The solution structure of parsley [2Fe‐2S]ferredoxin

Im, Sang Choul; Liu, G; Luchinat, Claudio; Sykes, A. Geoffrey; Bertini, Ivano

doi:10.1046/j.1432-1327.1998.2580465.x

Cited by 31 publications

(25 citation statements)

References 47 publications

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“…Furthermore, the experimental rate k on hop ϭ 1294 s Ϫ1 was measured at a pH of 8.34. At a physiologically more relevant acidic pH (69,70), the experimental rate for PT2 is smaller (k off hop ϭ 36 Ϯ 5 s Ϫ1 at pH 5.0 (2)), which, according to transition state theory, corresponds to a barrier increase by ⌬G PT2 ‡ ϭ 1.4 kcal/mol compared with pH 8.34. In the simulations for PT2, the carboxyl group of Asp 15 is deprotonated, which covers the situation down to a pH of Ϸ 4.1 (the pK a of Asp lies at 4.1 (71)).…”

Section: Discussionmentioning

confidence: 99%

Water-assisted Proton Transfer in Ferredoxin I

Lütz

Tubert‐Brohman²,

Yang

et al. 2011

Journal of Biological Chemistry

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The role of water molecules in assisting proton transfer (PT) is investigated for the proton-pumping protein ferredoxin I (FdI) from Azotobacter vinelandii. , a larger barrier than for the forward reaction is correctly predicted, but it is quantitatively overestimated (23.1 kcal/mol from simulations versus 14.1 from experiment). Possible reasons for this discrepancy are discussed. Compared with the water-assisted process (⌬E ≈ 10 kcal/mol), water-unassisted proton transfer yields a considerably higher barrier of ⌬E ≈ 35 kcal/mol.

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Section: Discussionmentioning

confidence: 99%

Water-assisted Proton Transfer in Ferredoxin I

Lütz

Tubert‐Brohman²,

Yang

et al. 2011

Journal of Biological Chemistry

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“…47,48 2Fe-2S ferredoxins (also referred to as β-grasp ferredoxins) are electron transporters in photosynthesis and nitrogen fixation. 49,50 TGS domain is named after three proteins [ThrRS, guanosine 5′-triphosphatase (GTPase), and SpoT] in which it is found, 51 and the TGS-like superfamily is represented by the N1 domain of the threonyl-tRNA synthetase 52 that may participate in the proofreading activity of this enzyme. 53 CAD and PB1 domains mediate protein complex formation through heterodimerization.…”

Section: High-scoring Pairs Between Scop Classes Folds or Superfamimentioning

confidence: 99%

Discrimination between Distant Homologs and Structural Analogs: Lessons from Manually Constructed, Reliable Data Sets

Cheng

Kim

Grishin

2008

Journal of Molecular Biology

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A natural way to study protein sequence, structure, and function is to put them in the context of evolution. Homologs inherit similarities from their common ancestor, while analogs converge to similar structures due to a limited number of energetically favorable ways to pack secondary structural elements. Using novel strategies, we previously assembled two reliable databases of homologs and analogs. In this study, we compare these two data sets and develop a support vector machine (SVM)-based classifier to discriminate between homologs and analogs. The classifier uses a number of well-known similarity scores. We observe that although both structure scores and sequence scores contribute to SVM performance, profile sequence scores computed based on structural alignments are the best discriminators between remote homologs and structural analogs. We apply our classifier to a representative set from the expert-constructed database, Structural Classification of Proteins (SCOP). The SVM classifier recovers 76% of the remote homologs defined as domains in the same SCOP superfamily but from different families. More importantly, we also detect and discuss interesting homologous relationships between SCOP domains from different superfamilies, folds, and even classes.

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“…As a consequence, the amide resonances of residues C12–F18 and R52–I62 are missing in the HSQC spectrum. In order to circumvent this difficulty, an accepted approach is to model the missing part based on structural homology (Lelong et al 1995; Baumann et al 1996; Im et al 1998; Mo et al 1999; Pochapsky et al 1999; Müller et al 2002). The backbone dihedral angle constraints from the X‐ray structure of the thioredoxin from A. aeolicus (PDB code 1F37) were selected as a template to model the residues V11–A22 and D49–V65 of HndAc (Fig.…”

Section: Methodsmentioning

confidence: 99%

Solution structure of HndAc: A thioredoxin‐like domain involved in the NADP‐reducing hydrogenase complex

Nouailler¹,

Morelli²,

Bornet³

et al. 2006

Protein Science

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The NADP-reducing hydrogenase complex from Desulfovibrio fructosovorans is a heterotetramer encoded by the hndABCD operon. Sequence analysis indicates that the HndC subunit (52 kDa) corresponds to the NADP-reducing unit, and the HndD subunit (63.5 kDa) is homologous to Clostridium pasteurianum hydrogenase. The role of HndA and HndB subunits (18.8 kDa and 13.8 kDa, respectively) in the complex remains unknown. The HndA subunit belongs to the [2Fe-2S] ferredoxin family typified by C. pasteurianum ferredoxin. HndA is organized into two independent structural domains, and we report in the present work the NMR structure of its C-terminal domain, HndAc. HndAc has a thioredoxin-like fold consisting in four b-strands and two relatively long helices. The [2Fe-2S] cluster is located near the surface of the protein and bound to four cysteine residues particularly well conserved in this class of proteins. Electron exchange between the HndD N-terminal [2Fe-2S] domain (HndD N ) and HndAc has been previously evidenced, and in the present studies we have mapped the binding site of the HndD N domain on HndAc. A structural analysis of HndB indicates that it is a FeS subunit with 41% similarity with HndAc and it contains a possible thioredoxin-like fold. Our data let us propose that HndAc and HndB can form a heterodimeric intermediate in the electron transfer between the hydrogenase (HndD) active site and the NADP reduction site in HndC. Keywords: NADP-reducing hydrogenase; thioredoxin-like domain; [2Fe-2S] ferredoxin; nuclear magnetic resonance (NMR); heteronuclear single quantum correlation (HSQC)Supplemental material: see www.proteinscience.org Hydrogenases are nonheme iron-sulfur proteins that catalyze the reversible oxidation of molecular hydrogen. They play a central role in the metabolism of sulfatereducing bacteria belonging to the genus Desulfovibrio that use hydrogen as an electron donor and sulfate as a terminal electron acceptor. The Desulfovibrio fructosovorans (Df) strain differs from all other Desulfovibrio species by its ability to use fructose as a carbon source allowing to gain ATP by substrate level phosphorylation. This organism harbors a well-characterized [NiFe]-hydrogenase (Hatchikian et al. 1990) and a partially purified [Fe]-hydrogenase (Casalot et al. 1998). Both are periplasmic enzymes. In addition, a cytoplasmic enzyme encoded by an operon made up of four genes named hndA, hndB, hndC, and hndD (Fig. 1A), has been detected in this organism (Malki et al. 1995). HndD presents strong identity with Clostridium pasteurianum hydrogenase (Cp Hyd I) and constitutes the monomeric [Fe]-hydrogenase subunit. Indeed, HndD contains three domains in addition to the H-cluster domain: starting from the N terminus, a [2Fe-2S] plant ferredoxin-like domain, a [4Fe-4S] domain, and a domain homologous to the

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The solution structure of parsley [2Fe‐2S]ferredoxin

Cited by 31 publications

References 47 publications

Water-assisted Proton Transfer in Ferredoxin I

Water-assisted Proton Transfer in Ferredoxin I

Discrimination between Distant Homologs and Structural Analogs: Lessons from Manually Constructed, Reliable Data Sets

Solution structure of HndAc: A thioredoxin‐like domain involved in the NADP‐reducing hydrogenase complex

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