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Electronic Journal of Biotechnology
Universidad Católica de Valparaíso
ISSN: 0717-3458
Vol. 6, Num. 1, 2003, pp. 16-28

Electronic Journal of Biotechnology, Vol. 6, No 1., April 15, 2003

A predicted structure of the cytochrome c oxidase from Burkholderia pseudomallei

Mohd. Firdaus Mohd. Raih1, Ahmad Tarmidi Sailan2, Zulkeflie Zamrod3, Mohd. Noor Embi4, Rahmah Mohamed*5

1Centre for Gene Analysis and Technology, School of BioSciences and Biotechnology, Faculty of Science and Technology, Universiti Kebangsaan Malaysia, 43600 UKM Bangi, Malaysia, Tel: +6 03 89267446, Fax: +6 03 89267972, E-mail: mfirr@cgat.ukm.my
2Centre for Gene Analysis and Technology, School of BioSciences and Biotechnology, Faculty of Science and Technology, Universiti Kebangsaan Malaysia, 43600 UKM Bangi, Malaysia, Tel: +6 03 89267446, Fax: +6 03 89267972, E-mail: tarmidi@medic.ukm.my
3Centre for Gene Analysis and Technology, School of BioSciences and Biotechnology, Faculty of Science and Technology, Universiti Kebangsaan Malaysia, 43600 UKM Bangi, Malaysia, Tel: +6 03 89267446, Fax: +6 03 89267972, E-mail: zza@pkrisc.cc.ukm.my
4Centre for Gene Analysis and Technology, School of BioSciences and Biotechnology, Faculty of Science and Technology, Universiti Kebangsaan Malaysia, 43600 UKM Bangi, Malaysia, Tel: +6 03 89267446, Fax: +6 03 89267972, E-mail: noormb@pkrisc.cc.ukm.my
5Centre for Gene Analysis and Technology, School of BioSciences and Biotechnology, Faculty of Science and Technology, Universiti Kebangsaan Malaysia, 43600 UKM Bangi, Malaysia, Tel: +6 03 89267446, Fax: +6 03 89267972, E-mail: ram@cgat.ukm.my http://cgat.ukm.my
* Corresponding author

Received June 26, 2002 / Accepted March 25, 2003

Financial support: This work was funded by the Intensification of Research in Priority Areas (IRPA) grants IRPA 01-02-02-001 and IRPA-TOPDOWN 09-02-02-T001 provided by the Ministry of Science, Technology and the Environment, Malaysia.

Code Number: ej03005

Abstract

Cytochrome c oxidase, the terminal enzyme of the respiratory chains of mitochondria and aerobic bacteria, catalyzes electron transfer from cytochrome c to molecular oxygen. The enzyme belongs to the haem-copper-containing oxidases superfamily. A recombinant plasmid carrying a 2.0 kb insert from a Burkholderia pseudomallei genomic library was subjected to automated DNA sequencing utilizing a primer walking strategy. Analysis of the 2002 bp insert revealed a 1536 bp open reading frame predicted to encode a putative cytochrome c oxidase. Further analysis using sequence alignments and tertiary structure analysis tools demonstrated that the hypothetical B. pseudomallei cytochrome c oxidase is similar to cytochrome c oxidases from other organisms such as Thermus thermophilus (36% protein sequence identity), Paracoccus denitrificans and bovine heart mitochondrial, the latter two which crystal structures available. The deduced 512 residue protein sequence includes the six canonical histidine residues involved in binding the low spin heme B and the binuclear center CuB/hemeA. The predicted tertiary structure of the hypothetical protein is consistent with previous models of electron transfer for cytochrome c oxidase.

Keywords: Burkholderia pseudomallei, cytochrome c oxidase, protein structure prediction, sequence alignments, structure-function extrapolation.

Acronyms:
Cox1: B. pseudomallei predicted cytochrome c oxidase subunit 1 protein;
Bp cox1: B. pseudomallei predicted cytocrome c oxidase subunit 1 gene;
SU: subunit;
ORF: open reading frame;
BLAST: Basic Local Alignment Search Tool;
TM: transmembrane;
TMH: transmembrane helices;
CVFF: consistent valence force field.

Article

Cytochrome c oxidase, a protein complex located in the inner membrane of mitochondria and many bacteria, is the terminal enzyme of most respiratory chains. It is a respiratory enzyme catalyzing the energy-conserving reduction of molecular oxygen to water. The system catalyzes the final electron transfer steps from cytochrome c to molecular oxygen, and is a member of the superfamily of heme-copper containing terminal oxidases. Some bacterial terminal oxidases use quinol as substrates (quinol oxidases). Due to the homology of their sequences, both types of enzymes belong to the superfamily of haem copper oxidases (Ferguson-Miller and Babcock, 1996; Michel et al. 1998). The cytochrome c oxidase from the soil bacterium Paracoccus denitrificans for instance, consists of the three core subunits - I, II, and III and a small non-conserved subunit IV of unknown function (Witt and Ludwig, 1997). Subunit (SU) I is the largest and best conserved subunit of cytochrome c oxidase. Protein SU I of most cytochrome c oxidase contains two heme A molecules (heme a and heme a3) and copper B (CuB). These enzymes receive electrons either from quinols or from cytochrome c to heme a3. CuB forms a binuclear active centre where dioxygen is reduced to water. Four protons are consumed in water formation per oxygen molecule. Electron transfer is coupled to proton translocation (up to four) across the membrane electrogenetically (‘pump’), resulting in a proton and charge gradient that is then employed by the F0F1-ATPase to synthesize ATP. Members of this family contain one low spin cytochrome and a bimetallic structure consisting of a high spin heme in close proximity to a copper ion. These metals reside in the large subunit of the complex, subunit I, where they are coordinated to at least six conserved histidine residues. The cytochrome c oxidase bind two additional copper ions in the CuA site to conserved histidine and cysteine residues of subunit II.

Burkholderia pseudomallei is the causative agent of melioidosis, a serious disease of humans and animals that occurs primarily in South East Asia, Northern Australia and other tropical areas (Dance, 2002). This pathogenic bacterium survives in diverse environmental conditions and secretes various extracellular products that have been implicated as factors involved in pathogenesis of this disease. In this paper, we summarize the identification of a cytochrome c oxidase gene in B. pseudomallei and its tertiary structure determination utilizing available protein structure prediction (comparative modeling) methods based on the predicted protein sequence. The postulated amino acid residues that play the major roles in oxygen reduction, proton and electron transfer pathways were used as reference points to gauge functional probability. The sequence we have identified and its predicted corresponding structure is the first functional annotation for this family of proteins in B. pseudomallei.

Materials and Methods

Genomic library preparation. A Burkholderia pseudomallei genomic DNA library was prepared in pSV-SPORT1 vector (Gibco, BRL) and transformed in Escherichia coli strain DH5a. After screening with a heterologous oligonucleotide probe, a recombinant plasmid containing a 20 kb EcoR1 insert was isolated. Plasmid preparations were carried out by standard procedures (Birnboim and Doly, 1979) and then subjected to automated DNA sequencing.

DNA sequencing. Automated DNA sequencing was carried out utilizing Taq DyeDeoxyTM Terminator Cycle Sequencing Kit, Amplitaq® DNA Polimerase (Perkin Elmer, USA), FS enzyme and electrophoresed via the ABI PRISM 377 Automated DNA sequencer. The insert was then subjected to a primer walking strategy initially utilizing universal primers USP6, UT7 (Gibco, BRL) and followed by four synthetic primer pairs.

The complete sequence of the ORF2 sequence has been deposited in the GenBank Database (http://www.ncbi.nlm.nih.gov/Genbank/) and was assigned the GenBank nucleotide accession number AF087002 (AAF13732 protein accession number). 

Gene prediction. Open reading frames were identified with the aid of DNAsis (Hitachi Software Engineering America Ltd.) and GeneMark ver. 2.0 programs (Lukashin and Borodovsky, 1998). Sequence database alignments and comparisons were done with the BLAST family of programs (blastx, blastp) against database specifications of non-redundant protein, SWISS-PROT and PDB which were available from the BLAST website at the National Center for Biotechnology Information webserver, (http://www.ncbi.nlm.nih.gov/blast/) (Altschul et al. 1997). Multiple sequence alignments were done using ClustalW 1.8 (Thompson et al. 1994). PROSIS was used to calculate the amino acid composition encoded by the ORFs and some predicted properties of the individual proteins.

Protein structure prediction. The B. pseudomallei Cox subunit I (AF087002) predicted protein sequence was submitted to several transmembrane prediction programs accessed via their web interfaces. The programs used were DAS (Cserzo et al. 1997; http://www.sbc.su.se/~miklos/DAS/), TOPPRED (Claros and von Heijne, 1994; http://bioweb.pasteur.fr/seqanal/interfaces/toppred.html), TMHMM (Krogh et al. 2001; http://www.cbs.dtu.dk/services/TMHMM-2.0/), Split (Juretic et al. 1999), MEMSAT (Jones et al. 1994; http://www.psipred.net) and SOSUI (Hirokawa et al. 1998; http://sosui.proteome.bio.tuat.ac.jp/cgi-bin/sosui.cgi?/sosui_submit.html). A survey of evaluated TM regions prediction program (Moller et al. 2001) was used as a reference to gauge accuracy and reliability of the TM prediction results.

The 512 residue amino acid sequence was submitted for further automated prediction of secondary structures and protein fold. The programs chosen were based on the results of CAFASP 2 (Fischer et al. 2001; http://www.cs.bgu.ac.il/~dfischer/CAFASP2/) for fully automated protein structure prediction. The following programs were used via their web browser interfaces: GenThreader (Jones, 1999; http://www.psipred.net), PHD (Rost  et al. 1994; http://cubic.bioc.columbia.edu/predictprotein/), bioinbgu (Fischer, 2000; http://www.cs.bgu.ac.il/~bioinbgu/) and 3D-PSSM (Kelley et al. 2000; http://www.sbg.bio.ic.ac.uk/~3dpssm/). These servers were accessed via a web directory interface of online protein structure prediction resources – SPORes: Structure Prediction with Online Resources website (http://cgat.ukm.my/spores/).

Structural topology was built from the secondary structure prediction data while template selection was done using the fold prediction data. The target sequence was then aligned to the template sequence using the Homology module of InsightII (MSI, ver. 98). Manual editing for optimal alignments were done where deemed necessary. The alignment was translated into tertiary structure using Modeller Release 6 (Sali and Blundell, 1993). The initial strain of the predicted structure was relieved by carrying out energy minimizations using Discover (MSI ver. 98) utilizing the CVFF force field. Short contacts were removed by manually rotating the side chains. Model evaluation was done using Procheck (Laskowski et al. 1993), Errat (Colovos and Yeates, 1993), What If (Vriend, 1990) and Verify3D (Luthy et al. 1992). Refinements of the structure and geometry optimizations, when necessary, were carried out using the Insight interface (MSI, ver. 98).

Results and Discussion

Sequence analysis

Complete sequencing of the 2.0 kb DNA insert from the recombinant clone showed that it contained a 1536 bp ORF designated Bp cox1 potentially encoding a subunit 1 cytochrome c oxidase termed Cox.

A thorough search of available sequence databases showed that the putative B. pseudomallei Cox (AF087002) sequence is homologous to other known cytochrome c oxidases with varying levels of sequence identity and appears to have structural features similar to the largest subunit of the heme/copper-requiring cytochrome c and quinol oxidases (Figure 1 and Figure 2). BLAST queries of the predicted B. pseudomallei Cox protein sequence yielded eight other sequences with E values lower than 10-50. All of these sequences were identified as being cytochrome c oxidases (6 sequences) or hypothetical cytochrome c oxidases (2 sequences) (Figure 1). Alignments of the predicted protein sequence against the PDB database also showed significant homology with the sequence of a solved crystal structure for cytochrome c oxidase (PDB identification = 1EHK) from Thermus thermophilus (Soulimane et al. 2000). Multiple sequence alignments on these sequences (P. denitrificans, T. thermophilus and bovine heart mitochondria aligned to the B. pseudomallei) showed several regions of high conservation despite some sequences being phylogenetically distant (Figure 1 and Figure 2). Several of these highly conserved regions were identified as crucial residues in other proposed models for electron transfer in cytochrome c oxidases.

The Thermus thermophilus sequence exhibited 36% identity to the B. pseudomallei AF087002 sequence. Figure 1 illustrates further the observed sequence conservation by showing the alignments of the amino acid sequences of the B. pseudomallei cytochrome c oxidase towards the other sequences chosen from the GenBank (non-redundant protein databases, SWISSPROT, PDB) BLAST searches. The B. pseudomallei subunit is shorter at both termini than the subunit from these cytochrome c oxidases, the degree of conservation however remains clear, as shown by the number residues that are identical across the sequences aligned. For clarity, the sequence alignment in Figure 2 shows only segments that include the six histidines present in every representative of these enzymes. The six histidine residues and other conserved amino acids are placed in a similar pattern along the putative membrane spanning hydrophobic segments.

Protein structure prediction

Multiple methods of transmembrane prediction were used to enable a consensus confirmation of predicted transmembrane helices via differing approaches (data not shown). The TM region search for B. pseudomallei Cox subunit I revealed 12 possible TM helices (Figure 2). The objective of this TM search step was to identify and map out regions of transmembrane helices to confirm our sequence database based hypothesis of the putative sequence being identified as a cytochrome c oxidase subunit I. Cythochrome c oxidases are known to have these transmembrane regions and the identification of these regions served as a confirmatory step in gauging the validity of the predicted structure. The observation from the transmembrane prediction step is consistent with the subunit I of most other haem copper oxidases and acts as confirmatory data for correctness of the protein fold generated by the Modeller program. The fold prediction methods used, proposed the crystal structure of a ba3-cytochrome c oxidase (PDB identification 1ehk) from Thermus thermophilus as a suitable template. The crystal structure for 1ehk  (Soulimane et al. 2000) was solved a relatively low resolution of 2.4Å, was however still selected as the template structure. The target sequence showed a sequence identity of 36% towards the template sequence (Figure 3). The 1ehk structure, has an unusual property for proteins in the oxidase superfamily as its subunit I contained a 13th TM helix instead of just the usual 12 TM segments.

The predicted structure was found to have an RMS fit of 3.1 Å to the template structure. The Ramachandran plot from the Procheck validation revealed five residues in the disallowed regions of the plot while 80.7% of the residues were in the most favoured regions of the plot and the remainder residues in the additional and generously allowed regions of the plot (Figure 3a). A check of the 1ehk template structure revealed two residues which violated the Ramachandran region. Validation by the Errat and Verify 3D programs showed that the predicted structure had a generally acceptable three dimensional profile (Figure 3a; Figure 3b and Table 2). Evaluation methods used generally agree on the correct threading of the backbone. Comparisons of the initial Errat and Verify-3D results with those conducted after refinement and subsequent geometry optimisations showed marked improvements (results not shown). Regions of bad geometry were found to be located mainly in regions with unaligned target-template sequences and structurally variable regions (Figure 1 and Figure 2).     

Despite the phylogenetically distant relationship of the target-template sequences, the sequence structure alignment yielded sufficient information of structurally conserved regions to enable a functionally probable model to be generated. The predicted protein structure for B. pseudomallei Cox consists of 12 discernible TM helices (Figure 4). An initial assessment for functional plausibility of the predicted protein fold was gauged from comparisons of the primary protein structure to the predicted tertiary structure. The folding of the functionally crucial residues, such as the haem and Cu ligands, electron transfer pathway residues and proton pathway residues were found to fold closely together in 3D space even though some of these residues were distant to each other in the primary structure. Furthermore, the structural placement of these residues, were found to be similar when compared to the template crystal structure. The overall structure shows a clear hydrophobic core with pores A, B and C, described in Iwata et al. 1995, visible when viewed from the periplasmic side.

Electron transfer

The structure-based sequence alignment of subunit I (Figure 2) between other cytochrome c oxidase sequences, the P. denitrificans and bovine heart oxidases shows that functionally vital residues, such as heme and Cu ligands or the residues proposed for the electron transfer from CuA to the hemes, are conserved. In addition to these residues, a highly conserved motif (VLYTFYPP, located between Val84 and Pro91) can be discerned from the alignment especially to T. thermophilus (Figure 3 and Figure 4). His236 in B. pseudomallei cox1, was postulated to be one ligand for CuB comparable to His326 and His 291 in P. denitrificans and bovine heart mitochondrion, respectively. This residue might form an electron transfer pathway from CuA directly to CuB. The current understanding of the oxygen reduction mechanism at the binuclear centre requires the input of at least one of the electrons via CuB (Hill, 1994; Michel et al. 1998). The electron transfer from CuA via haem a/b to heme a3 at the binuclear centre is well established (Hill, 1994), and the corresponding residues (Arg401, Arg400 and Phe338) are conserved in the B. pseudomallei cox1 (Table 1 and Figure 5). We propose the above-described pathway via Tyr89, Trp183 and His236 as an additional electron transfer pathway that could be used for electrons that are provided from CuB to the catalytic oxygen intermediates.

Proton pathways

Two possible proton transfer pathways have been suggested based on the crystal structure of the P. denitrificans enzyme and in agreement with the results of site directed mutagenesis (Garcia-Horsman et al. 1995) i.e. K-pathway and D-pathway. The shorter K-pathway, leads to the binuclear centre via the highly conserved residues SU I-Thr 351 and SU I-Tyr280 located in the TMH VI and VIII and the hydroxyl group or the heme a3 hydroxyethylfarnesyl chain (Michel et al. 1998). Two residues were postulated to have similar functions in Bp CoxI i.e. Su I-Thr262 and Thy190 (Table 1). Nevertheless, none of the residues in Bp CoxI were found to have counterparts in the longer D-pathway as for Paracoccus sp.

Acknowledgments

Computational facilities and resources used were based at the Bioinformatics Laboratory of the National Biotechnology and Bioinformatics Network (NBBnet), National Biotechnology Directorate (BIOTEK), Ministry of Science, Technology and the Environment, Malaysia.

Appendix

Table 1. Functions and residue sequence position comparisons table for functionally important amino acid residues in subunits of the cytochrome c oxidase from P. denitrificans, bovine heart mitochondria and predicted protein sequence from B. pseudomallei.
-

Residue position

-   -  

Residue

P. denitrificans

Bovine heart mitochondria

T. thermophilus

B. pseudomallei

Heme ligands

a

a3

His

His

His

94

413

411

61

378

376

72

24

339

337

CuB ligands

-  

His*

His

His

276

325

326

240

290

291

233

282

283

186

235

236

Proton pathways

K-pathway

Thr

Tyr*

351

280

316

244

309 (Ser)

237

262

190

Electron transfer

CuA           heme a

Arg

Arg

473

474

438

439

450

451

400

401

heme         heme a3

Phe

412

377

385

338

*Tyrosine is covalently bound to a CuB histidine ligand.

Table 2. Overall quality of the predicted model as assessed by various methods.

Method

Template structure (1ehk)

Predicted structure

Recommended value for good structures

Prochecka

-0.37

-0.45

>-0.5

Erratb

96.7%

93.5%

>95%

Whatifc

-0.624

-1.199

>-1.0

a G factors average score as listed in the “Procheck Summary” output.
b Confidence limit.
c Quality control value.

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Supported by UNESCO / MIRCEN network 

© 2003 by Universidad Católica de Valparaíso -- Chile


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