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Ephrin-B2/VEGF in angiogenesis control Ephrin-B ligands are well known as axon guidance molecules. Ephrin-B2 is also known to play a role in angiogenic remodelling. Two studies now show that signalling through ephrin-B2 controls vessel sprouting. Mechanistically, ephrin-B2 seems to function in part by regulating VEGFR internalization and signalling. The finding suggests that blocking ephrin-B2 signalling may be an alternative approach to blocking VEGFR function in angiogenesis. The protein ephrin-B2 is known to be upregulated during angiogenesis — the growth of new blood vessels — but its precise function has been unclear. Here it is shown that signalling through ephrin-B2 controls vessel sprouting. Mechanistically, ephrin-B2 seems to function in part by regulating the internalization of vascular endothelial growth factor receptors (VEGFRs). The results indicate that blocking ephrin-B2 signalling might be an alternative to blocking VEGFR function to disrupt angiogenesis in tumours. In development, tissue regeneration or certain diseases, angiogenic growth leads to the expansion of blood vessels and the lymphatic vasculature. This involves endothelial cell proliferation as well as angiogenic sprouting, in which a subset of cells, termed tip cells, acquires motile, invasive behaviour and extends filopodial protrusions 1 , 2 , 3 . Although it is already appreciated that angiogenesis is triggered by tissue-derived signals, such as vascular endothelial growth factor (VEGF) family growth factors, the resulting signalling processes in endothelial cells are only partly understood. Here we show with genetic experiments in mouse and zebrafish that ephrin-B2, a transmembrane ligand for Eph receptor tyrosine kinases, promotes sprouting behaviour and motility in the angiogenic endothelium. We link this pro-angiogenic function to a crucial role of ephrin-B2 in the VEGF signalling pathway, which we have studied in detail for VEGFR3, the receptor for VEGF-C. In the absence of ephrin-B2, the internalization of VEGFR3 in cultured cells and mutant mice is defective, which compromises downstream signal transduction by the small GTPase Rac1, Akt and the mitogen-activated protein kinase Erk. Our results show that full VEGFR3 signalling is coupled to receptor internalization. Ephrin-B2 is a key regulator of this process and thereby controls angiogenic and lymphangiogenic growth.

Activities as diverse as migration, proliferation and patterning occur simultaneously and in a coordinated fashion during tissue morphogenesis. In the growing vasculature, the formation of motile, invasive and filopodia-carrying endothelial sprouts is balanced with the stabilization of blood-transporting vessels. Here, we show that sprouting endothelial cells in the retina have high rates of VEGF uptake, VEGF receptor endocytosis and turnover. These internalization processes are opposed by atypical protein kinase C activity in more stable and mature vessels. aPKC phosphorylates Dab2, a clathrin-associated sorting protein that, together with the transmembrane protein ephrin-B2 and the cell polarity regulator PAR-3, enables VEGF receptor endocytosis and downstream signal transduction. Accordingly, VEGF receptor internalization and the angiogenic growth of vascular beds are defective in loss-of-function mice lacking key components of this regulatory pathway. Our work uncovers how vessel growth is dynamically controlled by local VEGF receptor endocytosis and the activity of cell polarity proteins. The sprouting activity of filopodia emerging from endothelial sprouting cells needs to be compensated for in mature stable vessels. Adams and colleagues find that sprouting cells in mouse retinal vasculature show high VEGF uptake and VEGF receptor turnover, both essential for sprouting. These are inhibited by an aPKC-mediated decrease in VEGF receptor endocytosis in mature vessels, through a mechanism implicating clathrin-associated proteins, the transmembrane protein ephrin-B2 and the polarity factor PAR-3.

Background Ephrin-B2 (EB2) signaling plays a crucial role in regulating memory and synaptic plasticity. Comprehensive identification of cell-type-specific transcriptomic changes in EB2 knockout mice is expected to shed light on potential mechanisms associated with EB2 signaling in cognitive functions. Results Our study captures changes in cell populations in response to EB2 manipulation and reveals previously uncharacterized cell types (CPA6 + inhibitory neurons) in the mPFC. We validated the differential transcriptomic activity of Pbx1 and Meis1 in CPA6 + neurons using fluorescence in situ hybridization (ISH) in EB2-vGATCre mice. The aberrant presence of CPA6 + neurons in the mPFC may correlate with cognitive impairments induced by EB2 deletion in vGAT + neurons. Analyzing differentially expressed genes (DEGs) in individual cell clusters, we identified alterations related to synapse organization and development, cognition, amyloid-beta formation, and locomotor behavior. Additionally, our DEGs overlapped with human genome-wide association study (GWAS) candidate genes related to cognition and anxiety, underscoring the relevance of our mouse model to human disease. Conclusions We present a comprehensive atlas of cell-type-specific gene expression changes in this synaptic deficiency model and identify novel cell-type-specific targets implicated in cognitive deficits. Our investigation provides a detailed map of the cell types, genes, and pathways altered in this inhibitory synaptic deficiency model.

Ephrin-B2/VEGF in angiogenesis control Ephrin-B ligands are well known as axon guidance molecules. Ephrin-B2 is also known to play a role in angiogenic remodelling. Two studies now show that signalling through ephrin-B2 controls vessel sprouting. Mechanistically, ephrin-B2 seems to function in part by regulating VEGFR internalization and signalling. The finding suggests that blocking ephrin-B2 signalling may be an alternative approach to blocking VEGFR function in angiogenesis. The protein ephrin-B2 is known to be upregulated during angiogenesis — the growth of new blood vessels — but its precise function has been unclear. Here it is shown that signalling through ephrin-B2 controls vessel sprouting. Mechanistically, ephrin-B2 seems to function in part by regulating the internalization of vascular endothelial growth factor receptors (VEGFRs). The results indicate that blocking ephrin-B2 signalling might be an alternative to blocking VEGFR function to disrupt angiogenesis in tumours. The formation and guidance of specialized endothelial tip cells is essential for both developmental and pathological angiogenesis 1 . Notch-1 signalling regulates the generation of tip cells, which respond to gradients of vascular endothelial growth factor (VEGF-A) 2 . The molecular cues and signalling pathways that control the guidance of tip cells are poorly understood. Bidirectional signalling by Eph receptors and ephrin ligands represents one of the most important guidance cues involved in axon path finding 3 . Here we show that ephrin-B2 reverse signalling involving PDZ interactions regulates endothelial tip cell guidance to control angiogenic sprouting and branching in physiological and pathological angiogenesis. In vivo , ephrin-B2 PDZ-signalling-deficient mice (ephrin-B2ΔV) exhibit a reduced number of tip cells with fewer filopodial extensions at the vascular front in the mouse retina. In pathological settings, impaired PDZ signalling decreases tumour vascularization and growth. Mechanistically, we show that ephrin-B2 controls VEGF receptor (VEGFR)-2 internalization and signalling. Importantly, internalization of VEGFR2 is necessary for activation and downstream signalling of the receptor and is required for VEGF-induced tip cell filopodial extension. Together, our results suggest that ephrin-B2 at the tip cell filopodia regulates the proper spatial activation of VEGFR2 endocytosis and signalling to direct filopodial extension. Blocking ephrin-B2 reverse signalling may be an attractive alternative or combinatorial anti-angiogenic therapy strategy to disrupt VEGFR2 function in tumour angiogenesis.

Cell segregation allows the compartmentalization of cells with similar fates during morphogenesis, which can be enhanced by cell fate plasticity in response to local molecular and biomechanical cues. Endothelial tip cells in the growing retina, which lead vessel sprouts, give rise to arterial endothelial cells and thereby mediate arterial growth. Here, we have combined cell type-specific and inducible mouse genetics, flow experiments in vitro, single-cell RNA sequencing and biochemistry to show that the balance between ephrin-B2 and its receptor EphB4 is critical for arterial specification, cell sorting and arteriovenous patterning. At the molecular level, elevated ephrin-B2 function after loss of EphB4 enhances signaling responses by the Notch pathway, VEGF and the transcription factor Dach1, which is influenced by endothelial shear stress. Our findings reveal how Eph-ephrin interactions integrate cell segregation and arteriovenous specification in the vasculature, which has potential relevance for human vascular malformations caused by EPHB4 mutations. Arteries are vital blood vessels for our body and their growth and patterning are critical for proper blood flow. Here they use a retina model to show that a balance of EphB4 receptor and ephrin-B2 ligand integrate a well-wired molecular network to control arteriovenous patterning and vascular growth.

Gastric cancer (GC) ranks among the most prevalent malignancies worldwide and is associated with high mortality rates. Ephrin-B2 (EFNB2), a membrane-bound ligand that interacts with Eph receptor tyrosine kinases, has been implicated in various cancer-related biological processes; however, its precise role in GC remains poorly understood. By integrating data from multiple public databases with immunohistochemical analyses of tissue microarrays, significant upregulation of EFNB2 expression in GC specimens compared with paired adjacent normal tissue was demonstrated. Elevated EFNB2 levels were associated with the poor overall survival and disease-free survival in patients with GC. EFNB2 knockdown inhibited cellular proliferation and viability, increased apoptosis, and induced cell cycle arrest at the G0/G1 phase in GC cells. By contrast, EFNB2 overexpression resulted in the opposite oncogenic effects. Mechanistically, rescue experiments identified the Wnt/β-catenin signaling cascade as the primary molecular pathway mediating EFNB2-driven tumorigenic effects. These results were further validated in vivo using cell-derived xenograft models, which confirmed the key role of Wnt/β-catenin pathway activation in EFNB2-induced tumor progression. Collectively, these results suggested that EFNB2 represents a promising molecular target for therapeutic intervention in GC.

Cedar virus (CedV) is a bat-borne henipavirus related to Nipah virus (NiV) and Hendra virus (HeV), zoonotic agents of fatal human disease. CedV receptor-binding protein (G) shares only ∼30% sequence identity with those of NiV and HeV, although they can all use ephrin-B2 as an entry receptor. We demonstrate that CedV also enters cells through additional B- and A-class ephrins (ephrin-B1, ephrin-A2, and ephrin-A5) and report the crystal structure of the CedV G ectodomain alone and in complex with ephrin-B1 or ephrin-B2. The CedV G receptor-binding site is structurally distinct from other henipaviruses, underlying its capability to accommodate additional ephrin receptors. We also show that CedV can enter cells through mouse ephrin-A1 but not human ephrin-A1, which differ by 1 residue in the key contact region. This is evidence of species specific ephrin receptor usage by a henipavirus, and implicates additional ephrin receptors in potential zoonotic transmission.

Bidirectional signalling is regarded as a notable hallmark of the Eph-ephrin signalling system: Eph-dependent forward signalling in Eph-expressing cells and ephrin-dependent reverse signalling in Ephrin-expressing cells. The notion of ephrin-dependent reverse signalling derives from genetic experiments utilizing mice carrying mutations in the intracellular region of ephrinBs. Here we show that EphB4-dependent forward signalling regulates lymphatic valve development, a process previously thought to be regulated by ephrinB2-dependent reverse signalling. We develop antibodies that selectively target EphB4 and ephrinB2. We find that mice bearing genetically altered cytoplasmic region of ephrinB2 have significantly altered EphB4-dependent forward signalling. Selective inhibition of EphB4 using a functional blocking antibody results in defective lymphatic valve development. Furthermore, a chemical genetic approach is used to unequivocally show that the kinase activity of EphB4 is essential for lymphatic valve development. The bidirectional Eph-ephrin signalling regulates a myriad of developmental programmes. Zhang et al . show that EphB4 forward signalling is crucial for lymphatic valve development, providing new insight into this important developmental process previously thought to be regulated by ephrinB2-dependent reverse signalling.

Mineralized bone forms when collagen-containing osteoid accrues mineral crystals. This is initiated rapidly (primary mineralization), and continues slowly (secondary mineralization) until bone is remodeled. The interconnected osteocyte network within the bone matrix differentiates from bone-forming osteoblasts; although osteoblast differentiation requires EphrinB2, osteocytes retain its expression. Here we report brittle bones in mice with osteocyte-targeted EphrinB2 deletion. This is not caused by low bone mass, but by defective bone material. While osteoid mineralization is initiated at normal rate, mineral accrual is accelerated, indicating that EphrinB2 in osteocytes limits mineral accumulation. No known regulators of mineralization are modified in the brittle cortical bone but a cluster of autophagy-associated genes are dysregulated. EphrinB2-deficient osteocytes displayed more autophagosomes in vivo and in vitro, and EphrinB2-Fc treatment suppresses autophagy in a RhoA-ROCK dependent manner. We conclude that secondary mineralization involves EphrinB2-RhoA-limited autophagy in osteocytes, and disruption leads to a bone fragility independent of bone mass. Osteoblasts mediate bone formation, and their differentiation requires expression of EphrinB2. Here, the authors show that EphrinB2 is also expressed by osteocytes, and that its genetic ablation in mice is associated with altered autophagy, elevated mineralization and brittle bone.

Endothelial integrity is vital for homeostasis and adjusted to tissue demands. Although fluid uptake by lymphatic capillaries is a critical attribute of the lymphatic vasculature, the barrier function of collecting lymphatic vessels is also important by ensuring efficient fluid drainage as well as lymph node delivery of antigens and immune cells. Here, we identified the transmembrane ligand EphrinB2 and its receptor EphB4 as critical homeostatic regulators of collecting lymphatic vessel integrity. Conditional gene deletion in mice revealed that EphrinB2/EphB4 signalling is dispensable for blood endothelial barrier function, but required for stabilization of lymphatic endothelial cell (LEC) junctions in different organs of juvenile and adult mice. Studies in primary human LECs further showed that basal EphrinB2/EphB4 signalling controls junctional localisation of the tight junction protein CLDN5 and junction stability via Rac1/Rho-mediated regulation of cytoskeletal contractility. EphrinB2/EphB4 signalling therefore provides a potential therapeutic target to selectively modulate lymphatic vessel permeability and function. Lymph vessels are thin walled tubes that, similar to blood vessels, carry white blood cells, fluids and waste. Unlike veins and arteries, however, lymph vessels do not carry red blood cells and their main function is to remove excess fluid from tissues. The cells that line vessels in the body are called endothelial cells, and they are tightly linked together by proteins to control what goes into and comes out of the vessels. The chemical, physical and mechanical signals that control the junctions between endothelial cells are often the same in different vessel types, but their effects can vary. The endothelial cells of both blood and lymph vessels have two interacting proteins on their membrane known as EphrinB2 and its receptor, EphB4. When these two proteins interact, the EphB4 receptor becomes activated, which leads to changes in the junctions that link endothelial cells together. Frye et al. examined the role of EphrinB2 and EphB4 in the lymphatic system of mice. When either EphrinB2 or EphB4 are genetically removed in newborn or adult mice, lymph vessels become disrupted, but no significant effect is observed on blood vessels. The reason for the different responses in blood and lymph vessels is unknown. The results further showed that lymphatic endothelial cells need EphB4 and EphrinB2 to be constantly interacting to maintain the integrity of the lymph vessels. Further examination of human endothelial cells grown in the laboratory revealed that this constant signalling controls the internal protein scaffold that determines a cell’s shape and integrity. Changes in the internal scaffold affect the organization of the junctions that link neighboring lymphatic endothelial cells together. The loss of signalling between EphrinB2 and EphB4 in lymph vessels reflects the increase in vessel leakage seen in response to bacterial infections and in some genetic conditions such as lymphoedema. Finding ways to control the signalling between these two proteins could help treat these conditions by developing drugs that improve endothelial cell integrity in lymph vessels.