Conserved electronic structure of the primary donor in reaction centres of sulfur and non-sulfur purple bacteria
Mueh, F.; Gardiner, A.T.; Witt, H.; Schulz, C.; Imhoff, J.F.; Cogdell, R.J.; Lubitz, W.
Photosynthesis Research 69(1-3): 73
2001
ISSN/ISBN: 0166-8595 Accession: 034639894
PDF emailed within 1 workday: $29.90
Related References
Daviso, E.; Prakash, S.; Alia, A.; Gast, P.; Neugebauer, J.; Jeschke, G.; Matysik, J.ör. 2009: The electronic structure of the primary electron donor of reaction centers of purple bacteria at atomic resolution as observed by photo-CIDNP 13C NMR Proceedings of the National Academy of Sciences of the United States of America 106(52): 22281-22286Inui, M.; Momma, K.; Matoba, R.; Ikuta, M.; Yamagata, H.; Yukawa, H. 1995: Characterization of alcohol-assimilating photosynthetic purple non-sulfur bacteria and cloning of molecular chaperones from a purple non-sulfur bacterium Energy Convers. Manage 36(6-9): 767-770
Tedro, S.M.; Meyer, T.E.; Kamen, M.D. 1976: Primary structure of a high potential iron-sulfur protein from the purple non-sulfur photosynthetic bacterium Rhodopseudomonas gelatinosa Journal of Biological Chemistry 251(1): 129-136
Tedro, S.M.; Meyer, T.E.; Kamen, M.D. 1976: Primary structure of a high potential iron-sulfur protein from the purple non-sulfur photosynthetic bacterium Rhodopseudomonas gelatinosa Journal of Biological Chemistry 251(1): 129-136
Spiedel, D.; Jones, M.R.; Robert, B. 2002: Tuning of the redox potential of the primary electron donor in reaction centres of purple bacteria: Effects of amino acid polarity and position FEBS Letters 527(1-3): 171-175
De Wit, R.; Van den Ende, F.P.; Van Gemerden, H. 1995: Mathematical simulation of the interactions among cyanobacteria, purple sulfur bacteria and chemotrophic sulfur bacteria in microbial mat communities Fems Microbiology Ecology 17(2): 117-136
D.W.t, R.; Van Den Ende, F.P.; Van Gemerden, H. 1995: Mathematical simulation of the interactions among cyanobacteria, purple sulfur bacteria and chemotropic sulfur bacteria in microbial mat communities FEMS Microbiology Ecology 17(2): 117-135
Tadros, M.H.; Drews, G. 1990: Pigment proteins of antenna complexes from purple non sulfur bacteria localization in the membrane alignments of primary structure and structural predictions Drews, G And E A Dawes (Ed ) Fems (Federation Of European Microbiological Societies) Symposium, No 53 Molecular Biology Of Membrane-Bound Complexes in Phototrophic Bacteria; Symposium Held By The Federation Of Microbiological Societies And Deutsche Forschungsgemeinschaft (German Research Association), Freiburg, Germany, August 2-5, 1989 Xi+491p Plenum Press: New York, New York, Usa Illus 181-192
Kim, L.I.; Hudz', S.P. 2007: Purple sulfur bacteria isolated from reservoirs of the Yavoriv sulfur deposit Mikrobiolohichnyi Zhurnal 69(1): 12-19
Mekhtieva, V.L.; Kondrat'eva, E.N. 1966: The fractionation of stable sulfur isotopes by purple photosynthetic sulfur bacteria of the genus Rhodopseudomonas Doklady Akademii Nauk SSSR 166(2): 465-468
Pringault; de Wit R; Kühl 1999: A microsensor study of the interaction between purple sulfur and green sulfur bacteria in experimental benthic gradients Microbial Ecology 37(3): 173-184
Oren, A.; Mana, L.; Jehlička, J. 2015: Probing single cells of purple sulfur bacteria with Raman spectroscopy: carotenoids and elemental sulfur Fems Microbiology Letters 362(6)
Van Gemerden, H. 1986: Production of elemental sulfur by green and purple sulfur bacteria Archives of Microbiology 146(1): 52-56
Khanam, A.; Powar, Z.; Fayyaz, M.; Chaudhary, A. 1974: Occurrence of purple sulfur and green sulfur photosynthetic bacteria in therapeutic mud from bari imam and hasan abdal Proceedings of the Pakistan Science Conference 25(3): C-9-C-10
Hay, P.J. 1977: Generalized valence bond studies of the electronic structure of sulfur difluoride, sulfur tetrafluoride, and sulfur hexafluoride Journal of the American Chemical Society 99(4): 1003-1012
Polishchuk, Y.; Shembel, E.; Strakova Fedorkova, A. 2020: Polymer Structure of Sulfur Ensures Low Self-Discharge of Li-S Primary and Secondary Batteries/Synergistic Effect of Sulfur Structure and Design of Sulfur Electrode ECS Transactions 99(1): 133-141
Erokhin, I.E.; Chugunov, V.A.; Makhneva, Z.K.; Agrikova, I.M.; Vasil'ev, B.G. 1978: Comparative study of B890 pigment-lipoprotein complexes from sulfur (Chromatium minutissimum) and non-sulfur (Rhodopseudomonas palustris) purple photosynthesizing bacteria Biokhimiia 43(4): 669-677
Bateman, L.; Glazebrook, R.W.; Moore, C.G. 1959: The reaction of sulfur and sulfur compounds with olefinic substances. Part XII. Effects of vulcanizing additives on the reaction of sulfur with 2,6-dimethylocta-2,6-diene, and their bearing on the mechanism of sulfur vulcanization of natural rubber Journal of Applied Polymer Science 1(3): 257-266
Brunisholz, R.A.; Zuber, H. 1988: Structural similarities between reaction center and antenna polypeptides of purple non sulfur bacteria Experientia 44(ABSTR): A37
Ivancich, A.; Kobayashi, M.; Drepper, F.; Fathir, I.; Saito, T.; Nozawa, T.; Mattioli, T.A. 1996: Hydrogen-bond interactions of the primary donor of the photosynthetic purple sulfur bacterium Chromatium tepidum Biochemistry 35(32): 10529-10538