Astrocytic contributions to blood-brain barrier (BBB) formation by endothelial cells: A possible use of aortic endothelial cell for In vitro BBB model

Astrocytic contribution of endothelial cell monolayer permeability was examined in two blood-brain barrier (BBB) models, using the coculture in a double chamber system: rat astrocytes and bovine aortic endothelial cells (BAECs) or bovine brain endothelial cells (BBECs). In system 1, where astrocytes were separated from endothelial cells, a 40% reduction in -glucose permeability of the BBEC monolayer, but not the BAEC monolayer, was observed by cocultivation with astrocytes. Although several passages of BBEC in culture elicited morphological transformation from spindle-shapes to cobblestone-like features, the passaged BBECs remained responsive to astrocytes in coculture in system 1 (37% reduction of the -glucose permeability). By contrast, in system 2, where respective endothelial cells and astrocytes layered on the upper and lower surfaces of a membrane, the permeability of both BAEC and BBEC monolayers was reduced by cocultivation with astrocytes (75% reduction for BAEC and 40% reduction for BBEC). BAECs in this contiguous coculture (system 2) with astrocytes showed numerous tight junction-like structures characteristic of the BBB in vivo. These results suggest that primary cultured BBECs, which had been primed by astrocytes in vivo, retain a higher sensitivity to astrocytes possibly through an astrocytic soluble factor (s) to exhibit BBB-specific phenotypes, and that even BAEC from extra-neural tissues, when cultured with astrocytes in close proximity in vitro, may acquire the similar phenotypes and serve for an extensive use of BBB model in vitro.     

sAPP modulates iron efflux from brain microvascular endothelial cells by stabilizing the ferrous iron exporter ferroportin

A sequence within the E2 domain of soluble amyloid precursor protein (sAPP) stimulates iron efflux. This activity has been attributed to a ferroxidase activity suggested for this motif. We demonstrate that the stimulation of efflux supported by this peptide and by sAPPα is due to their stabilization of the ferrous iron exporter, ferroportin (Fpn), in the plasma membrane of human brain microvascular endothelial cells (hBMVEC). The peptide does not bind ferric iron explaining why it does not and thermodynamically cannot promote ferrous iron autoxidation. This peptide specifically pulls Fpn down from the plasma membrane of hBMVEC; based on these results, FTP, for ferroportin‐targeting peptide, correctly identifies the function of this peptide. The data suggest that in stabilizing Fpn via the targeting due to the FTP sequence, sAPP will increase the flux of iron into the cerebral interstitium. This inference correlates with the observation of significant iron deposition in the amyloid plaques characteristic of Alzheimer's disease.     

Ferritin accumulation under iron scarcity in Drosophila iron cells

Ferritins are highly stable, multi-subunit protein complexes with iron-binding capacities that reach 4500 iron atoms per ferritin molecule. The strict dependence of cellular physiology on an adequate supply of iron cofactors has likely been a key driving force in the evolution of ferritins as iron storage molecules. The insect intestine has long been known to contain cells that are responsive to dietary iron levels and a specialized group of “iron cells” that always accumulate iron-loaded ferritin, even when no supplementary iron is added to the diet. Here, we further characterize ferritin localization in Drosophila melanogaster larvae raised under iron-enriched and iron-depleted conditions. High dietary iron intake results in ferritin accumulation in the anterior midgut, but also in garland (wreath) cells and in pericardial cells, which together filter the circulating hemolymph. Ferritin is also abundant in the brain, where levels remain unaltered following dietary iron chelation, a treatment that depletes ferritin from the aforementioned tissues. We attribute the stability of ferritin levels in the brain to the function of the blood-brain barrier that may shield this organ from systemic iron fluctuations. Most intriguingly, our dietary manipulations demonstrably iron-depleted the iron cells without a concomitant reduction in their production of ferritin. Therefore, insect iron cells may constitute an exception from the evolutionary norm with respect to iron-dependent ferritin regulation. It will be of interest to decipher both the physiological purpose served and the mechanism employed to untie ferritin regulation from cellular iron levels in this cell type.     

Restored vulnerability of cultured endothelial cells to high glucose by iron replenishment.

High glucose (HG) concentrations are toxic to various cells in vivo, but cells become insensitive to HG toxicity when they are subcultured serially in vitro. Oxidative stress is involved in HG toxicity, and metal ions, especially iron, mediate some oxidative stress. To investigate mechanisms involved in the insensitiveness of cultured cells to HG toxicity, we focused on the level of intracellular iron. Freshly prepared human umbilical vein endothelial cells contained a substantial amount of iron, whereas its level decreased rapidly during the course of culture (to less than 10%). The iron content was restored by incubation of the cells with Fe(III)/8-hydroxyquinoline, and the iron-supplemented cells were more susceptible to both oxidant- and HG-induced injury. Under the HG conditions, the iron-loaded cells were subjected to higher levels of oxidative stress. The enhanced HG toxicity by iron was attenuated by the treatment with several antioxidants including catalase, ascorbic acid, and pyruvate. These data suggested that the insensitiveness of subcultured cells to HG toxicity is, at least in part, due to rapid and dramatic loss of intracellular iron. Supplementation with iron is useful to restore the vulnerability of cultured cells to HG that is normally observed in in vivo situations.     

Metabolic capacity regulates iron homeostasis in endothelial cells

The sensitivity of endothelial cells to oxidative stress and the high concentrations of iron in mitochondria led us to test the hypotheses that (1) changes in respiratory capacity alter iron homeostasis, and (2) lack of aerobic metabolism decreases labile iron stores and attenuates oxidative stress. Two respiration-deficient (rho(o)) endothelial cell lines with selective deletion of mitochondrial DNA (mtDNA) were created by exposing a parent endothelial cell line (EA) to ethidium bromide. Surviving cells were cloned and mtDNA-deficient cell lines were demonstrated to have diminished oxygen consumption. Total cellular and mitochondrial iron levels were measured, and iron uptake and compartmentalization were measured by inductively coupled plasma atomic emission spectroscopy. Iron transport and storage protein expression were analyzed by real-time polymerase chain reaction and Western blot or ELISA, and total and mitochondrial reactive oxygen species (ROS) generation was measured. Mitochondrial iron content was the same in all three cell lines, but both rho(o) lines had lower iron uptake and total cellular iron. Protein and mRNA expressions of major cytosolic iron transport constituents were down-regulated in rho(o) cells, including transferrin receptor, divalent metal transporter-1 (-IRE isoform), and ferritin. The mitochondrial iron-handling protein, frataxin, was also decreased in respiration-deficient cells. The rho(o) cell lines generated less mitochondrial ROS but released more extracellular H(2)O(2), and demonstrated significantly lower levels of lipid aldehyde formation than control cells. In summary, rho(o) cells with a minimal aerobic capacity had decreased iron uptake and storage. This work demonstrates that mitochondria regulate iron homeostasis in endothelial cells.     

Telomere attrition and accumulation of senescent cells in cultured human endothelial cells

The human umbilical vein endothelial cell (HUVEC) is an important model of the human endothelium that is widely used in vascular research. HUVECs and the adult endothelium share many characteristics including progression into senescence as the cells age. Despite this, the shortening of telomeres and its relationship to the progression into senescence are poorly defined in HUVECs. In this study of several HUVEC lines we show notable consistency in their growth curves. There is a steady decline in the growth rate of HUVECs grown continually in culture and we estimate complete cessation of growth after approximately 70 population doublings. The HUVECs lose telomeric DNA at a consistent rate of 90 base pairs/population doubling and show a progressive accumulation of shortened telomeres (below 5 kilobases). This telomeric loss correlates with the accumulation of senescent HUVECs in culture as assessed by staining for beta-galactosidase activity at pH 6. Although the telomere length of a large population of cells is a relatively crude measure, we suggest that in HUVECs a mean telomere length (as measured by terminal restriction fragment length) of 5 kilobases is associated with entry into senescence. These data demonstrate the strong relationship between telomere attrition and cell senescence in HUVECs. They suggest that DNA damage and subsequent telomere attrition are likely to be key mechanisms driving the development of endothelial senescence in the pathogenesis of vascular disease.     

Comparison of binding and cyclic GMP accumulation by atrial natriuretic peptides in endothelial cells

Rat 125I-labeled atrial natriuretic factor (ANF (8-33)) was used to identify ANF receptors on cultured bovine aortic endothelial cells. Specific binding of 125I-ANF at 37 degrees C to confluent endothelial cells was saturable and of high affinity. Scatchard analysis of the equilibrium binding data indicated that endothelial cells contain a single class of binding sites with a Kd of 0.1 +/- 0.01 nM. This particular clone of endothelial cells had 16000 +/- 1300 receptors per cell. The order of potency for competing with 125I-ANF binding was human atrial natriuretic peptide (hANP) = atrial natriuretic factor (ANF (8-33)) greater than atriopeptin II greater than atriopeptin III greater than atriopeptin. The weakest competitor, atriopeptin I, had a K1 of 0.45 nM, which was only 6-fold higher than the K1 for hANP and ANF (8-33). ANF (8-33) and hANP in the presence of 0.5 mM isobutylmethyl-xanthine produced a 15-20-fold increase in cyclic GMP content at 10 pM and a maximal 500-fold elevation of cyclic GMP at 10 nM. The concentrations required to elicit a half-maximal increase in cyclic GMP for hANP, ANF (8-33), atriopeptin I, atriopeptin II and atriopeptin III were 0.30, 0.35, greater than 500, 4.0 and 5.0 nM, respectively. Although atriopeptin I acted as a partial agonist, it was unable to antagonize the effect of ANF (8-33) on cyclic GMP formation. These findings suggest that endothelial cells have multiple and functionally distinct ANF-binding sites.     

Homocysteine altered ROS generation and NO accumulation in endothelial cells

Mild hyperhomocysteinemia (HHcy) is a risk factor for vascular disease and is closely associated with endothelial dysfunction. Oxidative stress and decreased nitric oxide (NO) bioavailability were reported in HHcy-induced vascular injury; however, the exact relationship is not understood. We thus directly determine the production of reactive oxygen species (ROS) and NO in cultured endothelial cells (HUVECs) to demonstrate the correlated variation between ROS and NO induced by Hcy (homocysteine), Cys (cysteine), another thiol compound, and Met (methionine), precursor of HHcy in animal study. HUVECs were treated with Hcy, Cys, or Met for 0.5 or 22-24 h; ROS generation was detected by DCF fluorescence with flow cytometry and NO by chemiluminescence. In non-cytotoxic (<1.0 mM) concentration ranges, Met exerted no effects on either ROS production or NO concentration, Cys decreased ROS production and increased NO in both short-term (0.5 h) and long-term (22-24 h) treatments; Hcy, however, induced a biphasic effect on ROS production, i.e., inhibitory at 0.5 h but stimulatory at 24 h. The maximal stimulation by Hcy (0.25 mM) was significantly reduced by co-incubation (12 h) with estrogen (1 microM). Hcy caused an early (0.5 h) increase of medium NO which was absent in long-term Hcy treatment. The oxidative stress caused by long-term Hcy incubation could be ameliorated by estrogen, consistent with earlier in vivo observations that estrogen prevents HHcy-induced injury.     

Brain capillary endothelial cells mediate iron transport into the brain by segregating iron from transferrin without the involvement of divalent metal transporter 1

Rats were studied for [(59)Fe-(125)I]transferrin uptake in total brain, and fractions containing brain capillary endothelial cells (BCECs) or neurons and glia. (59)Fe was transported through BCECs, whereas evidence of similar transport of transferrin was questionable. Intravenously injected transferrin localized to BCECs and failed to accumulate within neurons, except near the ventricles. No significant difference in [(125)I]transferrin distribution was observed between Belgrade b/b rats with a mutation in divalent metal transporter I (DMT1), and Belgrade +/b rats with regard to accumulation in vascular and postvascular compartments. (59)Fe occurred in significantly lower amounts in the postvascular compartment in Belgrade b/b rats, indicating impaired iron uptake by transferrin receptor and DMT1-expressing neurons. Immunoprecipitation with transferrin antibodies on brains from Belgrade rats revealed lower uptake of transferrin-bound (59)Fe. In postnatal (P)0 rats, less (59)Fe was transported into the postvascular compartment than at later ages, suggesting that BCECs accumulate iron at P0. Supporting this notion, an in situ perfusion technique revealed that BCECs accumulated ferrous and ferric iron only at P0. However, BCECs at P0 together with those of older age lacked DMT1. In conclusion, BCECs probably mediate iron transport into the brain by segregating iron from transferrin without involvement of DMT1.     

Heme-oxygenase-mediated iron accumulation in the liver

Heme oxygenase (HO) isozymes, HO-1 and HO-2, catalyze the conversion of heme to iron, carbon monoxide, and biliverdin. The present study was aimed at elucidating the role of the HO system in iron accumulation and oxidative stress in the liver. We have also studied the regulation of an iron exporter, ferroportin-1 (FPN-1), as an adaptive response mechanism to increased iron levels. Sprague-Dawley rats were treated with HO inducer hemin or HO inhibitor tin-protoporphyrin IX (SnPPIX) for 1 month. A portion of liver tissues was subjected to RT-PCR for HO-1, HO-2, and FPN-1 gene expression as well as an HO activity assay. Paraffin-embedded tissues were stained for iron with Prussian blue. Hepatic iron concentration was measured by High Resolution-Inductively Coupled Plasma-Mass Spectrometry. 8-hydroxy-2'-deoxyguanosine (8-OHdG) stain, a sensitive and specific marker of oxidative DNA damage, was performed to assess oxidative stress. Hemin treatment led to augmented HO expression and activity in association with increased iron accumulation and oxidative stress. FPN-1 expression was also found to be upregulated. SnPPIX treatment reduced HO activity, intracellular iron levels, and oxidative stress as compared to controls. Our data provides evidence of increased HO activity as an important pro-oxidant mechanism leading to iron accumulation in the liver.     

哇巴因作用于血管内皮细胞的基因表达谱分析

目的:研究0.3 nmol/L哇巴因(ouabain)作用下血管内皮细胞的基因谱改变.方法:以包含8464条人类基因的DNA芯片检测血管内皮细胞受0.3 nmol/L哇巴因活化后的基因表达谱.结果:血管内皮细胞受哇巴因作用2 h后,340条基因出现表达差异,其中上调的共有145 条,多数与细胞代谢和转录调控相关.结论:提示哇巴因可能参与血管内皮细胞的正常生长代谢.     

Gene expression profiles of endothelial progenitor cells by oligonucleotide microarray analysis

Among the many tissue stem or progenitor cells recently being unveiled, endothelial progenitor cells (EPCs) have attracted particular attention, not only because of their cardinal role in vascular biology and embryology but also because of their potential use in the therapeutic development of a variety of postnatal diseases, including cardiovascular and peripheral vascular disorders and cancer. The aim of this study is to provide some basic and comprehensive information on gene expression of EPCs to characterize the cells in molecular terms. Here, we focus on EPCs derived from CD34-positive mononuclear cells of human umbilical cord blood. The EPCs were purified and expanded in culture and analyzed by a high-density oligonucleotide microarray and real-time RT-PCR analysis. We identified 169 up-regulated and 107 down-regulated genes in the EPCs compared with three differentiated endothelial cells of human umbilical vein endothelial cells (HUVEC), human lung microvascular endothelial cells (LMEC) and human aortic endothelial cells (AoEC). It is expected that the obtained list include key genes which are critical for EPC function and survival and thus potential targets of EPC recognition in vivo and therapeutic modulation of vasculogenesis in cancer as well as other diseases, in which de novo vasculogenesis plays a crucial role. For instance, the list includes Syk and galectin-3, which encode protein tyrosine kinase and β-galactoside-binding protein, respectively, and are expressed higher in EPCs than the three control endothelial cells. In situ hybridization showed that the genes were expressed in isolated cells in the fetal liver at E11.5 and E14.5 of mouse development.     

Evaluation of bone-derived and marrow-derived vascular endothelial cells by microarray analysis

This study focused on the differential expression levels of proteins that may exist between bone-derived and marrow-derived vascular endothelial cells (BVEC and MVEC). The vascular cells were isolated from trabecular bone regions and central marrow cavity regions of mouse long bones. Cells were cultured for 1 week to expand the population then separated from non-vascular cells using biotinylated isolectin B4, streptavidin-coated metallic microbeads, and a magnetic column. After an additional week of culture time, RNA was isolated from both cell types and compared using microarray analysis. RT-PCR was used to confirm and relatively quantitate the RNA messages. The bone-derived cells expressed more aldehyde dehydrogenase 3A1 (ALDH3A1), Secreted Modular Calcium-2 (SMOC-2), CCAAT enhancer binding protein (C/EBP-beta), matrix metalloproteinase 13 (MMP-13), and annexin 8 (ANX8) than the marrow-derived cells. Spalpha and matrix GLA-protein (MGP) were produced in greater abundance by the marrow-derived cells. This study reveals that there are profound and unique differences between the vasculature of the metaphysis as compared to that of the central marrow cavity. The unique array of proteins expressed by the bone-derived endothelial cells may support growth of tumors from cancer cells that frequently metastasize and lodge in the trabecular bone regions.     

Progressive iron accumulation induces a biphasic change in the glutathione content of neuroblastoma cells

Glutathione (GSH) constitutes the single most important antioxidant in neurons, whereas iron causes oxidative stress that leads to cell damage and death. Although GSH and iron produce opposite effects on redox cell status, no mechanistic relationships between iron and GSH metabolism are known. In this work, we evaluated in SH-SY5Y neuroblastoma cells the effects of iron accumulation on intracellular GSH metabolism. After 2 d exposure to increasing concentrations of iron, cells underwent concentration-dependent iron accumulation and a biphasic change in intracellular GSH levels. Increasing iron from 1 to 5 microM resulted in a marked increase in intracellular oxidative stress and increased GSH levels. Increased GSH levels were due to increased synthesis. Further increases in iron concentration led to significant reduction in both reduced (GSH) and total (GSH + (2 x GSSG)) glutathione. Cell exposure to high iron concentrations (20-80 microM) was associated with a marked decrease in the GSH/GSSG molar ratio and the GSH half-cell reduction potential. Moreover, increasing iron from 40 to 80 microM resulted in loss of cell viability. Iron loading did not change GSH reductase activity but induced significant increases in GSH peroxidase and GSH transferase activities. The changes in GSH homeostasis reported here recapitulate several of those observed in Parkinson's disease substantia nigra. These results support a model by which progressive iron accumulation leads to a progressive decrease in GSH content and cell reduction potential, which finally results in impaired cell integrity.     

Angiotensin-converting enzyme: accumulation in medium from cultured endothelial cells.

The activity of angiotensin converting enzyme has been measured in endothelial cells cultured from hog aorta, and in serum-free culture medium taken from both endothelial cells and smooth muscle cells. Endothelial cells maintained in medium containing 20% fetal calf serum contained 43 pmol/min/10⁶ cells of converting enzyme activity; freshly collected cells contained 518 pmol/min/10⁶ cells. Endothelial cells held in serum-free medium release this activity into the medium in amounts up to 40 times that associated with the cells; at the same time the activity associated with the cells rises 2 fold. The rise in cell-associated activity and the appearance of activity in the medium are both blocked by cycloheximide. These observations provide direct evidence that endothelial cells can produce excess angiotensin-converting enzyme and release it in active form, and thus serve as the source of circulating converting enzyme activity.     

Microarray analysis of shear stressed endothelial cells

The cDNA microarray is an extremely beneficial tool for study of differential gene expression in the cardiovascular system. This technique is used in many different applications including drug discovery, environmental science, and the effects of mechanical forces on vascular cell phenotype. The paper reviews work by others, and describes our study on effects of shear stress on vascular endothelial cells. These microarray studies verified earlier findings using Northern and polymerase chain reaction (PCR) analyses in this area; and also found previously unidentified differentially expressed genes, leading to new hypotheses regarding how cells and tissues respond to biochemical and mechanical stimuli.