Bioinformatics in bioinorganic chemistry

Bioinformatics is a central discipline in modern life sciences aimed at describing the complex properties of living organisms starting from large-scale data sets of cellular constituents such as genes and proteins. In order for this wealth of information to provide useful biological knowledge, databases and software tools for data collection, analysis and interpretation need to be developed. In this paper, we review recent advances in the design and implementation of bioinformatics resources devoted to the study of metals in biological systems, a research field traditionally at the heart of bioinorganic chemistry. We show how metalloproteomes can be extracted from genome sequences, how structural properties can be related to function, how databases can be implemented, and how hints on interactions can be obtained from bioinformatics.     

Correlated wavefunction methods in bioinorganic chemistry

In this commentary the challenges faced in the application of wavefunction-based ab initio methods to (open-shell) transition metal complexes of (bio)inorganic interest are briefly touched on. Both single-reference and multireference methods are covered. It is stressed that the generation and nature of the reference wavefunction is a subject of major importance. How erroneous results can be easily obtained even with coupled-cluster theory is illustrated through the example of the septet–quintet separation in iron(IV)–oxo complexes. Second, the interplay between relativistic and correlation effects is important. This is demonstrated with coupled-cluster calculations on models for dinuclear copper active sites, where relativity has a major influence on the relative stabilities of the bis(μ-oxo) and side-on peroxo species.     

Recent advances in bioinorganic chemistry of bismuth

Bismuth has been used in medicine for over two centuries for the treatment of various diseases, in particular for gastrointestinal disorders, owing to its antimicrobial activity. Recent structural characterization of bismuth drugs provides an insight into assembly and pharmacokinetic pathway of the drugs. Mining potential protein targets inside the pathogen via metallomic/metalloproteomic approach and further characterization on the interactions of bismuth drugs with these targets laid foundation in understanding the mechanism of action of bismuth drugs. Such studies would be beneficial in rational design of new potential drugs.     

Redox signaling: bioinorganic chemistry at its best

Oxidative modifications of amino acids in proteins can serve to regulate enzyme activity. This emerging field of redox regulation is related to other cellular signaling pathways, however, neither the chemical mechanisms in the cellular environment nor the affected metabolic and physiological changes are well understood. From data on endotoxin action in vascular tissue and reports on thiol modifications and tyrosine nitrations a unified scheme with five key components is proposed, governed solely by variations in the fluxes of nitrogen monoxide (NO) and superoxide (O(2)(-)). Crucial to the interactions is the formation of peroxynitrite which at concentrations of 10(-9)-10(-6)M elicits events like activation of prostanoid formation, metal catalyzed nitrations and two electron oxidations at cysteines and methionines. As a new concept we postulate that peroxynitrite formed in situ from NO and O(2)(-) is in rapid equilibrium with excess NO to form a nitrosating species that transfers NO(+). The resulting S-nitrosations occur prior to oxidative peroxynitrite action and seem to be involved in the down-regulation of reductive pathways. As the flux of O(2)(-) exceeds the one of NO, cellular damage develops induced by one-electron oxidations caused by nitrogen dioxide and by the Fenton reaction.     

Three-iron clusters in iron-sulfur proteins

Contents. 1. Introduction and history. 2. Characteristic spectroscopic features of 3Fe clusters. 1. General considerations. 2. M?ssbauer spectroscopy. 3. Magnetic circular dichroism (MCD) spectroscopy. 4. Electron paramagnetic resonance (EPR) spectroscopy. 5. Resonance Raman (RR) spectroscopy. 6. Extended X-ray fine-structure (EXAFS) spectroscopy. 3. Results of X-Ray diffraction studies. 4. Proteins containing or showing features characteristic of 3Fe clusters 1. Overview. 2. Ferredoxin I of Azotobacter vinelandii. 3. Ferredoxin II of Desulfovibrio gigas. 4. Aconitase from beef heart. 5. Other observations and considerations relevant to 3Fe clusters or cluster interconversions 1. Oxidative degradation of [4Fe-4S] clusters to 3Fe clusters. 2. Extrusion studies on 3Fe clusters. 3. Reconstitution of 3Fe clusters. 4. Disposition of iron ligands in cluster interconversions. 6. Do all 3Fe clusters have the same structure? Evidence for [3Fe-4S] clusters. 7. Are 3Fe clusters artifacts or biologically significant structures?     

Application of isothermal titration calorimetry in bioinorganic chemistry

The thermodynamics of metals ions binding to proteins and other biological molecules can be measured with isothermal titration calorimetry (ITC), which quantifies the binding enthalpy (ΔH°) and generates a binding isotherm. A fit of the isotherm provides the binding constant (K), thereby allowing the free energy (ΔG°) and ultimately the entropy (ΔS°) of binding to be determined. The temperature dependence of ΔH° can then provide the change in heat capacity (ΔC _p°) upon binding. However, ITC measurements of metal binding can be compromised by undesired reactions (e.g., precipitation, hydrolysis, and redox), and generally involve competing equilibria with the buffer and protons, which contribute to the experimental values (K _ITC, ΔH _ITC). Guidelines and factors that need to be considered for ITC measurements involving metal ions are outlined. A general analysis of the experimental ITC values that accounts for the contributions of metal–buffer speciation and proton competition and provides condition-independent thermodynamic values (K, ΔH°) for metal binding is developed and validated.     

The novel structure and chemistry of iron-sulfur clusters in the adenosylmethionine-dependent radical enzyme biotin synthase

Biotin synthase is an adenosylmethionine-dependent radical enzyme that catalyzes the substitution of sulfur for hydrogen at the saturated C6 and C9 positions in dethiobiotin. The structure of the biotin synthase monomer is an (alpha/beta)(8) barrel that contains one [4Fe-4S](2+) cluster and one [2Fe-2S](2+) cluster that encapsulate the substrates AdoMet and dethiobiotin. The air-sensitive [4Fe-4S](2+) cluster and the reductant-sensitive [2Fe-2S](2+) cluster have unique coordination environments that include close proximity to AdoMet and DTB, respectively. The relative positioning of these components, as well as several conserved protein residues, suggests at least two potential catalytic mechanisms that incorporate sulfur from either the [2Fe-2S](2+) cluster or a cysteine persulfide into the biotin thiophane ring. This review summarizes an accumulating consensus regarding the physical and spectroscopic properties of each FeS cluster, and discusses possible roles for the [4Fe-4S](2+) cluster in radical generation and the [2Fe-2S](2+) cluster in sulfur incorporation.     

Examples of high-frequency EPR studies in bioinorganic chemistry

Low-temperature EPR spectroscopy with frequencies between 95 and 345 GHz and magnetic fields up to 12 T has been used to study metal sites in proteins or inorganic complexes and free radicals. The high-field EPR method was used to resolve g-value anisotropy by separating it from overlapping hyperfine couplings. The presence of hydrogen bonding interactions to the tyrosyl radical oxygens in ribonucleotide reductases were detected. At 285 GHz the g-value anisotropy from the rhombic type 2 Cu(II) signal in the enzyme laccase has its g-value anisotropy clearly resolved from slightly different overlapping axial species. Simple metal site systems with S>1/2 undergo a zero-field splitting, which can be described by the spin Hamiltonian. From high-frequency EPR, the D values that are small compared to the frequency (high-field limit) can be determined directly by measuring the distance of the outermost signal to the center of the spectrum, which corresponds to (2 S-1)* mid R: Dmid R: For example, D values of 0.8 and 0.3 cm(-1) are observed for S=5/2 Fe(III)-EDTA and transferrin, respectively. When D values are larger compared to the frequency and in the case of half-integer spin systems, they can be obtained from the frequency dependence of the shifts of g(eff), as observed for myoglobin in the presence ( D=5 cm(-1)) or absence ( D=9.5 cm(-1)) of fluoride. The 285 and 345 GHz spectra of the Fe(II)-NO-EDTA complex show that it is best described as a S=3/2 system with D=11.5 cm(-1), E=0.1 cm(-1), and g(x)= g(y)= g(z)=2.0. Finally, the effects of HF-EPR on X-band EPR silent states and weak magnetic interactions are demonstrated.     

Heavy metal mutagenicity: insights from bioinorganic model chemistry

The mutagenicity of metal species may be the result of a direct interaction with the target molecule DNA. Possible scenarios leading to nucleobase mispairing are discussed, and selected examples are presented. They include changes in nucleobase selectivity as a consequence of alterations in acid-base properties of nucleobase atoms and groups involved in complementary H bond formation, guanine deprotonation, and stabilization of rare nucleobase tautomers by metal ions. Oxidative nucleobase damage brought about by metal species will not be considered.     

New approaches for medicinal applications of bioinorganic chemistry

Inorganic and bioinorganic chemistry have made important contributions to medical science and human health in the past half century. Today, metal-containing imaging agents and therapeutics constitute a multi-billion dollar industry. Recent discoveries in bioinorganic chemistry of potential biomedical importance include the use of metal ions as synthetic scaffolds for the preparation of small molecule therapeutics, which opens up a new route to molecular structure and diversity, as well as the examination of metal-organic frameworks as biological imaging and drug delivery agents. These areas represent some of the most recent and still relatively unexplored themes in inorganic and bioinorganic chemistry that might be exciting and fruitful topics of study for the community interested in 'metals in medicine'.     

Photoreduction and reoxidation of the three iron-sulfur clusters of reaction centers of green sulfur bacteria

Iron-sulfur clusters are the terminal electron acceptors of the photosynthetic reaction centers of green sulfur bacteria and photosystem I. We have studied electron-transfer reactions involving these clusters in the green sulfur bacterium Chlorobium tepidum, using flash-absorption spectroscopic measurements. We show for the first time that three different clusters, named F(X), F(1), and F(2), can be photoreduced at room temperature during a series of consecutive flashes. The rates of electron escape to exogenous acceptors depend strongly upon the number of reduced clusters. When two or three clusters are reduced, the escape is biphasic, with the fastest phase being 12-14-fold faster than the slowest phase, which is similar to that observed after single reduction. This is explained by assuming that escape involves mostly the second reducible cluster. Evidence is thus provided for a functional asymmetry between the two terminal acceptors F(1) and F(2). From multiple-flash experiments, it was possible to derive the intrinsic recombination rates between P840(+) and reduced iron-sulfur clusters: values of 7, 14, and 59 s(-1) were found after one, two and three electron reduction of the clusters, respectively. The implications of our results for the relative redox potentials of the three clusters are discussed.     

Non-redox roles for iron-sulfur clusters in enzymes

In recent years a number of enzymes have been discovered which, contrary to prior expectations, contain FeS clusters but do not participate in redox reactions. In all cases but one, where the FeS cluster in these enzymes has been identified, it is a [4Fe-4S] cluster. In mammalian aconitase a single Fe atom of the [4Fe-4S] cluster participates in catalysis of hydration-dehydration reactions by direct ligation to the substrates. A number of hydrolyases containing FeS clusters have now been identified. In Bacillus subtilis glutamine phosphoribosyl-pyrophosphate amidotransferase the [4Fe-4S] cluster is essential for the active structure of the enzyme, but probably does not participate directly in catalysis. Rather, the cluster may serve as part of a mechanism of oxidative inactivation of the enzyme in vivo, which is followed by its intracellular degradation. The role played by a [4Fe-4S] cluster in Escherichia coli endonuclease III is at present completely unknown. Thus, a number of novel roles for FeS clusters in enzymology and protein structure have been discovered, and more novel findings must be anticipated.     

The coupled-cluster description of electronic structure: perspectives for bioinorganic chemistry

This commentary provides an overview of the challenges and strengths of coupled-cluster theory when applied to active sites of metalloproteins. It is argued that thanks to increases in computer power and remarkable methodological developments, coupled-cluster methods will make increasingly important contributions to understanding the structure, properties and reactivity of transition metal cofactors.