Blood‐brain barrier development: Systems modeling and predictive toxicology

Saili, Katerine S.; Zurlinden, Todd J.; Schwab, Andrew J.; Silvin, Aymeric; Baker, Nancy C.; Hunter, E. Sidney; Ginhoux, Florent; Knudsen, Thomas B.

doi:10.1002/bdr2.1180

Cited by 56 publications

(30 citation statements)

References 253 publications

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“…Interactions between these NVU cell types is important for a variety of physiological processes such as angiogenesis, vessel maintenance and permeability, metabolic support, and regulation of blood flow (Brown et al 2019;McConnell et al 2017). The development of the NVU begins around embryonic day (E) 9.5 in mice, when specialized endothelial cells branch from vessels of the perineural vascular plexus to form capillaries that invade nearby neural tissue (Saili et al 2017). Pericytes associate with endothelial cells as nascent vessels generate at E9.5 (Armulik et al 2010;Bauer et al 1993;Yamanishi et al 2012;Daneman et al 2010) and these interactions are critical to form the BBB (Zlokovic 2008;Daneman et al 2010).…”

Section: Introductionmentioning

confidence: 99%

A Developmental Analysis of Juxtavascular Microglia Dynamics and Interactions with the Vasculature

et al. 2020

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Microglia, the resident macrophages of the central nervous system (CNS), are dynamic cells, 2 constantly extending and retracting their processes as they contact and functionally regulate 3 neurons and other glial cells. There is far less known about microglia-vascular interactions, 4 particularly under healthy steady-state conditions. Here, we use the male and female mouse 5 cerebral cortex to show that a higher percentage of microglia associate with the vasculature 6 during the first week of postnatal development compared to older ages and the timing of these 7 associations are dependent on the fractalkine receptor (CX3CR1). Similar developmental 8 microglia-vascular associations were detected in the prenatal human brain. Using live imaging 9 in mice, we found that juxtavascular microglia migrated when microglia are actively colonizing the cortex and became stationary by adulthood to occupy the same vascular space for nearly 2 months. Further, juxtavascular microglia at all ages contact vascular areas void of astrocyte endfeet and the developmental shift in microglial migratory behavior along vessels corresponded to when astrocyte endfeet more fully ensheath vessels. Together, our data provide a comprehensive assessment of microglia-vascular interactions. They support a mechanism by which microglia use the vasculature to migrate within the developing brain parenchyma. This migration becomes restricted upon the arrival of astrocyte endfeet when juxtavascular microglia then establish a long-term, stable contact with the vasculature.

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Section: Introductionmentioning

confidence: 99%

A Developmental Analysis of Juxtavascular Microglia Dynamics and Interactions with the Vasculature

et al. 2020

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“…The Blood-Brain Barrier as a Chemical Defense Another key function of the BBB is to regulate the flux of neurotransmitters/neuromodulators, hormones, and other molecules from the blood to the brain and vice versa. The brief summary that follows is based on studies of mammals such as rats, dogs, and humans, even though several BBB mechanisms are surprisingly conserved in both vertebrates and invertebrates (see DeSalvo et al 2014;Hindle and Bainton 2014;Hindle et al 2017;Saili et al 2017). For some molecules such as serotonin and steroid hormones, the flux is bidirectional; other molecules only flow from the blood to the brain (influx) as, for example, insulin and thyroid hormone.…”

Section: Securing the Brain: Possible Hostmentioning

confidence: 99%

“…The molecules that are only transported out of the brain (efflux) include GABA, glutamate, norepinephrine, dopamine, and the dopamine metabolite homovanillic acid (HVA). There are also active transporters that expel a variety of toxins and other foreign substances (xenobiotics), as well as metabolizing enzymes that inactivate them (Ohtsuki 2004;Banks 2012;Zhao et al 2015;Saili et al 2017). By clearing neuroactive molecules such as dopamine and GABA, the BBB probably contributes to regulate neurotransmission (Ohtsuki 2004).…”

Section: Securing the Brain: Possible Hostmentioning

confidence: 99%

Invisible Designers: Brain Evolution Through the Lens of Parasite Manipulation

Giudice¹

2019

The Quarterly Review of Biology

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keywords behavior, brain evolution, hormones, neurobiology, parasite-host interactions, parasite manipulation abstract The ability of parasites to manipulate host behavior to their advantage has been studied extensively, but the impact of parasite manipulation on the evolution of neural and endocrine mechanisms has remained virtually unexplored. If selection for countermeasures has shaped the evolution of nervous systems, many aspects of neural functioning are likely to remain poorly understood until parasites-the brain's invisible designers-are included in the picture. This article offers the first systematic discussion of brain evolution in light of parasite manipulation. After reviewing the strategies and mechanisms employed by parasites, the paper presents a taxonomy of host countermeasures with four main categories, namely: restrict access to the brain; increase the costs of manipulation; increase the complexity of signals; and increase robustness. For each category, possible examples of countermeasures are explored, and the likely evolutionary responses by parasites are considered. The article then discusses the metabolic, computational, and ecological constraints that limit the evolution of countermeasures. The final sections offer suggestions for future research and consider some implications for basic neuroscience and psychopharmacology. The paper aims to present a novel perspective on brain evolution, chart a provisional way forward, and stimulate research across the relevant disciplines.

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“…2,3 OCMs are being constructed from increasingly advanced materials and human stem cell sources, including embryonic stem cells and induced pluripotent stem cells (iPSCs). 4 A critical tissue of interest for modeling chemical toxicity is the neurovasculature of the central nervous system (CNS), which supplies blood to the brain, spinal cord, and the eye.…”

Section: Introductionmentioning

confidence: 99%

“…Endothelial cells (ECs) of the neurovascular interact with supporting cell types, including astrocytes (ACs), pericytes (PCs), and neurons to form the neurovascular unit (NVU), 4 which maintains stable blood flow to and from the CNS. Hypoxia, ischemia, and cerebral hypoperfusion resulting from NVU failure can cause the onset of neurodevelopmental or neurodegenerative diseases, including Alzheimer's disease, [5][6][7][8] Parkinson's disease, 9,10 autism spectrum disorders, 11,12 and diabetic retinopathy.…”

Section: Introductionmentioning

confidence: 99%

Neurovascular Organotypic Culture Models Using Induced Pluripotent Stem Cells to Assess Adverse Chemical Exposure Outcomes

Nguyen

Dombroe

Fisk

et al. 2019

Applied In Vitro Toxicology

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Introduction: Human-induced pluripotent stem cells (iPSCs) represent a promising cell source for the construction of organotypic culture models for chemical toxicity screening and characterization. Materials and Methods: To characterize the effects of chemical exposure on the human neurovasculature, we constructed neurovascular unit (NVU) models consisting of endothelial cells (ECs) and astrocytes (ACs) derived from human-iPSCs, as well as human brain-derived pericytes (PCs). The cells were cocultured on synthetic poly(ethylene glycol) (PEG) hydrogels that guided the self-assembly of capillary-like vascular networks. High-content epifluorescence microscopy evaluated dose-dependent changes to multiple aspects of NVU morphology. Results: Cultured vascular networks underwent quantifiable morphological changes when incubated with vascular disrupting chemicals. The activity of predicted vascular disrupting chemicals from a panel of 38 compounds (U.S. Environmental Protection Agency) was ranked based on morphological features detected in the NVU model. In addition, unique morphological neurovascular disruption signatures were detected per chemical. A comparison of PEG-based NVU and Matrigel Ô-based NVU models found greater sensitivity and consistency in chemical detection by the PEG-based NVU models. Discussion: We suspect that specific morphological changes may be used for discerning adverse outcome pathways initiated by chemical exposure and rapid mechanistic characterization of chemical exposure to neurovascular function. Conclusion: The use of human stem cell-derived vascular tissue and PEG hydrogels in the construction of NVU models leads to rapid detection of adverse chemical effects on neurovascular stability. The use of multiple cell types in coculture elucidates potential mechanisms of action by chemicals applied to the model.

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Blood‐brain barrier development: Systems modeling and predictive toxicology

Cited by 56 publications

References 253 publications

A Developmental Analysis of Juxtavascular Microglia Dynamics and Interactions with the Vasculature

A Developmental Analysis of Juxtavascular Microglia Dynamics and Interactions with the Vasculature

Invisible Designers: Brain Evolution Through the Lens of Parasite Manipulation

Neurovascular Organotypic Culture Models Using Induced Pluripotent Stem Cells to Assess Adverse Chemical Exposure Outcomes

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