Bioorganometallic mechanism of action, and inhibition, of IspH

Wang, Weixue; Wang, Ke; Liu, Yi Liang; No, Joo Hwan; Li, Jikun; Nilges, Mark J.; Oldfield, Eric

doi:10.1073/pnas.0911087107

Cited by 84 publications

(183 citation statements)

References 31 publications

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“…R55, R101, and R128 have been shown to be essential for catalysis in A. aeolicus IspG by Lee et al (7) and R141 (Thermus numbering) is essential for survival in Salmonella enterica (17). So, based on the docking results, their conserved nature (Table S1) and the mutagenesis results, these residues are all likely to be involved in MEcPP, reactive intermediate or HMBPP product binding, via their diphosphate groups, while the reactive intermediate and HMBPP product also interact directly with Fe via Fe-O and/or Fe-C bonds, the HMBPP O-1 Fe interaction being similar to that seen with HMBPP binding to IspH (18).…”

Section: Resultsmentioning

confidence: 99%

“…Mechanistically then, it appears that MEcPP binds to the conserved Arg/Lys residues in the A domain and that the carbocation that forms on ring opening is located very close to the 4Fe4S cluster domain, which then leads to formation of the reaction intermediate, X (2,16 (18), and an approximately 17 MHz hyperfine coupling for the C2 carbon (16). To see to what extent it might be possible to predict these spectroscopic observables, we used density functional theory (DFT) (19,20).…”

Section: Resultsmentioning

confidence: 99%

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Structure, function and inhibition of the two- and three-domain 4Fe-4S IspG proteins

Liu

Guerra

Wang³

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

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IspG is a 4Fe4S protein involved in isoprenoid biosynthesis. Most bacterial IspGs contain two domains: a TIM barrel (A) and a 4Fe4S domain (B), but in plants and malaria parasites, there is a large insert domain (A*) whose structure and function are unknown. We show that bacterial IspGs function in solution as (AB) 2 dimers and that mutations in either both A or both B domains block activity. Chimeras harboring an A-mutation in one chain and a B-mutation in the other have 50% of the activity seen in wild-type protein, because there is still one catalytically active AB domain. However, a plant IspG functions as an AA*B monomer. We propose, using computational modeling and electron microscopy, that the A* insert domain has a TIM barrel structure that interacts with the A domain. This structural arrangement enables the A and B domains to interact in a “cup and ball” manner during catalysis, just as in the bacterial systems. EPR/HYSCORE spectra of reaction intermediate, product, and inhibitor ligands bound to both two and three domain proteins are identical, indicating the same local electronic structure, and computational docking indicates these ligands bridge both A and B domains. Overall, the results are of broad general interest because they indicate the insert domain in three-domain IspGs is a second TIM barrel that plays a structural role and that the pattern of inhibition of both two and three domain proteins are the same, results that can be expected to be of use in drug design.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Structure, function and inhibition of the two- and three-domain 4Fe-4S IspG proteins

Liu

Guerra

Wang³

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

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“…Studies from Aquifex aeolicus and E. coli indicate that IspH has a trefoil-like structure with a central Fe 4 S 4 cluster, which is coordinated by the Cys residues located in each of the three folding domains (Rekittke et al, 2008;Gräwert et al, 2009). The central cavity is the active site, and the iron-sulfur cluster serves as an electrontransfer cofactor in the active site (Gräwert et al, 2004(Gräwert et al, , 2009(Gräwert et al, , 2010Rekittke et al, 2008;Wang et al, 2010). The IspH mechanism of action is still under debate, but there is considerable evidence in support of the organometallic hypothesis (Wang et al, 2010Span et al, 2012a;Xu et al, 2012;Li et al, 2013).…”

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confidence: 99%

“…The central cavity is the active site, and the iron-sulfur cluster serves as an electrontransfer cofactor in the active site (Gräwert et al, 2004(Gräwert et al, , 2009(Gräwert et al, , 2010Rekittke et al, 2008;Wang et al, 2010). The IspH mechanism of action is still under debate, but there is considerable evidence in support of the organometallic hypothesis (Wang et al, 2010Span et al, 2012a;Xu et al, 2012;Li et al, 2013). The substrate HMBPP initially forms a hydroxy complex with the iron-sulfur cluster, and a subsequent series of complexes with rare organometallic bonds leads to the synthesis of IPP and DMAPP (Wang et al, 2010Li et al, 2013).…”

mentioning

confidence: 99%

“…The IspH mechanism of action is still under debate, but there is considerable evidence in support of the organometallic hypothesis (Wang et al, 2010Span et al, 2012a;Xu et al, 2012;Li et al, 2013). The substrate HMBPP initially forms a hydroxy complex with the iron-sulfur cluster, and a subsequent series of complexes with rare organometallic bonds leads to the synthesis of IPP and DMAPP (Wang et al, 2010Li et al, 2013).…”

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Functional Evidence for the Critical Amino-Terminal Conserved Domain and Key Amino Acids of Arabidopsis 4-HYDROXY-3-METHYLBUT-2-ENYL DIPHOSPHATE REDUCTASE

et al. 2014

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The plant 4-HYDROXY-3-METHYLBUT-2-ENYL DIPHOSPHATE REDUCTASE (HDR) catalyzes the last step of the methylerythritol phosphate pathway to synthesize isopentenyl diphosphate and its allyl isomer dimethylallyl diphosphate, which are common precursors for the synthesis of plastid isoprenoids. The Arabidopsis (Arabidopsis thaliana) genomic HDR transgene-induced gene-silencing lines are albino, variegated, or pale green, confirming that HDR is essential for plants. We used Escherichia coli isoprenoid synthesis H (Protein Data Bank code 3F7T) as a template for homology modeling to identify key amino acids of Arabidopsis HDR. The predicted model reveals that cysteine (Cys)-122, Cys-213, and Cys-350 are involved in iron-sulfur cluster formation and that histidine (His)-152, His-241, glutamate (Glu)-242, Glu-243, threonine (Thr)-244, Thr-312, serine-379, and asparagine-381 are related to substrate binding or catalysis. Glu-242 and Thr-244 are conserved only in cyanobacteria, green algae, and land plants, whereas the other key amino acids are absolutely conserved from bacteria to plants. We used sitedirected mutagenesis and complementation assay to confirm that these amino acids, except His-152 and His-241, were critical for Arabidopsis HDR function. Furthermore, the Arabidopsis HDR contains an extra amino-terminal domain following the transit peptide that is highly conserved from cyanobacteria, and green algae to land plants but not existing in the other bacteria. We demonstrated that the amino-terminal conserved domain was essential for Arabidopsis and cyanobacterial HDR function. Further analysis of conserved amino acids in the amino-terminal conserved domain revealed that the tyrosine-72 residue was critical for Arabidopsis HDR. These results suggest that the structure and reaction mechanism of HDR evolution have become specific for oxygen-evolving photosynthesis organisms and that HDR probably evolved independently in cyanobacteria versus other prokaryotes.

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