Flexible Solar Thermal Fuel Devices: Composites of Fabric and a Photoliquefiable Azobenzene Derivative

Controllable storage and release of solar energy has always been a highlighted scientific issue for its benefit of mankind. Solar thermal fuels (STFs) supply a closed cycle and renewable energy‐storage strategy by transforming solar energy into chemical energy stored in the conformation of molecular isomers, such as cis/trans‐azobenzene, and releasing it as heat under various stimuli. Although the potential high energy density of the STFs which are based on the hybrids of azobenzene derivatives and carbon nanomaterials has been reported the solvent‐assistant charging hinders their practicability. In this study, a solid‐state STF device is designed and fabricated by compositing one photoliquefiable azobenzene (PLAZ) derivative with a flexible fabric template. The photoinduced phase transition of the PLAZ derivative enables the charging of the flexible STFs to be totally solvent‐free. Interestingly, the energy‐storage capacity (energy density ≈201 J g^?1) of flexible PLAZ STFs has been improved by the soft fabric template. The exothermic situation is monitored with one infrared camera, which shows 4 °C temperature difference between charged and discharged samples under blue light stimulus. The flexible STFs are may be used in practice as heating equipment.     

FRET-based Ca2+ measurement in B lymphocyte by flow cytometry and confocal microscopy

Upon the B cell antigen receptor (BCR) ligation Ca²⁺ mobilization is induced, which is essential for activation of downstream signaling molecules such as MAP kinase. Although synthetic fluorescent chelators such as Fluo-4 and Indo-1 are widely used for Ca²⁺ measurement upon BCR ligation, they are leaked or unfavorably localized into some organelles with time post loading. To solve these problems, we introduce a genetically encoded fluorescent indicator cameleon which is a fluorescence resonance energy transfer (FRET)-based indicator comprising two fluorescent proteins (CFP and YFP) and two Ca²⁺-responsive elements (a variant of calmodulin (CaM) and a CaM-binding peptide). Here, we demonstrate that cameleon as well as a conventional synthetic Ca²⁺ indicator enables Ca²⁺ measurement by flow cytometry clearly upon BCR ligation. In addition, confocal microscopy analysis allows us to detect cameleon-based Ca²⁺ mobilization in a single cell upon BCR ligation.     

Energy conversion in an internally illuminated annular‐plate airlift photobioreactor

Algal‐derived therapeutics, bioactive molecules, and fuels produced in photobioreactors (PBRs) are of great scientific and economic interest, but the high cost of production still prevents their widespread use. Specifically, the cost of the energy inputs and the control of the photonic inputs that enable production optimization continue to be problematic. To this end, a novel 55‐L annular‐plate airlift PBR (APAPBR) with internal illumination was designed and characterized for the batch production of algal biomass. The APAPBR was able to convert mixing and photonic energy inputs into Chlorella pituita SG1 biomass at an efficiency of 0.064 (J biomass [J input]^?1), or 0.27 g dry cell weight (DW) W^?1 d^?1. Thanks to a high degree of photon capture and the airlift effect that provided energy‐efficient mixing and mass transfer, this energy conversion is 54% of the theoretical maximum as determined in previous studies. Under these efficiency conditions, C. pituita SG1 was able to grow photoautotrophically to 3.9 ± 0.2 gDW L^?1. Additionally, a mathematical approach was used to predict the mean light intensity with the highest biomass yield per unit of photonic input and the maximum biomass concentration achievable under the given process conditions. These predictions were validated in our system by the experimental cultivation data. This APAPBR represents a simple, innovative, and energy‐efficient PBR configuration that could decrease the cost of phototrophic bioprocesses and enable novel bioprocesses that require a high degree of control over the photonic input.     

Coordinated reprogramming of metabolism and cell function in adipocytes from proliferation to differentiation

Adipose tissue plays a major role in regulating lipid and energy homeostasis by storing excess nutrients, releasing energetic substrates through lipolysis, and regulating metabolism of other tissues and organs through endocrine and paracrine signaling. Adipocytes within fat tissues store excess nutrients through increased cell number (hyperplasia), increased cell size (hypertrophy), or both. The differentiation of pre-adipocytes into mature lipid-accumulating adipocytes requires a complex interaction of metabolic pathways that is still incompletely understood. Here, we applied parallel labeling experiments and ¹³C-metabolic flux analysis to quantify precise metabolic fluxes in proliferating and differentiated 3T3-L1 cells, a widely used model to study adipogenesis. We found that morphological and biomass composition changes in adipocytes were accompanied by significant shifts in metabolic fluxes, encompassing all major metabolic pathways. In contrast to proliferating cells, differentiated adipocytes 1) increased glucose uptake and redirected glucose utilization from lactate production to lipogenesis and energy generation; 2) increased pathway fluxes through glycolysis, oxidative pentose phosphate pathway and citric acid cycle; 3) reduced lactate secretion, resulting in increased ATP generation via oxidative phosphorylation; 4) rewired glutamine metabolism, from glutaminolysis to de novo glutamine synthesis; 5) increased cytosolic NADPH production, driven mostly by increased cytosolic malic enzyme flux; 6) increased production of monounsaturated C16:1; and 7) activated a mitochondrial pyruvate cycle through simultaneous activity of pyruvate carboxylase, malate dehydrogenase and malic enzyme. Taken together, these results quantitatively highlight the complex interplay between pathway fluxes and cell function in adipocytes, and suggest a functional role for metabolic reprogramming in adipose differentiation and lipogenesis.     

Pt-based electro-catalytic materials derived from biosorption processes and their exploitation in fuel cell technology

Yeast-based biomass, immobilised in polyvinyl alcohol (PVA) cryogels, was used as a biosorbant material for the recovery of platinum (PtCl₆²⁻) from aqueous solutions. The resulting biomass-Pt matrices were then employed directly as an electro-catalytic anode in a fuel cell configuration to generate electrical energy from renewable sources such as glucose and ethanol. We suggest an integrated strategy incorporating the derivation of a high-value product from a bioremediative process with a view towards producing energy from renewable fuels such as glucose and ethanol.     

Playing both sides: nucleophosmin between tumor suppression and oncogenesis

A question preoccupying many researchers is how signal transduction pathways control metabolic processes and energy production. A study by Jang et al. (Jang, C., G. Lee, and J. Chung. 2008. J. Cell Biol. 183:11–17) provides evidence that in Drosophila melanogaster a signaling network controlled by the LKB1 tumor suppressor regulates trafficking of an Sln/dMCT1 monocarboxylate transporter to the plasma membrane. This enables cells to import additional energy sources such as lactate and butyrate, enhancing the repertoire of fuels they can use to power vital activities.     

Aerobic Glycolysis by Proliferating Cells: Protection against Oxidative Stress at the Expense of Energy Yield

Primary cultures of mitogen-activated rat thymocytes were used to study energy metabolism, gene expression of glycolytic enzymes, and production of reactive oxygen species during cell cycle progression. During transition from the resting to the proliferating state a 7- to 10-fold increase of glycolytic enzyme induction occurs which enables the cells to meet the enhanced energy demand by increased aerobic glycolysis. Cellular redox changes have been found to regulate gene expression of glycolytic enzymes by reversible oxidative inactivation of Spl-binding to the cognate DNA-binding sites in the promoter region. In contrast to nonproliferating cells, production of phorbol 12-myristate 13-acetate (PMA)-primed reactive oxygen species (ROS) in proliferating rat thymocytes and HL-60 cells is nearly abolished. Pyruvate, a product of aerobic glycolysis, is an effective scavenger of ROS, which could be shown to be generated mainly at the site of complex III of the mitochondrial respiratory chain. Aerobic glycolysis by proliferating cells is discussed as a means to minimize oxidative stress during the phases of the cell cycle when maximally enhanced biosynthesis and cell division do occur.     

Paracellular transport of insulin-like growth factor-I (IGF-I) across human umbilical vein endothelial cell monolayers

Insulin-like growth factors (IGFs) are well defined mitogens and growth promoters, which are found in blood associated with high affinity IGF binding proteins (IGFBPs). In vivo, the endothelium is potentially the primary site of uptake of IGFs or IGF-IGFBP complexes from blood for transport to the extravascular space. However, the pathway and mechanisms by which IGFs cross the endothelial cell barrier are not known. The presence of high affinity receptors for IGF-I and IGF-II on human umbilical vein endothelial (HUVE) cells was demonstrated by (i) radio-receptor assays using both IGF-I and IGF-II and (ii) affinity label cross-linking studies. In addition, Western ligand blotting and immunoblotting revealed that IGFBP-2, -3, and -4 are secreted into serum-free media conditioned by confluent HUVE cell monolayers. To study transendothelial migration of IGF-I, HUVE cells were grown on microporous membranes in a bichamber system. When compared with membranes without cells, HUVE monolayers restricted the passage of ¹²⁵I-IGF-I and [³H]inulin, whereas the control Madin Darby canine kidney (MDCK) cell line virtually excluded all passage of these molecules. Transport of ¹²⁵I-IGF-I across HUVE cell monolayers was not significantly different to that of [³H]inulin, a paracellular probe. Moreover, ¹²⁵I-IGF-I transport was not inhibited by either excess unlabelled IGF-I or a monoclonal antibody to the type I IGF receptor at a concentration shown to inhibit ¹²⁵I-IGF-I binding to HUVE cell monolayers. Our findings show that the movement of free IGF-I across HUVE cell monolayers occurs via a paracellular route and not by a receptor-mediated, transcellular pathway. J. Cell. Physiol. 170:290–298, 1997. © 1997 Wiley-Liss, Inc.     

Simultaneous measurement of aggregation, secretion, oxygen uptake, proton production, and intracellular metabolites in the same platelet suspension.

A cuvette is described for the simultaneous measurement of hydrogen ions, calcium ions, light transmission, and pO₂ in a single gel-filtered platelet suspension stirred at 37°C. A variable volume (2.5–10 ml) and special in- and outlets permit additions and sampling during incubation. Evidence is presented that changes in these parameters reflect lactate production in resting platelets (H⁺ measurement), secretion of dense granular content (Ca²⁺ measurement), shape change and aggregation (light transmission), and arachidonate oxidation and mitochondrial respiration (pO₂ measurement). The cuvette therefore enables direct correlation between function and energy metabolism in platelets.     

Post-proliferative cyclin E-associated kinase activity in differentiated osteoblasts: Inhibition by proliferating osteoblasts and osteosarcoma cells

Spontaneous differentiation of normal diploid osteoblasts in culture is accompanied by increased cyclin E associated kinase activity on (1) the retinoblastoma susceptibility protein pRB, (2) the p107 RB related protein, and (3) two endogenous cyclin E-associated substrates of 78 and 105 kD. Activity of the differentiation-related cyclin E complexes (diff.ECx) is not recovered in cdc2 or cdk2 immunoprecipitates. Phosphorylation of both the 105 kD endogenous substrate and the p107 exogenous substrate is sensitive to inhibitory activity (diff.ECx-i) present in proliferating osteoblasts. This inhibitory activity is readily recruited by the cyclin E complexes of differentiated osteoblasts but is not found in cyclin E immunoprecipitates of the proliferating cells themselves. Strong inhibitory activity on diff.ECx kinase activity is excerted by proliferating ROS 17/2.8 osteosarcoma cells. However, unlike the normal diploid cells, the diff.ECx-i activity of proliferating ROS 17/2.8 cells is recovered by cyclin E immunoprecipitation. The cyclin-dependent kinase inhibitor p21^CIP1/WAF1 inhibits diff.ECx kinase activity. Thus, our results suggest the existence of a unique regulatory system, possibly involving p21^CIP1/WAF1, in which inhibitory activity residing in proliferating cells is preferentially targeted towards differentiation-related cyclin E-associated kinase activity. J. Cell. Biochem. 66:141-152, 1997. © 1997 Wiley-Liss, Inc.     

Exogenous,basal, and flow-induced nitric oxide production and endothelial cell proliferation

The role of nitric oxide (NO) from endogenous and exogenous sources in regulating large vessel and microvascular endothelial cell proliferation was investigated. Exogenous NO liberated from five different chemical donors inhibited bovine aortic, bovine retinal microvascular, and human umbilical vein endothelial cell proliferation in a dose-dependent manner as determined by ³H-thymidine incorporation. The potency of the donors varied as a function of the donors' half-lives. Donors with half-lives greater than 30 min were more effective than donors with significantly shorter half-lives. Coincubation of endothelial cells with 0.4 mM deoxyadenosine and 0.4 mM deoxyguanosine reduced the percentage of inhibition due to an NO donor. These data are consistent with a ribonucleotide reductase-dependent mechanism of inhibition. Inhibition of basal NO production with four different inhibitors of nitric oxide synthase (NOS) did not modify proliferation. Laminar flow with a wall shear stress of 22 dyn/cm²inhibited the proliferation of subconfluent bovine aortic endothelial cells. The addition of a NOS inhibitor did not abrogate the flow-induced inhibition of proliferation, suggesting that flow-stimulated release of NO from endothelial cells did not account for flow-induced inhibition of proliferation. Taken together, these data suggest that relatively large concentrations of exogenous NO inhibit endothelial cell proliferation, while endogenous levels of NO are inadequate to inhibit proliferation. J. Cell. Physiol. 171:252–258, 1997. © 1997 Wiley-Liss, Inc.     

Vpr Stimulates Viral Expression and Induces Cell Killing in Human Immunodeficiency Virus Type 1-Infected Dividing Jurkat T Cells

In this study we investigated the effects of Vpr during human immunodeficiency virus (HIV) infection of proliferating Jurkat T cells by using a vesicular stomatitis virus envelope G glycoprotein pseudotyped HIV superinfection system. We observe that the expression of Vpr results in a severe reduction in the life span of HIV type 1 (HIV-1)-infected dividing T cells in culture. In agreement with a recent report (S. A. Stewart, B. Poon, J. B. M. Jowett, and I. S. Chen, J. Virol. 71:5579–5592, 1997), we show that events characteristic of apoptotic cell death are involved in the Vpr-mediated cytopathic effects. Our results also show that infection with viruses expressing the wild-type vpr gene results in an increase in viral gene expression and production. Interestingly, the effects of Vpr on cell viability and on viral gene expression both correlate with the ability of the protein to induce a cell cycle arrest in the G₂/M phase. Mutagenesis analyses show that the C terminus of Vpr is essential for these biological activities. Although the role of Vpr is currently associated with the infection of nondividing cells, our results suggest that Vpr can also directly increase viral replication in vivo in infected dividing T cells. Furthermore, these in vitro observations suggest that Vpr-mediated cytotoxic effects could contribute to the CD4⁺ depletion associated with AIDS progression.     

Development of a solar-powered microbial fuel cell

Aims: To understand factors that impact solar‐powered electricity generation by Rhodobacter sphaeroides in a single‐chamber microbial fuel cell (MFC). Methods and Results: The MFC used submerged platinum‐coated carbon paper anodes and cathodes of the same material, in contact with atmospheric oxygen. Power was measured by monitoring voltage drop across an external resistance. Biohydrogen production and in situ hydrogen oxidation were identified as the main mechanisms for electron transfer to the MFC circuit. The nitrogen source affected MFC performance, with glutamate and nitrate‐enhancing power production over ammonium. Conclusions: Power generation depended on the nature of the nitrogen source and on the availability of light. With light, the maximum point power density was 790 mW m^?2 (2·9 W m^?3). In the dark, power output was less than 0·5 mW m^?2 (0·008 W m^?3). Also, sustainable electrochemical activity was possible in cultures that did not receive a nitrogen source. Significance and Impact of the Study: We show conditions at which solar energy can serve as an alternative energy source for MFC operation. Power densities obtained with these one‐chamber solar‐driven MFC were comparable with densities reported in nonphotosynthetic MFC and sustainable for longer times than with previous work on two‐chamber systems using photosynthetic bacteria.     

Animal cell culture in stirred bioreactors: Observations on scale-up

Scale-up of stirred tank bioreactors from 0.02 m³ to 0.3 m³ commercial plant is discussed for hybridoma suspension culture. Schemes for dissolved oxygen control with sparged air in serum containing media are described as well as mechanical breakage of foam in small and large bioreactors. Porous metal spargers (180?200×10^?6 m) are found to produce foams which are hard to control. Aeration with larger (> 0.001 m) multihole spargers is recommended. Combined cell damage due to foam formation and control, and possible damage at mechanical seals or submerged bearings, are found to have no measurable effect on cell growth relative to roller bottle production. Hybridomas are shown to withstand significant impeller tip speed (> 1 ms^?1) and fluid turbulence as evidenced by impeller Reynolds numbers in excess of 10⁵. The size of the energy dissipating terminal eddies is calculated to be > 10-fold that of the hybridoma cells. Specific fluid turnover rate is employed as the scale-up criterion.     

Estimation of Chinese hamster ovary cell density in packed-bed bioreactor by lactate production rate

A method is described for estimating recombinant Chinese hamster ovary (rCHO) cell density in a packed-bed bioreactor by lactate production rate. The lactate production rate, which depended on both the cell numbers and cell growth rate, was modeled by segregating the cell population into two parts: one growing at a maximum specific growth rate and another non-growing. The individual cell in each part had the same lactate production rate. The established rate equation of lactate production matched the experimental data reasonably well and could be used to estimate the cell growth in the batch culture with microcarriers. Furthermore, in the perfusion culture of rCHO cells in a packed-bed bioreactor, the final cell density, 1.3×10¹⁰ cells l^–1, estimated by lactate production rate, was comparable to the direct sample counting of 1.2×10¹⁰ cells l^–1, showing that lactate production rate method would be useful in tracing the cell growth in packed-bed bioreactors.     

Asymmetrical cell division and differentiation are not dependent upon stratification in a corneal epithelial cell line

To determine whether asymmetrical cell division takes place during growth and differentiation of corneal epithelial cells, we analyzed the expression of some proteins required for the correct execution of the asymmetric division in cultured RCE1‐(5T5) cells, which mimic the differentiation of corneal epithelial cells. RT‐PCR and immunostaining showed that Par‐3, LGN (GPSM2), NuMA, and the mammalian homolog of inscuteable (Insc) are expressed by the cultured cells. Semi‐quantitative RT‐PCR demonstrated that Insc mRNA levels were stable throughout the experiment. Conversely, LGN and NuMA mRNAs increased slightly and steadily in proliferative cells, reaching a peak of about 20% above basal levels when cells were confluent. At later times, LGN and NuMA mRNAs decreased to become barely detectable when cells organized into a four‐layered epithelium and expressed terminal phenotype as indicated by the highest expression of LDH‐H mRNA. Cultivation under low Ca²⁺ conditions (0.09 mM) reduced about 50% Insc mRNA expression both in proliferating and confluent cultures, but did not affect the levels of LGN and NuMA mRNAs. Hence, asymmetric cell division seems to take place with a lower frequency in cells grown with low Ca²⁺ concentrations, in spite of the absence of stratification. Immunostaining experiments raise the possibility of an interaction between k3/K12 keratin cytoskeleton and Par‐3. The results show for the first time the coordination between the expression of corneal epithelial cell differentiation and the expression of cell polarity machinery. They also suggest that asymmetric division does not depend on stratification; instead, it seems to be part of the differentiation program. J. Cell. Physiol. 226: 700–709, 2011. © 2010 Wiley‐Liss, Inc.     

Conditionally lethal mutations in Chinese hamster cells. Characterization of a cell line with a possible defect in the krebs cycle

A variant Chinese hamster cell line has been isolated from a mutagenized population that has a markedly reduced ability to oxidize a variety of substrates via the Krebs cycle. The production of ¹⁴CO₂ from ¹⁴C-labeled compounds was measured using pyruvate, acetate, β-hydroxybutyrate, palmitate and glutamate, and in all cases it was negligible in the mutant. In contrast to this, significant amounts of ¹⁴CO₂ were produced from ¹⁴C-aspartate and ¹⁴C-succinate which suggests that some reactions of the Krebs cycle can take place and this conclusion is supported by tracer experiments with labeled compounds. The rate of respiration measured with a Clark oxygen electrode in the mutant was compared to several normal Chinese hamster cell lines and was found to be only 8%. Mitochondria appear to be present in normal numbers and with only minor differences in morphology. The measurement of difference spectra between oxidized and reduced states permits us to conclude that the cytochromes are all present and functional. These results lead us to believe that there may be a defect in the Krebs cycle between α-ketoglutarate and succinate. Alternatively a defect in a structural component of the mitochondria or in the electron-transport chain itself may be causing pleiotropic effects in the Krebs cycle and respiration.     

Greenhouse gas emissions and abatement costs of biofuel production in South Africa

Transport accounts for about one quarter of South Africa's final energy consumption. Most of the energy used is based on fossil fuels causing significant environmental burdens. This threat becomes even more dominant as a significant growth in transport demand is forecasted, especially in South Africa's economic hub, Gauteng province. The South African government has realized the potential of biofuel usage for reducing oil import dependency and greenhouse gas (GHG) and has hence developed a National Biofuels Industrial Strategy to enforce their use. However, there is limited experience in the country in commercial biofuel production and some of the proposed crops (i.e. rapeseed and sugar beet) have not been yet cultivated on a larger scale. Furthermore, there is only limited research available, looking at the feasibility of commercial scale biofuel production or abatement costs of GHG emissions. To assess the opportunities of biofuel production in South Africa, the production costs and consumer price levels of the fuels recommended by the national strategy are analysed in this article. Moreover, the lifecycle GHG emissions and mitigation costs are calculated compared to the calculated fossil fuel reference including coal to liquid (CTL) and gas to liquid (GTL) fuels. The results show that the cost for biofuel production in South Africa are currently significantly higher (between 30% and 80%) than for the reference fossil fuels. The lifecycle GHG emissions of biofuels (especially for sugar cane) are considerably lower (up to 45%) than the reference fossil GHG emissions. The resulting GHG abatement costs are between 1000 and 2500 ZAR₂₀₀₇ per saved ton of carbon dioxide equivalent, which is high compared to the current European CO₂ market prices of ca. 143 ZAR₂₀₀₇ t^?1. The analysis has shown that biofuel production and utilization in South Africa offers a significant GHG‐mitigation potential but at relatively high cost.     

Strategies for maximizing metallothionein promoter regulated recombinant protein production in mammalian cell cultures

A stably transformed BHK cell line, engineered to produce a human transferrin half-molecule under the control of a mouse metallothionein (MT) promoter, was used as a model system to develop strategies to increase inducible recombinant protein production. Gene expression regulated by the MT promoter is induced by heavy metals (e.g. Zn⁺² or Cd⁺²) in a dose dependent fashion. However, at high concentrations these metals are toxic to cells. Culture protocols which balance these counteractive effects are needed to maximize transferrin production. Fully induced cells produced up to 0.7 pg transferrin/cell·h, a 3-fold increase in production over uninduced levels. Cell growth was inhibited at Cd⁺² dosages above 1 fmol/cell; prolinged exposure at this dosage was cytotoxic. Cell specific transferrin productivities decreased within 48 h following induction with Cd⁺² although cell-associated Cd⁺² levels remain high. Further addition of Cd⁺² to cultures restored cell specific transferrin production rates. This suggests that cell associated Cd⁺² is sequestered into a form which does not stimulate the MT promoter. Cd⁺² dosing regimes which maintained cell associated Cd⁺² concentrations between 0.2 and 0.35 fmol/cell ensured cell growth and high cell specific productivities which maximized final product titers. For routine batch culture, initial Cd⁺² loadings of 0.8 fmol/cell gave near-maximum transferrin production levels. For extended culture, repeated small doses of 0.5 fmol/cell every 24 to 48 h maximized transferrin synthesis with this cell line.