Cadmium toxicity in animal cells by interference with essential metals.

Cadmium is found in the environment as part of several, mainly zinc-rich, ores. It has been used in many technological applications, but biological systems generally failed to safely deal with this element. In mammalian biology, cadmium exposure jeopardizes health and mechanisms of cadmium toxicity are multifarious. Mainly because bioavailable cadmium mimics other metals that are essential to diverse biological functions, cadmium follows a Trojan horse strategy to get assimilated. Metals susceptible to cadmium deceit include calcium, zinc, and iron. The wealth of data addressing cadmium toxicity in animal cells is briefly reviewed with special emphasis on disturbance of the homeostasis of calcium, zinc, and iron. A limited number of tissues and cell types are considered as main targets for cadmium toxicity. Still, the diversity of pathways affected by cadmium exposure points to a more general threat to basic cellular functions. The poor efficiency of cellular export systems for cadmium explains the long residence time of the element in mammals. Therefore, proper disposal and educated uses of this technologically appealing, but biologically malicious, element should be favored in the future. The comprehensive knowledge of cadmium biological effects is indeed a necessary step to protect human and animal populations from environmental and anthropological exposures.

Crystallization and preliminary X-ray diffraction data for the aconitase form of human iron-regulatory protein 1.

Iron-regulatory proteins (IRPs) 1 and 2 are closely related molecules involved in animal iron metabolism. Both proteins can bind to specific mRNA regions called iron-responsive elements and thereby control the expression of proteins involved in the uptake, storage and utilization of iron. In iron-replete cells, IRP1, but not IRP2, binds a [4Fe-4S] cluster and functions as a cytoplasmic aconitase, with simultaneous loss of its RNA-binding ability. Whereas IRP2 is known to be involved in Fe homeostasis, the role of IRP1 is less clear; it may provide a link between citrate and iron metabolisms and be involved in oxidative stress response. Here, two crystal forms of the aconitase version of recombinant human IRP1 are reported. An X-ray fluorescence measurement performed on a gold-derivative crystal showed the unexpected presence of zinc, in addition to gold and iron. Both native and MAD X-ray data at the Au, Fe and Zn absorption edges have been collected from these crystals.

Intramolecular electron transfer in [4Fe-4S] proteins: estimates of the reorganization energy and electronic coupling in Chromatium vinosum ferredoxin.

The semi-classical electron transfer theory has been very successful in describing reactions occurring in biological systems, but the relevant parameters in the case of iron-sulfur proteins remain unknown. The recent discovery that 2[4Fe-4S] proteins homologous to Chromatium vinosum ferredoxin contain clusters with different reduction potentials now gives the opportunity to study the dependence of the intramolecular electron transfer rate between these clusters as a function of the driving force. This work shows how decreasing the reduction potential difference between the clusters by site-directed mutagenesis of C. vinosum ferredoxin modifies the rate of electron hopping between the two redox sites of the protein by measuring the line broadening of selected 1H NMR signals. Beside the shifts of the reduction potentials, no signs of large structural changes or of significant alterations of the intrinsic kinetic parameters among the different variants of C. vinosum ferredoxin have been found. A reorganization energy of less than 0.5 eV was deduced from the dependence of the electron transfer rates with the reduction potential difference. This small value is associated with a weak electronic coupling between the two closely spaced clusters. This set of parameters, determined for the first time in an iron-sulfur protein, may help to explain how efficient vectorial electron transfer occurs with a small driving force in the many enzymatic systems containing a 2[4Fe-4S] domain.

Electron transfer properties of iron-sulfur proteins.

The details of most electron transfer reactions involving iron-sulfur proteins have remained undisclosed because of the lack of experimental methods suitable to measure precisely the relevant rates. Nuclear magnetic resonance (NMR) provides a powerful means to overcome these problems, at least with selected proteins. A combination of NMR studies and site-directed mutagenesis experiments has been instrumental in defining both the site of interaction and the main trends of the intracomplex electron transfer in the case of rubredoxin electron self-exchange. Analysis of the NMR data obtained for mixtures of different redox levels of several 2[4Fe-4S] ferredoxins provided both first-order, for intramolecular, and second-order, for intermolecular, rate constants. Their dependence as a function of structural changes gave insight into the mechanism of electron transfer in this type of protein. Contrary to some expectations, the high-spin [4Fe-4Se]+ clusters assembled in isopotential ferredoxins do not change the intramolecular electron transfer rate as compared to low-spin [4Fe-4S]+ homologs. In combination with activity measurements, the kinetic data have been used to model the electron transfer competent complexes between Clostridium pasteurianum ferredoxin and the main enzymes acting as redox partners in vivo.

Periplasmic electron carriers and photo-induced electron transfer in the photosynthetic bacterium Ectothiorhodospira sp.

A detailed analysis of the periplasmic electron carriers of the photosynthetic bacterium Ectothiorhodospira sp. has been performed. Two low mid-point redox potential electron carriers, cytochrome c' and cytochrome c, are detected. A high potential iron-sulfur protein is the only high mid-point redox potential electron transfer component present in the periplasm. Analysis of light-induced absorption changes shows that this high potential iron-sulfur protein acts in vivo as efficient electron donor to the photo-oxidized high potential heme of the Ectothiorhodospira sp. reaction center.

Human cytoplasmic aconitase (Iron regulatory protein 1) is converted into its [3Fe-4S] form by hydrogen peroxide in vitro but is not activated for iron-responsive element binding.

Iron regulatory protein 1 (IRP1) regulates the synthesis of proteins involved in iron homeostasis by binding to iron-responsive elements (IREs) of messenger RNA. IRP1 is a cytoplasmic aconitase when it contains a [4Fe-4S] cluster and an RNA-binding protein after complete removal of the metal center by an unknown mechanism. Human IRP1, obtained as the pure recombinant [4Fe-4S] form, is an enzyme as efficient toward cis-aconitate as the homologous mitochondrial aconitase. The aconitase activity of IRP1 is rapidly lost by reaction with hydrogen peroxide as the [4Fe-4S] cluster is quantitatively converted into the [3Fe-4S] form with release of a single ferrous ion per molecule. The IRE binding capacity of IRP1 is not elicited with H(2)O(2). Ferrous sulfate (but not other more tightly coordinated ferrous ions, such as the complex with ethylenediamine tetraacetic acid) counteracts the inhibitory action of hydrogen peroxide on cytoplasmic aconitase, probably by replenishing iron at the active site. These results cast doubt on the ability of reactive oxygen species to directly increase IRP1 binding to IRE and support a signaling role for hydrogen peroxide in the posttranscriptional control of proteins involved in iron homeostasis in vivo.

Unusual NMR, EPR, and Mössbauer properties of Chromatium vinosum 2[4Fe-4S] ferredoxin.

The ferredoxin from Chromatium vinosum (CvFd) exhibits sequence and structure peculiarities. Its two Fe4S4(SCys)4 clusters have unusually low potential transitions that have been unambiguously assigned here through NMR, EPR, and Mössbauer spectroscopy in combination with site-directed mutagenesis. The [4Fe-4S]2+/1+ cluster (cluster II) whose coordination sphere includes a two-turn loop between cysteines 40 and 49 was reduced by dithionite with an E degrees ' of -460 mV. Its S = 1/2 EPR signal was fast relaxing and severely broadened by g-strain, and its Mössbauer spectra were broad and unresolved. These spectroscopic features were sensitive to small perturbations of the coordination environment, and they were associated with the particular structural elements of CvFd, including the two-turn loop between two ligands and the C-terminal alpha-helix. Bulk reduction of cluster I (E degrees ' = -660 mV) was not possible for spectroscopic studies, but the full reduction of the protein was achieved by replacing valine 13 with glycine due to an approximately 60 mV positive shift of the potential. At low temperatures, the EPR spectrum of the fully reduced protein was typical of two interacting S = 1/2 [4Fe-4S]1+ centers, but because the electronic relaxation of cluster I is much slower than that of cluster II, the resolved signal of cluster I was observed at temperatures above 20 K. Contact-shifted NMR resonances of beta-CH2 protons were detected in all combinations of redox states. These results establish that electron transfer reactions involving CvFd are quantitatively different from similar reactions in isopotential 2[4Fe-4S] ferredoxins. However, the reduced clusters of CvFd have electronic distributions that are similar to those of clusters coordinated by the CysIxxCysIIxxCysIII.CysIVP sequence motif found in other ferredoxins with different biochemical properties. In all these cases, the electron added to the oxidized clusters is mainly accommodated in the pair of iron ions coordinated by CysII and CysIV.

The two [4Fe-4S] clusters in Chromatium vinosum ferredoxin have largely different reduction potentials. Structural origin and functional consequences.

The 2[4Fe-4S] ferredoxin from Chromatium vinosum arises as one prominent member of a recently defined family of proteins found in very diverse bacteria. The potentiometric circular dichroism titrations of the protein and of several molecular variants generated by site-directed mutagenesis have established that the reduction potentials of the two clusters differ widely by almost 200 mV. This large difference has been confirmed by electrochemical methods, and each redox transition has been assigned to one of the clusters. The unusually low potential center is surprisingly the one that displays a conventional CX1X2CX3X4C (Xn, variable amino acid) binding motif and a structural environment similar to that of clusters having less negative potentials. A comparison with other ferredoxins has highlighted factors contributing to the reduction potential of [4Fe-4S] clusters in proteins. (i) The loop between the coordinating cysteines 40 and 49 and the C terminus alpha-helix of C. vinosum ferredoxin cause a negative, but relatively moderate, shift of approximately 60 mV for the nearby cluster. (ii) Very negative potentials, below -600 mV, correlate with the presence of a bulky side chain in position X4 of the coordinating triad of cysteines. These findings set the framework in which previous observations on ferredoxins can be better understood. They also shed light onto the possible occurrence and properties of very low potential [4Fe-4S] clusters in less well characterized proteins.

Intramolecular electron transfer between [4Fe-4S] clusters studied by proton magnetic resonance spectroscopy.

The rate constants for the intramolecular electron transfer between the two [4Fe-4S] clusters of a series of native and genetically engineered ferredoxins have been determined by proton magnetic resonance (1H NMR) spectroscopy. The measurement relies on the properties of the signals assigned to beta-protons of the coordinating cysteines when the protein is substoichiometrically reduced: these signals include coalesced peaks arising from the fast hopping of an extra electron between the two oxidized clusters of the protein. An upper limit of significantly less than 10(5) M(-1) s(-1) for the intermolecular and an average of the order of 5 x 10(6) s(-1) for the intramolecular electron transfer rate constants of several ferredoxins have been obtained. Owing to the edge-to-edge intercluster distance of approximately 10 A derived from the crystallographic structure of Clostridium acidurici ferredoxin, the rate constant associated with the intramolecular process is as expected for a nonadiabatic redox process, assuming a reasonable value of less than 1 eV for the reorganization energy. The latter could not be determined from the temperature dependence of the rate constant since no variation was observed over the temperature range accessible in these experiments. Structural changes introduced around and between the two [4Fe-4S] clusters in Clostridium pasteurianum ferredoxin by site-directed mutagenesis have been used to probe the potential involvement of dominant electron transfer pathways between the clusters. These changes have no major effect on the value of the intramolecular electron transfer rate constant. From this analysis, no specific amino acid side chain seems to play a central role in the process. The rate constants derived in the present work may serve as a basis for the study of enzymes containing two closely spaced [4Fe-4S] clusters such as found in these ferredoxins.

Site-directed mutagenesis of rubredoxin reveals the molecular basis of its electron transfer properties.

Rubredoxins contain a single non-heme iron atom coordinated by four cysteines. This iron is redox active and confers a role to these proteins in electron transfer chains. The structural features responsible for setting the values of the reduction potential and of the electron self-exchange rate constant have been probed by site-directed mutagenesis. Replacements of the highly conserved residues in positions 8, 10, and 11 (valine, glycine, and tyrosine, respectively) all lead to shifts of the reduction potential, up to 75 mV. These cannot be explained by simple considerations about the physicochemical properties of the substituting side chains but rather indicate that the value of the reduction potential is finely tuned by a variety of interactions. In contrast, the electron self exchange rate constant measured by nuclear magnetic resonance does not vary much, except when a charged residue is included in position 8 or 10, at the surface of the protein closest to the iron atom. Analysis of the data with a model for electrostatic interactions, including both monopolar and dipolar terms, indicates that the presence of a charge in this region not only increases the repulsion between molecules but also affects the electron transfer efficiency of the bimolecular complexes formed. The studies presented constitute a first step toward probing the structural elements modulating the reactivity of the FeS4 unit in a protein and defining the electron transfer active site(s) of rubredoxin.

Atomic resolution (0.94 A) structure of Clostridium acidurici ferredoxin. Detailed geometry of [4Fe-4S] clusters in a protein.

The crystal structure of the 2[4Fe-4S] ferredoxin from Clostridium acidurici has been solved using X-ray diffraction data extending to atomic resolution, 0.94 A, recorded at 100 K. The model was refined with anisotropic representation of atomic displacement parameters for all non-hydrogen atoms and with hydrogens riding on their parent atoms. Stereochemical restraints were applied to the protein chain but not to the iron-sulfur clusters. The final R factor is 10.03 % for all data. Inversion of the final least-squares matrix allowed direct estimation of the errors of individual parameters. The estimated errors in positions for protein main chain atoms are below 0.02 A and about 0.003 A for the heavier [4Fe-4S] cluster atoms. Significant differences between the stereochemistry of the two clusters and distortion of both of them from ideal Td tetrahedral symmetry can be defined in detail at this level of accuracy. Regions of alternative conformations include not only protein side chains but also two regions of the main chain. One such region is the loop of residues 25-29, which was highly disordered in the room temperature structure.

Use of 1H longitudinal relaxation times in the solution structure of paramagnetic proteins. Application to [4Fe-4S] proteins.

The accuracy of the solution structures determined by NMR is often poor around paramagnetic centers because the properties of the near protons are strongly perturbed by the electronic spin. The structural information contained in the relaxation rates of these protons has been extracted here by measuring the longitudinal relaxation times with the inversion-recovery total correlation spectroscopy (IR-TOCSY) sequence based on the recovery of cross peaks. In addition to measurements with nonselective inversion-recovery for nonoverlapping signals, reliable data have been obtained for a majority of main-chain protons from Chromatium vinosum high-potential ferredoxin. When a small and constant contribution from diamagnetism as well as the electronic spin distribution over the [4Fe-4S] cluster are taken into account, the shortest longitudinal relaxation times depend directly on the distance separating the protons from the paramagnetic center. This indicates that electron-nuclei dipolar interactions are the most efficient relaxation mechanism for these protons. However, the expected dependence of the relaxation rates as the sixth power of the distance has to be corrected because of induced relaxation among fast relaxing protons. This approach reveals that the solution structure of the protein is significantly different from the crystal structure around Phe-48. In addition, it provides an independent confirmation of the actual electronic structure of the [4Fe-4S]3+ cluster in the protein. The method devised in this work, which does not rely on specific enrichment, should be useful to improve the determination of NMR-derived solution structures of paramagnetic macromolecules.

Crystal structure of the 2[4Fe-4S] ferredoxin from Chromatium vinosum: evolutionary and mechanistic inferences for [3/4Fe-4S] ferredoxins.

The crystal structure of the 2[4Fe-4S] ferredoxin from Chromatium vinosum has been solved by molecular replacement using data recorded with synchrotron radiation. The crystals were hexagonal prisms that showed a strong tendency to develop into long tubes. The hexagonal prisms diffracted to 2.1 A resolution at best, and a structural model for C. vinosum ferredoxin has been built with a final R of 19.2%. The N-terminal domain coordinates the two [4Fe-4S] clusters in a fold that is almost identical to that of other known ferredoxins. However, the structure has two unique features. One is a six-residue insertion between two ligands of one cluster forming a two-turn external loop; this short loop changes the conformation of the Cys 40 ligand compared to other ferredoxins and hampers the building of one NH...S H-bond to one of the inorganic sulfurs. The other remarkable structural element is a 3.5-turn alpha-helix at the C-terminus that covers one side of the same cluster and is linked to the cluster-binding domain by a six-residue external chain segment. The charge distribution is highly asymmetric over the molecule. The structure of C. vinosum ferredoxin strongly suggests divergent evolution for bacterial [3/4Fe-4S] ferredoxins from a common ancestral cluster-binding core. The unexpected slow intramolecular electron transfer rate between the clusters in C. vinosum ferredoxin, compared to other similar proteins, may be attributed to the unusual electronic properties of one of the clusters arising from localized changes in its vicinity rather than to a global structural rearrangement.

Zinc- and iron-rubredoxins from Clostridium pasteurianum at atomic resolution: a high-precision model of a ZnS4 coordination unit in a protein.

The Zn(Scys)4 unit is present in numerous proteins, where it assumes structural, regulatory, or catalytic roles. The same coordination is found naturally around iron in rubredoxins, several structures of which have been refined at resolutions of, or near to, 1 A. The fold of the small protein rubredoxin around its metal ion is an excellent model for many zinc finger proteins. Zn-substituted rubredoxin and its Fe-containing counterpart were both obtained as the products of the expression in Escherichia coli of the rubredoxin-encoding gene from Clostridium pasteurianum. The structures of both proteins have been refined with an anisotropic model at atomic resolution (1.1 A, R = 8.3% for Fe-rubredoxin, and 1.2 A, R = 9.6% for Zn-rubredoxin) and are very similar. The most significant differences are increased lengths of the M-S bonds in Zn-rubredoxin (average length, 2.345 A) as compared with Fe-rubredoxin (average length, 2.262 A). An increase of the CA-CB-SG-M dihedral angles involving Cys-6 and Cys-39, the first cysteines of each of the Cys-Xaa-Xaa-Cys metal binding motifs, has been observed. Another consequence of the replacement of iron by zinc is that the region around residues 36-46 undergoes larger displacements than the remainder of the polypeptide chain. Despite these changes, the main features of the FeS4 site, namely a local 2-fold symmetry and the characteristic network of N-H...S hydrogen bonds, are conserved in the ZnS4 site. The Zn-substituted rubredoxin provides the first precise structure of a Zn(Scys)4 unit in a protein. The nearly identical fold of rubredoxin around iron or zinc suggests that at least in some of the sites where the metal has mainly a structural role-e.g., zinc fingers-the choice of the relevant metal may be directed by its cellular availability and mobilization processes rather than by its chemical nature.

Molecular cloning and expression of the gene encoding Chromatium vinosum 2[4Fe-4S] ferredoxin.

The gene encoding Chromatium vinosum 2[4Fe-4S] ferredoxin has been cloned and expressed in Escherichia coli. It is flanked by a gene starting with the rare codon UUG and homologous to E. coli kdtB. Chromatium vinosum ferredoxin may represent a new sub-class of iron-sulfur proteins widely distributed among diverse, including non-photosynthetic, bacteria.

The influence of conserved aromatic residues on the electron transfer reactivity of 2[4Fe-4S] ferredoxins.

The detailed mechanism used by [4Fe-4S] ferredoxins to exchange electrons is not known. The importance of two highly conserved aromatic residues, each located close to one cluster of 2[4Fe-4S] ferredoxins has been probed by site-directed mutagenesis of Clostridium pasteurianum ferredoxin. All generated variants are less stable than the native protein and only hydrophobic residues can replace one of the two conserved aromatic residues. With leucine substituting both aromatics, Clostridium pasteurianum ferredoxin cannot even be completely purified because of its deleterious instability. The reduction potentials of Clostridium pasteurianum ferredoxin variants do not depend on the presence of aromatic residues near the clusters. However, the ferredoxin from Entamoeba histolytica which is naturally devoid of aromatic residues displays a reduction potential nearly 60 mV less negative than that of Clostridium pasteurianum ferredoxin. The rate constants for the oxidation of the reduced ferredoxins by the inorganic complexes hexaamine-cobalt(III) chloride and sodium ethylenediaminetetra-acetatecobaltate(III) are similar. This implies that electron transfer from the clusters of these molecules is not mediated by the conserved aromatic residues. These residues rather appear to be involved in maintaining the overall stability of ferredoxins.

Nuclear-magnetic-resonance determination of the electron self-exchange rate constant of Clostridium pasteurianum rubredoxin.

The iron ion of rubredoxins efficiently exchanges one electron between the Fe(II) and Fe(III) oxidation states in mixtures of oxidized and reduced protein. The conditions under which the relaxation properties of the NMR signals can provide information about this exchange process have been worked out. The rate constant for the rubredoxin electron self-exchange ranges between 1.5 x 10(5) M-1 s-1 at 12 degrees C and 3 x 10(5) M-1 s-1 at 30 degrees C with an activation energy of the order of 24-30 kJ mol-1 in 50 mM potassium phosphate, pH 7. The increase of the electron self-exchange rate constant with ionic strength suggests that neutralizing electrostatic repulsion between the active sites of two molecules further accelerates the already fast electron exchange.

Molecular mechanism of pyruvate-ferredoxin oxidoreductases based on data obtained with the Clostridium pasteurianum enzyme.

Pyruvate-ferredoxin oxidoreductase oxidises pyruvate in many fermentative microorganisms. The enzyme from Clostridium pasteurianum is an air-sensitive homodimer of 2x120000 daltons, for which pyruvate is the best substrate found among several alpha-ketoacids. Each subunit contains eight iron atoms in two [4Fe-4S] clusters. Two distinct EPR signals, possibly associated with two ligand environments, arise from one of these clusters. Binding of pyruvate does not generate a radical. The results reported suggest a scheme for the electron flow in pyruvate ferredoxin oxidoreductases according to which the detailed reaction mechanism depends on the number (even or odd) of [4Fe-4S] clusters present in a given enzyme.

Probing the role of electrostatic forces in the interaction of Clostridium pasteurianum ferredoxin with its redox partners.

The ability of several low-potential redox proteins to mediate electron transfer between Clostridium pasteurianum pyruvate-ferredoxin oxidoreductase and hydrogenase has been evaluated in a coupled enzymatic assay. The active electron mediators, whatever their structure, must have a reduction potential compatible with the two enzymes, but for proteins of similar potentials, a marked specificity is displayed by 2[4Fe-4S] ferredoxins of the clostridial type. Such ferredoxins are small proteins exchanging electrons with many enzymes involved in the metabolism of anaerobic bacteria. The forces underlying the interactions of ferredoxin with hydrogenase and pyruvate-ferredoxin oxidoreductase have been examined with an emphasis on electrostatics: site-directed mutagenesis experiments have been used to individually convert all conserved glutamates and aspartates of C. pasteurianum ferredoxin into either neutral or positively charged amino acids. Also, up to four of these residues have been replaced simultaneously. The biological activities of the resulting variants depend very little on the number and the distribution of the anionic side chains on the surface of the ferredoxin. Only those molecular forms for which the immediate environment of the clusters is perturbed, independently of the charge distribution, display variations in their catalytic properties. It is concluded that electron transfer between C. pasteurianum 2[4Fe-4S] ferredoxin and its partners is far less dependent on electrostatic interactions than in many other well-documented electron transfer systems.

Observation of holoprotein molecular ions of several ferredoxins by electrospray-ionization-mass spectrometry.

Several ferredoxins containing [4Fe-4S] or [2Fe-2S] active sites have been analyzed by electrospray-ionization-mass spectrometry. For these acidic proteins, low pH conditions must be implemented in order to ensure strong signals in positive-ionization mode. Under such conditions the iron-sulfur active sites were lost in most cases. In contrast, the holoproteins were preserved under negative-ionization mode conditions: they were weakly but sufficiently ionized and information about their cofactor content could be obtained. The experimental conditions set up here should provide a useful basis for the detailed characterization of more complex iron-sulfur proteins.