Jill R. Cupp-Vickery

Crystallographic structure of the K intermediate of bacteriorhodopsin: conservation of free energy after photoisomerization of the retinal.

The K state, an early intermediate of the bacteriorhodopsin photocycle, contains the excess free energy used for light-driven proton transport. The energy gain must reside in or near the photoisomerized retinal, but in what form has long been an open question. We produced the K intermediate in bacteriorhodopsin crystals in a photostationary state at 100K, with 40% yield, and determined its X-ray diffraction structure to 1.43 A resolution. In independent refinements of data from four crystals, the changes are confined mainly to the photoisomerized retinal. The retinal is 13-cis,15-anti, as known from vibrational spectroscopy. The C13=C14 bond is rotated nearly fully to cis from the initial trans configuration, but the C14-C15 and C15=NZ bonds are partially counter-rotated. This strained geometry keeps the direction of the Schiff base N-H bond vector roughly in the extracellular direction, but the angle of its hydrogen bond with water 402, that connects it to the anionic Asp85 and Asp212, is not optimal. Weakening of this hydrogen bond may account for many of the reported features of the infrared spectrum of K, and for its photoelectric signal, as well as the deprotonation of the Schiff base later in the cycle. Importantly, although 13-cis, the retinal does not assume the expected bent shape of this configuration. Comparison of the calculated energy of the increased angle of C12-C13=C14, that allows this distortion, with the earlier reported calorimetric measurement of the enthalpy gain of the K state indicates that a significant part of the excess energy is conserved in the bond strain at C13.

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.

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.

Structural Studies on Prokaryotic Cytochromes P450

The camphor monooxygenase from Pseudomonas putida, P450cam, has been the single best paradigm for P450 structure and function studies for over two decades.1 Following a wealth of biochemical and biophysical studies on P450cam, the high-resolution crystal structure became available in 1987.2 This was followed by a series of structures on various inhibitor/substrate complexes which revealed some key structure-function relationships in P450s. In addition, with the development of recombinant expression systems for P450cam, it has been possible to use site-directed mutagenesis3,4 with reference to the crystal structure to probe questions of how structure relates to function.

Structure of cytochrome P450eryF: substrate, inhibitors, and model compounds bound in the active site.

Much of our understanding of P450 reaction mechanisms derives from studies on P450cam, a bacterial camphor hydroxylase. P450cam has served as the model for understanding detailed structure/function relationships in mammalian P450 enzymes, which have not proved amenable to x-ray crystallographic techniques. To expand and improve the P450 model, we solved the structure of P450eryF, a cytochrome P450 involved in erythromycin biosynthesis. The overall structure of P450eryF is similar to that of P450cam, but differs in the exact positioning of several alpha-helices, which results in the enlargement of the substrate-binding pocket. P450eryF also differs from P450cam in having alanine in place of the highly conserved threonine residue in the active site. To assess the role of this alanine residue, two mutant forms of P450eryF and a substrate analog were examined. Our findings suggest that P450eryF has evolved an active site that utilizes the substrate to assist in catalysis. In addition, the enlarged substrate binding pocket of P450eryF enables P450eryF to bind certain steroid compounds and azole-based steroid hydroxylase inhibitors. Crystals have been obtained for P450eryF complexed with the antifungal drug ketoconazole, and the high-resolution structure has been determined.

Structural Analysis of ADP-Glucose Pyrophosphorylase from the Bacterium Agrobacterium tumefaciens†,‡

ADP-glucose pyrophosphorylase (ADPGlc PPase) catalyzes the conversion of glucose 1-phosphate and ATP to ADP-glucose and pyrophosphate. As a key step in glucan synthesis, the ADPGlc PPases are highly regulated by allosteric activators and inhibitors in accord with the carbon metabolism pathways of the organism. Crystals of Agrobacterium tumefaciens ADPGlc PPase were obtained using lithium sulfate as a precipitant. A complete anomalous selenomethionyl derivative X-ray diffraction data set was collected with unit cell dimensions a = 85.38 A, b = 93.79 A, and c = 140.29 A (alpha = beta = gamma = 90 degrees ) and space group I 222. The A. tumefaciens ADPGlc PPase model was refined to 2.1 A with an R factor = 22% and R free = 26.6%. The model consists of two domains: an N-terminal alphabetaalpha sandwich and a C-terminal parallel beta-helix. ATP and glucose 1-phosphate were successfully modeled in the proposed active site, and site-directed mutagenesis of conserved glycines in this region (G20, G21, and G23) resulted in substantial loss of activity. The interface between the N- and the C-terminal domains harbors a strong sulfate-binding site, and kinetic studies revealed that sulfate is a competitive inhibitor for the allosteric activator fructose 6-phosphate. These results suggest that the interface between the N- and C-terminal domains binds the allosteric regulator, and fructose 6-phosphate was modeled into this region. The A. tumefaciens ADPGlc PPase/fructose 6-phosphate structural model along with sequence alignment analysis was used to design mutagenesis experiments to expand the activator specificity to include fructose 1,6-bisphosphate. The H379R and H379K enzymes were found to be activated by fructose 1,6-bisphosphate.

X-ray diffraction analysis of a crystal of HscA from Escherichia coli

HscA is a constitutively expressed Hsp70 that interacts with the iron-sulfur cluster assembly protein IscU. Crystals of a truncated form of HscA (52 kDa; residues 17-505) grown in the presence of an IscU-recognition peptide, WELPPVKI, have been obtained by hanging-drop vapor diffusion using ammonium sulfate as the precipitant. A complete native X-ray diffraction data set was collected from a single crystal at 100 K to a resolution of 2.9 A. The crystal belongs to the orthorhombic space group P2(1)2(1)2(1), with unit-cell parameters a = 158.35, b = 166.15, c = 168.26 A, and contains six molecules per asymmetric unit. Phases were determined by molecular replacement using the nucleotide-binding domain from DnaK and the substrate-binding domain from HscA as models. This is the first reported crystallization of an Hsp70 containing both nucleotide- and substrate-binding domains.

Preliminary crystallographic analysis of ADP-glucose pyrophosphorylase from Agrobacterium tumefaciens

ADP-glucose pyrophosphorylase catalyzes the conversion of glucose-1-phosphate and ATP to ADP-glucose and pyrophosphate, a key regulated step in both bacterial glycogen and plant starch biosynthesis. Crystals of ADP-glucose pyrophosphorylase from Agrobacterium tumefaciens (420 amino acids, 47 kDa) have been obtained by the sitting-drop vapor-diffusion method using lithium sulfate as a precipitant. A complete native X-ray diffraction data set was collected to a resolution of 2.0 A from a single crystal at 100 K. The crystals belong to space group I222, with unit-cell parameters a = 92.03, b = 141.251, c = 423.64 A. To solve the phase problem, a complete anomalous data set was collected from a selenomethionyl derivative. These crystals display one-fifth of the unit-cell volume of the wild-type crystals, with unit-cell parameters a = 85.38, b = 93.79, c = 140.29 A and space group I222.

Preliminary crystallographic analysis of the cysteine desulfurase IscS from Escherichia coli

IscS is a widely distributed cysteine desulfurase that catalyzes the pyridoxal phosphate dependent beta-elimination of sulfur from L-cysteine and plays a central role in the delivery of sulfur to a variety of metabolic pathways. Crystals of Escherichia coli IscS have been obtained by the hanging-drop vapor-diffusion method using polyethylene glycol (PEG) as a precipitant. Initial seed crystals were obtained using PEG 6000 and sodium acetate, and diffraction-quality crystals were grown using a mixture of PEG 2000 and PEG 10 000 in the presence of sodium citrate. A complete native X-ray diffraction data set was collected from a single crystal at 103 K to a resolution of 2.1 A. The crystals belong to space group P2(1)2(1)2(1) and have unit-cell parameters a = 73.7086, b = 101.9741, c = 108.617 A (alpha = beta = gamma = 90 degrees ). Analysis of the Matthews equation and self-rotation function suggest two molecules per asymmetric unit, consistent with the presence of a single dimeric molecule.