Effect of oxygen on ascorbic acid uptake and concentration in embryonic chick brain

The effects of oxygen on ascorbic acid concentration and transport were studied in chick embryo (Gallus gallus domesticus). During normoxic incubations, plasma ascorbic acid concentration peaked on fetal day 12 and then fell, before increasing again on day 20 when pulmonary respiration began. In contrast, cerebral ascorbic acid concentration rose after day 6, was maintained at a relatively high level during days 8–18, and then fell significantly by day 20. Exposure of day 16 embryos for 48 h to 42% ambient O₂ concentration decreased ascorbic acid concentration by four-fifths in plasma and by one-half in brain, compared to values in normoxic (21% O₂) or hypoxic (15% O₂) controls. Hyperoxic preincubation of embryos also inhibited ascorbic acid transport, as evidenced by decreased initial rates of saturable and Na⁺-dependent [¹⁴C]ascorbic acid uptake into isolated brain cells. It may be concluded that changes in ascorbic acid concentration occur in response to oxidative stress, consistent with a role for the vitamin in the detoxification of oxygen radicals in fetal tissues. However, changing O₂ levels have less effect on ascorbic acid concentration in brain than in plasma, indicating regulation of the vitamin by brain cells. Furthermore, the effect of hyperoxia on cerebral vitamin C may result, in part, from inhibition of cellular ascorbic acid transport.     

Rapid Method for Assessing Oxygen Consumption Rate of Cells from Transient-state Measurements of Pericellular Dissolved Oxygen Concentration

Recently we described a method for estimating the oxygen consumption rate (OCR) of cells in static culture from equilibrium measurements of dissolved oxygen concentration (dO₂), using an oxygen-sensing microplate and the steady-state solution to Fick's Law (Guarino et al. 2004). Here we describe a complementary method for estimating OCR from the transient-state rate of change of measured dO₂. Although the system is open to the atmosphere and subject to a significant lag in sensor response, the rate of change of the measured dO₂ immediately after seeding correlated directly with both cell number and steady-state OCR. This transient-state method is linear with cell number to a much higher density than is possible with the steady-state method because it derives from measurements made before diffusion limitations can be established. For a given sensor thickness, the same correlation line between the transient and non-diffusion-limited steady-state estimates of OCR was found to apply for various preparations of rat hepatocytes. The correlation slope varied predictably with sensor thickness. Thus, despite the non-idealities of this system, the initial rate measurement offers a rapid method to obtain an estimate of absolute OCR. To demonstrate the utility of this method, we purposefully treated rat hepatocytes in ways expected to change OCR. Cells deprived of oxygen by storage under several centimeters of medium showed decreases in both OCR and viability with time. Likewise, the OCR of hepatocytes exposed to the oxidative phosphorylation inhibitor rotenone decreased, whereas those exposed to the uncoupler dinoseb increased.     

AMP-activated protein kinase plays a role in initiating metabolic rate suppression in goldfish hepatocytes

In the present study, we test the hypothesis that AMP-activated protein kinase (AMPK) initiates metabolic rate suppression in isolated goldfish hepatocytes. To accomplish this, we attempted to pharmacologically activate AMPK in goldfish hepatocytes with 5-aminoimidazole-4-carboxamide ribonucleoside (AICAR) and the thienopyridone, A769662, to examine the effects of AMPK activation on eukaryotic elongation factor-2 (eEF2), protein synthesis, and cellular oxygen consumption rate ( [(M)\dot]_{\textO 2} \dot{M}_{{{\text{O}}_{ 2} }} ). Goldfish hepatocytes treated with 1 mM AICAR under normoxic conditions (>200 μM O₂) showed a modest but significant 1.1-fold increase in AMPK phosphorylation, a 7.5-fold increase in AMPK activity, a 1.4-fold increase in eEF2 phosphorylation, and a 24% decrease in [(M)\dot]_{\textO 2} \dot{M}_{{{\text{O}}_{ 2} }} . At physiologically relevant [O₂] (<40 μM O₂), the addition of 1 mM AICAR resulted in only a 13% decrease in cellular [(M)\dot]_{\textO 2} \dot{M}_{{{\text{O}}_{ 2} }} with no change in sensitivity to [O₂] as assessed by estimates of cellular P₅₀ and P₉₀ values. The addition of compound C, a general protein kinase inhibitor, after AICAR incubation did not reverse the effects of AICAR on [(M)\dot]_{\textO 2} \dot{M}_{{{\text{O}}_{ 2} }} in normoxia. Treatment of hepatocytes with ≤200 μM A769662 did not affect AMPK activity, AMPK phosphorylation, eEF2 phosphorylation, or cellular [(M)\dot]_{\textO 2} \dot{M}_{{{\text{O}}_{ 2} }} . These data suggest that A769662 is not an activator of AMPK in goldfish hepatocytes. Although our study provides support for the hypothesis that AMPK plays a role in initiating metabolic rate suppression in goldfish hepatocytes, this support must be viewed cautiously because of the known off-target effects of the pharmacological agents used.     

Cultured rat hepatocytes adapt their cellular glycolytic activity and adenylate energy status to tissue oxygen tension: Influences of extracellular matrix components,insulin and glucagon

The influence of extracellular matrix components, insulin, and glucagon on the cellular response to periportal- or pericentral-equivalent tissue oxygen tension was investigated in freshly isolated rat hepatocytes cultured at 13% O₂ or 4% O₂ in Teflon membrane dishes. With extended culture time, significant increases in lactate release and cellular lactate content were observed in cultures at 4% O₂ compared with 13% O_2. This shift toward glycolysis was detectable when hepatocytes were cultured on dishes coated with rat liver crude membrane fraction (CMF/COL) but not in collagen type I-coated dishes. This indicates that extracellular matrix components are involved in the process of adaptation. ATP and total adenylate content in cells cultured at 4% O₂ were up to 40% lower than in cells cultured at 13% O_2. However, the adenylate energy charge was not affected, suggesting that an adequate energy supply was maintained also in hepatocytes cultured at pericentral-equivalent oxygen tension. This adaptation was reversible. When hepatocytes were transferred either from 4% to 13% O₂ or from 13% to 4% O₂, they adapted the corresponding metabolic profile to the new oxygen tension within 2 days. This demonstrates that hepatocytes are not fully unidirectionally programmed. The modulation of the glycolytic activity by insulin and glucagon was effective in cultures at pericentral-equivalent oxygen tension (4% O₂) only. Insulin (0.1-100 nM) counteracted the effect of insulin in a dose-dependent manner. Clearly, oxygen tension is the principal regulator in the hepatic glycolytic activity, whereas the hormones (insulin and glucagon) act as secondary modulators. © 1994 Wiley-Liss, Inc.     

Quantitative phosphoproteomic analysis of prion-infected neuronal cells

Following cultivation of distinct mesenchymal stem cell (MSC) populations derived from human umbilical cord under hypoxic conditions (between 1.5% to 5% oxygen (O₂)) revealed a 2- to 3-fold reduced oxygen consumption rate as compared to the same cultures at normoxic oxygen levels (21% O₂). A simultaneous measurement of dissolved oxygen within the culture media from 4 different MSC donors ranged from 15 μmol/L at 1.5% O₂ to 196 μmol/L at normoxic 21% O₂. The proliferative capacity of the different hypoxic MSC populations was elevated as compared to the normoxic culture. This effect was paralleled by a significantly reduced cell damage or cell death under hypoxic conditions as evaluated by the cellular release of LDH whereby the measurement of caspase3/7 activity revealed little if any differences in apoptotic cell death between the various cultures. The MSC culture under hypoxic conditions was associated with the induction of hypoxia-inducing factor-alpha (HIF-1α) and an elevated expression of energy metabolism-associated genes including GLUT-1, LDH and PDK1. Concomitantly, a significantly enhanced glucose consumption and a corresponding lactate production could be observed in the hypoxic MSC cultures suggesting an altered metabolism of these human stem cells within the hypoxic environment.     

Hypoxia or in situ normoxia: The stem cell paradigm

Although O₂ concentrations are considerably lowered in vivo, depending on the tissue and cell population in question (some cells need almost anoxic environment for their maintenance) the cell and tissue cultures are usually performed at atmospheric O₂ concentration (20–21%). As an instructive example, the relationship between stem cells and micro‐environmental/culture oxygenation has been recapitulated. The basic principle of stem cell biology, “the generation‐age hypothesis,” and hypoxic metabolic properties of stem cells are considered in the context of the oxygen‐dependent evolution of life and its transposition to ontogenesis and development. A hypothesis relating the self‐renewal with the anaerobic and hypoxic metabolic properties of stem cells and the actual O₂ availability is elaborated (“oxygen stem cell paradigm”). Many examples demonstrated that the cellular response is substantially different at atmospheric O₂ concentration when compared to lower O₂ concentrations which better approximate the physiologic situation. These lower O₂ concentrations, traditionally called “hypoxia” represent, in fact, an in situ normoxia, and should be used in experimentation to get an insight of the real cell/cytokine physiology. The revision of our knowledge on cell/cytokine physiology, which has been acquired ex vivo at non physiological atmospheric (20–21%) O₂ concentrations representing a hyperoxic state for most primate cells, has thus become imperious. J. Cell. Physiol. 219: 271–275, 2009. © 2009 Wiley‐Liss, Inc.     

Rapid and enhanced repolarization in sandwich-cultured hepatocytes on an oxygen-permeable membrane

In this study, we established rat primary hepatocyte sandwich cultures on oxygen-permeable membranes and investigated the change in their repolarization. Functional bile canaliculi in sandwich-cultured hepatocytes on oxygen-permeable polydimethylsiloxane (PDMS) membranes were re-established more quickly than those in a conventional sandwich culture on polystyrene (PS). This enhanced biliary excretory activity was also observed in hepatocytes on another oxygen-permeable membrane plate but not on a PDMS surface whose oxygen permeability is blocked. An apical efflux transporter protein, Mrp2, was more rapidly distributed in hepatocytes cultured on PDMS membranes than in hepatocytes cultured on conventional PS plates. Moreover, the area of distribution of the Mrp2 in polarized hepatocytes cultured on PDMS membranes was more widespread than that for the hepatocytes grown on sandwich-cultured PS plates. The observation of ultrastructure in transmission electron microscopy clearly confirmed the presence of bile canalicular lumens possessing microvilli and tight junctions. Additionally, we demonstrated that the 7-ethoxyresorufin-O-deethylation activity of hepatocytes on PDMS membranes was also improved as compared to those on a PS surface. Therefore, sandwich-cultured hepatocytes on oxygen-permeable substrates can provide a simple tool for predicting the hepatic metabolism and toxicity of xenobiotics in vivo with short span and low cost in the course of drug discovery and evaluation.     

Ex vivo expansion of human mesenchymal stem cells: A more effective cell proliferation kinetics and metabolism under hypoxia

The low bone marrow (BM) MSC titers demand a fast ex vivo expansion process to meet the clinically relevant cell dosage. Attending to the low oxygen tension of BM in vivo, we studied the influence of hypoxia on human BM MSC proliferation kinetics and metabolism. Human BM MSC cultured under 2% (hypoxia) and 20% O₂ (normoxia) were characterized in terms of proliferation, cell division kinetics and metabolic patterns. BM MSC cultures under hypoxia displayed an early start of the exponential growth phase, and cell numbers obtained at each time point throughout culture were consistently higher under low O₂, resulting in a higher fold increase after 12 days under hypoxia (40 ± 10 vs. 30 ± 6). Cell labeling with PKH26 allowed us to determine that after 2 days of culture, a significant higher cell number was already actively dividing under 2% compared to 20% O₂ and BM MSC expanded under low oxygen tension displayed consistently higher percentages of cells in the latest generations (generations 4–6) until the 5th day of culture. Cells under low O₂ presented higher specific consumption of nutrients, especially early in culture, but with lower specific production of inhibitory metabolites. Moreover, 2% O₂ favored CFU‐F expansion, while maintaining BM MSC characteristic immunophenotype and differentiative potential. Our results demonstrated a more efficient BM MSC expansion at 2% O₂, compared to normoxic conditions, associated to an earlier start of cellular division and supported by an increase in cellular metabolism efficiency towards the maximization of cell yield for application in clinical settings. J. Cell. Physiol. 223: 27–35, 2010. © 2009 Wiley‐Liss, Inc.     

Maintaining blood–brain barrier integrity: Pericytes perform better than astrocytes during prolonged oxygen deprivation

The blood–brain barrier (BBB), consisting of specialized endothelial cells surrounded by astrocytes and pericytes, plays a crucial role in brain homeostasis. Many cerebrovascular diseases are associated with BBB breakdown and oxygen (O₂) deprivation constitutes a critical factor that onsets its disruption. We investigated the impact of astrocytes and pericytes on brain endothelial cell permeability and survival during different degrees of O₂ deprivation. Prolonged exposure to 1% O₂ caused barrier breakdown and exposure to 0.1% O₂ dramatically accelerated disruption and induced cell death, mediated at least in part via caspase‐3 activation. Reoxygenation allowed only cells exposed to 1% O₂ to re‐establish barrier function. Notably co‐culture with astrocytes and pericytes substantially enhanced barrier function under normoxic conditions, and produced differential responses during O₂ deprivation. At 1% O₂ astrocytes partially maintained barrier integrity whereas pericytes accelerated its disruption in the short‐term, having positive effects only after prolonged exposure. Unexpectedly, at 0.1% O₂ pericytes were more effective than astrocytes in preserving barrier function although the protection afforded by both cells involved inhibition of caspase‐3 pathways. Furthermore, cell‐specific regulation of auto‐ and paracrine VEGF signaling pathways were also in part responsible for the differential modulation of barrier function. Our data suggests that cellular cross‐talk within the neurovascular unit is crucial for preservation of barrier integrity and that pericytes, not astrocytes, play a significant role during severe and prolonged O₂ deprivation. J. Cell. Physiol. 218: 612–622, 2009. © 2008 Wiley‐Liss, Inc.     

Responses of type II pneumocyte antioxidant enzymes to normoxic and hyperoxic culture

Summary Cultured type II pneumocyte responses to in vitro normoxia (95% air: 5% CO₂) or hyperoxia (95% O₂:5% CO₂) were quantified. Normoxic culture (0 to 96 h) of rabbit type II cells resulted in enhanced cell-monolayer protein and DNA content. During this same time, cellular activities of superoxide dismutase (SOD), catalase, and glutathione peroxidase (GSH Px) decreased. Compared to cultures maintained in normoxia, hyperoxic exposure of cultures resulted in decreased cell-associated protein and DNA content. Exposure to hyperoxia also resulted in cytotoxicity as demonstrated by elevated cellular release of DNA, lactate dehydrogenase (LDH), and preincorporated 8-[¹⁴C]adenine. Cellular catalase and GSH Px activities in hyperoxic cells decreased similarly to normoxic controls. In contrast, cellular SOD activity in hyperoxic cells decreased less than in normoxic cultures. Cellular SOD activity in hyperoxic cultures, when normalized for cellular protein, but not DNA, was greater than normoxic values after 24 to 96 h of exposure. Unlike the decrease in cellular antioxidant enzymes during normoxic and hyperoxic culture, cellular LDH activity increased during both these exposures. Cellular LDH activity in 24 to 96 h hyperoxia-exposed cells increased to a lesser extent than normoxic controls. The extent of depression in LDH activity was dependent on whether the activity was normalized for cellular protein or DNA. Type II pneumocytes, which normally undergo hyperplasia and hypertrophy during hyperoxia in vivo, exhibited oxygen sensitivity in vitro. Exposure of type II cells to hyperoxia in vitro resulted in alterations in cellular SOD and LDH activities, but recognition of such changes were dependent on whether enzymatic activities were normalized for cellular DNA or protein. This work was supported by a grant from the Health Effects Institute, grant HL40458 from the National Institutes of Health, Bethesda, MD, and a grant from the American Lung Association, New York, NY.     

Oxygen consumption rate in rotifers

The oxygen consumption rate (OCR) is a cumulative index of metabolic losses during aerobic metabolism. The generalized relationship of oxygen consumption rate (R, n1 O₂ ind^–1 h^–1) and dry body mass (M, µg) for rotifers is described by the equation: R = 9.15M^0.716. The level of rotifer metabolism is slightly lower than that of multicellular poikilothermic animals. Differences of OCR values in ontogenesis are substantial. Embryos and senile individuals are characterized by minimal OCR values. The OCR of oviparous females in the beginning of reproduction exceeds 2–3 times OCR values of juveniles. Differences in oxygen consumption intensity (OCI) are not so essential. OCR depends on food concentration. An increase of food concentration from 1.4 to 7.0 µg dry mass m1^–1 resulted in Brachionus calyciflorus in an OCR escalation of 2.5 times at 30°C, and 0.5 times at 25°C. Maximal OCR values occur at food concentration close to the saturation concentration for population growth rate. An exponential equation is adequate to describe R-t dependence for animals, long-term adapted to different constant temperatures (2 < Q₁₀ < 3). Acclimation effects observed during sharp temperature changes are determined by peculiarities of compensation reactions in species and separate populations. The formation of a zone of relative temperature independence of OCR (Q¹⁰ 1) at fluctuating temperature is observed. It is necessary to study enzymatic activities parallel to OCR and OCI measurements.     

Influence of long-term hypoxia on the energy metabolism of the haemoglobin-containing bivalve Scapharca inaequivalvis: critical O2 levels for metabolic depression

Summary The oxygen consumption rate of Scapharca inaequivalvis measured under normoxic conditions over 48 h showed a significant daily cycle with lowest values occurring shortly after the dark period; all hypoxia exposure experiments were carried out during the declining part of the cycle. Animals were exposed to a constant level of hypoxia for a 12-h period in a series of 14 experiments, each at a different oxygen tension. The oxygen consumption was measured continuously, and the extent of accumulation of end-products (succinate and propionate), and the inhibitory effect of adenosine triphosphate on phosphofructokinase were determined at the end of exposures. All three parameters (oxygen consumption, end-product accumulation, phosphofructokinase inhibition) showed a remarkable correlation with major changes occurring between 2.5 and 1.5 ppm (7 and 4 kPa) O₂. The oxygen consumption rates showed a drop to 6% of the normoxic rate, but a consistent low consumption remained below 2 ppm (5.5 kPa) which partly recovered over the 12-h exposure period by about three-fold. Succinate and propionate accumulated progressively between 2.5 and 1.5 ppm (7 and 4 kPa); at [O₂]<1.5 ppm (4kPa) the concentration did not increase further, indicating that anaerobic metabolism had reached a maximum. Over the same range, phosphofructokinase showed an increased sensitivity for adenosine triphosphate, the lower inhibitor concentration at 50% V _max value pointing to depression of glycolytic rate. Despite the activation of anaerobic metabolism and the evident depression of aerobic metabolism, simple calculation demonstrates that Scapharca inaequivalvis relies mainly on aerobic metabolism even during severe hypoxia. It is assumed that the occurrence of haemoglobin in this species is essential for its capacity to survive long periods of hypoxia.Abbreviations ATP adenosine triphosphate - I₅₀ inhibitor concentration at 50% V _max - PFK phosphofructokinase - P _c critical PO₂ - SEM standard error of mean - VO₂ oxygen consumption rate - ww wet weight     

Hemoglobin regulates the metabolic and synthetic function of rat insulinoma cells cultured in a hollow fiber bioreactor

Pancreatic islet transplantation continues to benefit patients with type 1 diabetes by normalizing glucose metabolism and improving other complications of diabetes. However, islet transplantation therapy is limited by the inadequate availability of pancreatic islets. In order to address this concern, this work investigated the expansion of rat insulinoma cells (INS‐1) and their ability to generate insulin in a hollow fiber bioreactor (HFB). The long‐term goal of this project is to develop a bioartificial pancreas. HFBs were incubated at two different oxygenation conditions (10% and 19% O₂) to determine the best scenario for O₂ transport to cultured cells. Also, bovine hemoglobin (BvHb) was supplemented in the cell culture media of the HFBs in order to increase O₂ transport under both oxygenation conditions. Our results show that INS‐1 cells expanded under all oxygenation conditions after 2 weeks of culture, with a slightly higher cell expansion under normoxic oxygenation (19% O₂) for both control HFBs and BvHb HFBs. In addition, cellular insulin production remained steady throughout the study for normoxic control HFBs and BvHb HFBs, while it increased under hypoxic oxygenation (10% O₂) for both types of HFBs but to different extents. Under the two different oxygenation conditions, cellular insulin production was more uniform with time in BvHb HFBs versus control HFBs. These results, along with qRT‐PCR analysis, suggest a possible dysregulation of the insulin‐signaling pathway under hypoxic culture conditions. In conclusion, the HFB culture system is an environment capable of expanding insulinomas while maintaining their viability and insulin production capabilities. Biotechnol. Bioeng. 2010;107: 582–592. © 2010 Wiley Periodicals, Inc.     

Bridging the gap between chemistry, physiology, and evolution: quantifying the functionality of sperm whale myoglobin mutants

This work merges a large set of previously reported thermochemical data for myoglobin (Mb) mutants with a physiological model of O₂-transport and -storage. The model allows a quantification of the functional proficiency of myoglobin (Mb) mutants under various physiological conditions, i.e. O₂-consumption rate resembling workload, O₂ partial pressure resembling hypoxic stress, muscle cell size, and Mb concentration, resembling different organism-specific and compensatory variables. We find that O₂-storage and -transport are distinct functions that rank mutants and wild type differently depending on O₂ partial pressure. Specifically, the wild type is near-optimal for storage at all conditions, but for transport only at severely hypoxic conditions. At normoxic conditions, low-affinity mutants are in fact better O₂-transporters because they still have empty sites for O₂, giving rise to a larger [MbO₂] gradient (more varying saturation curve). The distributions of functionality reveal that many mutants are near-neutral with respect to function, whereas only a few are strongly affected, and the variation in functionality increases dramatically at lower O₂ pressure. These results together show that conserved residues in wild type (WT) Mb were fixated under a selection pressure of low P_O2.     

New method for the detection of reactive oxygen species in anti-tumoural activity of adriamycin: A comparison between hypoxic and normoxic cells

Tumour hypoxia plays a role in chemoresistance in several human tumours. However, how hyperbaric oxygen leads to chemotherapeutic gain is unclear. This study investigates the relation of reactive oxygen species (ROS) generation with anti-tumoural effect of adriamycin (ADR) on CCRF-CEM cells under hypoxic (2% O₂) and normoxic (21% O₂) conditions. A new method was used to measure intracellular ROS variations through the fluorescence lifetime of 1-pyrenebutyric acid. At 24 h, ADR, probably via semiquinone radical, enhances ROS levels in normoxic cells compared to hypoxic cells. Long-term studies show that ROS are also generated by a second mechanism related to cell functions perturbation. ADR arrests the cell cycle progression both under hypoxia and normoxia, indicating that oxygen and ROS does not influence the DNA damaging activity of ADR. The findings reveal that moderate improvement of ADR cytotoxicity results from higher ROS formation in normoxic cells, leading to elevated induction of cell death.     

Mixtures of hemoglobin‐based oxygen carriers and perfluorocarbons exhibit a synergistic effect in oxygenating hepatic hollow fiber bioreactors

Hepatic hollow fiber (HF) bioreactors are being developed for use as bioartificial liver assist devices (BLADs). In general, BLADs suffer from O₂ limited transport, which reduces their performance. This modeling study seeks to investigate if O₂ carrying solutions consisting of mixtures of hemoglobin‐based oxygen carriers (HBOCs) and perfluorocarbons (PFCs) can enhance O₂ transport to hepatocytes cultured in the extra capillary space (ECS) of HF bioreactors. We simulated supplementing the circulating cell culture media stream of the HF bioreactor with a mixture containing these two types of oxygen carriers (HBOCs and PFCs). A mathematical model was developed based on the dimensions and physical characteristics of a commercial HF bioreactor. The resulting set of partial differential equations, which describes fluid transport; as well as, mass transport of dissolved O₂ in the pseudo‐homogeneous PFC/water phase and oxygenated HBOC, was solved to yield the O₂ concentration field in the three HF domains (lumen, membrane and ECS). Our results show that mixtures of HBOC and PFC display a synergistic effect in oxygenating the ECS. Therefore, the presence of both HBOC and PFC in the circulating cell culture media dramatically improves transport of O₂ to cultured hepatocytes. Moreover, the in vivo O₂ spectrum in a liver sinusoid can be recapitulated by supplementing the HF bioreactor with a mixture of HBOCs and PFCs at an inlet pO₂ of 80 mmHg. Therefore, we expect that PFC‐based oxygen carriers will be more efficient at transporting O₂ at higher O₂ levels (e.g., at an inlet pO₂ of 760 mmHg, which corresponds to pure O₂ in equilibrium with aqueous cell culture media at 1 atm). Biotechnol. Bioeng. 2010; 105: 534–542. © 2009 Wiley Periodicals, Inc.     

Characteristics of human lipoaspirate-isolated mesenchymal stromal cells cultivated under lower oxygen tension

The effect of reduced oxygen concentration in the gas phase on the proliferation, viability, and immunophenotype of human mesenchymal stromal cells isolated from lipoaspirate (lMSC) has been investigated. It was shown that the proliferation activity of cells under hypoxic conditions (5% O₂) was, on average, 2.9 times higher than those cultivated under routine (normoxic) (20% O₂) conditions. Decreased oxygen level in the culture medium did not cause any change in lMSC viability or immunophenotype. Thus, the permanent cultivation of lMSC in medium with a lower oxygen tension may be an efficient approach to obtaining a higher mass of cells that maintain their characteristics over a shorter period of time, which is a requirement for regenerative medicine.     

Differential responses in two varieties of winter wheat to elevated ozone concentration under fully open‐air field conditions

Two modern cultivars [Yangmai16 (Y16) and Yangfumai 2 (Y2)] of winter wheat (Triticum aestivum L.) with almost identical phenology were investigated to determine the impacts of elevated ozone concentration (E‐O₃) on physiological characters related to photosynthesis under fully open‐air field conditions in China. The plants were exposed from the initiation of tillering to final harvest, with E‐O₃ of 127% of the ambient ozone concentration (A‐O₃). Measurements of pigments, gas exchange rates, chlorophyll a fluorescence and lipid oxidation were made in three replicated plots throughout flag leaf development. In cultivar Y2, E‐O₃ significantly accelerated leaf senescence, as indicated by increased lipid oxidation as well as faster declines in pigment amounts and photosynthetic rates. The lower photosynthetic rates were mainly due to nonstomatal factors, e.g. lower maximum carboxylation capacity, electron transport rates and light energy distribution. In cultivar Y16, by contrast, the effects of E‐O₃ were observed only at the very last stage of flag leaf ageing. Since the two cultivars had almost identical phenology and very similar leaf stomatal conductance before senescence, the greater impacts of E‐O₃ on cultivars Y2 than Y16 cannot be explained by differential ozone uptake. Our findings will be useful for scientists to select O₃‐tolerant wheat cultivars against the rising surface [O₃] in East and South Asia.     

The ROS‐induced cytotoxicity of ascorbate is attenuated by hypoxia and HIF‐1alpha in the NCI60 cancer cell lines

Intravenous application of high‐dose ascorbate is used in complementary palliative medicine to treat cancer patients. Pharmacological doses of ascorbate in the mM range induce cytotoxicity in cancer cells mediated by reactive oxygen species (ROS), namely hydrogen peroxide and ascorbyl radicals. However, little is known about intrinsic or extrinsic factors modulating this ascorbate‐mediated cytotoxicity. Under normoxia and hypoxia, ascorbate IC₅₀ values were determined on the NCI60 cancer cells. The cell cycle, the influence of cobalt chloride‐induced hypoxia‐inducible factor‐1α (HIF‐1α) and the glucose transporter 1 (GLUT‐1) expression (a pro‐survival HIF‐1α‐downstream‐target) were analysed after ascorbate exposure under normoxic and hypoxic conditions. The amount of ascorbyl radicals increased with rising serum concentrations. Hypoxia (0.1% O₂) globally increased the IC₅₀ of ascorbate in the 60 cancer cell lines from 4.5 ± 3.6 mM to 10.1 ± 5.9 mM (2.2‐fold increase, P < 0.001, Mann–Whitney t‐test), thus inducing cellular resistance towards ascorbate. This ascorbate resistance depended on HIF‐1α‐signalling, but did not correlate with cell line‐specific expression of the ascorbate transporter GLUT‐1. However, under normoxic and hypoxic conditions, ascorbate treatment at the individual IC₅₀ reduced the expression of GLUT‐1 in the cancer cells. Our data show a ROS‐induced, HIF‐1α‐ and O₂‐dependent cytotoxicity of ascorbate on 60 different cancer cells. This suggests that for clinical application, cancer patients should additionally be oxygenized to increase the cytotoxic efficacy of ascorbate.