TCDB is operated by the Saier Lab Bioinformatics Group
« See all members of the family


3.D.4.5.1
Quinol oxidase (CyoABCD). This cytochrome bo3 ubiquinol oxidase is a transmembrane protein of 663 aas and 14 or 15 TMSs, which oxidizes ubiquinone and reduces oxygen, while pumping protons (Marušič et al. 2020). The cytochrome bo3 complex is the component of the aerobic respiratory chain of E. coli that predominates when cells are grown under high aeration conditions. It has proton pumping activity, pumping 2 protons/electron. Protons are probably pumped via D- and K-channels found in the cyoB subunit (Abramson et al. 2000). Two independent structures of the proton-pumping, respiratory cytochrome bo 3 ubiquinol oxidase (cytbo3) have been determined by cryo-EM in styrene-maleic acid (SMA) copolymer nanodiscs and in membrane scaffold protein (MSP) nanodiscs to 2.55- and 2.19-Å resolution, respectively (Li et al. 2021). The structures include the metal redox centers (heme b, heme o3 , and CuB), the redox-active cross-linked histidine-tyrosine cofactor, and the internal water molecules in the proton-conducting D channel. Each structure also contains one equivalent of ubiquinone-8 (UQ8) in the substrate binding site as well as several phospholipid molecules. The isoprene side chain of UQ8 is clamped within a hydrophobic groove in subunit I by TMS0, which is only present in quinol oxidases and not in the closely related cytochrome c oxidases. Both structures show carbonyl O1 of the UQ8 headgroup hydrogen bonded to D75(I) and R71(I). In both structures, residue H98(I) occupies two conformations. In conformation 1, H98(I) forms a hydrogen bond with carbonyl O4 of the UQ8 headgroup, but in conformation 2, the imidazole side chain of H98(I) has flipped to form a hydrogen bond with E14(I) at the N-terminal end of TMS0. The authors proposed that H98(I) dynamics facilitate proton transfer from ubiquinol to the periplasmic aqueous phase during oxidation of the substrate. Computational studies show that TMS0 creates a channel, allowing access of water to the ubiquinol headgroup and to H98(I) (Li et al. 2021). Jose et al. 2021 investigated the key PM intermediate, which forms after O–O bond cleavage and precedes proton pumping, using magnetic circular dichroism spectroscopy. The authors observed features demonstrating that PM is a three-spin system,  consistent with a consensus model including an iron(IV)-oxo species, a copper(II) ion, and a tyrosyl radical. These results provide validation of the O–O cleavage mechanism and open the door to understanding the proton pumping step (Jose et al. 2021).  

Accession Number:P0ABJ1
Protein Name:Ubiquinol oxidase subunit 2
Length:315
Molecular Weight:34911.00
Species:Escherichia coli (strain K12) [83333]
Number of TMSs:3
Location1 / Topology2 / Orientation3: Cell inner membrane1 / Multi-pass membrane protein2
Substrate hydron

Cross database links:

DIP: DIP-47942N DIP-47942N
Entrez Gene ID: 945080   
Pfam: PF00116    PF06481   
KEGG: ecj:JW0422    eco:b0432   

Gene Ontology

GO:0009319 C:cytochrome o ubiquinol oxidase complex
GO:0005887 C:integral to plasma membrane
GO:0070469 C:respiratory chain
GO:0005507 F:copper ion binding
GO:0009486 F:cytochrome bo3 ubiquinol oxidase activity
GO:0008827 F:cytochrome o ubiquinol oxidase activity
GO:0004129 F:cytochrome-c oxidase activity
GO:0009055 F:electron carrier activity
GO:0020037 F:heme binding
GO:0015453 F:oxidoreduction-driven active transmembrane transporter activity
GO:0048039 F:ubiquinone binding
GO:0019646 P:aerobic electron transport chain

References (12)

[1] “The sequence of the cyo operon indicates substantial structural similarities between the cytochrome o ubiquinol oxidase of Escherichia coli and the aa3-type family of cytochrome c oxidases.”  Chepuri V.et.al.   2162835
[2] “The complete genome sequence of Escherichia coli K-12.”  Blattner F.R.et.al.   9278503
[3] “Highly accurate genome sequences of Escherichia coli K-12 strains MG1655 and W3110.”  Hayashi K.et.al.   16738553
[4] “Transcriptional regulation of the cytochrome b562-o complex in Escherichia coli. Gene expression and molecular characterization of the promoter.”  Minagawa J.et.al.   2162837
[5] “AmpG, a signal transducer in chromosomal beta-lactamase induction.”  Lindquist S.et.al.   8231804
[6] “Modified, large-scale purification of the cytochrome o complex (bo-type oxidase) of Escherichia coli yields a two heme/one copper terminal oxidase with high specific activity.”  Minghetti K.C.et.al.   1322173
[7] “The use of gene fusions to determine the topology of all of the subunits of the cytochrome o terminal oxidase complex of Escherichia coli.”  Chepuri V.et.al.   2165491
[8] “Recent studies of the cytochrome o terminal oxidase complex of Escherichia coli.”  Chepuri V.et.al.   2168206
[9] “Protein complexes of the Escherichia coli cell envelope.”  Stenberg F.et.al.   16079137
[10] “Global topology analysis of the Escherichia coli inner membrane proteome.”  Daley D.O.et.al.   15919996
[11] “Crystal structure of the membrane-exposed domain from a respiratory quinol oxidase complex with an engineered dinuclear copper center.”  Wilmanns M.et.al.   8618822
[12] “The structure of the ubiquinol oxidase from Escherichia coli and its ubiquinone binding site.”  Abramson J.et.al.   11017202
Structure:
1CYW   1CYX   1FFT     

External Searches:

Analyze:

Predict TMSs (Predict number of transmembrane segments)
Window Size: Angle:  
FASTA formatted sequence
1:	MRLRKYNKSL GWLSLFAGTV LLSGCNSALL DPKGQIGLEQ RSLILTAFGL MLIVVIPAIL 
61:	MAVGFAWKYR ASNKDAKYSP NWSHSNKVEA VVWTVPILII IFLAVLTWKT THALEPSKPL 
121:	AHDEKPITIE VVSMDWKWFF IYPEQGIATV NEIAFPANTP VYFKVTSNSV MNSFFIPRLG 
181:	SQIYAMAGMQ TRLHLIANEP GTYDGISASY SGPGFSGMKF KAIATPDRAA FDQWVAKAKQ 
241:	SPNTMSDMAA FEKLAAPSEY NQVEYFSNVK PDLFADVINK FMAHGKSMDM TQPEGEHSAH 
301:	EGMEGMDMSH AESAH