Advantages and Challenges of Cardiovascular and Lymphatic Studies in Zebrafish Research

Since its introduction, the zebrafish has provided an important reference system to model and study cardiovascular development as well as lymphangiogenesis in vertebrates. A scientific workshop, held at the 2018 European Zebrafish Principal Investigators Meeting in Trento (Italy) and chaired by Massimo Santoro, focused on the most recent methods and studies on cardiac, vascular and lymphatic development. Daniela Panáková and Natascia Tiso described new molecular mechanisms and signaling pathways involved in cardiac differentiation and disease. Arndt Siekmann and Wiebke Herzog discussed novel roles for Wnt and VEGF signaling in brain angiogenesis. In addition, Brant Weinstein’s lab presented data concerning the discovery of endothelium-derived macrophage-like perivascular cells in the zebrafish brain, while Monica Beltrame’s studies refined the role of Sox transcription factors in vascular and lymphatic development. In this article, we will summarize the details of these recent discoveries in support of the overall value of the zebrafish model system not only to study normal development, but also associated disease states

Zebrafish mutants in vegfab can affect endothelial cell proliferation without altering ERK phosphorylation and are phenocopied by loss of PI3K signaling.

The formation of appropriately patterned blood vessel networks requires endothelial cell migration and proliferation. Signaling through the Vascular Endothelial Growth Factor A (VEGFA) pathway is instrumental in coordinating these processes. mRNA splicing generates short (diffusible) and long (extracellular matrix bound) Vegfa isoforms. The differences between these isoforms in controlling cellular functions are not understood. In zebrafish, vegfaa generates short and long isoforms, while vegfab only generates long isoforms. We found that mutations in vegfaa had an impact on endothelial cell (EC) migration and proliferation. Surprisingly, mutations in vegfab more strongly affected EC proliferation in distinct blood vessels, such as intersegmental blood vessels in the zebrafish trunk and central arteries in the head. Analysis of downstream signaling pathways revealed no change in MAPK (ERK) activation, while inhibiting PI3 kinase signaling phenocopied vegfab mutant phenotypes in affected blood vessels. Together, these results suggest that extracellular matrix bound Vegfa might act through PI3K signaling to control EC proliferation in a distinct set of blood vessels during angiogenesis.We would like to thank Reinhild Bussmann, Mona Finch Stephen, Nadine Greer and Bill Vought for excellent fish care. In addition, we would like to thank Roman Tsaryk and Zeenat Diwan for critically reading of the manuscript and Caitlyn Parker for excellent technical assistance. We are grateful to Federica Lunella for help with the mouse retina dissection and immunohistochemistry. We would like to thank William Jones and Mary Mullins for providing the pCS2þ β-galactosidase plasmid. This work was funded by the Max-Planck-Society (A.F.S.), the Deutsche Forschungsgemeinschaft (DFG SI-1374/4-1, DFG SI-1374/5-1 and DFG SI-1374/6-1; A.F.S.) and start-up funds from the Cardiovascular Institute and the Department of Cell and Developmental Biology of the University of Pennsylvania Perelman School of Medicine (A.F.S.). We further acknowledge support from the NIH R01HL152086 (A.F.S.). Work in R.B.’s lab was funded by the Ministerio de Economía, Industría y Competitividad (MEIC: SAF2017-89299-P and RYC-2013-13209) and the European Research Council (ERC-2014-StG – 638028 AngioGenesHD).S

Chemokine Signaling Directs Trunk Lymphatic Network Formation along the Preexisting Blood Vasculature

SummaryThe lymphatic system is crucial for fluid homeostasis, immune responses, and numerous pathological processes. However, the molecular mechanisms responsible for establishing the anatomical form of the lymphatic vascular network remain largely unknown. Here, we show that chemokine signaling provides critical guidance cues directing early trunk lymphatic network assembly and patterning. The chemokine receptors Cxcr4a and Cxcr4b are expressed in lymphatic endothelium, whereas chemokine ligands Cxcl12a and Cxcl12b are expressed in adjacent tissues along which the developing lymphatics align. Loss- and gain-of-function studies in zebrafish demonstrate that chemokine signaling orchestrates the stepwise assembly of the trunk lymphatic network. In addition to providing evidence for a lymphatic vascular guidance mechanism, these results also suggest a molecular basis for the anatomical coalignment of lymphatic and blood vessels

MicroRNA 139-5p coordinates APLNR-CXCR4 crosstalk during vascular maturation

G protein-coupled receptor (GPCR) signalling, including that involving apelin (APLN) and its receptor APLNR, is known to be important in vascular development. How this ligand–receptor pair regulates the downstream signalling cascades in this context remains poorly understood. Here, we show that mice with Apln, Aplnr or endothelial-specific Aplnr deletion develop profound retinal vascular defects, which are at least in part due to dysregulated increase in endothelial CXCR4 expression. Endothelial CXCR4 is negatively regulated by miR-139-5p, whose transcription is in turn induced by laminar flow and APLN/APLNR signalling. Inhibition of miR-139-5p in vivo partially phenocopies the retinal vascular defects of APLN/APLNR deficiency. Pharmacological inhibition of CXCR4 signalling or augmentation of the miR-139-5p-CXCR4 axis can ameliorate the vascular phenotype of APLN/APLNR deficient state. Overall, we identify an important microRNA-mediated GPCR crosstalk, which plays a key role in vascular development

Future directions for therapeutic strategies in post-ischaemic vascularization: a position paper from European Society of Cardiology Working Group on Atherosclerosis and Vascular Biology

Modulation of vessel growth holds great promise for treatment of cardiovascular disease. Strategies to promote vascularization can potentially restore function in ischaemic tissues. On the other hand, plaque neovascularization has been shown to associate with vulnerable plaque phenotypes and adverse events. The current lack of clinical success in regulating vascularization illustrates the complexity of the vascularization process, which involves a delicate balance between pro- and anti-angiogenic regulators and effectors. This is compounded by limitations in the models used to study vascularization that do not reflect the eventual clinical target population. Nevertheless, there is a large body of evidence that validate the importance of angiogenesis as a therapeutic concept. The overall aim of this Position Paper of the ESC Working Group of Atherosclerosis and Vascular biology is to provide guidance for the next steps to be taken from pre-clinical studies on vascularization towards clinical application. To this end, the current state of knowledge in terms of therapeutic strategies for targeting vascularization in post-ischaemic disease is reviewed and discussed. A consensus statement is provided on how to optimize vascularization studies for the identification of suitable targets, the use of animal models of disease, and the analysis of novel delivery methods

Distinct tissue-specificity of three zebrafish ext1 genes encoding proteoglycan modifying enzymes and their relationship to somitic Sonic hedgehog signaling.

Proteins of the EXT (Exostosin) 1 family are known for their role in human disease. Mutations in EXT1 cause hereditary multiple exostoses (HME), benign outgrowths of the bones, and therefore were classed as tumor suppressors. More recently, their role during embryonic development of Drosophila and mouse was addressed, revealing important functions of EXT1 genes in major signaling pathways. Here, we report the isolation of three zebrafish members of the EXT1 family, which we named ext1a, ext1b, and ext1c, respectively. They are expressed in restricted temporal and spatial domains during development. Both ext1a and ext1b are provided maternally and expressed during gastrulation: ext1a in the neurectoderm and ext1b in the embryonic midline and in the involuting mesendoderm of the germ ring. During somitogenesis stages, transcripts of all three ext genes can be found in the somitic mesoderm. Furthermore, ext1a is expressed in the dorsal neural tube. These expression domains become more pronounced at 24 hr postfertilization (hpf). At 48 hpf, ext1 genes are present in the brain, while somitic expression ceases. Zebrafish have three members of the EXT1 family, in contrast to only one EXT1 gene in mammals or Xenopus, consistent with the occurrence of partial genome duplications in the teleost lineage. Our expression analysis reveals that the three ext genes have distinct expression patterns, reflecting functional divergence after duplication. In addition, expression of ext1a and ext1c responds to elevated and reduced levels of Sonic hedgehog (shh) signaling in the somites, whereas expression of ext1b does not. This suggests a differential relationship between the shh pathway and individual ext gene function in zebrafish. Developmental Dynamics 232:498-505, 2005. (c) 2004 Wiley-Liss, Inc

Notch signalling limits angiogenic cell behaviour in developing zebrafish arteries

Recent evidence indicates that growing blood-vessel sprouts consist of endothelial cells with distinct cell fates and behaviours; however, it is not clear what signals determine these sprout cell characteristics. Here we show that Notch signalling is necessary to restrict angiogenic cell behaviour to tip cells in developing segmental arteries in the zebrafish embryo. In the absence of the Notch signalling component Rbpsuh (recombining binding protein suppressor of hairless) we observed excessive sprouting of segmental arteries, whereas Notch activation suppresses angiogenesis. Through mosaic analysis we find that cells lacking Rbpsuh preferentially localize to the terminal position in developing sprouts. In contrast, cells in which Notch signalling has been activated are excluded from the tip-cell position. In vivo time-lapse analysis reveals that endothelial tip cells undergo a stereotypical pattern of proliferation and migration during sprouting. In the absence of Notch, nearly all sprouting endothelial cells exhibit tip-cell behaviour, leading to excessive numbers of cells within segmental arteries. Furthermore, we find that flt4 (fms-related tyrosine kinase 4, also called vegfr3) is expressed in segmental artery tip cells and becomes ectopically expressed throughout the sprout in the absence of Notch. Loss of flt4 can partially restore normal endothelial cell number in Rbpsuh-deficient segmental arteries. Finally, loss of the Notch ligand dll4 (delta-like 4) also leads to an increased number of endothelial cells within segmental arteries. Together, these studies indicate that proper specification of cell identity, position and behaviour in a developing blood-vessel sprout is required for normal angiogenesis, and implicate the Notch signalling pathway in this process

The Tip Cell Concept Ten Years After : New Players Tune in for a Common Theme

Embryonic growth, organ formation and regeneration rely on properly patterned vascular networks. During these processes, tissue growth is accompanied by an expansion of the respective vascular beds by angiogenesis. Angiogenesis involves the sprouting of new vessels from pre-existing ones and the eventual fusion of these sprouts with other sprouts or blood vessels to form new vascular loops. Sprouting blood vessels are made up of different cell populations: leading tip cells, which guide the sprout, and following stalk cells, which make up the base of the sprout and maintain the connection to the parental vessel. The functional and molecular differences between tip and stalk cells and how such differences ensure proper angiogenesis has drawn great attention within the last decade. In this review, we present recent progress in our understanding of tip cell specification and function during sprouting angiogenesis and anastomosis. We furthermore discuss similarities and variations in tip cell biology in different vascular beds and how they might be important for the formation of structurally and functionally distinct vascular networks

Chemokine signaling guides regional patterning of the first embryonic artery

The aorta traverses the body, yet little is known about how it is patterned in different anatomical locations. Here, we show that the aorta develops from genetically distinct endothelial cells originating from diverse locations within the embryo. Furthermore, chemokine (C-X-C motif) receptor 4a (cxcr4a) is restricted to endothelial cells derived from anterior mesoderm, and is required specifically for formation of the lateral aortae. Cxcl12b, a cxcr4a ligand, is expressed in endoderm underlying the lateral aortae, and loss of cxcl12b phenocopies cxcr4a deficiency. These studies reveal unexpected endothelial diversity within the aorta that is necessary to facilitate its regional patterning by local cues