Inclusion complex of Orange II with β-Cyclodextrin (β-CD) and the anti-photolysis effect under UV-light were investigated. The molar ratio of inclusion complex of β-Cyclodextrin and Orange Ⅱ is 1∶1. The formation...Inclusion complex of Orange II with β-Cyclodextrin (β-CD) and the anti-photolysis effect under UV-light were investigated. The molar ratio of inclusion complex of β-Cyclodextrin and Orange Ⅱ is 1∶1. The formation constant K=1.236×10 3 L/mol was determined by the UV and Fluorescence spectra respectively, which was quite in accordance with the calculation with a modified Benesi-Hildbrand equation. The inclusion complex was characterized by the IR spectra and the molar ratio of inclusion complex is 1∶1 too. The formation constant K=1.266×10 3 L/mol was determined by 1 H NMR analysis and was nearly the same by UV and fluorescence spectra. The photocatalytic decolorization rate of Orange Ⅱ solutions containing β-CD and TiO_ 2 was smaller by 51.9% than that of the Orange Ⅱ solutions only containing TiO_ 2 , while in the case of direct photolysis of Orange Ⅱ solutions, β-CD can lower the photolysis rate by 48.1% under UV-light. This result indicates β-CD can inhibit the photolysis and photocatalytic decolorization of Orange Ⅱ under UV-light. The β-CD inclusion complex was found to be persistent to UV-light photolysis.展开更多
The main task of this article was to prepared of new pigment model in situ solar cells accordance to charge-transfer complexes of rhodamine C(RhC) donor as dye laser gain media with iodine(σ-acceptor) and chloranilic...The main task of this article was to prepared of new pigment model in situ solar cells accordance to charge-transfer complexes of rhodamine C(RhC) donor as dye laser gain media with iodine(σ-acceptor) and chloranilic acid, CLA(π-acceptor). The synthesis stoichiometry of these complexes were of 1∶2(donor∶acceptor) with general formulas [(RhC)]I·I3 and [(RhC)(CLA)2]. The discussed data of elemental analysis, conductivity measurements, FT-IR, UV-Vis spectroscopy and photometric titration data visualized the stoichiometry, formula and complexity of the complexes. The physicochemical and spectroscopic analyses obtained suggested that the electron transfer occurred through nitrogen atom in a tertiary amine —N(C2H5)2 of RhC donor with acceptor. The synthesized solid complexes were under go to thermogravimetric analyses to investigate their thermal stability and decomposition steps. The molar conductance measurements revealed that RhC complexes have an electrolytic statement. The thermal stability of rhodamine C complexes was enhanced in comparable with RhC itself. The polymer membranes of poly-methyl methacrylate)(PMMA) combined with the RhC charge(transfer complexes in chloroform solvent have been prepared and characterized by(infrared & electronic) spectroscopy and scanning electron microscopy(SEM) morphological examination. The photo-stability properties of the RhC complexes have been investigated.展开更多
An ever-increasing number of intracellular multi-protein networks have been identified in plant cells.Split-GFP-based protein–protein interaction assays combine the advantages of in vivo interaction studies in a nati...An ever-increasing number of intracellular multi-protein networks have been identified in plant cells.Split-GFP-based protein–protein interaction assays combine the advantages of in vivo interaction studies in a native environment with additional visualization of protein complex localization.Because of their simple protocols,they have become some of the most frequently used methods.However,standard fluorescent proteins present several drawbacks for sophisticated microscopy.With the HaloTag system,these drawbacks can be overcome,as this reporter forms covalent irreversible bonds with synthetic photostable fluorescent ligands.Dyes can be used in adjustable concentrations and are suitable for advanced microscopy methods.Therefore,we have established the Split-HaloTag imaging assay in plants,which is based on the reconstitution of a functional HaloTag protein upon protein–protein interaction and the subsequent covalent binding of an added fluorescent ligand.Its suitability and robustness were demonstrated using a well-characterized interaction as an example of protein–protein interaction at cellular structures:the anchoring of the molybdenumcofactor biosynthesis complex to filamentous actin.In addition,a specific interactionwas visualized in a more distinctivemannerwith subdiffractional polarizationmicroscopy,Airyscan,and structured illumination microscopy to provide examples of sophisticated imaging.Split-GFPand Split-HaloTag can complement one another,as Split-HaloTag represents an alternative option and an addition to the large toolbox of in vivo methods.Therefore,this promising new Split-HaloTag imaging assay provides a unique and sensitive approach formore detailed characterization of protein–protein interactions using specific microscopy techniques,such as 3D imaging,single-molecule tracking,and super-resolution microscopy.展开更多
文摘Inclusion complex of Orange II with β-Cyclodextrin (β-CD) and the anti-photolysis effect under UV-light were investigated. The molar ratio of inclusion complex of β-Cyclodextrin and Orange Ⅱ is 1∶1. The formation constant K=1.236×10 3 L/mol was determined by the UV and Fluorescence spectra respectively, which was quite in accordance with the calculation with a modified Benesi-Hildbrand equation. The inclusion complex was characterized by the IR spectra and the molar ratio of inclusion complex is 1∶1 too. The formation constant K=1.266×10 3 L/mol was determined by 1 H NMR analysis and was nearly the same by UV and fluorescence spectra. The photocatalytic decolorization rate of Orange Ⅱ solutions containing β-CD and TiO_ 2 was smaller by 51.9% than that of the Orange Ⅱ solutions only containing TiO_ 2 , while in the case of direct photolysis of Orange Ⅱ solutions, β-CD can lower the photolysis rate by 48.1% under UV-light. This result indicates β-CD can inhibit the photolysis and photocatalytic decolorization of Orange Ⅱ under UV-light. The β-CD inclusion complex was found to be persistent to UV-light photolysis.
基金the Deanship of Scientific Research at Imam Abdulrahman Bin Faisal University(2017-143-CED)
文摘The main task of this article was to prepared of new pigment model in situ solar cells accordance to charge-transfer complexes of rhodamine C(RhC) donor as dye laser gain media with iodine(σ-acceptor) and chloranilic acid, CLA(π-acceptor). The synthesis stoichiometry of these complexes were of 1∶2(donor∶acceptor) with general formulas [(RhC)]I·I3 and [(RhC)(CLA)2]. The discussed data of elemental analysis, conductivity measurements, FT-IR, UV-Vis spectroscopy and photometric titration data visualized the stoichiometry, formula and complexity of the complexes. The physicochemical and spectroscopic analyses obtained suggested that the electron transfer occurred through nitrogen atom in a tertiary amine —N(C2H5)2 of RhC donor with acceptor. The synthesized solid complexes were under go to thermogravimetric analyses to investigate their thermal stability and decomposition steps. The molar conductance measurements revealed that RhC complexes have an electrolytic statement. The thermal stability of rhodamine C complexes was enhanced in comparable with RhC itself. The polymer membranes of poly-methyl methacrylate)(PMMA) combined with the RhC charge(transfer complexes in chloroform solvent have been prepared and characterized by(infrared & electronic) spectroscopy and scanning electron microscopy(SEM) morphological examination. The photo-stability properties of the RhC complexes have been investigated.
基金supported by the Deutsche Forschungsgemeinschaft(grant GRK2223/1)to R.H.and R.R.M.
文摘An ever-increasing number of intracellular multi-protein networks have been identified in plant cells.Split-GFP-based protein–protein interaction assays combine the advantages of in vivo interaction studies in a native environment with additional visualization of protein complex localization.Because of their simple protocols,they have become some of the most frequently used methods.However,standard fluorescent proteins present several drawbacks for sophisticated microscopy.With the HaloTag system,these drawbacks can be overcome,as this reporter forms covalent irreversible bonds with synthetic photostable fluorescent ligands.Dyes can be used in adjustable concentrations and are suitable for advanced microscopy methods.Therefore,we have established the Split-HaloTag imaging assay in plants,which is based on the reconstitution of a functional HaloTag protein upon protein–protein interaction and the subsequent covalent binding of an added fluorescent ligand.Its suitability and robustness were demonstrated using a well-characterized interaction as an example of protein–protein interaction at cellular structures:the anchoring of the molybdenumcofactor biosynthesis complex to filamentous actin.In addition,a specific interactionwas visualized in a more distinctivemannerwith subdiffractional polarizationmicroscopy,Airyscan,and structured illumination microscopy to provide examples of sophisticated imaging.Split-GFPand Split-HaloTag can complement one another,as Split-HaloTag represents an alternative option and an addition to the large toolbox of in vivo methods.Therefore,this promising new Split-HaloTag imaging assay provides a unique and sensitive approach formore detailed characterization of protein–protein interactions using specific microscopy techniques,such as 3D imaging,single-molecule tracking,and super-resolution microscopy.