Mural-Endothelial cell-cell interactions stabilize the developing zebrafish dorsal aorta

Stratman, Amber N.; Pezoa, Sofia A.; Farrelly, Olivia; Castranova, Daniel; Dye, Louis; Butler, Matthew G.; Sidik, Harwin; Talbot, William S.; Weinstein, Brant M.

doi:10.1242/dev.143131

Cited by 91 publications

(106 citation statements)

References 73 publications

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“…It is important to note that although co-transplantation with MSCs facilitates engraftment, h-iECs derived from the S1-modETV2 protocol were also able to engraft and form perfused vessels when We also examined the presence of mural cell investment around the newly-formed human vessels, a hallmark of proper vessel maturation and stabilization (24). There was a striking difference between h-iECs generated with the S1-modETV2 protocol and those generated with the early modETV2 with regard to perivascular investment ( Fig.…”

Section: Timely Activation Of Etv2 Is Critical For Proper Vascular Nementioning

confidence: 99%

Robust differentiation of human pluripotent stem cells into endothelial cells via temporal modulation of ETV2 with modified mRNA

Wang

Lin

Hong

et al. 2020

Preprint

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Human induced pluripotent stem cell (h-iPSC)-derived endothelial cells (h-iECs) have become a valuable tool in regenerative medicine. However, current differentiation protocols remain inefficient and lack reliability. Here, we describe a method for rapid, consistent, and highly efficient generation of h-iECs. The protocol entails the delivery of modified mRNA encoding the transcription factor ETV2 at the intermediate mesodermal stage of differentiation. This approach reproducibly differentiated thirteen diverse h-iPSC lines into h-iECs with exceedingly high efficiency. In contrast, standard differentiation methods that relied on endogenous ETV2 were inefficient and notably inconsistent. Our h-iECs were functionally competent in many respects, including the ability to form perfused vascular networks in vivo. Importantly, timely activation of ETV2 was critical, and bypassing the mesodermal stage produced putative h-iECs with reduced expansion potential and inability to form functional vessels. Our protocol has broad applications and could reliably provide an unlimited number of h-iECs for vascular therapies.

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Section: Timely Activation Of Etv2 Is Critical For Proper Vascular Nementioning

confidence: 99%

Robust differentiation of human pluripotent stem cells into endothelial cells via temporal modulation of ETV2 with modified mRNA

Wang

Lin

Hong

et al. 2020

Preprint

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“…Animal experiments frequently use zebrafish as a model system, since their transparent nature enables complex in vivo microscopic analysis and real‐time visualization of cellular behaviour in situ . However, findings are not always translatable into humans . Knockout studies in mice using Cre recombinase under endothelial‐specific promoters are possible, but global phenotypes are often difficult to interpret or may even obscure organ‐specific effects.…”

Section: Endothelial Dysfunction and Comorbidity: Diagnostic Prognosmentioning

confidence: 99%

Endothelial cells and organ function: applications and implications of understanding unique and reciprocal remodelling

Reiterer

Branco

2019

The FEBS Journal

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The microvasculature is a heterogeneous, dynamic and versatile component of the systemic circulation, with a unique ability to locally self‐regulate and to respond to organ demand and environmental stimuli. Endothelial cells from different organs display considerable variation, but it is currently unclear to what extent functional properties of organ‐specific endothelial cells are intrinsic, acquired and/or reprogrammable. Vascular function is a fundamental pillar of homeostasis, and dysfunction results in systemic consequences for the organism. Additionally, vascular failure can occur downstream of organ disease or environmental stress, often driving an exacerbation of symptoms and pathologies originally independent of the local circulation. The understanding of the molecular mechanisms underlying endothelial physiology and metabolism holds the promise to inform and improve diagnosis, prognosis and treatment options for a myriad of conditions as unrelated as cancer, neurodegeneration or pulmonary hypertension, and likely everything in between, if we consider that also treatments for such conditions are primarily distributed via the bloodstream. However, studying endothelial function has its challenges: the origin, isolation, culture conditions and preconditioning stimuli make this an extremely variable cell type to study and difficult to source. Animal models exist but are neither trivial to generate, nor necessarily adequately translatable to human disease. In this article, we aim to illustrate the breadth of microvascular functions in different environments, highlighting current and pioneering studies that have advanced our insight into the importance of the integrity of this tissue, as well as the limitations posed by its heterogeneity and plasticity.

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“…The localization pattern of fzd4 mRNA is reminiscent of pericytes, a type of perivascular cell associated with capillaries and involved in regulating vascular structure, dynamics and homeostasis. 29,30 The presence of pericytes has been previously reported, by transmission electron microscopy, as a component of the adult zebrafish retinal vasculature 23 and, more recently, by the presence of platelet-derived growth factor receptor ß (pdgfrß) positive cells surrounding the hyaloid vasculature of 72 hpf fish larvae. 31 In order to confirm the presence and identity of pericytes in adult retinas, we performed single fluorescent ISH staining with two known pericyte markers, notch3 31 and pdgfrß mRNA.…”

Section: Localization Of Fzd4 Mrna In the Retinal Vasculaturementioning

confidence: 99%

Frizzled 4 regulates ventral blood vessel remodeling in the zebrafish retina

Cáceres

Prykhozhij

Cairns

et al. 2019

Developmental Dynamics

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Background Familial exudative vitreoretinopathy (FEVR) is a rare congenital disorder characterized by a lack of blood vessel growth to the periphery of the retina with secondary fibrovascular proliferation at the vascular‐avascular junction. These structurally abnormal vessels cause leakage and hemorrhage, while the fibroproliferative scarring results in retinal dragging, detachment and blindness. Mutations in the FZD4 gene represent one of the most common causes of FEVR. Methods A loss of function mutation resulting from a 10‐nucleotide insertion into exon 1 of the zebrafish fzd4 gene was generated using transcription activator‐like effector nucleases (TALENs). Structural and functional integrity of the retinal vasculature was examined by fluorescent microscopy and optokinetic responses. Results Zebrafish retinal vasculature is asymmetrically distributed along the dorsoventral axis, with active vascular remodeling on the ventral surface of the retina throughout development. fzd4 mutants exhibit disorganized ventral retinal vasculature with discernable tubular fusion by week 8 of development. Furthermore, fzd4 mutants have impaired optokinetic responses requiring increased illumination. Conclusion We have generated a visually impaired zebrafish FEVR model exhibiting abnormal retinal vasculature. These fish provide a tractable system for studying vascular biology in retinovascular disorders, and demonstrate the feasibility of using zebrafish for evaluating future FEVR genes identified in humans.

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Mural-Endothelial cell-cell interactions stabilize the developing zebrafish dorsal aorta

Cited by 91 publications

References 73 publications

Robust differentiation of human pluripotent stem cells into endothelial cells via temporal modulation of ETV2 with modified mRNA

Robust differentiation of human pluripotent stem cells into endothelial cells via temporal modulation of ETV2 with modified mRNA

Endothelial cells and organ function: applications and implications of understanding unique and reciprocal remodelling

Frizzled 4 regulates ventral blood vessel remodeling in the zebrafish retina

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