). Ephrin-B ligands are transmembrane proteins and bind to receptors of the Eph-B subclass. Ephrin-B2 was shown to mark future arteries while its receptor Eph-B4 reciprocally marks the venous endothelium (218). Furthermore, embryos lacking Ephrin-B2 displayed severe defects in vascular remodeling in both arterial and venous domains. These findings provide some of the earliest known markers distinguishing the arterial and venous endothelia. These data for the first time show the existence of bidirectional signaling between these vessel types. This suggests that the molecular differences are at least in part programmed genetically in arterial versus venous endothelia and that these differences may be critical to normal development of the vasculature.

As the ephrins and Eph receptors distinguish arterial versus venous endothelial cells in the primary vascular plexus and are membrane bound, they interact with each other at sites of cell-to-cell contact, and the interactions are considered to lead to cell retraction. This signaling may happen at the junction of arterial and venous cells, or when the developing tubules pass each other and come in contact with adjacent sprouts during early remodeling of embryonic vasculature (230). These local interactions may ensure that new angiogenic sprouts fuse only with their counterpart branches. Inhibitory interactions may also help fusion to occur between the right type of vessels during remodeling, e.g., preventing fusion of arterial and venous structures and ensuring remodeling into a proper capillary network. On the other hand, coexpression of ligands and receptors in the same vessels may provide stimulatory signals to endothelial cells and promote sprouting and morphogenesis resulting in formation of functional vessels (5).

Other members of the Eph family are also critical for the remodeling of the vascular network (5). It has been also shown that the interactions of ephrins and Ephs are not restricted to the arterial/venous boundary but occur throughout vasculature and in mesenchymal cells adjacent to the blood vessels. These endothelial-mesenchymal contact zones may be critical for the patterning of the vasculature.

	III. MARKERS OF THE LYMPHATIC ENDOTHELIUM

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A major advance in the field of lymphangiogenesis has come from the discovery of lymphatic endothelium-specific markers (Table 1). VEGFR-3 was the first molecule found to be expressed in the lymphatic endothelium, but further studies have revealed that it is also expressed in a subset of blood vessels and in addition can be reactivated in the angiogenic vessels in certain pathological conditions (165, 214). Podoplanin is a glomerular podocyte membrane mucoprotein, which occurs together with VEGFR-3 in the lymphatic endothelium and in benign vascular tumors and angiosarcomas, but is also expressed in certain nonendothelial cells, such as osteoblastic cells, kidney podocytes, and lung alveolar type I cells (29, 30). Podoplanin is present in small lymphatics but not in the larger ones having smooth muscle cells, and all the blood vessels as well as high endothelial venules in the lymph nodes are negative for podoplanin expression. Prox-1 is a homeobox transcription factor gene product involved in the growth and elongation of the lymphatic vessel sprouts during development (222). Consistent with this, Prox +/ heterozygous newborns develop chylous ascites and die shortly after birth (222). Prox-1 is also expressed in nonendothelial cells in the lens, heart, liver, pancreas, and nervous system. The third marker, lymphatic vessel endothelial HA receptor-1 (LYVE-1), is a receptor for extracellular matrix/lymphatic fluid glycosaminoglycan in lymphatic endothelial cells (13). This molecule, which is related to the CD44 receptor for hyaluronan, is distributed equally among the luminal and abluminal surfaces of lymphatic vessels and is involved in the uptake of hyaluronan by lymphatic endothelial cells and its transport from the tissues to the lymph (171). However, LYVE-1 is not completely specific for the lymphatic endothelial cells, as it is also present, e.g., in normal hepatic blood sinusoidal endothelial cells (43).

Recently, a -chemokine receptor D6 was shown to be present in a subset of lymphatic vessels in the skin, intestine, and lymphoid tissues (151). Interestingly, lymphatic vessels in most of the organs remained negative for D6 immunoreactivity. The existence of this receptor on only a subset of lymphatics suggests a functional heterogeneity within the lymphatic vasculature. Consistent with this, recent findings revealed the coexpression of NRP-2 and VEGFR-3 in the lymphatic vessels of the intestine, whereas dermal lymphatic vessels did not show NRP-2 expression (106). The mannose receptor of macrophages is also expressed by lymphatic endothelium in addition to macrophages and other nonendothelial cells (134). The biological role of this receptor in lymphatic vessels is not known, but it may play a role in inflammation and immunity. 5'-Nucleotidase and desmoplakin have also been used to distinguish the lymphatic from the blood vascular endothelium (188, 212), and because lymphatic capillaries lack a continuous basement membrane, immunohistochemistry for extracellular matrix components type IV collagen and laminin have been used to distinguish them from blood capillaries (16). VEGFR-2 is occasionally expressed in lymphatic endothelia (166), and Tie-1 and Tie-2 may also have a role in lymphatic vessel regulation, as they also appear in lymphatic endothelia (103, 166) and mice deficient for the Ang-2 have a lymphatic phenotype (G. Thurston and G. Yancopoulos, unpublished data). In cultured lymphatic endothelial cells, the VEGFR-3, LYVE-1, and podoplanin were essentially located in the same cells (144). In addition, VEGFR-1, VEGFR-2, and VEGFR-3 were expressed in the same cultured lymphatic endothelial cells.

The markers of lymphatic endothelium show overlapping expression patterns in the lymphatic vessels of most benign tissues. However, recent findings have revealed that at least VEGFR-3 and LYVE-1 can be expressed in blood vascular endothelia in physiological conditions (43, 165). More information needs to be obtained to clarify the specificity of these markers in the lymphatic vessels in disease processes. Until then, several markers should be used to confirm the staining of lymphatic vessels in pathological conditions.

	IV. DISEASES OF THE LYMPHATIC VESSELS

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Pathological processes similar to those that affect blood vessels, such as thrombosis, inflammation, vessel wall hypertrophy, and sclerosis, may also occur to some extent in lymphatic vessels. However, the slow flow of the lymphatic fluid makes lymphatic disorders less acute in character (227). Lymphatic vessel defects are associated with intense fibrosis and overgrowth rather than the dramatic occlusive events such as occur in blood vessels when the blood flow is interrupted.

An important function of the lymphatic vessels is to regulate the pressure of interstitial fluid in tissues by transporting excess fluid back into the circulation. Edema represents an imbalance between lymph formation and its absorption into the lymphatic vessels. Clinical situations in which the lymphatic system is involved include lymphedema due to impaired lymphatic drainage. This can be caused by inflammatory or neoplastic obstruction of the lymphatic vessels including accumulation of ascites fluid due to lymphatic obstruction in peritoneal carcinomatosis or edema of the arm after surgery or radiotherapy for breast cancer. Lymphatic filariasis, globally the second leading cause of permanent and long-term disability, is a parasitic infection in the lymphatic vessels, which leads to abnormal transport function, massive edema, and deformation of the limbs (227).

Primary lymphedema is a rare developmental disorder in which the transport failure of the cutaneus lymphatic vessels results in interstitial lymph fluid accumulation. Chronic lymphatic dysfunction gradually results in thickening of the skin, accumulation of adipose tissue, and dermal fibrosis of the affected area (129). Recently, several groups have reported linkage of congenital lymphedema (Milroy's disease) to the VEGFR-3 gene (59, 66, 226) with autosomal dominant inheritance. This mutation was shown to lead to reduced VEGFR-3 tyrosine kinase activity and subsequent failure in transducing sufficient physiological VEGF-C/VEGF-D signals to the lymphatic endothelial cells (107). In all lymphedema families studied, the affected individuals had only one mutant allele (98, 107). This is compatible with the results that inactivation of both VEGFR-3 alleles in mice is embryonic lethal (52).

The mutation affecting the biological activity of VEGFR-3 is probably one cause of primary lymphedema, but some other lymphedema genes also exist, for example, FOXC2 (60). Identification of genetic markers and high-risk members of lymphedema families would facilitate the identification and management of environmental factors influencing the expression and severity of lymphedema. In particular, these findings permit better-informed genetic counseling in affected families and effective therapeutic regimens for lymphedema.

Kaposi's sarcoma is a multicentric neoplasm consisting of multiple vascular nodules appearing in the skin, mucous membranes, and viscera. Typically, the tumor respects tissue planes and is rarely invasive. Molecular and epidemiological studies indicate that development of Kaposi's sarcoma is associated with infection by the human herpesvirus-8 (HHV-8) (204). However, predominantly individuals with specific conditions of immunodysregulation, especially acquired immunodeficiency syndrome patients, develop Kaposi's sarcoma. The nodules are characterized by clusters of spindle-shaped tumor cells and by prominent vasculature consisting of small, irregular, endothelial-lined spaces. It is thought not to be a neoplastic transformation of cells in the classic sense, but rather a manifestation of excessive proliferation of the spindle cells. A central question in the pathogenesis of Kaposi's sarcoma has long been, which cell type in early lesions gives rise to the uniform tumor cells of late nodules (77). The spindle cells are most likely endothelial in origin, but there has been controversy as to whether they are of lymphatic or blood vascular derivation. The pathobiology of Kaposi's sarcoma is complex, and several vascular growth factors have been reported to be expressed in the nodules, suggesting that the balance of angiogenic/lymphangiogenic molecules is behind this tumor type (77).

Several reports support the idea that the cells in Kaposi's sarcoma are of lymphatic endothelial origin. The spindle cells and cells lining the irregular vascular spaces are positive for both VEGFR-3 and podoplanin (30, 103). In addition, the spindle cells have been shown to express VEGFR-2, Ang-2, Tie-1, and Tie-2 (31, 164, 195).

Vascular malformations are structural anomalies of the vascular system and may be composed of arteries, capillaries, veins, lymphatics, or combinations of them (78). They are often congenital benign lesions present at birth, but their enlargement ceases with the growth of the patient. An activating mutation in the Tie-2 receptor has been shown to cause inherited venous malformations (217). Altered Tie-2 regulation leads to abnormal venous growth or remodeling due to local uncoupling between proliferation and differentiation of endothelial and smooth muscle cells. This resembles the defects in the transgenic mice overexpressing Ang-1 (207, 208). An activating mutation of Tie-2 or overexpression of its activating ligand are both apparently able to cause similar changes in vascular remodeling (reviewed in Ref. 69).

Vascular tumors consist of a broad morphological spectrum from hamartomas to malignant neoplasia. They can be divided into benign tumors (hemangioma) and malignant vascular tumors (angiosarcoma) and to the tumors of lymphatic vessels (lymphangioma) and perivascular cells (glomus tumors). The molecular characteristics of these tumors are so far mostly unknown, but VEGF and its receptors have been shown to be expressed in the endothelial cells of these tumors (180). Although normal mesenchymal tissues show VEGFR-3 in the lymphatic endothelial cells, cells of benign and malignant vascular tumors show widespread VEGFR-3 expression, suggesting that VEGFR-3 is upregulated in the proliferating blood vascular endothelial cells. This is consistent with the VEGFR-3 expression in the embryonic developing vessels, as well as reactivation in adult angiogenic blood vessels (52, 214). Although strong expression of VEGFR-3 would be consistent with lymphatic differentiation, the extensive erythrocyte content in the vascular lumina of these lesions supports the idea that VEGFR-3 expression in these tumors reflects a proliferative vascular phenotype rather than a lymphatic phenotype. The expression of VEGFR-3 among vascular proliferations demonstrates that blood vessel endothelia can acquire VEGFR-3 expression independently of lymphatic vascular differentiation.

Classification of angiosarcomas is mostly based on morphological criteria. It has been suggested that some of the angiosarcomas contain components of a lymphatic lineage, but since the antibodies used for the detection of blood endothelia show overlapping staining of lymphatic endothelia, there is no proof of this. Some cell populations in angiosarcomas are positive for podoplanin, which retains its lymphatic endothelial cell specificity in vascular tumors, supporting the idea of mixed expression of both blood and lymphatic phenotypes in angiosarcomas (30). As expression of VEGFR-3 is seen in the majority of benign and malignant vascular tumors (164), it could thus be used as a lineage marker to identify endothelial cell differentiation in the tumors. However, further studies are needed to evaluate the sensitivity and specificity of both VEGFR-3 and podoplanin in the malignant transformation of blood or lymphatic endothelial cells.

Lymphangiomas result from abnormal development of lymphatic vessels, which prevents lymph fluid draining from the affected area. Lymphangiomas can originate in most organs, although they are most often found in the soft tissues of the head and neck (cystic hygroma) and axilla. They consist of a benign multicystic mass of dilated networks of lymphatic channels. Both VEGFR-3 and podoplanin specifically stain the endothelia of lymphangiomas and could be used for diagnostic purposes (30, 103, 164).

	V. TUMORIGENESIS AND METASTASIS

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Cancer is a disease involving dynamic changes to the genome. Mutations produce oncogenes that gain a dominant function, and tumor suppressor genes become inactivated and lose function (reviewed in Ref. 88). Lots of evidence indicates that tumorigenesis in humans is a multistep process, and these steps reflect the genetic alterations that drive the progressive transformation. Cancer cells have defects in regulatory circuits that govern normal proliferation and homeostasis. Whereas normal cells require mitogenic signals before they can move from a quiescent state into an active proliferative stage, malignant cells are self-sufficient for the growth signals and insensitive to the growth-inhibitory signals, which normally operate to maintain cellular quiescence and tissue homeostasis. Tumor cells generate many of their own growth signals, thereby reducing their dependence on stimulation from the normal tissue microenvironment. They develop various strategies to avoid terminal differentiation and are therefore more capable of proliferating than the well-differentiated benign cells. Most soluble mitogenic growth factors are produced by one cell type to stimulate the proliferation of another, whereas many cancer cells acquire the ability to synthesize their own growth factors leading to autocrine stimulation. It has long been thought that tumors are independent from the surrounding cells and their action, but now it seems more likely that cancer development depends on interactions between tumor cells and their benign neighbors. Tumors and metastases tend to harbor complex mixtures of several cell types that collaborate to create a malignant growth, including fibroblasts, immune cells, and endothelial cells (68, 88).

The cells within aberrant proliferative lesions initially lack angiogenic ability, preventing their expansion. The ability to induce and sustain angiogenesis seems to be acquired in discrete steps during tumor development via an angiogenic switch from vascular quiescence to proliferation (88). In studies