Larry E. Vickery

Inhibition of human aromatase by mammalian lignans and isoflavonoid phytoestrogens.

Isoflavonoid phytoestrogens and lignans in plants are known to be constituents of animal and human food and recently they have been found in human urine and other biological materials. These compounds have received increasing attention because of their interesting biological properties and possible role in human cancer and other diseases. The present study demonstrates that the main mammalian lignan enterolactone (trans-2,3-bis[(3-hydroxyphenyl)methyl]-butyrolactone) and some other diphenols are moderate or weak inhibitors of human estrogen synthetase (aromatase) and that this lignan binds to or near the substrate region of the active site of the P-450 enzyme. The inhibition is competitive with respect to testosterone and androstenedione, and the lignan affinity is 1/75-1/300 that of these natural substrates. It is suggested that the high concentration of lignans in vegetarians, by inhibiting aromatase in peripheral and/or cancer cells and lowering estrogen levels, may play a protective role as antipromotional compounds during growth of estrogen-dependent cancers.

Suppressors of Superoxide Dismutase (SOD1) Deficiency in Saccharomyces cerevisiae IDENTIFICATION OF PROTEINS PREDICTED TO MEDIATE IRON-SULFUR CLUSTER ASSEMBLY

Yeast deficient in the cytosolic copper/zinc superoxide dismutase (SOD1) exhibit metabolic defects indicative of oxidative damage even under non-stress conditions. To help identify the endogenous sources of this oxidative damage, we isolated mutant strains of S. cerevisiae that suppressed metabolic defects associated with loss of SOD1. Six complementation groups were isolated and three of the corresponding genes have been identified. One sod1Δ suppressor represents SSQ1 which encodes a hsp70-type molecular chaperone found in the mitochondria. A second sod1Δsuppressor gene, designated JAC1, represents a new member of the 20-kDa J-protein family of co-chaperones. Jac1p contains a mitochondrial targeting consensus sequence and may serve as the partner for Ssq1p. Homologues of Ssq1p and Jac1p are found in bacteria in close association with genes proposed to be involved in iron-sulfur protein biosynthesis. The third suppressor gene identified wasNFS1. Nfs1p is homologous to cysteine desulfurase enzymes that function in iron-sulfur cluster assembly and is also predicted to be mitochondrial. Each of the suppressor mutants identified exhibited diminished rates of respiratory oxygen consumption and was found to have reduced mitochondrial aconitase and succinate dehydrogenase activities. Taken together these results suggest a role for Ssq1p, Jac1p, and Nfs1p in assembly/maturation of mitochondrial iron-sulfur proteins and that one or more of the target Fe/S proteins contribute to oxidative damage in cells lacking copper/zinc SOD.

Crystal Structure of IscS, a Cysteine Desulfurase from Escherichia coli

IscS is a widely distributed cysteine desulfurase that catalyzes the pyridoxal phosphate-dependent desulfuration of L-cysteine and plays a central role in the delivery of sulfur to a variety of metabolic pathways. We report the crystal structure of Escherichia coli IscS to a resolution of 2.1A. The crystals belong to the space group P2(1)2(1)2(1) and have unit cell dimensions a=73.70A, b=101.97A, c=108.62A (alpha=beta=gamma=90 degrees ). Molecular replacement with the Thermotoga maritima NifS model was used to determine phasing, and the IscS model was refined to an R=20.6% (R(free)=23.6%) with two molecules per asymmetric unit. The structure of E.coli IscS is similar to that of T.maritima NifS with nearly identical secondary structure and an overall backbone r.m.s. difference of 1.4A. However, in contrast to NifS a peptide segment containing the catalytic cysteine residue (Cys328) is partially ordered in the IscS structure. This segment of IscS (residues 323-335) forms a surface loop directed away from the active site pocket. Cys328 is positioned greater than 17A from the pyridoxal phosphate cofactor, suggesting that a large conformational change must occur during catalysis in order for Cys328 to participate in nucleophilic attack of a pyridoxal phosphate-bound cysteine substrate. Modeling suggests that rotation of this loop may allow movement of Cys328 to within approximately 3A of the pyridoxal phosphate cofactor.

Molecular Chaperones HscA/Ssq1 and HscB/Jac1 and Their Roles in Iron-Sulfur Protein Maturation

ABSTRACT Genetic and biochemical studies have led to the identification of several cellular pathways for the biosynthesis of iron-sulfur proteins in different organisms. The most broadly distributed and highly conserved system involves an Hsp70 chaperone and J-protein co-chaperone system that interacts with a scaffold-like protein involved in [FeS]-cluster preassembly. Specialized forms of Hsp70 and their co-chaperones have evolved in bacteria (HscA, HscB) and in certain fungi (Ssq1, Jac1), whereas most eukaryotes employ a multifunctional mitochondrial Hsp70 (mtHsp70) together with a specialized co-chaperone homologous to HscB/Jac1. HscA and Ssq1 have been shown to specifically bind to a conserved sequence present in the [FeS]-scaffold protein designated IscU in bacteria and Isu in fungi, and the crystal structure of a complex of a peptide containing the IscU recognition region bound to the HscA substrate binding domain has been determined. The interaction of IscU/Isu with HscA/Ssq1 is regulated by HscB/Jac1 which bind the scaffold protein to assist delivery to the chaperone and stabilize the chaperone-scaffold complex by enhancing chaperone ATPase activity. The crystal structure of HscB reveals that the N-terminal J-domain involved in regulation of HscA ATPase activity is similar to other J-proteins, whereas the C-terminal domain is unique and appears to mediate specific interactions with IscU. At the present time the exact function(s) of chaperone-[FeS]-scaffold interactions in iron-sulfur protein biosynthesis remain(s) to be established. In vivo and in vitro studies of yeast Ssq1 and Jac1 indicate that the chaperones are not required for [FeS]-cluster assembly on Isu. Recent in vitro studies using bacterial HscA, HscB and IscU have shown that the chaperones destabilize the IscU[FeS] complex and facilitate cluster delivery to an acceptor apo-protein consistent with a role in regulating cluster release and transfer. Additional genetic and biochemical studies are needed to extend these findings to mtHsp70 activities in higher eukaryotes.

Molecular recognition and electron transfer in mitochondrial steroid hydroxylase systems.

Mitochondrial monooxygenase systems are involved in the biosynthesis of glucocorticoids, mineralocorticoids, bile acids, and 1,25-dihydroxyvitamin D. The reactions are catalyzed by specific P450 enzymes that receive reducing equivalents via NADPH-ferredoxin oxidoreductase (adrenodoxin reductase) and ferredoxin (adrenodoxin). Although the three-dimensional structures of the individual components have not yet been solved, methods of expressing recombinant forms of these enzymes in Escherichia coli have allowed the use of site-directed mutagenesis to investigate the roles of specific amino acids in protein binding interactions, electron transfer, and catalysis. These studies have identified key charged residues in NADPH-ferredoxin oxidoreductase, ferredoxin, and P450scc, which are involved in electrostatic interactions critical for recognition, high-affinity binding, and electron transfer. The finding that the binding sites on ferredoxin for NADPH-ferredoxin oxidoreductase and P450 show significant overlap supports the proposed function for ferredoxin as a mobile electron shuttle between the reductase and P450 enzymes and is consistent with ferredoxins role in serving multiple P450 isoforms.

Studies on the Mechanism of Catalysis of Iron-Sulfur Cluster Transfer from IscU[2Fe2S] by HscA/HscB Chaperones

The HscA/HscB chaperone/cochaperone system accelerates transfer of iron-sulfur clusters from the FeS-scaffold protein IscU (IscU(2)[2Fe2S], holo-IscU) to acceptor proteins in an ATP-dependent manner. We have employed visible region circular dichroism (CD) measurements to monitor chaperone-catalyzed cluster transfer from holo-IscU to apoferredoxin and to investigate chaperone-induced changes in properties of the IscU(2)[2Fe2S] cluster. HscA-mediated acceleration of [2Fe2S] cluster transfer exhibited an absolute requirement for both HscB and ATP. A mutant form of HscA lacking ATPase activity, HscA(T212V), was unable to accelerate cluster transfer, suggesting that ATP hydrolysis and conformational changes accompanying the ATP (T-state) to ADP (R-state) transition in the HscA chaperone are required for catalysis. Addition of HscA and HscB to IscU(2)[2Fe2S] did not affect the properties of the [2Fe2S] cluster, but subsequent addition of ATP was found to cause a transient change of the visible region CD spectrum, indicating distortion of the IscU-bound cluster. The dependence of the rate of decay of the observed CD change on ATP concentration and the lack of an effect of the HscA(T212V) mutant were consistent with conformational changes in the cluster coupled to ATP hydrolysis by HscA. Experiments carried out under conditions with limiting concentrations of HscA, HscB, and ATP further showed that formation of a 1:1:1 HscA-HscB-IscU(2)[2Fe2S] complex and a single ATP hydrolysis step are sufficient to elicit the full effect of the chaperones on the [2Fe2S] cluster. These results suggest that acceleration of iron-sulfur cluster transfer involves a structural change in the IscU(2)[2Fe2S] complex during the T --> R transition of HscA accompanying ATP hydrolysis.

Contributions of the LPPVK motif of the iron-sulfur template protein IscU to interactions with the Hsc66-Hsc20 chaperone system.

Hsc66 (HscA) and Hsc20 (HscB) from Escherichia coli comprise a specialized chaperone system that selectively binds the iron-sulfur cluster template protein IscU. Hsc66 interacts with peptides corresponding to a discrete region of IscU including residues 99–103 (LPPVK), and a peptide containing residues 98–106 stimulates Hsc66 ATPase activity in a manner similar to IscU. To determine the relative contributions of individual residues in the LPPVK motif to Hsc66 binding and regulation, we have carried out an alanine mutagenesis scan of this motif in the Glu98–Cys106 peptide and the IscU protein. Alanine substitutions in the Glu98–Cys106 peptide resulted in decreased ATPase stimulation (2–10-fold) because of reduced binding affinity, with peptide(P101A) eliciting <10% of the parent peptide stimulation. Alanine substitutions in the IscU protein also revealed lower activities resulting from decreased apparent binding affinity, with the greatest changes in Km observed for the Pro101 (77-fold), Val102 (4-fold), and Lys103 (15-fold) mutants. Calorimetric studies of the binding of IscU mutants to the Hsc66·ADP complex showed that the P101A and K103A mutants also exhibit decreased binding affinity for the ADP-bound state. When ATPase stimulatory activity was assayed in the presence of the co-chaperone Hsc20, each of the mutants displayed enhanced binding affinity, but the P101A and V102A mutants exhibited decreased ability to maximally simulate Hsc66 ATPase. A charge mutant containing the motif sequence of NifU, IscU(V102E), did not bind the ATP or ADP states of Hsc66 but did bind Hsc20 and weakly stimulated Hsc66 ATPase in the presence of the co-chaperone. These results indicate that residues in the LPPVK motif are important for IscU interactions with Hsc66 but not for the ability of Hsc20 to target IscU to Hsc66. The results are discussed in the context of a structural model based on the crystallographic structure of the DnaK peptide-binding domain.

Multiple Turnover Transfer of [2Fe2S] Clusters by the Iron-Sulfur Cluster Assembly Scaffold Proteins IscU and IscA

IscU/Isu and IscA/Isa (and related NifU and SufA proteins) have been proposed to serve as molecular scaffolds for preassembly of [FeS] clusters to be used in the biogenesis of iron-sulfur proteins. In vitro studies demonstrating transfer of preformed scaffold-[FeS] complexes to apoprotein acceptors have provided experimental support for this hypothesis, but investigations to date have yielded only single-cluster transfer events. We describe an in vitro assay system that allows for real-time monitoring of [FeS] cluster formation using circular dichroism spectroscopy and use this to investigate de novo [FeS] cluster formation and transfer from Escherichia coli IscU and IscA to apo-ferredoxin. Both IscU and IscA were found to be capable of multiple cycles of [2Fe2S] cluster formation and transfer suggesting that these scaffold proteins are capable of acting “catalytically.” Kinetic studies further showed that cluster transfer exhibits Michaelis-Menten behavior indicative of complex formation of holo-IscU and holo-IscA with apoferredoxin and consistent with a direct [FeS] cluster transfer mechanism. Analysis of the dependence of the rate of cluster transfer, however, revealed enhanced efficiency at low ratios of scaffold to acceptor protein suggesting participation of a transient, labile scaffold-[FeS] species in the transfer process.

Structure and dynamics of the iron-sulfur cluster assembly scaffold protein IscU and its interaction with the cochaperone HscB.

IscU is a scaffold protein that functions in iron-sulfur cluster assembly and transfer. Its critical importance has been recently underscored by the finding that a single intronic mutation in the human iscu gene is associated with a myopathy resulting from deficient succinate dehydrogenase and aconitase [Mochel, F., Knight, M. A., Tong, W. H., Hernandez, D., Ayyad, K., Taivassalo, T., Andersen, P. M., Singleton, A., Rouault, T. A., Fischbeck, K. H., and Haller, R. G. (2008) Am. J. Hum. Genet. 82, 652-660]. IscU functions through interactions with a chaperone protein HscA and a cochaperone protein HscB. To probe the molecular basis for these interactions, we have used NMR spectroscopy to investigate the solution structure of IscU from Escherichia coli and its interaction with HscB from the same organism. We found that wild-type apo-IscU in solution exists as two distinct conformations: one largely disordered and one largely ordered except for the metal binding residues. The two states interconvert on the millisecond time scale. The ordered conformation is stabilized by the addition of zinc or by the single-site IscU mutation, D39A. We used apo-IscU(D39A) as a surrogate for the folded state of wild-type IscU and assigned its NMR spectrum. These assignments made it possible to identify the region of IscU with the largest structural differences in the two conformational states. Subsequently, by following the NMR signals of apo-IscU(D39A) upon addition of HscB, we identified the most perturbed regions as the two N-terminal beta-strands and the C-terminal alpha-helix. On the basis of these results and analysis of IscU sequences from multiple species, we have identified the surface region of IscU that interacts with HscB. We conclude that the IscU-HscB complex exists as two (or more) distinct states that interconvert at a rate much faster than the rate of dissociation of the complex and that HscB binds to and stabilizes the ordered state of apo-IscU.

Facilitated Transfer of IscU–[2Fe2S] Clusters by Chaperone-Mediated Ligand Exchange

The scaffold protein IscU and molecular chaperones HscA and HscB play central roles in biological assembly of iron-sulfur clusters and maturation of iron-sulfur proteins. However, the structure of IscU-FeS complexes and the molecular mechanism whereby the chaperones facilitate cluster transfer to acceptor proteins are not well understood. We have prepared amino acid substitution mutants of Escherichia coli IscU in which potential ligands to the FeS cluster (Cys-37, Cys-63, His-105, and Cys-106) were individually replaced with alanine. The properties of the IscU-FeS complexes formed were investigated by measuring both their ability to transfer preformed FeS clusters to apo-ferredoxin and the activity of the IscU proteins in catalyzing cluster assembly on apo-ferredoxin using inorganic iron with inorganic sulfide or with IscS and cysteine as a sulfur source. The ability of the HscA/HscB chaperone system to accelerate ATP-dependent cluster transfer from each IscU substitution mutant to apo-ferredoxin was also determined. All of the mutants formed FeS complexes with a stoichiometry similar to the wild-type holo-protein, i.e., IscU(2)[2Fe2S], raising the possibility that different cluster ligation states may occur during iron-sulfur protein maturation. Spectroscopic properties of the mutants and the kinetics of transfer of performed IscU-FeS clusters to apo-ferredoxin indicate that the most stable form of holo-IscU involves iron coordination by Cys-63 and Cys-106. Results of studies on the ability of mutants to catalyze formation of holo-ferredoxin using iron and different sulfur sources were consistent with proposed roles for Cys-63 and Cys-106 in FeS cluster binding and also indicated an essential role for Cys-106 in sulfide transfer to IscU from IscS. Measurements of the ability of the chaperones HscA and HscB to facilitate cluster transfer from holo-IscU to apo-ferredoxin showed that only IscU(H105A) behaved similarly to wild-type IscU in exhibiting ATP-dependent stimulation of cluster transfer. IscU(C63A) and IscU(C106A) displayed elevated rates of cluster transfer in the ±ATP whereas IscU(C37A) exhibited low rates of cluster transfer ±ATP. In interpreting these findings, we propose that IscU(2)[2Fe2S] is able undergo structural isomerization to yield conformers having different cysteine residues bound to the cluster. On the basis of the crystal structure of HscA complexed with an IscU-derived peptide, we propose that the chaperone binds and stabilizes an isomer of IscU(2)[2Fe2S] in which the cluster is bound by cysteine residues 37 and 63 and that the [2Fe2S] cluster, being held less tightly than that coordinated by Cys-63 and Cys-106 in free IscU(2)[2Fe2S], is more readily transferred to acceptor proteins such as apo-ferredoxin.