Conformational Coupling between the Cytoplasmic Carboxylic Acid and the Retinal in a Fungal Light-Driven Proton Pump

Conformational Coupling between the Cytoplasmic Carboxylic Acid and the Retinal in a Fungal Light-Driven Proton Pump

Many fungal rhodopsins, eukaryotic structural homologues of the archaeal light-driven proton pump bacteriorhodopsin, have been discovered in the course of genome sequencing projects. Recently, two fungal rhodopsins were characterized in vitro and exhibited very different photochemical behavior. Neur...

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Bibliographic Details
Published in:Biochemistry (Easton) Vol. 45; no. 51; pp. 15349 - 15358
Main Authors: Furutani, Yuji, Sumii, Masayo, Fan, Ying, Shi, Lichi, Waschuk, Stephen A, Brown, Leonid S, Kandori, Hideki
Format: Journal Article
Language:English
Published: United States American Chemical Society 26-12-2006
Subjects:
Amino Acid Substitution - genetics
Ascomycota
Asparagine - genetics
Aspartic Acid - genetics
Carboxylic Acids - chemistry
Carboxylic Acids - metabolism
Cytoplasm - chemistry
Cytoplasm - metabolism
Glutamic Acid - genetics
Lasers
Neurospora
Protein Conformation
Proton Pumps - chemistry
Proton Pumps - metabolism
Retinaldehyde - chemistry
Retinaldehyde - metabolism
Rhodopsin - chemistry
Rhodopsin - genetics
Rhodopsin - metabolism
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Summary:Many fungal rhodopsins, eukaryotic structural homologues of the archaeal light-driven proton pump bacteriorhodopsin, have been discovered in the course of genome sequencing projects. Recently, two fungal rhodopsins were characterized in vitro and exhibited very different photochemical behavior. Neurospora rhodopsin possesses a slow photocycle and shows no ion transport, reminiscent of sensory rhodopsins, while Leptosphaeria rhodopsin has a fast bacteriorhodopsin-like photocycle and pumps protons light-dependently. Such a dramatic difference is surprising considering the very high degree of sequence homology of the two proteins. In this paper, we investigate whether the chemical structure of a cytoplasmic carboxylic acid, the homologue of Asp-96 of bacteriorhodopsin serving as a proton donor for the retinal Schiff base, can define the photochemical properties of fungal rhodopsins. We studied mutants of Leptosphaeria rhodopsin in which this aspartic acid was replaced with Glu or Asn using spectroscopy in the infrared and visible ranges. We show that Glu at this position is inefficient as a proton donor similar to a nonprotonatable Asn. Moreover, this replacement induces long-range structural perturbations of the retinal environment, as evidenced by changes in the vibrational bands of retinal (especially, hydrogen-out-of-plane modes) and neighboring aspartic acids and water molecules. The conformational coupling of the mutation site to the retinal may be mediated by helical rearrangements as suggested by the changes in amide and proline vibrational bands. We conclude that the difference in the photochemical behavior of fungal rhodopsins from Leptosphaeria and Neurospora may be ascribed, to some extent, to the replacement of the cytoplasmic proton donor Asp with Glu.
Bibliography:This work was supported in part by grants from Japanese Ministry of Education, Culture, Sports, Science, and Technology to H.K. and by the NSERC, PREA, and Research Corporation grants to L.S.B. L.S.B. acknowledges JSPS for the Invitation Fellowship, which was instrumental in the writing of this paper.
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content type line 23
ISSN:0006-2960
1520-4995
DOI:10.1021/bi061864l