Protected Sulfur Transfer Reactions by the <i>Escherichia coli</i> Suf System

Selbach, Bruna Pelegrim; Pradhan, Pradyumna K; Santos, Patricia C. Dos

doi:10.1021/bi4001479

Cited by 44 publications

(71 citation statements)

References 24 publications

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“…However, the structure of the E. coli SufS apo -SufE apo complex and potential conformational changes that result from their interaction are not defined. SufE binding increases the SufS desulfurase activity, at least in part, by acting as a co-substrate for the ping-pong reaction pathway that depends on SufE Cys-51 (9,11). In this study, we used HDX-MS, HDX deuterium trapping, and biochemical assays to better define the role protein dynamics plays in possible SufE allosteric activation of SufS catalytic activity.…”

Section: Discussionmentioning

confidence: 99%

“…It is also known that in the absence of a further sulfur acceptor (e.g. SufB or a thiol reductant), Cys-51 of SufE can accept multiple sulfur groups, thereby forming a polymeric sulfur species (8,11). This indicates that both apo and persulfurated/polysulfurated SufE can bind to SufS, presumably with protrusion of the Cys-51 side chain into the active site cavity, as was observed in the co-structure of CsdA-CsdE in which the CsdE Cys-61 thiolate is exposed and oriented toward Cys-358 of CsdA (31).…”

Section: Discussionmentioning

confidence: 99%

“…sulfide intermediate form of SufS (SufS per ) stimulates SufS desulfurase activity by providing an acceptor for the persulfide species via direct sulfur transfer (9,11,18). Thus, SufS could have a different conformational response to SufE that is dependent on the SufS catalytic intermediate state.…”

Section: Deuterium Trapping With the Sufs Persulfide Intermediatementioning

confidence: 99%

“…The monomeric 15.8-kDa SufE co-substrate protein interacts with the SufS dimer to stimulate cysteine desulfurase activity and accepts sulfane sulfur through a persulfide transfer reaction (8,9). This sulfur transfer reaction, which proceeds via a pingpong mechanism, may be important for limiting sulfide release under oxidative stress conditions (10,11). SufE transfers the persulfide to SufB of the SufBC 2 D complex, which is a scaffold complex that assembles [4Fe-4S] clusters (12)(13)(14).…”

mentioning

confidence: 99%

“…In the presence of SufE, SufS cysteine desulfurase activity is increased by an order of magnitude (8,9). The invariant Cys-51 of SufE acts as a co-substrate for SufS and accepts the sulfur from Cys-364 of SufS, thereby enhancing the catalytic rate (9,11,18). It is also possible that interaction with SufE may elicit changes in structural dynamics within the active site that facilitate the desulfuration reaction (5).…”

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confidence: 99%

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Escherichia coli SufE Sulfur Transfer Protein Modulates the SufS Cysteine Desulfurase through Allosteric Conformational Dynamics

Singh

Dai

Outten

et al. 2013

Journal of Biological Chemistry

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Background: SufS cysteine desulfurase mobilizes sulfur for stress-responsive iron-sulfur cluster biogenesis in bacteria. Results: Interaction with the sulfur transfer protein SufE triggers conformational changes in the SufS active site. Conclusion: SufE participates in allosteric regulation of SufS activity in addition to being a sulfur acceptor. Significance: New insight into sulfur mobilization and transfer during iron-sulfur cluster metallocofactor assembly is provided.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Deuterium Trapping With the Sufs Persulfide Intermediatementioning

confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

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Escherichia coli SufE Sulfur Transfer Protein Modulates the SufS Cysteine Desulfurase through Allosteric Conformational Dynamics

Singh

Dai

Outten

et al. 2013

Journal of Biological Chemistry

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FeS Cluster Assembly: NIF System in Nitrogen‐Fixing Bacteria

Santos

Dean

2017

Encyclopedia of Inorganic and Bioinorganic Chemistry

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Biological nitrogen fixation is restricted to a specialized group of microorganisms, called diazotrophs, and is catalyzed by the complex metalloenzyme nitrogenase. All diazotrophs recognized so far produce a molybdenum‐containing nitrogenase. However, some diazotrophs also produce paralogous nitrogenases that utilize a transition metal other than Mo as a constituent of the active site cofactor called FeMo‐cofactor. Early genetic studies established that proteins required to produce, activate, and sustain nitrogenase are not limited to the catalytic components but also include other proteins involved in the assembly of nitrogenase‐associated metal‐containing cofactors, protein folding, electron transfer, and regulation. The number of genes associated with nitrogen fixation varies among different species, and the involvement of accessory proteins depends on the metabolic and environmental conditions encountered during growth. To date, nearly all nitrogen‐fixing species having sequenced genomes contain a minimum of six genes dedicated to nitrogen fixation. These include genes encoding the nitrogenase catalytic components, nifH , nifD , nifK , and three genes, nifE , nifN , and nifB , whose products are required for FeMo‐cofactor formation. In some instances, genes associated with nitrogen fixation encode proteins that mirror other related cellular process. For example, the products of nifU and nifS are specifically involved in the assembly of [Fe–S] clusters dedicated to nitrogenase activation, whereas the structurally and functionally related housekeeping genes iscU and iscS are involved in [Fe–S] cluster formation that supports other Fe–S proteins. The best‐studied diazotrophic organism is the strict aerobic microbe Azotobacter vinelandii . This organism is capable of producing three genetically distinct, but mechanistically similar, nitrogenases: Mo‐, V‐, and Fe‐only‐dependent enzymes. Under conditions of diazotrophy, A . vinelandii specifically elevates the expression of more than 60 genes. Among those, NifU and NifS are known to affect the synthesis and accumulation of active nitrogenase catalytic components in all three systems. In this chapter, we describe the initial assembly of [Fe–S] clusters necessary for the formation of both simple and complex [Fe–S] clusters associated with nitrogen fixation. This minimal toolkit for [Fe–S] cluster assembly includes a cysteine desulfurase, encoded by nifS , and an [Fe–S] cluster assembly scaffold, encoded by nifU . Studies on the nitrogenase specific system have also indicated that electron transfer reactions are required for effective [Fe–S] cluster formation and that preformed [Fe–S] clusters are likely trafficked to client proteins by specific carrier proteins. All of these features have provided a framework for studies on the general process of [Fe–S] cluster assembly that appears to be conserved throughout nature.

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FeSCluster Assembly:SUFSystem in Bacteria, Plastids and Archaea

Dong

Witcher

Outten

et al. 2017

Encyclopedia of Inorganic and Bioinorganic Chemistry

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Iron–sulfur (Fe–S) clusters are essential cofactors in biology due to their use in critical pathways such as nitrogen fixation, photosynthesis, and respiration. Fe–S cluster biogenesis requires complex systems to mobilize iron and sulfide, assemble the nascent cluster, and target Fe–S clusters to downstream target proteins. All of these steps must be coordinated to protect Fe–S cluster biogenesis intermediates from reactive oxygen species and other stressors. Multiple Fe–S cluster biogenesis pathways exist in different organisms and organelles. The Suf ( su lfur f ormation) pathway is phylogenetically the most ancient of the cluster biogenesis systems and is distributed across all domains of life. It can be found as the primary Fe–S cluster biogenesis pathway or as an auxiliary pathway adapted to maintain Fe–S cluster metabolism under stress conditions. Here we describe the biochemical, genetic, and physiological characterization of the Suf system, in all of its iterations.

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Protected Sulfur Transfer Reactions by the Escherichia coli Suf System

Cited by 44 publications

References 24 publications

Escherichia coli SufE Sulfur Transfer Protein Modulates the SufS Cysteine Desulfurase through Allosteric Conformational Dynamics

Escherichia coli SufE Sulfur Transfer Protein Modulates the SufS Cysteine Desulfurase through Allosteric Conformational Dynamics

FeS Cluster Assembly: NIF System in Nitrogen‐Fixing Bacteria

FeSCluster Assembly:SUFSystem in Bacteria, Plastids and Archaea

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