Protein-derived cofactors. Expanding the scope of post-translational modifications

Recent advances in enzymology, structural biology, and protein chemistry have extended the scope of the field of cofactor-dependent enzyme catalysis. It has been documented that catalytic and redox-active prosthetic groups may be derived from post-translational modification of amino acid residues of proteins. These protein-derived cofactors typically arise from the oxygenation of aromatic residues, covalent cross-linking of amino acid residues, or cyclization or cleavage of internal amino acid residues. In some cases, the post-translation modification is a self-processing event, whereas in others, another processing enzyme is required. The characterization of protein-derived cofactors and their mechanisms of biogenesis introduce a new dimension to our current views about protein evolution and protein structure-function relationships.     

Protein dynamics and enzyme catalysis: the ghost in the machine?

One of the most controversial questions in enzymology today is whether protein dynamics are significant in enzyme catalysis. A particular issue in these debates is the unusual temperature-dependence of some kinetic isotope effects for enzyme-catalysed reactions. In the present paper, we review our recent model [Glowacki, Harvey and Mulholland (2012) Nat. Chem. 4, 169-176] that is capable of reproducing intriguing temperature-dependences of enzyme reactions involving significant quantum tunnelling. This model relies on treating multiple conformations of the enzyme-substrate complex. The results show that direct 'driving' motions of proteins are not necessary to explain experimental observations, and show that enzyme reactivity can be understood and accounted for in the framework of transition state theory.     

Micellar enzymology: potentialities in fundamental and applied areas

Micellar enzymology, a new trend in molecular biology, studies catalysis by enzymes entrapped in hydrated reversed micelles of surfactants (phospholipids, detergents) in organic solvents. In this review, the key research problems of micellar enzymology are formulated and examples of biocatalysis in microheterogeneous media are discussed. In particular, new applications are presented of micellar enzymology in fine organic syntheses, in clinical and chemical analyses (bioluminescence and enzyme immunoassays), in bioconversion of energy and mass, in therapy (engineering of new drugs capable of targeted penetration into cells), as well as in biotechnology (processes using nanogranulated or nanocapsulated enzymes).     

Mechanisms of cytochrome P-450 catalysis

Cytochrome P-450 (P-450) enzymes catalyze the oxidation of a wide variety of substrates. Although a large number of P-450s have been characterized in different species and tissues, the mechanisms of catalysis of oxygenation may be understood in terms of a few basic principles. The chemistry is dominated by the ability of a high-valent formal (FeO)3+ species to carry out one-electron oxidations through the abstraction of hydrogen atoms, abstraction of electrons in n or pi orbitals, or the addition to pi bonds. A series of radical recombination reactions then completes the oxidation process. The protein structures are postulated to provide the axial thiolate ligand to the heme, to control the juxtaposition of the substrate (and therefore the regio- and stereoselectivity of oxidation), to alter the effective oxidation potential of the (FeO)3+ complex, and possibly to participate in specific acid/base catalysis in the oxidation of some substrates.     

The second E.C. Slater lecture. Micellar enzymology: its relation to membranology

Micellar enzymology, a new trend in molecular biology, studies catalysis by enzymes entrapped in hydrated reversed micelles composed of surfactants (phospholipids, detergents) in organic solvents. The key research problems of micellar enzymology and its relation to enzyme membranology 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.     

Mechanisms of cytochrome P450 substrate oxidation: MiniReview

Cytochrome P450 (P450) enzymes catalyze a variety of oxidation and some reduction reactions, collectively involving thousands of substrates. A general chemical mechanism can be used to rationalize most of the oxidations and involves a perfenyl intermediate (FeO3+) and odd-electron chemistry, i.e. abstraction of a hydrogen atom or electron followed by oxygen rebound and sometimes rearrangement. This general mechanism can explain carbon hydroxylation, heteroatom oxygenation and dealkylation, epoxidation, desaturation, heme destruction, and other reactions. Another approach to understanding catalysis involves analysis of the more general catalytic cycle, including substrate specificity, because complex patterns of cooperativity are observed with several P450s. Some of the complexity is due to slow conformational changes in the proteins that occur on the same timescale as other steps.     

Mechanisms and structures of vitamin B(6)-dependent enzymes involved in deoxy sugar biosynthesis

PLP is well-regarded for its role as a coenzyme in a number of diverse enzymatic reactions. Transamination, deoxygenation, and aldol reactions mediated by PLP-dependent enzymes enliven and enrich deoxy sugar biosynthesis, endowing these compounds with unique structures and contributing to their roles as determinants of biological activity in many natural products. The importance of deoxy aminosugars in natural product biosynthesis has spurred several recent structural investigations of sugar aminotransferases. The structure of a PMP-dependent enzyme catalyzing the C-3 deoxygenation reaction in the biosynthesis of ascarylose was also determined. These studies, and the crystal structures they have provided, offer a wealth of new insights regarding the enzymology of PLP/PMP-dependent enzymes in deoxy sugar biosynthesis. In this review, we consider these recent achievements in the structural biology of deoxy sugar biosynthetic enzymes and the important implications they hold for understanding enzyme catalysis and natural product biosynthesis in general. This article is part of a Special Issue entitled: Pyridoxal Phosphate Enzymology.     

Protein dynamics and enzyme catalysis: insights from simulations

The role of protein dynamics in enzyme catalysis is one of the most active and controversial areas in enzymology today. Some researchers claim that protein dynamics are at the heart of enzyme catalytic efficiency, while others state that dynamics make no significant contribution to catalysis. What is the biochemist - or student - to make of the ferocious arguments in this area? Protein dynamics are complex and fascinating, as molecular dynamics simulations and experiments have shown. The essential question is: do these complex motions have functional significance? In particular, how do they affect or relate to chemical reactions within enzymes, and how are chemical and conformational changes coupled together? Biomolecular simulations can analyse enzyme reactions and dynamics in atomic detail, beyond that achievable in experiments: accurate atomistic modelling has an essential part to play in clarifying these issues. This article is part of a Special Issue entitled: Protein Dynamics: Experimental and Computational Approaches.     

Reactions of *NO, *NO2 and peroxynitrite in membranes: physiological implications

Nitric oxide (^·NO) and nitrogen dioxide (^·NO₂) are hydrophobic gases. Therefore, lipid membranes and hydrophobic regions of proteins are potential sinks for these species. In these hydrophobic environments, reactive nitrogen species will exhibit different chemistry than in aqueous environments due to higher local concentrations and the lack of hydrolysis reactions. The peroxynitrite anion (ONOO^-) and peroxynitrous acid (ONOOH) can freely pass through lipid membranes, making peroxynitrite-mediated reactions in a hydrophobic environment also of extreme relevance. The reactions observed by these reactive nitrogen species in a hydrophobic milieu include oxidation, nitration and even potent chain-breaking antioxidant reactions. The physiological and toxicological relevance of these reactions is discussed.     

氨氧化古菌的生态学研究进展

上百年来细菌一直被认为是地球氨氧化过程的主要驱动者,2005年海洋中分离到迄今唯一的非极端环境泉古菌,发现其氧化氨态氮获得能源生长,是氨氧化古菌。氨氧化古菌和细菌对地球氨氧化过程的相对贡献率,是目前全球氮循环研究最重要的微生物生态学问题之一。已有的证据表明古菌在海洋氨氧化过程中发挥了重要作用,细菌则是土壤氨氧化过程的主要驱动者。本文重点探讨了原位自然环境下氨氧化古菌的生态学研究进展。     

湖泊氮素氧化及脱氮过程研究进展

自然界中氮的生物地球化学循环主要由微生物驱动,由固氮作用、硝化作用、反硝化作用和氨化作用来完成。过去数十年间,随着异养硝化、厌氧氨氧化和古菌氨氧化作用的发现,人们对环境中氮素循环认识逐步深入,提出了多种脱氮途径新假说。对湖泊生态系统中氮素的输入、输出及其在水体、沉积物和水土界面的迁移转化过程进行了概括,对湖泊生态系统中反硝化和厌氧氨氧化脱氮机理及脱氮效率的最新研究进展进行了探讨,并对以后的氮素循环研究进行了展望。     

The chemistry of cell signaling by reactive oxygen and nitrogen species and 4-hydroxynonenal

During the past several years, major advances have been made in understanding how reactive oxygen species (ROS) and nitrogen species (RNS) participate in signal transduction. Identification of the specific targets and the chemical reactions involved still remains to be resolved with many of the signaling pathways in which the involvement of reactive species has been determined. Our understanding is that ROS and RNS have second messenger roles. While cysteine residues in the thiolate (ionized) form found in several classes of signaling proteins can be specific targets for reaction with H₂O₂ and RNS, better understanding of the chemistry, particularly kinetics, suggests that for many signaling events in which ROS and RNS participate, enzymatic catalysis is more likely to be involved than non-enzymatic reaction. Due to increased interest in how oxidation products, particularly lipid peroxidation products, also are involved with signaling, a review of signaling by 4-hydroxy-2-nonenal (HNE) is included. This article focuses on the chemistry of signaling by ROS, RNS, and HNE and will describe reactions with selected target proteins as representatives of the mechanisms rather attempt to comprehensively review the many signaling pathways in which the reactive species are involved.     

Protein Dynamics Control the Progression and Efficiency of the Catalytic Reaction Cycle of the Escherichia coli DNA-Repair Enzyme AlkB

A central goal of enzymology is to understand the physicochemical mechanisms that enable proteins to catalyze complex chemical reactions with high efficiency. Recent methodological advances enable the contribution of protein dynamics to enzyme efficiency to be explored more deeply. Here, we utilize enzymological and biophysical studies, including NMR measurements of conformational dynamics, to develop a quantitative mechanistic scheme for the DNA repair enzyme AlkB. Like other iron/2-oxoglutarate-dependent dioxygenases, AlkB employs a two-step mechanism in which oxidation of 2-oxoglutarate generates a highly reactive enzyme-bound oxyferryl intermediate that, in the case of AlkB, slowly hydroxylates an alkylated nucleobase. Our results demonstrate that a microsecond-to-millisecond time scale conformational transition facilitates the proper sequential order of substrate binding to AlkB. Mutations altering the dynamics of this transition allow generation of the oxyferryl intermediate but promote its premature quenching by solvent, which uncouples 2-oxoglutarate turnover from nucleobase oxidation. Therefore, efficient catalysis by AlkB depends upon the dynamics of a specific conformational transition, establishing another paradigm for the control of enzyme function by protein dynamics.     

Molybdenum in enzymatic and heterogeneous catalysis

The chemistry common to molybdenum at the active centers of molybdoenzymes and at the surface of heterogeneous catalysts is described. Oxomolybdenum(VI) compounds catalyze selective oxidation of unsaturated hydrocarbons, e.g., propene to acrolein. Similarly, oxomolybdenum species take part in reactions catalyzed by molybdoenzymes, e.g., xanthine oxidase, sulfite oxidase, nitrate reductase. In these reactions H+, O2- or HO-, and electrons transfer between substrate molecules and molybdenum atoms and groups at the active centres. The chemistry involved is the acid-base and redox chemistry of molybdenum. Molybdenum disulfide catalyzes hydrogenation of unsaturated hydrocarbons, e.g., acetylene. The active site is a coordinately unsaturated molybdenum atom in a sulfur-ligand environment. The enzyme nitrogenase, which is a protein-bound iron-molybdenum sulfide, is also an excellent hydrogenation catalyst. Both catalysts exploit the chemistry of lower-valent molybdenum coordinated by sulfur. The extent to which understanding of the catalysis can be transferred between the two types of catalyst is assessed.     

C(alpha)-tetrasubstituted amino acid based peptides in asymmetric catalysis

C(alpha)-tetrasubstituted alpha-amino acids constitute a powerful tool for controlling the conformation of short peptide sequences. Chiral peptides may be used in stereoselective reactions both for asymmetric induction and in kinetic resolution. By reviewing recent data from our own laboratories and by presenting new results on the stereoselective oxidation of chalcone to the corresponding oxide, this contribution shows that the control of peptide conformation is a critical issue in order to achieve successful stereoselective catalysis.     

Structural biology of proteins involved in nitrogen cycling

Microbial metabolic processes drive the global nitrogen cycle through sophisticated and often unique metalloenzymes that facilitate difficult redox reactions at ambient temperature and pressure. Understanding the intricacies of these biological nitrogen transformations requires a detailed knowledge that arises from the combination of a multitude of powerful analytical techniques and functional assays. Recent developments in spectroscopy and structural biology have provided new, powerful tools for addressing existing and emerging questions, which have gained urgency due to the global environmental implications of these fundamental reactions. The present review focuses on the recent contributions of the wider area of structural biology to understanding nitrogen metabolism, opening new avenues for biotechnological applications to better manage and balance the challenges of the global nitrogen cycle.     

Intermediate forms of cytochrome oxidase observed in transient kinetic experiments and those visited in the catalytic cycle

The cytochrome oxidase family of heme-copper oxidases has been the subject of intense kinetic and mechanistic enquiry. Much of this work has focussed on transient kinetic studies of the partial reactions of the enzyme with the goal being to build a kinetic model describing the catalytic cycle that the enzyme undergoes to direct the oxidation of substrate, reduction of oxygen and vectorial proton transfer. A key aspect of such a model is to define the structures of each of the intermediate forms the enzyme takes up as it traverses the catalytic cycle. One complication that has been prevalent with mitochondrial cytochrome c oxidase is the existence of structural variants of the enzyme, as isolated, that may not be participants in catalysis. Studies of structurally simpler procaryotic members of the family may offer new insight on the intermediates of catalysis. In this paper transient-state and steady-state kinetic studies of cytochrome aa(3)-600 from Bacillus subtilis are integrated into a model of the catalytic cycle. This model specifies that the P intermediate accumulates in the steady-state and it is proposed that the step following its formation is limited by proton uptake.     

Polyoxometalates in catalytic selective homogeneous oxygenation and anti-HIV chemotherapy

This review concentrates on two areas of intense research interest involving polyoxometalates, homogeneous catalysis and medicine. The discussion of homogeneous catalysis covers a brief historical overview of organic substrate oxidation, oxidant desirability, and other classes of oxidation catalysts. The principal focus of the catalysis, use of oxidatively resistant d-electron-transition-metal-substituted polyoxometalates (TMSP) for sustained oxygenation of organic substrates, is then examined. A general compilation is given in Table I of the literature reactions involving 21 TMSP complexes, 10 oxidants, five classes of substrates, and 10 solvent systems. Possible extensions of this chemistry are discussed.The discussion of polyoxometalates in anti-HIV chemotherapy includes brief historical background of this rapidly developing area followed by an evaluation of the effectiveness of polyoxometalates as anti-HIV agents. Over two hundred polyoxometalates have been examined in cell culture with the activities (EC₅₀ values) and toxicities (IC₅₀ values) listed in Table II. Polyoxotungstates as a class of polyoxometalates show the most promise with respectable levels of activity, selectivity, and low toxicity. The effect of polyoxometalate countercation and modes of HIV inhibition are discussed. The review contains 60 references.     

Core and periphery functionalized dendrimers for transition metal catalysis; a covalent and a non-covalent approach

Dendrimers are well-defined hyperbranched macromolecules with characteristic globular structures for the larger systems. The recent impressive strides in synthetic procedures increased the accessibility of functionalized dendrimers at a practicable scale, resulting in a rapid development of dendrimer chemistry. Dendrimers have inspired many chemists to develop new materials and several applications have been explored, catalysis being one of them. The position of the catalytic site(s) as well as the spatial separation of the catalysts within the dendritic framework is of crucial importance. Dendrimers that are functionalized with transition metals in the core can potentially mimic properties of enzymes, their efficient natural counterparts, whereas the surface-functionalized systems have been proposed to fill the gap between homogeneous and heterogeneous catalysis. We prepared both core- and periphery-functionalized dendritic catalysts that are sufficiently large to enable separation by modern nanofiltration techniques. Here we review our recent findings using these promising novel transition metal-functionalized dendrimers as catalysts in several reactions. We will discuss some of the consequences of the architecturally different systems that have been studied and will elaborate on a novel non-covalent strategy of dendrimer functionalization.