Redesign of the Proton-Pumping Machinery of Cytochrome c Oxidase:  Proton Pumping Does Not Require Glu(I-286)

One of the putative proton-transfer pathways leading from solution toward the binuclear center in many cytochrome c oxidases is the D-pathway, so-called because it starts with a highly conserved aspartate [D(I-132)] residue. Another highly conserved amino acid residue in this pathway, glutamate(I-28...

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Published in:Biochemistry (Easton) 2000-12, Vol.39 (51), p.15847-15850
Main Authors: Aagaard, Anna, Gilderson, Gwen, Mills, Denise A, Ferguson-Miller, Shelagh, Brzezinski, Peter
Format: Article
Language:English
Subjects:
Catalysis
Electron Transport Complex IV - chemistry
Electron Transport Complex IV - genetics
Electron Transport Complex IV - metabolism
Glutamic Acid - chemistry
Glutamic Acid - genetics
Glutamic Acid - metabolism
Mitochondria - enzymology
Mutagenesis, Site-Directed
Proton Pumps - chemistry
Proton Pumps - genetics
Proton Pumps - metabolism
Recombinant Proteins - chemical synthesis
Recombinant Proteins - metabolism
Rhodobacter sphaeroides - enzymology
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Summary:One of the putative proton-transfer pathways leading from solution toward the binuclear center in many cytochrome c oxidases is the D-pathway, so-called because it starts with a highly conserved aspartate [D(I-132)] residue. Another highly conserved amino acid residue in this pathway, glutamate(I-286), has been indicated to play a central role in the proton-pumping machinery of mitochondrial-type enzymes, a role that requires a movement of the side chain between two distinct positions. In the present work we have relocated the glutamate to the opposite side of the proton-transfer pathway by constructing the double mutant EA(I-286)/IE(I-112). This places the side chain in about the same position in space as in the original enzyme, but does not allow for the same type of movement. The results show that the introduction of the second-site mutation, IE(I-112), in the EA(I-286) mutant enzyme results in an increase of the enzyme activity by a factor of >10. In addition, the double mutant enzyme pumps ∼0.4 proton per electron. This observation restricts the number of possible mechanisms for the operation of the redox-driven proton pump. The proton-pumping machinery evidently does require the presence of a protonatable/polar residue at a specific location in space, presumably to stabilize an intact water chain. However, this residue does not necessarily have to be at a strictly conserved location in the amino acid sequence. In addition, the results indicate that E(I-286) is not the “proton gate” of cytochrome c oxidase controlling the flow of pumped protons from one to the other side of the membrane.
ISSN:0006-2960
1520-4995
DOI:10.1021/bi0012641