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Journal Abstract Search

195 related items for PubMed ID: 28559347

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  • 3. Evolution of Ycf54-independent chlorophyll biosynthesis in cyanobacteria.
    Chen GE, Hitchcock A, Mareš J, Gong Y, Tichý M, Pilný J, Kovářová L, Zdvihalová B, Xu J, Hunter CN, Sobotka R.
    Proc Natl Acad Sci U S A; 2021 Mar 09; 118(10):. PubMed ID: 33649240
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  • 4. Conserved residues in Ycf54 are required for protochlorophyllide formation in Synechocystis sp. PCC 6803.
    Hollingshead S, Bliss S, Baker PJ, Neil Hunter C.
    Biochem J; 2017 Feb 20; 474(5):667-681. PubMed ID: 28008132
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  • 7. Aerobic and anaerobic Mg-protoporphyrin monomethyl ester cyclases in purple bacteria: a strategy adopted to bypass the repressive oxygen control system.
    Ouchane S, Steunou AS, Picaud M, Astier C.
    J Biol Chem; 2004 Feb 20; 279(8):6385-94. PubMed ID: 14617630
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  • 8. Distribution and origin of oxygen-dependent and oxygen-independent forms of Mg-protoporphyrin monomethylester cyclase among phototrophic proteobacteria.
    Boldareva-Nuianzina EN, Bláhová Z, Sobotka R, Koblízek M.
    Appl Environ Microbiol; 2013 Apr 20; 79(8):2596-604. PubMed ID: 23396335
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  • 9. Granick revisited: Synthesizing evolutionary and ecological evidence for the late origin of bacteriochlorophyll via ghost lineages and horizontal gene transfer.
    Ward LM, Shih PM.
    PLoS One; 2021 Apr 20; 16(1):e0239248. PubMed ID: 33507911
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  • 11. Identification of the chlE gene encoding oxygen-independent Mg-protoporphyrin IX monomethyl ester cyclase in cyanobacteria.
    Yamanashi K, Minamizaki K, Fujita Y.
    Biochem Biophys Res Commun; 2015 Aug 07; 463(4):1328-33. PubMed ID: 26102037
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  • 12. Incomplete Hydrogenation by Geranylgeranyl Reductase from a Proteobacterial Phototroph Halorhodospira halochloris, Resulting in the Production of Bacteriochlorophyll with a Tetrahydrogeranylgeranyl Tail.
    Tsukatani Y, Harada J, Kurosawa K, Tanaka K, Tamiaki H.
    J Bacteriol; 2022 Mar 15; 204(3):e0060521. PubMed ID: 35225690
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  • 13. Identification of two homologous genes, chlAI and chlAII, that are differentially involved in isocyclic ring formation of chlorophyll a in the cyanobacterium Synechocystis sp. PCC 6803.
    Minamizaki K, Mizoguchi T, Goto T, Tamiaki H, Fujita Y.
    J Biol Chem; 2008 Feb 01; 283(5):2684-92. PubMed ID: 18039649
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  • 14. Mg-protoporphyrin IX monomethyl ester cyclase from Rhodobacter capsulatus: radical SAM-dependent synthesis of the isocyclic ring of bacteriochlorophylls.
    Wiesselmann M, Hebecker S, Borrero-de Acuña JM, Nimtz M, Bollivar D, Jänsch L, Moser J, Jahn D.
    Biochem J; 2020 Dec 11; 477(23):4635-4654. PubMed ID: 33211085
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  • 15. Potential roles of YCF54 and ferredoxin-NADPH reductase for magnesium protoporphyrin monomethylester cyclase.
    Herbst J, Girke A, Hajirezaei MR, Hanke G, Grimm B.
    Plant J; 2018 May 11; 94(3):485-496. PubMed ID: 29443418
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  • 17. The trouble with oxygen: The ecophysiology of extant phototrophs and implications for the evolution of oxygenic photosynthesis.
    Hamilton TL.
    Free Radic Biol Med; 2019 Aug 20; 140():233-249. PubMed ID: 31078729
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  • 18. Elucidation of the preferred routes of C8-vinyl reduction in chlorophyll and bacteriochlorophyll biosynthesis.
    Canniffe DP, Chidgey JW, Hunter CN.
    Biochem J; 2014 Sep 15; 462(3):433-40. PubMed ID: 24942864
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  • 19. Two Unrelated 8-Vinyl Reductases Ensure Production of Mature Chlorophylls in Acaryochloris marina.
    Chen GE, Hitchcock A, Jackson PJ, Chaudhuri RR, Dickman MJ, Hunter CN, Canniffe DP.
    J Bacteriol; 2016 May 15; 198(9):1393-400. PubMed ID: 26903415
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  • 20. Polychromatic solar energy conversion in pigment-protein chimeras that unite the two kingdoms of (bacterio)chlorophyll-based photosynthesis.
    Liu J, Friebe VM, Frese RN, Jones MR.
    Nat Commun; 2020 Mar 24; 11(1):1542. PubMed ID: 32210238
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