Fixation CO 2 with microalgae is a potential promising technique to reduce CO 2 emission for its various advantages. In this work, we develop a microalgal fixation CO 2 system to capture CO 2 from actual flue gas. At first, we evolved a strain Scenedesmus obliquus, named S. obliquus WUST4, with a UV mutagenesis technique, which can endure actual flue gas. The S. obliquus WUST4 can tolerate high concentration CO 2 , and possesses high CO 2 fixation ability. Then, we developed a pilot scale microalgal fixation CO 2 system to capture CO 2 from actual flue gas with the evolved S. obliquus WUST4. The flue gas was discharged from the combustion chamber in a coke oven. A 100 L air-lift photobioreactor was built in this system. In the pilot scale system, CO 2 can be captured from the actual flue gas by the S. obliquus WUST4. The CO 2 removal ratio can reach 67% with the optimal operation conditions. This provides an efficient technique for CO 2 capture.
' EXPERIMENTAL SECTIONMicroalgae Strain and Culture Conditions. S. obliquus was used in this work. It was obtained from Institute of Hydrobiology
Several proteins are attached to the cell membrane by a glycosyl- phosphatidylinositol (GPI) anchor. In this report, we show that during vesiculation of human RBCs in vitro, two of these proteins, acetylcholinesterase and decay accelerating factor, redistribute on the cell surface and become enriched in the released vesicles. As a result, the remnant cells are depleted of these proteins. We suggest that alterations in the architecture of the RBC membrane that precede vesiculation lead to selective polarization of GPI-anchored proteins within the domain of the membrane destined to become a vesicle. Since vesiculation occurs in many cell types, and if the loss of GPI-anchored proteins accompanies this process, it may have important biologic significance.
Several proteins are attached to the cell membrane by a glycosyl- phosphatidylinositol (GPI) anchor. In this report, we show that during vesiculation of human RBCs in vitro, two of these proteins, acetylcholinesterase and decay accelerating factor, redistribute on the cell surface and become enriched in the released vesicles. As a result, the remnant cells are depleted of these proteins. We suggest that alterations in the architecture of the RBC membrane that precede vesiculation lead to selective polarization of GPI-anchored proteins within the domain of the membrane destined to become a vesicle. Since vesiculation occurs in many cell types, and if the loss of GPI-anchored proteins accompanies this process, it may have important biologic significance.
Microalgal photo-biocatalysis is a green technique for asymmetric synthesis. Asymmetric reduction of nonnatural prochiral ketones to produce chiral alcohols by microalgal photo-biocatalysis was studied in this work. Acetophenone (ACP) and ethyl acetoacetate (EAA) were chosen as model substrates for aromatic ketones and β-ketoesters, respectively. Two prokaryotic cyanophyta and two eukaryotic chlorophyta were selected as photo-biocatalysts. The results proved that nonnatural prochiral ketones can be reduced by microalgal photo-biocatalysis with high enantioselectivity. Illumination is indispensable to the photo-biocatalysis. For aromatic ketone, cyanophyta are eligible biocatalysts. For ACP asymmetric reduction reaction, about 45% yield and 97% e.e. can be achieved by the photo-biocatalysis reaction with Spirulina platensis as biocatalyst. On the contrary, chlorophyta are efficient biocatalysts for β-ketoester asymmetric reduction reaction among the four tested algae. For EAA asymmetric reduction reaction, about 70% yield and 90% e.e. can be achieved with Scenedesmus obliquus as biocatalyst. The microalgae used in this study outperformed other characterized biocatalysts such as microbial and plant cells.
To delineate further the underlying mechanism by which amphiphilic drugs can modulate vesicle release from human RBCs, we studied the effect of chlorpromazine on erythrocyte vesiculation induced by ATP depletion. This was correlated with turnover of the phosphoinositides as well as RBC deformability during the process since phosphoinositide metabolism may be involved in shape regulation of RBCs. Echinocytic shape transformation and subsequent vesiculation of RBCs, which commonly occur during ATP depletion, were inhibited by chlorpromazine. Furthermore, with a newly developed two-dimensional thin-layer chromatography separation of RBC membrane phospholipids, we showed that chlorpromazine significantly decreased the dephosphorylation of phosphatidylinositol-4,5-bisphosphate (PIP2) in both ATP-depleted RBCs as well as in cells with partly maintained ATP levels. Concomitantly, there was a smaller increase in the relative amount of phosphatidylinositol. In addition, chlorpromazine also inhibited the decreased in RBC deformability as well as the shift of osmotic fragility that occurs during ATP depletion of erythrocytes.
A series of energetic salts based on 3,4-diamino-1,2,4-triazole with promising detonation performances have been synthesized using a metathesis reaction method or a protonation reaction method.
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