Characterization of Quinolinate Synthases from Escherichia coli, Mycobacterium tuberculosis, and Pyrococcus horikoshii Indicates That [4Fe-4S] Clusters Are Common Cofactors throughout This Class of Enzymes

Saunders, Allison; Griffiths, Amy E.; Lee, Kyung Hoon; Cicchillo, Robert M.; Tu, Loretta; Stromberg, Jeffrey A.; Krebs, Carsten; Booker, Squire J.

doi:10.1021/bi801268f

Cited by 31 publications

(41 citation statements)

References 45 publications

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“…For example, bacteria can neo-synthesize quinolinic acid (Marinoni et al, 2008; Reichmann et al, 2015; Sakuraba et al, 2005; Saunders et al, 2008), and unique prokaryotic enzymes can degrade kynurenic acid (Taniuchi and Hayaishi, 1963). Bacterial neosynthesis of quinolinic acid begins with the condensation of iminoaspartate with dihydroxyacetone, and the latter compound also inhibits α-amino-β-carboxymuconate-ε-semialdehyde decarboxylase (ACMSD) (Garavaglia et al, 2009).…”

Section: The Gut-brain Axismentioning

confidence: 99%

The kynurenine pathway and the brain: Challenges, controversies and promises

2017

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Research on the neurobiology of the kynurenine pathway has suffered years of relative obscurity because tryptophan degradation, and its involvement in both physiology and major brain diseases, was viewed almost exclusively through the lens of the well-established metabolite serotonin. With increasing recognition that kynurenine and its metabolites can affect and even control a variety of classic neurotransmitter systems directly and indirectly, interest is expanding rapidly. Moreover, kynurenine pathway metabolism itself is modulated in conditions such as infection and stress, which are known to induce major changes in well-being and behaviour, so that kynurenines may be instrumental in the etiology of psychiatric and neurological disorders. It is therefore likely that the near future will not only witness the discovery of additional physiological and pathological roles for brain kynurenines, but also ever-increasing interest in drug development based on these roles. In particular, targeting the kynurenine pathway with new specific agents may make it possible to prevent disease by appropriate pharmacological or genetic manipulations. The following overview focuses on areas of kynurenine research which are either controversial, of major potential therapeutic interest, or just beginning to receive the degree of attention which will clarify their relevance to neurobiology and medicine. It also highlights technical issues so that investigators entering the field, and new research initiatives, are not misdirected by inappropriate experimental approaches or incorrect interpretations at this time of skyrocketing interest in the subject matter.

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Section: The Gut-brain Axismentioning

confidence: 99%

The kynurenine pathway and the brain: Challenges, controversies and promises

2017

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“…both catalyze a dehydration process and coordinate a Fe 4 S 4 cluster with only three cysteine protein ligands, which in NadA are organized in a CX86 -112CX 86-99C motif. [5][6][7] Consequently, it was suggested that the unique iron site of the NadA Fe 4 S 4 cluster should also be directly involved in dehydration steps, acting as a Lewis acid. Partial mechanistic information has been obtained from the two available crystal structures of NadA, 8 , 9 which correspond to the inactive apo form of the enzyme.…”

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confidence: 99%

The Crystal Structure of Fe₄S₄ Quinolinate Synthase Unravels an Enzymatic Dehydration Mechanism That Uses Tyrosine and a Hydrolase-Type Triad

et al. 2014

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Quinolinate synthase (NadA) is a Fe 4 S 4 cluster-containing dehydrating enzyme involved in the synthesis of quinolinic acid (QA), the universal precursor of the essential nicotinamide adenine dinucleotide (NAD) coenzyme. A previously determined apo NadA crystal structure revealed the binding of one substrate analog, providing partial mechanistic information. Here, we report on the holo X-ray structure of NadA. The presence of the Fe 4 S 4 cluster generates an internal tunnel and a cavity in which we have docked the last precursor to be dehydrated to form QA. We find that the only suitably placed residue to initiate this process is the conserved Tyr21. Furthermore, Tyr21 is close to a conserved Thr-His-Glu triad reminiscent of those found in proteases and other hydrolases. Our mutagenesis data show that all of these residues are essential for activity and strongly suggest that Tyr21 deprotonation, to form the reactive nucleophilic phenoxide anion, is mediated by the triad. NadA displays a dehydration mechanism significantly different from the one found in archetypical dehydratases such as aconitase, which use a serine residue deprotonated by an oxyanion hole. The X-ray structure of NadA will help us unveil its catalytic mechanism, the last step in the understanding of NAD biosynthesis.

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“…monodentate or bidentate coordination of the substrate) (47). The interacting iron atom could facilitate nucleophilic attack at the sulfate sulfur by acting as a Lewis acid, analogous to aconitase (29).…”

Section: Discussionmentioning

confidence: 99%

Spectroscopic Studies on the [4Fe-4S] Cluster in Adenosine 5′-Phosphosulfate Reductase from Mycobacterium tuberculosis

Bhave¹,

Hong

Lee³

et al. 2011

Journal of Biological Chemistry

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Mycobacterium tuberculosis adenosine 5-phosphosulfate reductase (MtAPR) is an iron-sulfur protein and a validated target to develop new antitubercular agents, particularly for the treatment of latent infection. The enzyme harbors a [4Fe-4S]2؉ cluster that is coordinated by four cysteinyl ligands, two of which are adjacent in the amino acid sequence. The ironsulfur cluster is essential for catalysis; however, the precise role of the [4Fe-4S] cluster in APR remains unknown. Progress in this area has been hampered by the failure to generate a paramagnetic state of the [4Fe-4S] cluster that can be studied by electron paramagnetic resonance spectroscopy. Herein, we overcome this limitation and report the EPR spectra of MtAPR in the [4Fe-4S] ؉ state. The EPR signal is rhombic and consists of two overlapping S ‫؍‬ 1 ⁄ 2 species. Substrate binding to MtAPR led to a marked increase in the intensity and resolution of the EPR signal and to minor shifts in principle g values that were not observed among a panel of substrate analogs, including adenosine 5-diphosphate. Using site-directed mutagenesis, in conjunction with kinetic and EPR studies, we have also identified an essential role for the active site residue Lys-144, whose side chain interacts with both the iron-sulfur cluster and the sulfate group of adenosine 5-phosphosulfate. The implications of these findings are discussed with respect to the role of the iron-sulfur cluster in the catalytic mechanism of APR.In bacteria and plants, activation of inorganic sulfur is required for de novo biosynthesis of cysteine. To this end, the metabolic assimilation of sulfate from the environment proceeds via adenosine 5Ј-phosphosulfate (APS) 2 or 3Ј-phosphoadenosine-5Ј-phosphosulfate (PAPS) (1). These intermediates are produced by the action of ATP-sulfurylase (EC 2.7.7.4), which condenses sulfate and ATP to form APS (2, 3), and by APS kinase (EC 2.7.1.25), which produces PAPS from ATP and APS (4).APS and PAPS are reduced by enzymes in the reductive branch of the sulfate assimilation pathway, producing sulfite and AMP or adenosine 3Ј,5Ј-diphosphate (Scheme 1). These enzymes can be subdivided into two groups according to their substrate preference: the APS reductases (APR) and the PAPS reductases (PAPR) (EC 1.8.99.4). Functional and structural studies have been used to investigate the chemical reaction mechanism of APR and PAPR enzymes (1,(5)(6)(7)(8). The mechanism involves nucleophilic attack by the active site cysteine on the sulfur atom of APS or PAPS to form an enzyme S-sulfocysteine intermediate, which is cleaved by thiol-disulfide exchange with thioredoxin or glutaredoxin (Fig. 1). The sulfite product is then reduced to sulfide by sulfite reductase (EC 1.8.7.1) and utilized to synthesize cysteine and other essential sulfur-containing biomolecules (9). In the human pathogen Mycobacterium tuberculosis, APR is a validated target against the latent phase of infection (10).Only a 3Ј-phosphate group distinguishes PAPS from APS. Accordingly, APR and PAPR have nearly identical three...

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Characterization of Quinolinate Synthases from Escherichia coli, Mycobacterium tuberculosis, and Pyrococcus horikoshii Indicates That [4Fe-4S] Clusters Are Common Cofactors throughout This Class of Enzymes

Cited by 31 publications

References 45 publications

The kynurenine pathway and the brain: Challenges, controversies and promises

The kynurenine pathway and the brain: Challenges, controversies and promises

The Crystal Structure of Fe₄S₄ Quinolinate Synthase Unravels an Enzymatic Dehydration Mechanism That Uses Tyrosine and a Hydrolase-Type Triad

Spectroscopic Studies on the [4Fe-4S] Cluster in Adenosine 5′-Phosphosulfate Reductase from Mycobacterium tuberculosis

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Characterization of Quinolinate Synthases from Escherichia coli, Mycobacterium tuberculosis, and Pyrococcus horikoshii Indicates That [4Fe-4S] Clusters Are Common Cofactors throughout This Class of Enzymes

Cited by 31 publications

References 45 publications

The kynurenine pathway and the brain: Challenges, controversies and promises

The kynurenine pathway and the brain: Challenges, controversies and promises

The Crystal Structure of Fe4S4 Quinolinate Synthase Unravels an Enzymatic Dehydration Mechanism That Uses Tyrosine and a Hydrolase-Type Triad

Spectroscopic Studies on the [4Fe-4S] Cluster in Adenosine 5′-Phosphosulfate Reductase from Mycobacterium tuberculosis

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The Crystal Structure of Fe₄S₄ Quinolinate Synthase Unravels an Enzymatic Dehydration Mechanism That Uses Tyrosine and a Hydrolase-Type Triad