Lysophosphatidic acid via LPA-receptor 5/protein kinase D-dependent pathways induces a motile and pro-inflammatory microglial phenotype.

BACKGROUND: Extracellular lysophosphatidic acid (LPA) species transmit signals via six different G protein-coupled receptors (LPAR1-6) and are indispensible for brain development and function of the nervous system. However, under neuroinflammatory conditions or brain damage, LPA levels increase, thereby inducing signaling cascades that counteract brain function. We describe a critical role for 1-oleyl-2-hydroxy-sn-glycero-3-phosphate (termed "LPA" throughout our study) in mediating a motile and pro-inflammatory microglial phenotype via LPAR5 that couples to protein kinase D (PKD)-mediated pathways. METHODS: Using the xCELLigence system and time-lapse microscopy, we investigated the migrational response of microglial cells. Different M1 and M2 markers were analyzed by confocal microscopy, flow cytometry, and immunoblotting. Using qPCR and ELISA, we studied the expression of migratory genes and quantitated the secretion of pro-inflammatory cytokines and chemokines, respectively. Different transcription factors that promote the regulation of pro-inflammatory genes were analyzed by western blot. Reactive oxygen species (ROS) and nitric oxide (NO) production, phagocytosis, and microglial cytotoxicity were determined using commercially available assay kits. RESULTS: LPA induces MAPK family and AKT activation and pro-inflammatory transcription factors' phosphorylation (NF-κB, c-Jun, STAT1, and STAT3) that were inhibited by both LPAR5 and PKD family antagonists. LPA increases migratory capacity, induces secretion of pro-inflammatory cytokines and chemokines and expression of M1 markers, enhances production of ROS and NO by microglia, and augments cytotoxicity of microglial cell-conditioned medium towards neurons. The PKD family inhibitor blunted all of these effects. We propose that interference with this signaling axis could aid in the development of new therapeutic approaches to control neuroinflammation under conditions of overshooting LPA production. CONCLUSIONS: In the present study, we show that inflammatory LPA levels increased the migratory response of microglia and promoted a pro-inflammatory phenotype via the LPAR5/PKD axis. Interference with this signaling axis reduced microglial migration, blunted microglial cytotoxicity, and abrogated the expression and secretion of pro-inflammatory mediators.

Hyperbaric Oxygen Therapy and Tissue Regeneration: A Literature Survey.

By addressing the mechanisms involved in transcription, signaling, stress reaction, apoptosis and cell-death, cellular structure and cell-to-cell contacts, adhesion, migration as well as inflammation; HBO upregulates processes involved in repair while mechanisms perpetuating tissue damage are downregulated. Many experimental and clinical studies, respectively, cover wound healing, regeneration of neural tissue, of bone and cartilage, muscle, and cardiac tissue as well as intestinal barrier function. Following acute injury or in chronic healing problems HBO modulates proteins or molecules involved in inflammation, apoptosis, cell growth, neuro- and angiogenesis, scaffolding, perfusion, vascularization, and stem-cell mobilization, initiating repair by a variety of mechanisms, some of them based on the modulation of micro-RNAs. HBO affects the oxidative stress response via nuclear factor erythroid 2-related factor 2 (Nrf2) or c-Jun N-terminal peptide and downregulates inflammation by the modulation of high-mobility group protein B1 (HMGB-1), toll-like receptor 4 and 2 (TLR-4, TLR-2), nuclear factor kappa-B (NFκB), hypoxia-inducible factor (HIF-1α) and nitric oxide (NO•). HBO enhances stem-cell homeostasis via Wnt glycoproteins and mammalian target of rapamycin (mTOR) and improves cell repair, growth, and differentiation via the two latter but also by modulation of extracellular-signal regulated kinases (ERK) and the phosphatidylinositol-3-kinase (PI3K)/protein kinase B (AKT) pathway. The HBO-induced downregulation of matrix metalloproteinases-2 and 9 (MMP-2/-9), rho-associated protein kinase (ROCK) and integrins improve healing by tissue remodeling. Interestingly, the action of HBO on single effector proteins or molecules may involve both up- or downregulation, respectively, depending on their initial level. This probably mirrors a generally stabilizing potential of HBO that tends to restore the physiological balance rather than enhancing or counteracting single mechanisms.

Hypoxia factors suppression effect on the energy metabolism of a malignant melanoma cell SK-MEL-30.

OBJECTIVE: Malignant melanoma (MM), as well as other cancers, is a disorder in the cell life cycle at many levels. In terms of energy, the sync of cytosolic and mitochondrial metabolism is required for each cell. Mismatches also caused by hypoxic factors accumulate defects leading to the formation, development and invasiveness of malignant melanoma. Our aim was to compare the effect of HIF-1α and miR-210 on the metabolism of malignant melanoma cells in normoxia and pseudohypoxia. Further, we also investigated how gene silencing affects the viability in order to evaluate the potential of gene therapy in the treatment of MM. MATERIALS AND METHODS: We targeted oxidative phosphorylation by genetically suppressing HIF-1α and miR-210. We have examined mitochondrial activity, cytosolic glycolysis and cell viability. RESULTS: The ratio of NADH/NAD+ in the cytoplasm under normal conditions is stable and can thus serve as a specific cellular metabolic marker. Therefore, the study was aimed at finding the cause of the reduction in NADH levels in increasing hypoxia under ideal in vitro conditions on the SK-MEL-30 malignant melanoma cells. The relationship between HIF-1α and miR-210, their effect on transcriptional level, and the subsequent effect on metabolic process attenuation in cells was investigated. Obtained results indicate that the NADH which is accumulated by cells in hypoxia was significantly decreased upon gene silencing. CONCLUSIONS: Our studies have shown that small regulatory molecules with organelle-specific effect (such as miRs) need to be targeted, and that the resultant effect is comparable to silencing of "general" hypoxic transcription factors.

Purification and Application of Genetically Encoded Potassium Ion Indicators for Quantification of Potassium Ion Concentrations within Biological Samples.

Vital cells maintain a steep potassium ion (K+ ) gradient across the plasma membrane. Intracellular potassium ion concentrations ([K+ ]) and especially the [K+ ] within the extracellular matrix are strictly regulated, the latter within a narrow range of ∼3.5 to 5.0 mM. Alterations of the extracellular K+ homeostasis are associated with severe pathological alterations and systemic diseases including hypo- or hypertension, heart rate alterations, heart failure, neuronal damage or abnormal skeleton muscle function. In higher eukaryotic organisms, the maintenance of the extracellular [K+ ] is mainly achieved by the kidney, responsible for K+ excretion and reabsorption. Thus, renal dysfunctions are typically associated with alterations in serum- or plasma [K+ ]. Generally, [K+ ] quantifications within bodily fluids are performed using ion selective electrodes. However, tracking such alterations in experimental models such as mice features several difficulties, mainly due to the small blood volume of these animals, hampering the repetitive collection of sample volumes required for measurements using ion selective electrodes. We have recently developed highly sensitive, genetically encoded potassium ion indicators, the GEPIIs, applicable for in vitro determinations of [K+ ]. In addition to the determination of [K+ ] within bodily fluids, GEPIIs proved suitable for the real-time visualization of cell viability over time and the exact determination of the number of dead cells. © 2019 The Authors.

Evidence for a receptor-activated Ca2+ entry pathway independent from Ca2) store depletion in endothelial cells.

Ca(2+) entry in endothelial cells is a key signaling event as it prolongs the Ca(2+) signal activated by a receptor agonist, and thus allows an adequate production of a variety of compounds. The possible routes that lead to Ca(2+) entry in non-excitable cells include the receptor-activated Ca(2+) entry (RACE), which requires the presence of an agonist to be activated, and the store-operated Ca(2+) entry (SOCE) pathway, whose activation requires the depletion of the ER Ca(2+) store. However, the relative importance of these two influx pathways during physiological stimulation is not known. In the present study we experimentally differentiated these two types of influxes and determined under which circumstances they are activated. We show that La(3+) (at 10 microM) is a discriminating compound that efficiently blocks SOCE but is almost without effect on histamine-induced Ca(2+) entry (RACE). In line with this, histamine does not induce massive store depletion when performed in the presence of extracellular Ca(2+). In addition, inhibition of mitochondrial respiration significantly reduces SOCE but modestly affects RACE. Thus, agonist-induced Ca(2+) entry is insensitive to La(3+), and only modestly affected by mitochondrial depolarization. These data shows that agonist relies almost exclusively on RACE for sustained Ca(2+) signaling in endothelial cells.

Ca2+ refilling of the endoplasmic reticulum is largely preserved albeit reduced Ca2+ entry in endothelial cells.

In this study the relationship between the efficiency of endoplasmic reticulum (ER) Ca2+ refilling and the extent of Ca2+ entry was investigated in endothelial cells. ER and mitochondrial Ca2+ concentration were measured using genetically encoded Ca2+ sensors, while the amount of entering Ca2+ was controlled by varying either the extracellular Ca2+ or the electrical driving force for Ca2+ by changing the plasma membrane potential. In the absence of an agonist, ER Ca2+ replenishment was fully accomplished even if the Ca2+ concentration applied was reduced from 2 to 0.5mM. A similar strong efficiency of ER Ca2+ refilling was obtained under condition of plasma membrane depolarization. However, in the presence of histamine, ER Ca2+ refilling depended on mitochondrial Ca2+ transport and was more susceptible to membrane depolarization. Store-operated Ca2+ entry (SOCE), was strongly reduced under low Ca2+ and depolarizing conditions but increased if ER Ca2+ uptake was blocked or if ER Ca2+ was released continuously by IP(3). A correlation of the kinetics of ER Ca2+refilling with cytosolic Ca2+ signals revealed that termination of SOCE is a rapid event that is not delayed compared to ER refilling. Our data indicate that ER refilling occurs in priority to, and independently from the cytosolic Ca2+ elevation upon Ca2+ entry and that this important process is widely achieved even under conditions of diminished Ca2+entry.

N-acetylaspartate catabolism determines cytosolic acetyl-CoA levels and histone acetylation in brown adipocytes.

Histone acetylation depends on the abundance of nucleo-cytoplasmic acetyl-CoA. Here, we present a novel route for cytoplasmic acetyl-CoA production in brown adipocytes. N-acetylaspartate (NAA) is a highly abundant brain metabolite catabolized by aspartoacylase yielding aspartate and acetate. The latter can be further used for acetyl-CoA production. Prior to this work, the presence of NAA has not been described in adipocytes. Here, we show that accumulation of NAA decreases the brown adipocyte phenotype. We increased intracellular NAA concentrations in brown adipocytes via media supplementation or knock-down of aspartoacylase and measured reduced lipolysis, thermogenic gene expression, and oxygen consumption. Combinations of approaches to increase intracellular NAA levels showed additive effects on lipolysis and gene repression, nearly abolishing the expression of Ucp1, Cidea, Prdm16, and Ppara. Transcriptome analyses of aspartoacylase knock-down cells indicate deficiencies in acetyl-CoA and lipid metabolism. Concordantly, cytoplasmic acetyl-CoA levels and global histone H3 acetylation were decreased. Further, activating histone marks (H3K27ac and H3K9ac) in promoters/enhancers of brown marker genes showed reduced acetylation status. Taken together, we present a novel route for cytoplasmic acetyl-CoA production in brown adipocytes. Thereby, we mechanistically connect the NAA pathway to the epigenomic regulation of gene expression, modulating the phenotype of brown adipocytes.

Activation of a small-conductance Ca(2+)-dependent K+ channel contributes to bradykinin-induced stimulation of nitric oxide synthesis in pig aortic endothelial cells.

Bradykinin-induced K+ currents, membrane hyperpolarization, as well as rises in cytoplasmic Ca2+ and cGMP levels were studied in endothelial cells cultured from pig aorta. Exposure of endothelial cells to 1 microM bradykinin induced a whole-cell K+ current and activated a small-conductance (approximately 9 pS) K+ channel in on-cell patches. This K+ channel lacked voltage sensitivity, was activated by increasing the Ca2+ concentration at the cytoplasmic face of inside-out patches and blocked by extracellular tetrabutylammonium (TBA). Bradykinin concomitantly increased membrane potential and cytoplasmic Ca2+ of endothelial cells. In high (140 mM) extracellular K+ solution, as well as in the presence of the K(+)-channel blocker TBA (10 mM), bradykinin-induced membrane hyperpolarization was abolished and increases in cytoplasmic Ca2+ were reduced to a slight transient response. Bradykinin-induced rises in intracellular cGMP levels which reflect Ca(2+)-dependent formation of EDRF(NO) were clearly attenuated in the presence of TBA (10 mM). Our results suggest that bradykinin hyperpolarizes pig aortic endothelial cells by activation of small-conductance Ca(2+)-activated K+ channels. Opening of these K+ channels results in membrane hyperpolarization which promotes Ca2+ entry, and consequently, NO synthesis.

High D-glucose-induced changes in endothelial Ca2+/EDRF signaling are due to generation of superoxide anions.

Pretreatment of porcine aortic endothelial cells with high D-glucose results in enhanced endothelium-derived relaxing factor (EDRF) formation (39%) due to increased endothelial Ca2+ release (57%) and Ca2+ entry (97%) to bradykinin. This study was designed to investigate the intracellular mechanisms by which high D-glucose affects endothelial Ca2+/EDRF response. The aldose-reductase inhibitors, sorbinil and zopolrestat, failed to diminish high D-glucose-mediated alterations in Ca2+/EDRF response, suggesting that aldose-reductase does not contribute to high D-glucose-initiated changes in Ca2+/EDRF signaling. Pretreatment of cells with the nonmetabolizing D-glucose analog, 3-O-methylglucopyranose (3-OMG), mimicked the effect of high D-glucose on Ca2+ release (41%) and Ca2+ entry (114%) to bradykinin, associated with elevated EDRF formation (26%). High D-glucose and 3-OMG increased superoxide anion (O2-) formation (133 and 293%, respectively), which was insensitive to inhibitors of cyclooxygenase (5,8,11,14-eicosatetraynoic acid [ETYA], indomethacin), lipoxygenase (ETYA, gossypol, nordihydroguaiaretic acid [NDGA]), cytochrome P450 (NDGA, econazole, miconazole), and nitric oxide (NO) synthase (L-omega N-nitroarginine), while it was diminished by desferal, a metal chelator. The gamma-glutamyl-cysteine-synthase inhibitor, buthioninesulfoximine (BSO), also increased formation of O2- by 365% and mimicked the effect of high D-glucose on Ca2+/EDRF signaling. The effects of high D-glucose, 3-OMG, and BSO were abolished by co-incubation with superoxide dismutase. Like high D-glucose, pretreatment with the O2(-)-generating system, xanthine oxidase/hypoxanthine, elevated bradykinin-stimulated Ca2+ release (+10%), Ca2+ entry (+75%), and EDRF (+73%). We suggest that prolonged exposure to pathologically high D-glucose concentration results in enhanced formation of O2-, possibly due to metal-mediated oxidation of D-glucose within the cells. This overshoot of O2- enhances agonist-stimulated Ca2+/EDRF signaling via a yet unknown mechanism.

Intracellular mechanisms involved in D-glucose-mediated amplification of agonist-induced Ca2+ response and EDRF formation in vascular endothelial cells.

Prolonged treatment of vascular endothelial cells with pathologically high D-glucose amplifies autacoid-induced Ca2+ mobilization and thus formation of nitric oxide. This study investigated the Ca2+ source for the change in endothelial CA2+ response on agonist stimulation. Pretreatment with high D-glucose (44 vs. 5 mM) enhanced release of intracellular Ca2+ by bradykinin as a result of a 2.0-fold increased formation of inositol 1,4,5-trisphosphate. High D-glucose also amplified Ca2+ influx (2.0-fold). In high D-glucose preincubated cells, stimulation with bradykinin significantly increased transplasmalemmal 45Ca2+ flux (3.2-fold) and caused a 2.0-fold increase in permeability to Mn2+, a surrogate for endothelial plasma membrane Ca2+ channels. A significant 2.0-fold increase occurred in the maximal slope, suggesting a higher rate of Mn2+ (Ca2+) influx. Ca2+ influx, stimulated by an inositol phosphate-independent depletion of intracellular Ca2+ stores with 2,5-di-(tert-butyl)-hydroquinone was also significantly increased 2.4-fold by high D-glucose, with no effect on intracellular Ca2+ release. D-glucose failed to modulate resting or stimulated cAMP levels. We suggest that prolonged exposure to pathologically high D-glucose increases formation of inositol polyphosphates, thus increasing Ca2+ release. Ca2+ entry is increased by amplification of unknown signal transduction mechanisms triggered by Ca2+ store depletion.

Exposure to elevated D-glucose concentrations modulates vascular endothelial cell vasodilatory response.

The possible role of endothelial dysfunction in early stages of uncomplicated diabetes mellitus was investigated in porcine aortic endothelial cells. Prolonged exposure to various D-glucose concentrations resulted in concentration-dependent amplification of agonist-induced Ca2+ mobilization, whereas L-glucose and D-mannitol failed to mimic the effect of D-glucose. This stimulatory effect of high D-glucose on endothelial Ca2+ mobilization could be antagonized by coincubation with cytochalasin B, which prevented D-glucose uptake into the cells. In agreement with its effect on agonist-induced Ca2+ response, prolonged preincubation with pathological D-glucose concentrations amplified formation of endothelium-derived relaxing factor, which is well established to be strictly attributable to increases in endothelial free Ca2+. In contrast to endothelium-derived relaxing factor formation stimulated by receptor-interacting autacoids, preincubation with high D-glucose failed to modulate A 23,187-induced endothelium-derived relaxing factor formation, which is attributable to unphysiological increases in endothelial free Ca2+ by this ionophore. Similar to its effect on D-glucose-mediated amplification of agonist-stimulated Ca2+ mobilization, cytochalasin B abolished the stimulatory effect of high D-glucose on endothelium-derived relaxing factor formation. We therefore suggest that prolonged exposure to pathological high D-glucose concentrations results in an enhanced endothelium-derived relaxing factor formation caused by amplification of agonist-stimulated Ca2+ mobilization in endothelial cells. This mechanism may be of particular importance representing a possible basis of pathological vasodilation and reduced peripheral resistance in early stages of diabetes mellitus.

Lipoprotein lipase mediates the uptake of glycated LDL in fibroblasts, endothelial cells, and macrophages.

The nonenzymatic glycation of LDL is a naturally occurring chemical modification of apolipoprotein (apo)-B lysine residues by glucose. Once glycated, LDL is only poorly recognized by lipoprotein receptors including the LDL receptor (LDL-R), the LDL-R-related protein (LRP), and scavenger receptors. Glycated LDL (gLDL) is a preferred target for oxidative modifications. Additionally, its presence initiates different processes that can be considered "proatherogenic." Thus, LDL glycation might contribute to the increased atherosclerotic risk of patients with diabetes and familial hypercholesterolemia. Here we investigate whether lipoprotein lipase (LPL) can mediate the cellular uptake of gLDL. The addition of exogenous LPL to the culture medium of human skin fibroblasts, porcine aortic endothelial cells, and mouse peritoneal macrophages enhanced the binding, uptake, and degradation of gLDL markedly, and the relative effect of LPL on lipoprotein uptake increased with the degree of apoB glycation. The efficient uptake of gLDL by LDL-R-deficient fibroblasts and LRP-deficient Chinese hamster ovary cells in the presence of LPL suggested a mechanism that was independent of the LDL-R and LRP. In macrophages, the uptake of gLDL was also correlated with their ability to produce LPL endogenously. Mouse peritoneal macrophages from genetically modified mice, which lacked LPL, exhibited a 75% reduction of gLDL uptake compared with normal macrophages. The LPL-mediated effect required the association of the enzyme with cell surface glycosaminoglycans but was independent of its enzymatic activity. The uptake of gLDL in different cell types by an LPL-mediated process might have important implications for the cellular response after gLDL exposure as well as the removal of gLDL from the circulation.

Human diabetes is associated with hyperreactivity of vascular smooth muscle cells due to altered subcellular Ca2+ distribution.

Alterations of vascular smooth muscle function have been implicated in the development of vascular complications and circulatory dysfunction in diabetes. However, little is known about changes in smooth muscle contractility and the intracellular mechanisms contributing to altered responsiveness of blood vessels of diabetic patients. Therefore, smooth muscle and endothelial cell function were assessed in 20 patients with diabetes and compared with 41 age-matched control subjects. In rings from uterine arteries, smooth muscle sensitivity to K+, norepinephrine (NE), and phenylephrine (PE) was enhanced by 1.4-, 2.3-, and 9.7-fold, respectively, and endothelium-dependent relaxation was reduced by 64% in diabetic patients, as compared with control subjects. In addition, in freshly isolated smooth muscle cells from diabetic patients, an increased perinuclear Ca2+ signaling to K+ (30 mmol/l >73%; 60 mmol/l >68%) and NE (300 nmol/l >86%; 10 micromol/l >67%) was found. In contrast, subplasmalemmal Ca2+ response, which favors smooth muscle relaxation caused by activation of Ca2+-activated K+ channels, was reduced by 38% in diabetic patients as compared with control subjects, indicating a significant change in the subcellular Ca2+ distribution in vascular smooth muscle cells in diabetic patients. In contrast to the altered Ca2+ signaling found in freshly isolated cells from diabetic patients, in cultured smooth muscle cells isolated from control subjects and diabetic patients, no difference in the intracellular Ca2+ signaling to stimulation with either K+ or NE was found. Furthermore, production of superoxide anion (*O2-) in intact and endothelium-denuded arteries from diabetic patients was increased by 150 and 136%, respectively. Incubation of freshly isolated smooth muscle cells from control subjects with the *O2- -generating system xanthine oxidase/hypoxanthine mimicked the effect of diabetic patients on subcellular Ca2+ distribution in a superoxide dismutase-sensitive manner. We conclude that in diabetic subjects, smooth muscle reactivity is increased because of changes in subcellular Ca2+ distribution on cell activation. Increased *O2- production may play a crucial role in the alteration of smooth muscle function.

Glycated low-density lipoprotein attenuates shear stress-induced nitric oxide synthesis by inhibition of shear stress-activated L-arginine uptake in endothelial cells.

Little is known about the mechanism(s) of endothelial dysfunction in diabetes. In this study, the effect of nonenzymatic glycated LDL, a phenomenon induced by elevated D-glucose levels associated with diabetes, on porcine aortic endothelial cells was investigated. Two fractions of LDL from diabetic patients were separated by affinity column chromatography and are referred to herein as fraction alpha (nonglycated LDL) and fraction beta (glycated LDL). Incubation of endothelial cells for 24 h with total LDL isolated from diabetic subjects (dLDL) increased the release of superoxide anions (*O2-) by fivefold, while no effect of LDL isolated from healthy individuals (nLDL) was found. Fraction beta, but not fraction alpha, evoked the *O2- release. In vitro-glycated LDL mimicked the effect of dLDL/fraction beta on *O2- release that correlated with its degree of glycation (R2 = 0.96). Moreover, nitric oxide (NO) stability (measured with a porphyrinic-based electrode) and NO bioactivity (measured by its ability to elevate cellular cGMP levels) were reduced in cells treated with dLDL by 46 and 41%, respectively. dLDL (but not nLDL or fraction alpha) abolished shear stress-induced L-arginine uptake. The inhibitory effect of dLDL on shear stress-induced L-arginine uptake was mimicked by in vitro-glycated LDL. The efficiency of in vitro-glycated LDL to diminish shear stress-evoked L-arginine uptake correlated with the extent of glycation (R2 = 0.88). Moreover, dLDL, but not nLDL or fraction alpha, reduced shear stress-mediated cGMP formation and NOx production by 47 and 88%, respectively. This effect was also mimicked by in vitro-glycated LDL, correlating with its degree of glycation (R2 = 0.86). Under these experimental conditions, glycated LDL reduced shear stress-induced increase in NO synthesis by inhibition of shear stress-stimulated L-arginine uptake and NO bioactivity due to increased endothelial cell *O2- release. These properties may contribute to the reduced vasodilatory response and the vascular complications in diabetes.

Effect of sodium fluoride on cytosolic free Ca2(+)-concentrations and cGMP-levels in endothelial cells.

Sodium fluoride was used to investigate a possible involvement of G-proteins in the regulation of endothelial calcium channels. Incubation of cultured porcine aortic endothelial cells with sodium fluoride produced a dose-dependent increase in intracellular free calcium (EC50 approximately 5 mM). The effect strictly depended on the presence of extracellular CaCl2, indicating an enhanced influx of extracellular Ca2+ rather than a release of Ca2+ from intracellular stores. The Al3+ chelator deferoxamine abolished the stimulatory effect of sodium fluoride but did not interfere with the stimulatory effect of bradykinin. These data confirm the current hypothesis that the complex AlF-4 and not the fluoride anion activates G-proteins and exclude a direct inhibitory effect of deferoxamine on Ca2(+)-uptake. In contrast to isoproterenol and 5'-N-ethylcarboxamido-adenosine (NECA), which elevated endothelial cAMP-levels without affecting intracellular Ca2(+)-concentrations, sodium fluoride was not able to increase endothelial cAMP. This indicates that the effect of sodium fluoride on endothelial Ca2(+)-levels is not due to stimulation of a Gs-protein. Similar to its effect on cytoplasmic Ca2+, sodium fluoride also increased endothelial cGMP-levels which has recently been suggested to serve as biochemical marker for the formation of endothelium derived relaxing factor (EDRF). Thus, similar to the activation of receptor operated calcium channels, direct stimulation of a G-protein by sodium fluoride results in an increase of cytoplasmic Ca2+ and the formation of EDRF.

Oxidized low-density lipoprotein antagonizes the activation of purified soluble guanylate cyclase by endothelium-derived relaxing factor but does not interfere with its biosynthesis.

Oxidized low-density lipoprotein (LDLox) is a molecule with strong atherogenic properties. In a concentration dependent fashion, LDLox antagonized the activation of purified soluble guanylate cyclase by endothelium-derived relaxing factor (EDRF), which was produced in vitro by incubation of a partially purified EDRF-forming enzyme in the presence of L-arginine, Ca2+ and NADPH. The inhibitory effect of LDLox was potentiated by preincubation of the soluble guanylate cyclase with LDLox, but not when the EDRF-forming enzyme was pretreated with LDLox. As LDLox did not diminish the calmodulin-dependent conversion of L-arginine into L-citrulline by the EDRF-forming enzyme it would appear that EDRF-biosynthesis was not affected by LDLox. It is suggested that the impaired relaxant response of atherosclerotic blood vessels to endothelium-dependent vasodilators was not due to a reduced formation of EDRF but due to a diminished responsiveness of soluble guanylate cyclase.

Impact of apolipoprotein(a) on in vitro angiogenesis.

Angiostatin, which consists of the kringle I-IV domains of plasminogen and which is secreted into urine, is an efficient inhibitor of angiogenesis and tumor growth. Because N-terminal apolipoprotein(a) [apo(a)] fragments, which also contain several types of kringle IV domains, are found in urine as well, we evaluated the potential angiostatic properties of these urinary apo(a) fragments and of a recombinant form of apo(a) [r-apo(a)]. We used human microvascular endothelial cell (hMVEC)-based in vitro assays of tube formation in 3-dimensional fibrin matrixes. Purified urinary apo(a) fragments or r-apo(a) inhibited the basic fibroblast growth factor/tumor necrosis factor-alpha-induced formation of capillary-like structures. At concentrations varying from 0.2 to 10 microgram/mL, urinary apo(a) fragments inhibited tube formation by as much as 70%, whereas there was complete inhibition by r-apo(a). The highest concentrations of both inhibitors also reduced urokinase plasminogen activator production of basic fibroblast growth factor-induced hMVEC proliferation. The inhibitors had no effect on plasminogen activator inhibitor-1 expression. If our in vitro model for angiogenesis is valid for the in vivo situation as well, our data point toward the possibility that apo(a) may also be physiologically operative in modulating angiogenesis, as the concentration of free apo(a) found in humans exceeds that tested herein.

Temperature dependence of agonist-stimulated Ca2+ signaling in cultured endothelial cells.

In cultured endothelial cells, the temperature dependence of bradykinin-initiated Ca2+ signaling was studied using Fura-2 technique. Initially, the temperature dependence of the dissociation constant of Fura-2 for Ca2+ was investigated. Temperature-initiated changes in the apparent dissociation constant (K'D) using the ratio (F340/F380) were due to a hypsochromic shift in excitation wavelengths and changes in the effective dissociation constant of Fura-2 for Ca2+ (K"D). Equations were provided to correct the dissociation constant for Fura-2, either for using the common ratio (F340/F380) or the shift corrected ratio (F340-delta lambda/F380-delta lambda). In a simple experimental protocol, the temperature dependence of the transient increase in free intracellular Ca2+ to bradykinin (i.e. Ca2+ release, sequestration and extrusion) and Ca2+/Mn2+ entry through a Ca2+ store-operated Ca2+ entry pathway (SOCP) were determined. While the temperature dependence of intracellular Ca2+ release, sequestration and extrusion (i.e. enzymatically controlled phenomena) were found to follow the same exponential function [t = A x e(-B x T); t, reaction time; A, B, constants; T, experimental temperature in K; K = degree C + 273], Ca2+/Mn2+ entry upon ion application to pre-stimulated cells strictly followed Fick's law of diffusion [t = A x (1/T) x e(B/T); t, reaction time; A, B, constants; T, experimental temperature in K]. In contrast to the temperature dependence of bradykinin-stimulated Ca2+/Mn2+ entry, the temperature dependence of Mn2+ entry on addition of agonist did not correlate with Fick's law of diffusion, but followed the same exponential function obtained for Ca2+ release, sequestration and extrusion. In conclusion, these data suggest that activation of SOCP by autacoid is due to enzymatic mechanism(s), while Ca2+ entry through SOCP, once activated, is due to a diffusion-like phenomenon.

Mechanisms of Ca2+ store depletion in single endothelial cells in a Ca(2+)-free environment.

Depletion of agonist-sensitive Ca2+ stores results in activation of capacitative Ca2+ entry (CCE) in endothelial cells. The proportion of Ca2+ stores contributing to the regulation of CCE is unknown. In fura-2/am loaded single endothelial cells freshly isolated from bovine left circumflex coronary arteries, we investigated whether a resting period in a Ca(2+)-free environment results in emptying of bradykinin-sensitive Ca2+ stores (BsS) and activation of CCE. In a Ca(2+)-free environment, depletion of BsS occurred in a time-dependent manner (59% after 10 min in Ca(2+)-free solution). This effect was prevented by inhibition of the Na(+)-Ca2+ exchange but not by a blockade of ryanodine-sensitive Ca2+ release (RsCR). In contrast to BsS, mitochondrial Ca2+ content remained unchanged in the Ca(2+)-free environment. Remarkably, activity of CCE (monitored as Mn2+ influx) did not increase after depletion of BsS in the Ca(2+)-free environment. In contrast to Mn2+ influx, the effect of re-addition of Ca2+ to elevate bulk Ca2+ concentration ([Ca2+]b) decreased with the time the cells rested in Ca(2+)-free buffer. This decrease was prevented by an inhibition of RsCR. In low Na+ conditions the effect of Ca2+ on [Ca2+]b was reduced while it did not change the time the cells rested in Ca(2+)-free solution. After a 2 min period in low Na+ conditions, ryanodine-induced Ca2+ extrusion was markedly diminished. Inhibition of RsCR re-established the effect of Ca2+ on [Ca2+]b in low Na+ conditions. Collapsing subplasmalemmal Ca2+ stores with nocodazole, increased the effect of Ca2+ on [Ca2+]b. In nocodazole-treated cells, the effect of Ca2+ on [Ca2+]b was not reduced in Ca(2+)-free environment. These data indicate that activation of CCE is not associated with the agonist-sensitive Ca2+ pools that deplete rapidly in a Ca(2+)-free environment. Subplasmalemmal ryanodine-sensitive Ca2+ stores (RsS) are emptied in Ca(2+)-free/low Na+ solution and re-sequester Ca2+ which enters the cells prior an increase in [Ca2+]b occurs. Thus, in endothelial cells there are differences in the functions of various subplasmalemmal Ca2+ stores (i.e. BsS and RsS), which include either activation of CCE or regulation of subplasmalemmal Ca2+.

Effect of intracellular Ca2+ concentration on endothelin-1 secretion.

The role of intracellular free Ca2+ concentration ([Ca2+]i) in cellular regulation of endothelin-1 (ET-1) secretion was investigated in cultured porcine aortic endothelial cells of first passage. Intracellular Ca2+ concentrations were adjusted between 50 nM and 1 microM using EGTA and thapsigargin, respectively. ET-1 secretion was maximal at [Ca2+]i of 190-470 nM, and reduced at low (50 and 110 nM) and high (> 470 nM) [Ca2+]i. The Ca2+ ionophores A23187 and ionomycin (each 1 microM), both of which raise [Ca2+]i above 1 microM, also potently inhibited ET-1 secretion under basal and stimulated conditions. The A23187-induced reduction in ET-1 secretion was not affected by NG-nitro-L-arginine (0.1 mM). Our results provide evidence that basal ET-1 secretion is regulated by Ca2+ and that Ca2+ ionophores reduce ET-1 secretion due to the inhibitory effect of high [Ca2+]i.