PDBsum entry 1c09

Electron transport

PDB id

1c09

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Contents

			Protein chains

					53 a.a. *

			Metals

					_FE ×3

			Waters ×158

* Residue conservation analysis

PDB id:

1c09

Links

Name:

Electron transport

Title:

Rubredoxin v44a cp

Structure:

Rubredoxin. Chain: a, b, c. Synonym: rd. Mutation: yes

Source:

Clostridium pasteurianum. Organism_taxid: 1501

Resolution:

1.60Å

R-factor:

0.176

Authors:

T.Min,B.Beard,C.Kang

Key ref:

M.K.Eidsness et al. (1999). Modulation of the redox potential of the [Fe(SCys)(4)] site in rubredoxin by the orientation of a peptide dipole. Biochemistry, 38, 14803-14809. PubMed id: 10555962 DOI: 10.1021/bi991661f

Date:

15-Jul-99

Release date:

21-Feb-01

PROCHECK

	Headers

	References

Protein chains

P00268 (RUBR_CLOPA) - Rubredoxin from Clostridium pasteurianum

Seq: Struc:					54 a.a. 53 a.a.*

Key:

PfamA domain

Secondary structure

CATH domain

* PDB and UniProt seqs differ at 1 residue position (black cross)

DOI no: 10.1021/bi991661f	Biochemistry 38:14803-14809 (1999)
PubMed id: 10555962

Modulation of the redox potential of the [Fe(SCys)(4)] site in rubredoxin by the orientation of a peptide dipole.
M.K.Eidsness, A.E.Burden, K.A.Richie, D.M.Kurtz, R.A.Scott, E.T.Smith, T.Ichiye, B.Beard, T.Min, C.Kang.

ABSTRACT

Rubredoxins (Rds) may be separated into two classes based upon the correlation of their reduction potentials with the identity of residue 44; those with Ala44 have reduction potentials that are approximately 50 mV higher than those with Val44. The smaller side chain volume occupied by Ala44 relative to that occupied by Val44 has been proposed to explain the increase in the reduction potential, based upon changes in the Gly43-Ala44 peptide bond orientation and the distance to the [Fe(SCys)(4)] center in the Pyrococcus furiosus (Pf) Rd crystal structure compared to those of Gly43-Val44 in the Clostridium pasteurianum (Cp) Rd crystal structure. As an experimental test of this hypothesis, single-site Val44 <--> Ala44 exchange mutants, [V44A]Cp and [A44V]Pf Rds, have been cloned and expressed. Reduction potentials of these residue 44 variants and pertinent features of the X-ray crystal structure of [V44A]Cp Rd are reported. Relative to those of wild-type Cp and Pf Rds, the V44A mutation in Cp Rd results in an 86 mV increase in midpoint reduction potential and the [A44V] mutation in Pf Rd results in a 95 mV decrease in midpoint reduction potential, respectively. In the crystal structure of [V44A]Cp Rd, the peptide bond between residues 43 and 44 is approximately 0.3 A closer to the Fe center and the hydrogen bond distance between the residue 44 peptide nitrogen and the Cys42 gamma-sulfur decreases by 0.32 A compared to the analogous distances in the wild-type Cp Rd crystal structure. The results described herein support the prediction that the identity of residue 44 alone determines whether a Rd reduction potential of about -50 or 0 mV is observed.

Literature references that cite this PDB file's key reference

PubMed id

Reference

20635418

B.S.Perrin, and T.Ichiye (2010).
Fold versus sequence effects on the driving force for protein-mediated electron transfer.

Proteins, 78, 2798-2808.

20159152

Y.Luo, C.E.Ergenekan, J.T.Fischer, M.L.Tan, and T.Ichiye (2010).
The molecular determinants of the increased reduction potential of the rubredoxin domain of rubrerythrin relative to rubredoxin.

Biophys J, 98, 560-568.

19099403

G.Saab-Rincón, and B.Valderrama (2009).
Protein engineering of redox-active enzymes.

Antioxid Redox Signal, 11, 167-192.

19799419

I.J.Lin, B.Xia, D.S.King, T.E.Machonkin, W.M.Westler, and J.L.Markley (2009).
Hyperfine-Shifted (13)C and (15)N NMR Signals from Clostridium pasteurianum Rubredoxin: Extensive Assignments and Quantum Chemical Verification.

J Am Chem Soc, 131, 15555-15563.

18250895

C.Dennison (2008).
The role of ligand-containing loops at copper sites in proteins.

Nat Prod Rep, 25, 15-24.

18446387

F.Bonomi, S.Iametti, P.Ferranti, D.M.Kurtz, A.Morleo, and E.M.Ragg (2008).
"Iron priming" guides folding of denatured aporubredoxins.

J Biol Inorg Chem, 13, 981-991.

18053245

D.M.Lemaster, J.S.Anderson, L.Wang, Y.Guo, H.Li, and G.Hernandez (2007).
NMR and X-ray analysis of structural additivity in metal binding site-swapped hybrids of rubredoxin.

BMC Struct Biol, 7, 81.

PDB codes:

2pve 2pvx

17576605

G.Battistuzzi, M.Bellei, L.Casella, C.A.Bortolotti, R.Roncone, E.Monzani, and M.Sola (2007).
Redox reactivity of the heme Fe3+/Fe 2+ couple in native myoglobins and mutants with peroxidase-like activity.

J Biol Inorg Chem, 12, 951-958.

16362979

M.L.Tan, C.Kang, and T.Ichiye (2006).
The role of backbone stability near Ala44 in the high reduction potential class of rubredoxins.

Proteins, 62, 708-714.

16084387

D.M.LeMaster, and G.Hernández (2005).
Additivity in both thermodynamic stability and thermal transition temperature for rubredoxin chimeras via hybrid native partitioning.

Structure, 13, 1153-1163.

16133205

G.Battistuzzi, M.Bellei, M.Borsari, G.Di Rocco, A.Ranieri, and M.Sola (2005).
Axial ligation and polypeptide matrix effects on the reduction potential of heme proteins probed on their cyanide adducts.

J Biol Inorg Chem, 10, 643-651.

15983423

H.Bönisch, C.L.Schmidt, P.Bianco, and R.Ladenstein (2005).
Ultrahigh-resolution study on Pyrococcus abyssi rubredoxin. I. 0.69 A X-ray structure of mutant W4L/R5S.

Acta Crystallogr D Biol Crystallogr, 61, 990.

PDB codes:

1yk4 1yk5

16199518

I.J.Lin, E.B.Gebel, T.E.Machonkin, W.M.Westler, and J.L.Markley (2005).
Changes in hydrogen-bond strengths explain reduction potentials in 10 rubredoxin variants.

Proc Natl Acad Sci U S A, 102, 14581-14586.

16100392

J.B.Vicente, and M.Teixeira (2005).
Redox and spectroscopic properties of the Escherichia coli nitric oxide-detoxifying system involving flavorubredoxin and its NADH-oxidizing redox partner.

J Biol Chem, 280, 34599-34608.

15895271

R.B.Iyer, R.Silaghi-Dumitrescu, D.M.Kurtz, and W.N.Lanzilotta (2005).
High-resolution crystal structures of Desulfovibrio vulgaris (Hildenborough) nigerythrin: facile, redox-dependent iron movement, domain interface variability, and peroxidase activity in the rubrerythrins.

J Biol Inorg Chem, 10, 407-416.

PDB codes:

1yux 1yuz 1yv1

15382226

I.Y.Park, M.K.Eidsness, I.J.Lin, E.B.Gebel, B.Youn, J.L.Harley, T.E.Machonkin, R.O.Frederick, J.L.Markley, E.T.Smith, T.Ichiye, and C.Kang (2004).
Crystallographic studies of V44 mutants of Clostridium pasteurianum rubredoxin: effects of side-chain size on reduction potential.

Proteins, 57, 618-625.

PDB codes:

1t9o 1t9p 1t9q

14747706

M.Maher, M.Cross, M.C.Wilce, J.M.Guss, and A.G.Wedd (2004).
Metal-substituted derivatives of the rubredoxin from Clostridium pasteurianum.

Acta Crystallogr D Biol Crystallogr, 60, 298-303.

PDB codes:

1r0f 1r0g 1r0h 1r0i 1r0j

14581187

C.E.Ergenekan, D.Thomas, J.T.Fischer, M.L.Tan, M.K.Eidsness, C.Kang, and T.Ichiye (2003).
Prediction of reduction potential changes in rubredoxin: a molecular mechanics approach.

Biophys J, 85, 2818-2829.

12655046

D.T.Logan, E.Mulliez, K.M.Larsson, S.Bodevin, M.Atta, P.E.Garnaud, B.M.Sjoberg, and M.Fontecave (2003).
A metal-binding site in the catalytic subunit of anaerobic ribonucleotide reductase.

Proc Natl Acad Sci U S A, 100, 3826-3831.

PDB code:

1hk8

12524306

I.Bertini, C.Luchinat, K.Nerinovski, G.Parigi, M.Cross, Z.Xiao, and A.G.Wedd (2003).
Application of NMRD to hydration of rubredoxin and a variant containing a (Cys-S)3FeIII(OH) site.

Biophys J, 84, 545-551.

12900405

J.P.Emerson, E.D.Coulter, R.S.Phillips, and D.M.Kurtz (2003).
Kinetics of the superoxide reductase catalytic cycle.

J Biol Chem, 278, 39662-39668.

14622009

Z.M.Beharry, D.M.Eby, E.D.Coulter, R.Viswanathan, E.L.Neidle, R.S.Phillips, and D.M.Kurtz (2003).
Histidine ligand protonation and redox potential in the rieske dioxygenases: role of a conserved aspartate in anthranilate 1,2-dioxygenase.

Biochemistry, 42, 13625-13636.

11914373

G.Shen, J.Zhao, S.K.Reimer, M.L.Antonkine, Q.Cai, S.M.Weiland, J.H.Golbeck, and D.A.Bryant (2002).
Assembly of photosystem I. I. Inactivation of the rubA gene encoding a membrane-associated rubredoxin in the cyanobacterium Synechococcus sp. PCC 7002 causes a loss of photosystem I activity.

J Biol Chem, 277, 20343-20354.

11872724

J.B.van Beilen, M.Neuenschwander, T.H.Smits, C.Roth, S.B.Balada, and B.Witholt (2002).
Rubredoxins involved in alkane oxidation.

J Bacteriol, 184, 1722-1732.

11875515

K.Chen, C.A.Bonagura, G.J.Tilley, J.P.McEvoy, Y.S.Jung, F.A.Armstrong, C.D.Stout, and B.K.Burgess (2002).
Crystal structures of ferredoxin variants exhibiting large changes in [Fe-S] reduction potential.

Nat Struct Biol, 9, 188-192.

PDB codes:

1f5b 1f5c

11704670

K.Chen, Y.S.Jung, C.A.Bonagura, G.J.Tilley, G.S.Prasad, V.Sridhar, F.A.Armstrong, C.D.Stout, and B.K.Burgess (2002).
Azotobacter vinelandii ferredoxin I: a sequence and structure comparison approach to alteration of [4Fe-4S]2+/+ reduction potential.

J Biol Chem, 277, 5603-5610.

PDB codes:

1g3o 1g6b 1gao

11463610

B.W.Beck, Q.Xie, and T.Ichiye (2001).
Sequence determination of reduction potentials by cysteinyl hydrogen bonds and peptide pipoles in [4Fe-4S] ferredoxins.

Biophys J, 81, 601-613.

11115635

G.Renger (2001).
Photosynthetic water oxidation to molecular oxygen: apparatus and mechanism.

Biochim Biophys Acta, 1503, 210-228.

11454214

P.N.da Costa, C.V.Romão, J.LeGall, A.V.Xavier, E.Melo, M.Teixeira, and L.M.Saraiva (2001).
The genetic organization of Desulfovibrio desulphuricans ATCC 27774 bacterioferritin and rubredoxin-2 genes: involvement of rubredoxin in iron metabolism.

Mol Microbiol, 41, 217-227.

11170381

P.Strop, P.M.Takahara, H.Chiu, H.C.Angove, B.K.Burgess, and D.C.Rees (2001).
Crystal structure of the all-ferrous [4Fe-4S]0 form of the nitrogenase iron protein from Azotobacter vinelandii.

Biochemistry, 40, 651-656.

PDB codes:

1g1m 1g5p

11344329

T.Min, C.E.Ergenekan, M.K.Eidsness, T.Ichiye, and C.Kang (2001).
Leucine 41 is a gate for water entry in the reduction of Clostridium pasteurianum rubredoxin.

Protein Sci, 10, 613-621.

PDB codes:

1fhh 1fhm

11050226

A.Lombardi, D.Marasco, O.Maglio, L.Di Costanzo, F.Nastri, and V.Pavone (2000).
Miniaturized metalloproteins: application to iron-sulfur proteins.

Proc Natl Acad Sci U S A, 97, 11922-11927.

11188691

C.L.Colbert, M.M.Couture, L.D.Eltis, and J.T.Bolin (2000).
A cluster exposed: structure of the Rieske ferredoxin from biphenyl dioxygenase and the redox properties of Rieske Fe-S proteins.

Structure, 8, 1267-1278.

PDB code:

1fqt

11123953

C.M.Gomes, J.B.Vicente, A.Wasserfallen, and M.Teixeira (2000).
Spectroscopic studies and characterization of a novel electron-transfer chain from Escherichia coli involving a flavorubredoxin and its flavoprotein reductase partner.

Biochemistry, 39, 16230-16237.

10975569

K.Schweimer, S.Hoffmann, J.Wastl, U.G.Maier, P.Rösch, and H.Sticht (2000).
Solution structure of a zinc substituted eukaryotic rubredoxin from the cryptomonad alga Guillardia theta.

Protein Sci, 9, 1474-1486.

PDB codes:

1dx8 1h7v

The most recent references are shown first. Citation data come partly from CiteXplore and partly from an automated harvesting procedure. Note that this is likely to be only a partial list as not all journals are covered by either method. However, we are continually building up the citation data so more and more references will be included with time. Where a reference describes a PDB structure, the PDB codes are shown on the right.