Robert Monette scite author profile

The objective of this study was to generate an immortal cell line representative of specialized human brain microvascular endothelia forming the blood-brain barrier (BBB) in vivo. Human capillary and microvascular endothelial cells (HCEC) were transfected with the plasmid pSV3-neo coding for the SV40 large T antigen and the neomycin gene. The neomycin-resistant transfected cells overcame proliferative senescence, and after a 6-8 wk period of crisis produced immortalization-competent cell colonies. Single-cell clones of near-diploid genotype were isolated from these colonies, propagated, and characterized. Immortalized HCEC (SV-HCEC) exhibited accelerated proliferation rates, but remained serum and anchorage dependent and retained the characteristic cobblestone morphology at confluence. SV-HCEC displayed a stable nuclear expression of SV40 large T antigen, lacked the invasiveness of transformed cells, and maintained major phenotypic properties of early passage control cells including expression of factor VIII-related antigen, uptake of acetylated low-density lipoprotein, binding of fluorescently labeled lectins, expression of transferrin receptor and transferrin receptor-mediated endocytosis, and high activities of the BBB-specific enzymes alkaline phosphatase and gamma-glutamyl transpeptidase. The diffusion of radiolabeled sucrose across SV-HCEC monolayers was fivefold lower than that observed with human lung microvascular endothelial cells. Furthermore, media conditioned by fetal human astrocytes increased the transendothelial electrical resistance of SV-HCEC monolayers by 2.5-fold. Therefore, this newly established human cell line expressing the specialized phenotype of BBB endothelium may serve as a readily available in vitro model for studying the properties of the human BBB.

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Semaphorin3A elevates vascular permeability and contributes to cerebral ischemia-induced brain damage

Hou

Nilchi

et al. 2015

Sci Rep

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Semaphorin 3A (Sema3A) increased significantly in mouse brain following cerebral ischemia. However, the role of Sema3A in stroke brain remains unknown. Our aim was to determine wether Sema3A functions as a vascular permeability factor and contributes to ischemic brain damage. Recombinant Sema3A injected intradermally to mouse skin, or stereotactically into the cerebral cortex, caused dose- and time-dependent increases in vascular permeability, with a degree comparable to that caused by injection of a known vascular permeability factor vascular endothelial growth factor receptors (VEGF). Application of Sema3A to cultured endothelial cells caused disorganization of F-actin stress fibre bundles and increased endothelial monolayer permeability, confirming Sema3A as a permeability factor. Sema3A-mediated F-actin changes in endothelial cells were through binding to the neuropilin2/VEGFR1 receptor complex, which in turn directly activates Mical2, a F-actin modulator. Down-regulation of Mical2, using specific siRNA, alleviated Sema3A-induced F-actin disorganization, cellular morphology changes and endothelial permeability. Importantly, ablation of Sema3A expression, cerebrovascular permeability and brain damage were significantly reduced in response to transient middle cerebral artery occlusion (tMCAO) and in a mouse model of cerebral ischemia/haemorrhagic transformation. Together, these studies demonstrated that Sema3A is a key mediator of cerebrovascular permeability and contributes to brain damage caused by cerebral ischemia.

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Molecular mechanisms of glutamate neurotoxicity in mixed cultures of NT2‐derived neurons and astrocytes: Protective effects of coenzyme Q₁₀

Sandhu

Pandey

Ribecco-Lutkiewicz

et al. 2003

J of Neuroscience Research

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Although glutamate excitotoxicity has long been implicated in neuronal cell death associated with a variety of neurological disorders, the molecular mechanisms underlying this process are not yet fully understood. In part, this is due to the lack of relevant experimental cell systems recapitulating the in vivo neuronal environment, mainly neuronal-glial interactions. To explore these mechanisms, we have analyzed the cytotoxic effects of glutamate on mixed cultures of NT2/N neurons and NT2/A astrocytes derived from human NT2/D1 cells. In these cultures, the neurons were resistant to glutamate alone (up to 2 mM for 24-48 hr), but they responded to a simultaneous exposure to 0.5 mM glutamate and 6 hr of hypoxia. Neuronal cell death occurred during subsequent periods of reoxygenation (>30% within 24 hr). This was associated with a marked decrease of intracellular ATP, a significant increase in reactive oxygen species (ROS) and downregulation of glutamate uptake by astrocytes. Thus, under energy failure and high levels of ROS production, only the neurons from these mixed cultures succumbed to glutamate neurotoxicity; the astrocytic cells remained unaffected by the treatment. Taken together, our data suggested that glutamate excitotoxicity might be due to the energy failure and oxidative stress affecting the properties of the NMDA glutamate receptors and causing impairment of glutamate transporters. Cells pretreated for 72 hr with 10 microg/ml of coenzyme Q(10) (functions both as a ROS scavenger and co-factor of mitochondrial electron transport), were protected, suggesting a useful role for coenzyme Q(10) in treatments of neurological diseases associated with glutamate excitotoxicity. A model of the complex interactions between neurons and astrocytes in regulating glutamate metabolism is presented.

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In Vitro Studies of Antifreeze Glycoprotein (AFGP) and a C-Linked AFGP Analogue

et al. 2007

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Antifreeze glycoproteins (AFGPs) are a subclass of biological antifreezes found in deep sea Teleost fish. These compounds have the ability to depress the freezing point of the organism such that it can survive the subzero temperatures encountered in its environment. This physical property is very attractive for the cryopreservation of cells, tissues, and organs. Recently, our laboratory has designed and synthesized a functional carbon-linked (Clinked) AFGP analogue (1) that demonstrates tremendous promise as a novel cryoprotectant. Herein we describe the in Vitro effects and interactions of C-linked AFGP analogue 1 and native AFGP 8. Our studies reveal that AFGP 8 is cytotoxic to human embryonic liver and human embryonic kidney cells at concentrations higher than 2 and 0.63 mg/mL, respectively, whereas lower concentrations are not toxic. The mechanism of this cytotoxicity is consistent with apoptosis because caspase-3/7 levels are significantly elevated in cell cultures treated with AFGP 8. In contrast, C-linked AFGP analogue 1 displayed no in Vitro cytotoxicity even at high concentrations, and notably, caspase-3/7 activities were suppressed well below background levels in cell lines treated with 1. Although the results from these studies limit the human applications of native AFGP, they illustrate the benefits of developing functional C-linked AFGP analogues for various medical, commercial and industrial applications.

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Robert Monette

Development of immortalized human cerebromicrovascular endothelial cell line as an in vitro model of the human blood–brain barrier

Semaphorin3A elevates vascular permeability and contributes to cerebral ischemia-induced brain damage

Molecular mechanisms of glutamate neurotoxicity in mixed cultures of NT2‐derived neurons and astrocytes: Protective effects of coenzyme Q₁₀

In Vitro Studies of Antifreeze Glycoprotein (AFGP) and a C-Linked AFGP Analogue

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Robert Monette

Development of immortalized human cerebromicrovascular endothelial cell line as an in vitro model of the human blood–brain barrier

Semaphorin3A elevates vascular permeability and contributes to cerebral ischemia-induced brain damage

Molecular mechanisms of glutamate neurotoxicity in mixed cultures of NT2‐derived neurons and astrocytes: Protective effects of coenzyme Q10

In Vitro Studies of Antifreeze Glycoprotein (AFGP) and a C-Linked AFGP Analogue

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Molecular mechanisms of glutamate neurotoxicity in mixed cultures of NT2‐derived neurons and astrocytes: Protective effects of coenzyme Q₁₀