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Journal Abstract Search

232 related items for PubMed ID: 8942673

  • 1. Spectroscopic evidence for altered chromophore--protein interactions in low-temperature photoproducts of the visual pigment responsible for congenital night blindness.
    Fahmy K, Zvyaga TA, Sakmar TP, Siebert F.
    Biochemistry; 1996 Nov 26; 35(47):15065-73. PubMed ID: 8942673
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  • 7. Time-resolved spectroscopy of the early photolysis intermediates of rhodopsin Schiff base counterion mutants.
    Jäger S, Lewis JW, Zvyaga TA, Szundi I, Sakmar TP, Kliger DS.
    Biochemistry; 1997 Feb 25; 36(8):1999-2009. PubMed ID: 9047297
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  • 8. FTIR studies of the photoactivation processes in squid retinochrome.
    Furutani Y, Terakita A, Shichida Y, Kandori H.
    Biochemistry; 2005 Jun 07; 44(22):7988-97. PubMed ID: 15924417
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  • 9. The nature of the primary photochemical events in rhodopsin and isorhodopsin.
    Birge RR, Einterz CM, Knapp HM, Murray LP.
    Biophys J; 1988 Mar 07; 53(3):367-85. PubMed ID: 2964878
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  • 10. A resonance Raman study of the C=N configurations of octopus rhodopsin, bathorhodopsin, and isorhodopsin.
    Huang L, Deng H, Weng G, Koutalos Y, Ebrey T, Groesbeek M, Lugtenburg J, Tsuda M, Callender RH.
    Biochemistry; 1996 Jul 02; 35(26):8504-10. PubMed ID: 8679611
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  • 11. Structural changes in the Schiff base region of squid rhodopsin upon photoisomerization studied by low-temperature FTIR spectroscopy.
    Ota T, Furutani Y, Terakita A, Shichida Y, Kandori H.
    Biochemistry; 2006 Mar 07; 45(9):2845-51. PubMed ID: 16503639
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  • 12. Rhodopsin mutation G90D and a molecular mechanism for congenital night blindness.
    Rao VR, Cohen GB, Oprian DD.
    Nature; 1994 Feb 17; 367(6464):639-42. PubMed ID: 8107847
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  • 13. Disruption of Hydrogen-Bond Network in Rhodopsin Mutations Cause Night Blindness.
    Katayama K, Takeyama Y, Enomoto A, Imai H, Kandori H.
    J Mol Biol; 2020 Sep 04; 432(19):5378-5389. PubMed ID: 32795534
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  • 14. Fourier-transform infrared difference spectroscopy of rhodopsin and its photoproducts at low temperature.
    Bagley KA, Balogh-Nair V, Croteau AA, Dollinger G, Ebrey TG, Eisenstein L, Hong MK, Nakanishi K, Vittitow J.
    Biochemistry; 1985 Oct 22; 24(22):6055-71. PubMed ID: 4084506
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  • 15. A comparative study of the infrared difference spectra for octopus and bovine rhodopsins and their bathorhodopsin photointermediates.
    Bagley KA, Eisenstein L, Ebrey TG, Tsuda M.
    Biochemistry; 1989 Apr 18; 28(8):3366-73. PubMed ID: 2742842
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  • 16. FTIR spectroscopy of the all-trans form of Anabaena sensory rhodopsin at 77 K: hydrogen bond of a water between the Schiff base and Asp75.
    Furutani Y, Kawanabe A, Jung KH, Kandori H.
    Biochemistry; 2005 Sep 20; 44(37):12287-96. PubMed ID: 16156642
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  • 17. Resonance Raman microprobe spectroscopy of rhodopsin mutants: effect of substitutions in the third transmembrane helix.
    Lin SW, Sakmar TP, Franke RR, Khorana HG, Mathies RA.
    Biochemistry; 1992 Jun 09; 31(22):5105-11. PubMed ID: 1351402
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  • 18. Time-resolved rapid-scan Fourier transform infrared difference spectroscopy on a noncyclic photosystem: rhodopsin photointermediates from Lumi to Meta II.
    Lüdeke S, Lórenz Fonfría VA, Siebert F, Vogel R.
    Biopolymers; 2006 Oct 05; 83(2):159-69. PubMed ID: 16721790
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  • 19. Identification of glutamic acid 113 as the Schiff base proton acceptor in the metarhodopsin II photointermediate of rhodopsin.
    Jäger F, Fahmy K, Sakmar TP, Siebert F.
    Biochemistry; 1994 Sep 13; 33(36):10878-82. PubMed ID: 7916209
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  • 20. The role of Glu181 in the photoactivation of rhodopsin.
    Lüdeke S, Beck M, Yan EC, Sakmar TP, Siebert F, Vogel R.
    J Mol Biol; 2005 Oct 21; 353(2):345-56. PubMed ID: 16169009
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