Your search keyword '"Verdon, Rachel"' showing total 3 results

1. Adoption of in vitro systems and zebrafish embryos as alternative models for reducing rodent use in assessments of immunological and oxidative stress responses to nanomaterials.

Author

Johnston HJ, Verdon R, Gillies S, Brown DM, Fernandes TF, Henry TB, Rossi AG, Tran L, Tucker C, Tyler CR, and Stone V

Subjects

Animals, Animals, Genetically Modified, Embryo, Nonmammalian, Inflammation chemically induced, Inflammation immunology, Macrophages drug effects, Neutrophils immunology, Neutrophils pathology, Reactive Oxygen Species metabolism, Rodentia, Nanostructures toxicity, Oxidative Stress drug effects, Toxicity Tests methods, Zebrafish embryology, Zebrafish immunology

Abstract

Assessing the safety of engineered nanomaterials (NMs) is paramount to the responsible and sustainable development of nanotechnology, which provides huge societal benefits. Currently, there is no evidence that engineered NMs cause detrimental health effects in humans. However, investigation of NM toxicity using in vivo, in vitro, in chemico, and in silico models has demonstrated that some NMs stimulate oxidative stress and inflammation, which may lead to adverse health effects. Accordingly, investigation of these responses currently dominates NM safety assessments. There is a need to reduce reliance on rodent testing in nanotoxicology for ethical, financial and legislative reasons, and due to evidence that rodent models do not always predict the human response. We advocate that in vitro models and zebrafish embryos should have greater prominence in screening for NM safety, to better align nanotoxicology with the 3Rs principles. Zebrafish are accepted for use by regulatory agencies in chemical safety assessments (e.g. developmental biology) and there is growing acceptance of their use in biomedical research, providing strong foundations for their use in nanotoxicology. We suggest that investigation of the response of phagocytic cells (e.g. neutrophils, macrophages) in vitro should also form a key part of NM safety assessments, due to their prominent role in the first line of defense. The development of a tiered testing strategy for NM hazard assessment that promotes the more widespread adoption of non-rodent, alternative models and focuses on investigation of inflammation and oxidative stress could make nanotoxicology testing more ethical, relevant, and cost and time efficient.

Published

2018

2. Renin expression in developing zebrafish is associated with angiogenesis and requires the Notch pathway and endothelium.

Author

Rider SA, Mullins LJ, Verdon RF, MacRae CA, and Mullins JJ

Subjects

Animals, Hemodynamics physiology, Larva, Neovascularization, Physiologic genetics, Receptors, Notch genetics, Receptors, Vascular Endothelial Growth Factor antagonists & inhibitors, Regional Blood Flow physiology, Renin genetics, Signal Transduction genetics, Signal Transduction physiology, Endothelium, Vascular metabolism, Neovascularization, Physiologic physiology, Receptors, Notch metabolism, Renin biosynthesis, Zebrafish metabolism

Abstract

Although renin is a critical regulatory enzyme of the cardiovascular system, its roles in organogenesis and the establishment of cardiovascular homeostasis remain unclear. Mammalian renin-expressing cells are widespread in embryonic kidneys but are highly restricted, specialized endocrine cells in adults. With a functional pronephros, embryonic zebrafish are ideal for delineating the developmental functions of renin-expressing cells and the mechanisms governing renin transcription. Larval zebrafish renin expression originates in the mural cells of the juxtaglomerular anterior mesenteric artery and subsequently at extrarenal sites. The role of renin was determined by assessing responses to renin-angiotensin system blockade, salinity variation, and renal perfusion ablation. Renin expression did not respond to renal flow ablation but was modulated by inhibition of angiotensin-converting enzyme and altered salinity. Our data in larval fish are consistent with conservation of renin's physiological functions. Using transgenic renin reporter fish, with mindbomb and cloche mutants, we show that Notch signaling and the endothelium are essential for developmental renin expression. After inhibition of angiogenesis, renin-expressing cells precede angiogenic sprouts. Arising from separate lineages, but relying on mutual interplay with endothelial cells, renin-expressing cells are among the earliest mural cells observed in larval fish, performing both endocrine and paracrine functions., (Copyright © 2015 the American Physiological Society.)

Published

2015

3. Advanced in vivo imaging of the interactions between vascular and renal development in the zebrafish pronephric kidney

Author

Verdon, Rachel Faye, Pennings, Sari, and Wiegand, Ulrich

Subjects

571.8, pronephros, zebrafish, nephrogenesis, development, cardiovascular, renal, vasculature, microscopy, time-lapse

Abstract

BACKGROUND Heart disease and renal dysfunction are often mutually reinforcing conditions, although the factors underlying this relationship are not fully understood. Cardiac remodelling resulting from disease is partly caused by the reactivation of developmental programmes. By unravelling the mechanisms that drive kidney development and function, it may be possible to gain novel insight into remodelled kidney states that are linked to disease. In this study, we have investigated the interplay between renal and cardiovascular systems during nephrogenesis at the level of the blood filter. METHODOLOGY Owing to the optical transparency and rapid external development of the embryo, the zebrafish provides a research model for advanced imaging technologies, allowing us to visualise structures located deep within living specimens. Here, we combine deep-tissue live imaging and novel functional assays to study development and function of the pronephric kidney - the first and most basic kidney to form in the embryo. RESULTS Using two-photon excitation microscopy, we have successfully established methodology for performing, deep-tissue, time-lapse imaging in living embryos of the two primary cell types forming the kidney – endothelial and epithelial cells. Fluorescence angiograms were performed using supra-vital dye agents to visualise circulatory flow in relation to the pronephric vasculature and the process of blood-filtration. Observations from live imaging studies, supported by immunostaining, were used to create a comprehensive model of the developing glomerular morphology, and interactions at the endothelial-epithelial cell interface, where glomerular epithelial primordia merge around the vascular component of the pronephric kidney. To investigate renal function, we devised a novel assay of pronephric filtration, by tracking the accumulation of injected fluorescent tracers within the excreted filtrate of embryos. This allowed us to relate our time-lapse observations to maturation of the glomerulus, and the evolution of perm-selective function. Finally, we explored methods of mechanically obstructing blood-flow in order to investigate whether altered hemodynamic forces would influence pronephric development. We found that in those embryos with severely disrupted circulatory flow, the glomerular morphology was affected. CONCLUSIONS In summary, the combination of these techniques has allowed us to visualise the multi-cellular organisation of the pronephric kidney over time, which has previously been limited to primarily fixed-tissue approaches. A detailed model of pronephric development has been developed, which could ultimately be used to dissect the molecular mechanisms underlying embryonic kidney development.

Published

2015