Stellacyanin. Studies of the metal-binding site using x-ray absorption spectroscopy.

Stellacyanin is a mucoprotein of molecular weight approximately 20,000 containing one copper atom in a blue or type I site. The metal ion can exist in both the Cu(II) and Cu(I) redox states. The metal binding site in plastocyanin, another blue copper protein, contains one cysteinyl, one methionyl, and two imidazoyl residues (Colman et al. 1978. Nature [Lond.]. 272:319-324.), but an exactly analogous site cannot exist in stellacyanin as it lacks methionine. The copper coordination in stellacyanin has been studied by x-ray edge absorption and extended x-ray absorption fine structure (EXAFS) analysis. A new, very conservative data analysis procedure has been introduced, which suggests that the there are two nitrogen atoms in the first coordination shell of the oxidized [Cu(II)] protein and one in the reduced [Cu(I)] protein; these N atoms have normal Cu--N distances: 1.95-2.05 A. In both redox states there are either one or two sulfur atoms coordinating the copper, the exact number being indeterminable from the present data. In the oxidized state the Cu--S distance is intermediate between the short bond found in plastocyanin and those found in near tetragonal copper model compounds. Above -140 degree C, radiation damage of the protein occurs. At room temperature the oxidized proteins is modified in the x-ray beam at a rate of 0.25%/s.     

Multiple structures and functions of cytochrome oxidase

X-ray absorption studies have been used to investigate the structure of the four redox centers (2Fe, 2Cu) of the terminal enzyme in the respiratory chain, cytochrome c oxidase in the resting oxidized form as well as in the functional intermediates that are freeze-trapped. Methods of x-ray fluorescence detection for these low-concentration samples together with low-temperature cryostats and simultaneous optical monitoring were developed to ensure good signal-to-noise data and sample integrity. The resting oxidized form contains a sulfur bridge between the copper and iron of the active site which are separated by approximately 3.8 A. This separation of the active site metal atoms was uniquely identified by comparison of both the iron and copper EXAFS data and iron EXAFS of the copper-depleted enzyme. In the reduced state, the CO or O2 is bound to the active site iron having a structure identical to CO or oxy hemoglobin while the sulfur remains with the active site copper. Little change in structure is observed for the other iron and copper. It is the sulfur bridged active site form that is isolated by the Yonetani and Caughy methods with greater than or equal to 85% homogeneity but not the Hartzell-Beinert or similar methods. Another form observed in the redox cycle is also fully oxidized but lacks the sulfur bridged active site with the iron of the active site having a structure identical to that of the peroxidases. This form exhibits peroxidase as well as oxidase activity, and a stable intermediate is formed with hydrogen and ethylhydrogen peroxide in which the iron of the active site is structurally similar to that of the peroxidase intermediate. The active site copper, however, does not participate in the peroxidatic role and the structures of the other iron and copper are identical to those of the sulfur bridged resting oxidized form. Thus this unique enzyme has peroxidase activity which may serve to safeguard its main oxidase function.     

X-ray absorption spectroscopic study of the active copper sites in dopamine beta-hydroxylase

X-ray absorption spectroscopy has been used to investigate the local environment of the copper sites in bovine dopamine beta-hydroylase, the enzyme that catalyzes the conversion of dopamine to norepinephrine in the adrenal medulla and noradrenergic nerve cells. The marked similarity of the x-ray absorption edge features of the oxidized and ascorbate-reduced forms of the enzyme with those of the corresponding Cu(imidazole)4 complexes suggests that the ligation in both cases is very similar. Furthermore, this similarity is found for the extended x-ray absorption fine structure data, and analysis shows only nitrogen (or oxygen) ligation for both enzyme forms. Thus, four nitrogen atoms provide the best fit to the data at an average distance of 1.97 +/- 0.02 A for the oxidized enzyme and four nitrogen atoms at 2.05 +/- 0.02 A for the ascorbate-reduced form. The present data analysis also indicates that there is little change in the average copper ligand environment upon reduction of the enzyme-bound copper from Cu(II) to the Cu(I). The data for the oxidized form of the enzyme are in agreement with previous spin-echo EPR experiments that show three to four imidazole nitrogen ligands for each copper (McCracken, J., Desai, P. R., Papadopoulos, N. J., Villafranca, J. J., and Peisach, J. (1988) Biochemistry 27, 4133-4137). In addition, the data do not indicate the presence of any heavy atom (sulfur or chlorine) ligation to the ascorbate-reduced form of the enzyme as reported by Scott et al. (Scott, R. A., Sullivan, R. J., DeWolf, W. E., Jr., Dolle, R. E., and Kruse, L. I. (1988) Biochemistry 27, 5411-5417).     

Vectorially oriented membrane protein monolayers: profile structures via x-ray interferometry/holography.

X-ray interferometry/holography was applied to meridional x-ray diffraction data to determine uniquely the profile structures of a single monolayer of an integral membrane protein and a peripheral membrane protein, each tethered to the surface of a solid inorganic substrate. Bifunctional, organic self-assembled monolayers (SAMs) were utilized to tether the proteins to the surface of Ge/Si multilayer substrates, fabricated by molecular beam epitaxy, to facilitate the interferometric/holographic x-ray structure determination. The peripheral membrane protein yeast cytochrome c was covalently tethered to the surface of a sulfhydryl-terminated 11-siloxyundecanethiol SAM via a disulfide linkage with residue 102. The detergent-solubilized, photosynthetic reaction center integral membrane protein was electrostatically tethered to the surface of an analogous amine-terminated SAM. Optical absorption measurements performed on these two tethered protein monolayer systems were consistent with the x-ray diffraction results indicating the reversible formation of densely packed single monolayers of each fully functional membrane protein on the surface of the respective SAM. The importance of utilizing the organic self-assembled monolayers (as opposed to Langmuir-Blodgett) lies in their ability to tether specifically both soluble peripheral membrane proteins and detergent-solubilized integral membrane proteins. The vectorial orientations of the cytochrome c and the reaction center molecules were readily distinguishable in the profile structure of each monolayer at a spatial resolution of 7 A.     

X-ray absorption studies of yeast copper metallothionein

The local structures of the metal sites in copper metallothionein from Saccharomyces cerevisiae have been investigated by x-ray absorption spectroscopy at the copper and sulfur K edges. Analysis of the EXAFS (extended x-ray absorption fine structure) data indicates that each copper is trigonally coordinated to sulfur at a distance of 2.23 A. Cu-Cu interactions at 2.7 and 3.9 A have also been tentatively identified. Sulfur K edge data are compatible with cysteinyl thiolates bridging each of the eight Cu(I) ions. The data support a model for the copper cluster in yeast metallothionein consisting of a Cu8S12 core. EXAFS data on two specifically engineered carboxyl-terminal truncated mutants reveal that the copper coordination in the mutants is similar to that observed in the wild-type protein.     

Effect of cyanide binding on the copper sites of cytochrome c oxidase: an X-ray absorption spectroscopic study

Cu x-ray absorption spectroscopy (XAS) has been used to investigate the effect of cyanide treatment on the structures of the copper sites in beef heart cytochrome c oxidase. The Cu K-edge spectrum changes significantly upon cyanide binding to resting state enzyme, as does the Cu extended x-ray absorption fine structure (EXAFS) spectrum. The Cu EXAFS Fourier transfer (FT) exhibits an enhanced peak for the cyanide-treated enzyme in the region containing the Cu...Fe peak in the resting state FT (at R' approximately equal to 2.6-2.7 A). This peak in the cyanide-treated sample is hypothesized to arise from "outer shell" scattering from a linear Cu-cyanide moiety, suggesting cyanide binding to CuB only (CuB 2+-CN-) or cyanide bridging between the Fe of heme a3 and CuB (Fe3+-(CN-)-CuB 2+).     

Positioning membrane proteins by novel protein engineering and biophysical approaches

Membrane proteins are unique, in that they can function properly only when they are bound to cellular membranes in a distinct manner. Therefore, positioning of membrane proteins with respect to the membrane is required in addition to the three-dimensional structures in order to understand their detailed molecular mechanisms. Atomic-resolution structures of membrane proteins that have been determined to date provide the atom coordinates in arbitrary coordinate systems with no relation to the membrane and therefore provide little or no information on how the protein would interact with the membrane. This is especially true for peripheral membrane proteins, because they, unlike integral proteins, are devoid of well-defined hydrophobic transmembrane domains. Here, we present a novel technique for determination of the configuration of a protein-membrane complex that involves protein ligation, segmental isotope labeling, polarized infrared spectroscopy, membrane depth-dependent fluorescence quenching, and analytical geometry algorithms. We have applied this approach to determine the structure of a membrane-bound phospholipase A2. Our results provide an unprecedented structure of a membrane-bound protein in which the z-coordinate of each atom is the distance from the membrane center and therefore allows precise location of each amino acid relative to the membrane. Given the functional significance of the orientation and location of membrane-bound proteins with respect to the membrane, we propose to specify this structural feature as the "quinary" structure of membrane proteins.     

Dynamics of proteins in crystals: comparison of experiment with simple models

The dynamic behavior of proteins in crystals is examined by comparing theory and experiments. The Gaussian network model (GNM) and a simplified version of the crystallographic translation libration screw (TLS) model are used to calculate mean square fluctuations of C(alpha) atoms for a set of 113 proteins whose structures have been determined by x-ray crystallography. Correlation coefficients between the theoretical estimations and experiment are calculated and compared. The GNM method gives better correlation with experimental data than the rigid-body libration model and has the added benefit of being able to calculate correlations between the fluctuations of pairs of atoms. By incorporating the effect of neighboring molecules in the crystal the correlation is further improved.     

The signal peptide as a new target for drug design

Many current and potential drug targets are membrane-bound or secreted proteins that are expressed and transported via the Sec61 secretory pathway. They are targeted to translocon channels across the membrane of the endoplasmic reticulum (ER) by signal peptides (SPs), which are temporary structures on the N-termini of their nascent chains. During translation, such proteins enter the lumen and membrane of the ER by a process known as co-translational translocation. Small molecules have been found that interfere with this process, decreasing protein expression by recognizing the unique structures of the SPs of particular proteins. The SP may thus become a validated target for designing drugs for numerous disorders, including certain hereditary diseases.     

Identification of differentially expressed genes in response to dietary iron deprivation in rat duodenum

We sought to identify novel genes involved in intestinal iron absorption by inducing iron deficiency in rats during postnatal development from the suckling period through adulthood. We then performed comparative gene chip analyses (RAE230A and RAE230B chips; Affymetrix) with cRNA derived from duodenal mucosa. Real-time PCR was used to confirm changes in gene expression. Genes encoding the apical iron transport-related proteins [divalent metal transporter 1 (DMT1) and duodenal cytochrome b] were strongly induced at all ages studied, whereas increases in mRNA encoding the basolateral proteins iron-regulated gene 1 and hephaestin were observed only by real-time PCR. In addition, transferrin receptor 1 and heme oxygenase 1 were induced. We also identified induction of novel genes not previously associated with intestinal iron transport. The Menkes copper ATPase (ATP7a) and metallothionein were strongly induced at all ages studied, suggesting increased copper absorption by enterocytes during iron deficiency. We also found significantly increased liver copper levels in 7- to 12-wk-old iron-deficient rats. Also upregulated at most ages examined were the sodium-dependent vitamin C transporter, tripartite motif protein 27, aquaporin 4, lipocalin-interacting membrane receptor, and the breast cancer-resistance protein (ABCG2). Some genes also showed decreased expression with iron deprivation, including several membrane transporters, metabolic enzymes, and genes involved in the oxidative stress response. We speculate that dietary iron deprivation leads to increased intestinal copper absorption via DMT1 on the brush-border membrane and the Menkes copper ATPase on the basolateral membrane. These findings may thus explain copper loading in the iron-deficient state. We also demonstrate that many other novel genes may be differentially regulated in the setting of iron deprivation.     

Membrane-bound conformation of M13 major coat protein: a structure validation through FRET-derived constraints

M13 major coat protein, a 50-amino-acid-long protein, was incorporated into DOPC/DOPG (80/20 molar ratio) unilamellar vesicles. Over 60% of all amino acid residues was replaced with cysteine residues, and the single cysteine mutants were labeled with the fluorescent label I-AEDANS. The coat protein has a single tryptophan residue that is used as a donor in fluorescence (or F?rster) resonance energy transfer (FRET) experiments, using AEDANS-labeled cysteines as acceptors. Based on FRET-derived constraints, a straight alpha-helix is proposed as the membrane-bound conformation of the coat protein. Different models were tested to represent the molecular conformations of the donor and acceptor moieties. The best model was used to make a quantitative comparison of the FRET data to the structures of M13 coat protein and related coat proteins in the Protein Data Bank. This shows that the membrane-bound conformation of the coat protein is similar to the structure of the coat protein in the bacteriophage that was obtained from x-ray diffraction. Coat protein embedded in stacked, oriented bilayers and in micelles turns out to be strongly affected by the environmental stress of these membrane-mimicking environments. Our findings emphasize the need to study membrane proteins in a suitable environment, such as in fully hydrated unilamellar vesicles. Although larger proteins than M13 major coat protein may be able to handle environmental stress in a different way, any membrane protein with water exposed parts in the C or N termini and hydrophilic loop regions should be treated with care.     

Import of proteins into mitochondria. Energy-dependent, two-step processing of the intermembrane space enzyme cytochrome b2 by isolated yeast mitochondria

Import of in vitro-synthesized cytochrome b2 (a soluble intermembrane space enzyme) was studied wih isolated yeast mitochondria. Import requires an electrochemical gradient across the inner membrane and is accompanied by cleavage of the precursor to the corresponding mature form. This conversion proceeds via an intermediate form of cytochrome b2, which can be detected as a transient species when mitochondria are incubated with the cytochrome b2 precursor for short times or at low temperatures. Conversion of the precursor to the intermediate form is energy-dependent and catalyzed by an o-phenanthroline-sensitive protease located in the soluble matrix. The intermediate is subsequently converted to mature cytochrome b2 in a reaction which is o-phenanthroline-insensitive and requires neither an energized inner membrane nor a soluble component of the intermembrane space. Whereas mature cytochrome b2 is soluble, the intermediate formed by isolated mitochondria is membrane-bound and exposed to the intermembrane space. The same intermediate is detected as a transient species during cytochrome b2 maturation in intact yeast cells (Reid, G. A., Yonetani, T., and Schatz, G (1982) J. Biol. Chem. 257, 13068-13074). The in vitro studies reported here suggest that a part of the cytochrome b2 precursor polypeptide chain is transported to the matrix where it is cleaved to a membrane-bound intermediate form by the same protease that processes polypeptides destined for the matrix space or for the inner membrane. In a second reaction, the cytochrome b2 intermediate is converted to mature cytochrome b2 which is released into the intermembrane space. The binding of heme is not necessary for converting the intermediate to the mature polypeptide.     

X-ray scattering with momentum transfer in the plane of membrane. Application to gramicidin organization.

We demonstrate a technique for measuring x-ray (or neutron) scattering with the momentum transfer confined in the plane of membrane, for the purpose of studying lateral organization of proteins and peptides in membrane. Unlike freeze-fracture electron microscopy or atomic force microscopy which requires the membrane to be frozen or fixed, in-plane x-ray scattering can be performed with the membrane maintained in the liquid crystalline state. As an example, the controversial question of whether gramicidin forms aggregates in membrane was investigated. We used dilauroylphosphatidylcholine (DLPC) bilayers containing gramicidin in the molar ratio of 10:1. Very clear scattering curves reflecting gramicidin channel-channel correlation were obtained, even for the sample containing no heavy atoms. Thallium ions bound to gramicidin channels merely increase the magnitude of the scattering curve. Analysis of the data shows that the channels were randomly distributed in the membrane, similar to a computer simulation of freely moving disks in a plane. We suggest that oriented proteins may provide substantial x-ray contrast against the lipid background without requiring heavy-atom labeling. This should open up many possible new experiments.     

Resonant X-Ray Scattering and Absorption for the Global and Local Structures of Cu-modified Metallothioneins in Solution

With Cd and Zn metal ions removed from the native rabbit-liver metallothionein upon unfolding, Cu-modified metallothioneins (Cu-MTs) were obtained during refolding in solutions containing Cu^I or Cu^II ions. X-ray absorption near-edge spectroscopic results confirm the respectively assigned oxidation states of the copper ions in Cu^I-MT and Cu^II-MT. Global and local structures of the Cu-MTs were subsequently characterized by anomalous small-angle x-ray scattering (ASAXS) and extended x-ray absorption fine structure. Energy-dependent ASAXS results indicate that the morphology of Cu^II-MT resembles that of the native MT, whereas Cu^I-MT forms oligomers with a higher copper content. Both dummy-residue simulation and model-shape fitting of the ASAXS data reveal consistently rodlike morphology for Cu^II-MT. Clearly identified Cu-S, Cu-O, and Cu-Cu contributions in the extended x-ray absorption fine structure analysis indicate that both Cu^I and Cu^II ions are bonded with O and S atoms of nearby amino acids in a four-coordination environment, forming metal clusters smaller than metal thiolate clusters in the native MT. It is demonstrated that a combination of resonant x-ray scattering and x-ray absorption can be particularly useful in revealing complementary global and local structures of metalloproteins due to the atom specific characteristics of the two techniques.     

Purification and properties of membrane-bound methane hydroxylase from <Emphasis Type="Italic">Methylococcus capsulatus</Emphasis> (Strain M)

Membrane fraction of Methylococcus capsulatus (strain M) were treated with [¹⁴C]acetylene, an affinity label binding to the active center of membrane-bound methane monooxygenase (MMO). High-purity particulate form of methane hydroxylase (pMH) was obtained by ion exchange and hydrophobic chromatography. According to SDS-PAGE data, the enzyme contained three polypeptides with molecular weights of 47 (α), 27 (β), and 25 (γ) kDa in the ratio 1: 1: 1. The radiolabel was contained in the β-subunit of pMH. The protein contained 1 or 2 atoms of nonheme iron and 2–4 atoms of copper per a minimum molecular weight of 99 kDa. This protein did not oxidize methane or propylene in the presence of NADH but was able to oxidize low quantities of methane in the presence of duroquinol. It was established that methanol dehydrogenase (MD) and NADH oxidoreductase (NADH-OR) are peripheral membrane proteins. Possible causes of low activity of high-purity methane hydroxylase are discussed.     

NMR of membrane proteins in micelles and bilayers: the FXYD family proteins

Determining the atomic resolution structures of membrane proteins is of particular interest in contemporary structural biology. Helical membrane proteins constitute one-third of the expressed proteins encoded in a genome, many drugs have membrane-bound proteins as their receptors, and mutations in membrane proteins result in human diseases. Although integral membrane proteins provide daunting technical challenges for all methods of protein structure determination, nuclear magnetic resonance (NMR) spectroscopy can be an extremely versatile and powerful method for determining their structures and characterizing their dynamics, in lipid environments that closely mimic the cell membranes. Once milligram amounts of isotopically labeled protein are expressed and purified, micelle samples can be prepared for solution NMR analysis, and lipid bilayer samples can be prepared for solid-state NMR analysis. The two approaches are complementary and can provide detailed structural and dynamic information. This paper describes the steps for membrane protein structure determination using solution and solid-state NMR. The methods for protein expression and purification, sample preparation and NMR experiments are described and illustrated with examples from the FXYD proteins, a family of regulatory subunits of the Na,K-ATPase.     

Structure and location of amiodarone in a membrane bilayer as determined by molecular mechanics and quantitative x-ray diffraction.

Amiodarone is a drug used in the treatment of cardiac arrhythmias and is believed to have a persistent interaction with cellular membranes. This study sought to examine the structure and location of amiodarone in a membrane bilayer. Amiodarone has a high membrane partition coefficient on the order of 10(6). Small angle x-ray diffraction was used to determine the position of the iodine atoms of amiodarone in dipalmitoylphosphatidylcholine (DPPC) lipid bilayers under conditions of low temperature and hydration where the DPPC bilayer is in the gel state. The time-averaged position of the iodine atoms was determined to be approximately 6 A from the center (terminal methyl region) of the lipid bilayer. A dielectric constant of kappa = 2, which approximates that of the bilayer hydrocarbon core region, was used in calculating a minimum energy structure for membrane-bound amiodarone. This calculated structure when compared with the crystal structure of amiodarone demonstrated that amiodarone could assume a conformation in the bilayer significantly different from that in the crystal. The results reported here are an attempt to correlate the position of a membrane-active drug in a lipid bilayer with its time-averaged conformation. This type of analysis promises to be of great use in the design of drugs with greater potency and higher specificity.     

Comparative analysis of the human and chicken prion protein copper binding regions at pH 6.5

Recent experimental evidence supports the hypothesis that prion proteins (PrPs) are involved in the Cu(II) metabolism. Moreover, the copper binding region has been implicated in transmissible spongiform encephalopathies, which are caused by the infectious isoform of prion proteins (PrP(Sc)). In contrast to mammalian PrP, avian prion proteins have a considerably different N-terminal copper binding region and, most interestingly, are not able to undergo the conversion process into an infectious isoform. Therefore, we applied x-ray absorption spectroscopy to analyze in detail the Cu(II) geometry of selected synthetic human PrP Cu(II) octapeptide complexes in comparison with the corresponding chicken PrP hexapeptide complexes at pH 6.5, which mimics the conditions in the endocytic compartments of neuronal cells. Our results revealed that structure and coordination of the human PrP copper binding sites are highly conserved in the pH 6.5-7.4 range, indicating that the reported pH dependence of copper binding to PrP becomes significant at lower pH values. Furthermore, the different chicken PrP hexarepeat motifs display homologous Cu(II) coordination at sub-stoichiometric copper concentrations. Regarding the fully cation-saturated prion proteins, however, a reduced copper coordination capability is supposed for the chicken prion protein based on the observation that chicken PrP is not able to form an intra-repeat Cu(II) binding site. These results provide new insights into the prion protein structure-function relationship and the conversion process of PrP.     

Identification of the missing component in the mitochondrial benzamidoxime prodrug-converting system as a novel molybdenum enzyme

Amidoximes can be used as prodrugs for amidines and related functional groups to enhance their intestinal absorption. These prodrugs are reduced to their active amidines. Other N-hydroxylated structures are mutagenic or responsible for toxic effects of drugs and are detoxified by reduction. In this study, a N-reductive enzyme system of pig liver mitochondria using benzamidoxime as a model substrate was identified. A protein fraction free from cytochrome b5 and cytochrome b5 reductase was purified, enhancing 250-fold the minor benzamidoxime-reductase activity catalyzed by the membrane-bound cytochrome b5/NADH cytochrome b5 reductase system. This fraction contained a 35-kDa protein with homologies to the C-terminal domain of the human molybdenum cofactor sulfurase. Here it was demonstrated that this 35-kDa protein contains molybdenum cofactor and forms the hitherto ill defined third component of the N-reductive complex in the outer mitochondrial membrane. Thus, the 35-kDa protein represents a novel group of molybdenum proteins in eukaryotes as it forms the catalytic part of a three-component enzyme complex consisting of separate proteins. Supporting these findings, recombinant C-terminal domain of the human molybdenum cofactor sulfurase exhibited N-reductive activity in vitro, which was strictly dependent on molybdenum cofactor.     

Characterization of molecules involved in protein translocation using a specific antibody

The vectorial translocation of nascent proteins through the membrane of the rough endoplasmic reticulum has been shown to require a specific membrane-bound protein whose cytoplasmic domain can be proteolytically cleaved and isolated as an active peptide of mol wt 60,000 (Meyer and Dobberstein, 1980, J. Cell Biol. 87:503-508). Rabbit antibodies raised against this peptide were used to further characterize the membrane- bound molecule. Immunoprecipitation of solubilized, radiolabeled rough microsomal proteins yielded a single polypeptide of mol wt 72,000, representing the membrane-bound protein from which the 60,000-mol wt peptide was proteolytically derived. The antibody could also be used to remove exclusively the 60,000-mol wt peptide, and thus the translocation activity, from elastase digests tested in a reconstituted system. Moreover, immunoprecipitation of elastase extracts alkylated with [14C] N-ethylmaleimide selected a single species of mol wt 60,000. Immunoprecipitation of in vivo radiolabeled proteins from the appropriate cell type yielded the 72,000-mol wt membrane protein irrespective of the duration of labeling, or if followed by a chase. Subsequent treatment with protease generated the 60,000-mol wt fragment. In addition, the antibody could be used to visualize reticular structures in intact cells which correspond to endoplasmic reticulum at the ultrastructural level. It is thus clear that one membrane component required in the vectorial translocation of nascent secretory (and membrane) proteins is a peptide of mol wt 72,000.