The ability of Ephs and ephrins to mediate a variety of
cell-cell interactions places the Eph/ephrin system in an ideal position to regulate a variety of different biological processes during
embryonic development.
Bi-directional signaling Unlike most other RTKs, Ephs have a unique capacity to initiate an intercellular signal in both the receptor-bearing cell ("forward" signaling) and the opposing ephrin-bearing cell ("reverse" signaling) following cell-cell contact, which is known as bi-directional signaling. Although the functional consequences of Eph/ephrin bi-directional signaling have not been completely elucidated, it is clear that such a unique signaling process allows for ephrin Ephs to have opposing effects on
growth cone survival and allows for the segregation of Eph-expressing cells from ephrin-expressing cells.
Segmentation Segmentation is a basic process of embryogenesis occurring in most invertebrates and all vertebrates by which the body is initially divided into functional units. In the segmented regions of the embryo, cells begin to present biochemical and morphological boundaries at which cell behavior is drastically different – vital for future differentiation and function. In the hindbrain, segmentation is a precisely defined process. In the paraxial
mesoderm, however, development is a dynamic and adaptive process that adjusts according to posterior body growth. Various Eph receptors and ephrins are expressed in these regions, and, through functional analysis, it has been determined that Eph signaling is crucial for the proper development and maintenance of these segment boundaries.
Axon guidance As the nervous system develops, the patterning of neuronal connections is established by molecular guides that direct axons (
axon guidance) along pathways by target and pathway derived signals. This mechanism of repelling migrating axons through decreased growth cone survival depends on relative levels of Eph and ephrin expression and allows gradients of Eph and ephrin expression in target cells to direct the migration of axon growth cones based on their own relative levels of Eph and ephrin expression. Typically, forward signaling by both EphA and EphB receptors mediates growth cone collapse while reverse signaling via ephrin-A and ephrin-B induces growth cone survival. The ability of Eph/ephrin signaling to direct migrating axons along Eph/ephrin expression gradients is evidenced in the formation of the
retinotopic map in the visual system, with graded expression levels of both Eph receptors and ephrin ligands leading to the development of a resolved neuronal map (for a more detailed description of Eph/ephrin signaling see "Formation of the Retinotopic Map" in
ephrin). Further studies then showed the role of Eph's in topographic mapping in other regions of the central nervous system, such as learning and memory via the formation of projections between the septum and hippocampus. In addition to the formation of topographic maps, Eph/ephrin signaling has been implicated in the proper guidance of
motor neuron axons in the
spinal cord. Although several members of Ephs and ephrins contribute to motor neuron guidance,
ephrin-A5 reverse signaling has been shown to play a critical role in the survival of motor neuron growth cones and to mediate growth cone migration by initiating repellence in EphA-expressing migrating axons. In the chick and rat embryo trunk, the migration of crest cells is partially mediated by EphB receptors. Similar mechanisms have been shown to control crest movement in the hindbrain within rhombomeres 4, 5, and 7, which distribute crest cells to brachial arches 2, 3, and 4 respectively. In
C. elegans a knockout of the
vab-1 gene, known to encode an Eph receptor, and its Ephrin ligand
vab-2 results in two cell migratory processes being affected.
Angiogenesis Eph receptors are present in high degrees during
vasculogenesis,
angiogenesis, and other early development of the
circulatory system. This development is disturbed without it. It is thought to distinguish arterial and venous
endothelium, stimulating the production of
capillary sprouts as well as in the differentiation of
mesenchyme into
perivascular support cells. The construction of blood vessels requires the coordination of endothelial and supportive mesenchymal cells through multiple phases to develop the intricate networks required for a fully functional circulatory system. The dynamic nature and expression patterns of the Ephs make them, therefore, ideal for roles in angiogenesis. Mouse embryonic models show expression of EphA1 in mesoderm and pre-endocardial cells, later spreading up into the dorsal aorta then primary head vein, intersomitic vessels, and limb bud vasculature, as would be consistent with a role in angiogenesis. Different class A Eph receptors have also been detected in the lining of the aorta, brachial arch arteries, umbilical vein, and endocardium. Expression of EphB2 and ephrin-B2 was also detected on supportive mesenchymal cells, suggesting a role in wall development through mediation of endothelial-mesenchymal interactions. Blood vessel formation during embryogenesis consists of vasculogenesis, the formation of a primary capillary network followed by a second remodeling and restructuring into a finer tertiary network - studies utilizing ephrin-B2 deficient mice showed a disruption of the embryonic vasculature as a result of a deficiency in the restructuring of the primary network. This expression is seen in the distal end of the limb buds, where cells are still undifferentiated and dividing, and appears to be under the regulation of retinoic acid, FGF2, FGF4, and BMP-2 – known to regulate limb patterning. EphA4 defective mice do not present abnormalities in limb morphogenesis (personal communication between Andrew Boyd and Nigel Holder), so it is possible that these expression patterns are related to neuronal guidance or vascularisation of the limb with further studies being required to confirm or deny a potential role of Eph in limb development.
Cancer As a member of the RTK family and with responsibilities as diverse as Ephs, it is not surprising to learn that the Ephs have been implicated in several aspects of
cancer. While used extensively throughout development, Ephs are rarely detected in adult tissues. Elevated levels of expression and activity have been correlated with the growth of solid tumors, with Eph receptors of both classes A and B being over expressed in a wide range of cancers including melanoma, breast, prostate, pancreatic, gastric, esophageal, and colon cancer, as well as hematopoietic tumors. Increased expression was also correlated with more malignant and metastatic tumors, consistent with the role of Ephs in governing cell movement. The angiogenic properties of the Eph system may increase vascularisation of and thus growth capacity of tumors. Second, elevated Eph levels may disrupt cell-cell adhesion via cadherin, known to alter expression and localisation of Eph receptors and ephrins, which is known to further disrupt cellular adhesion, a key feature of metastatic cancers. Third, Eph activity may alter cell matrix interactions via integrins by the sequestering of signaling molecules following Eph receptor activation, as well as providing potential adherence via ephrin ligand binding following metastasis. == Discovery and history ==