Kinetic mechanism and quaternary structure of Aminobacter aminovorans NADH:flavin oxidoreductase: an unusual flavin reductase with bound flavin

Functional and mechanistic characterization of an atypical flavin reductase encoded by the pden_5119 gene in Paracoccus denitrificans

Pden_5119, annotated as an NADPH-dependent FMN reductase, shows homology to proteins assisting in utilization of alkanesulfonates in other bacteria. Here, we report that inactivation of the pden_5119 gene increased susceptibility to oxidative stress, decreased growth rate and increased growth yield; growth on lower alkanesulfonates as sulfur sources was not specifically influenced. Pden_5119 transcript rose in response to oxidative stressors, respiratory chain inhibitors and terminal oxidase downregulation. Kinetic analysis of a fusion protein suggested a sequential mechanism in which FMN binds first, followed by NADH. The affinity of flavin toward the protein decreased only slightly upon reduction. The observed strong viscosity dependence of k_cat demonstrated that reduced FMN formed tends to remain bound to the enzyme where it can be re-oxidized by oxygen or, less efficiently, by various artificial electron acceptors. Stopped flow data were consistent with the enzyme-FMN complex being a functional oxidase that conducts the reduction of oxygen by NADH. Hydrogen peroxide was identified as the main product. As shown by isotope effects, hydride transfer occurs from the pro-S C4 position of the nicotinamide ring and partially limits the overall turnover rate. Collectively, our results point to a role for the Pden_5119 protein in maintaining the cellular redox state.

A mechanistic study on SMOB-ADP1: an NADH:flavin oxidoreductase of the two-component styrene monooxygenase of Acinetobacter baylyi ADP1

Two styrene monooxygenase types, StyA/StyB and StyA1/StyA2B, have been described each consisting of an epoxidase and a reductase. A gene fusion which led to the chimeric reductase StyA2B and the occurrence in different phyla are major differences. Identification of SMOA/SMOB-ADP1 of Acinetobacter baylyi ADP1 may enlighten the gene fusion event since phylogenetic analysis indicated both proteins to be more related to StyA2B than to StyA/StyB. SMOB-ADP1 is classified like StyB and StyA2B as HpaC-like reductase. Substrate affinity and turnover number of the homo-dimer SMOB-ADP1 were determined for NADH (24 µM, 64 s(-1)) and FAD (4.4 µM, 56 s(-1)). SMOB-ADP1 catalysis follows a random sequential mechanism, and FAD fluorescence is quenched upon binding to SMOB-ADP1 (K d = 1.8 µM), which clearly distinguishes that reductase from StyB of Pseudomonas. In summary, this study confirmes made assumptions and provides phylogenetic and biochemical data for the differentiation of styrene monooxygenase-related flavin reductases.

Perspectives of data analysis of enzyme inhibition and activation, Part 3: Equations for calculation of the initial rates of enzymatic reactions

Equations for calculation of the initial rates of activated enzymatic reactions and the inhibited enzymatic reactions, unavailable in experimental enzymology, were obtained. Examples of practically using of these equations are given.

Vibrio harveyi flavin reductase--luciferase fusion protein mimics a single-component bifunctional monooxygenase

Vibrio harveyi luciferase and flavin reductase FRP are, together, a two-component monooxygenase couple. The reduced flavin mononucleotide (FMNH2) generated by FRP must be supplied, through either free diffusion or direct transfer, to luciferase as a substrate. In contrast, single-component bifunctional monooxygenases each contains a bound flavin cofactor and does not require any flavin addition to facilitate catalysis. In this study, we generated and characterized a novel fusion enzyme, FRP-alphabeta, in which FRP was fused to the luciferase alpha subunit. Both FRP and luciferase within FRP-alphabeta were catalytically active. Kinetic properties characteristic of a direct transfer of FMNH2 cofactor from FRP to luciferase in a FRP:luciferase noncovalent complex were retained by FRP-alphabeta. At submicromolar levels, FRP-alphabeta was significantly more active than an equal molar mixture of FRP and luciferase in coupled bioluminescence without FMN addition. Importantly, FRP-alphabeta gave a higher total quantum output without than with exogenously added FMN. Moreover, effects of increasing concentrations of oxygen on light intensity were investigated using sub-micromolar enzymes, and results indicated that the bioluminescence produced by FRP-alphabeta without added flavin was derived from direct transfer of reduced flavin whereas bioluminescence from a mixture of FRP and luciferase with or without exogenously added flavin relied on free-diffusing reduced flavin. Therefore, the overall catalytic reaction of FRP-alphabeta without any FMN addition closely mimics that of a single-component bifunctional monooxygenase. This fusion enzyme approach could be useful to other two-component monooxygenases in enhancing the enzyme efficiencies under conditions hindering reduced flavin delivery. Other potential utilities of this approach are discussed.

Thermodynamic analysis of the binding of oxidized and reduced FMN cofactor to Vibrio harveyi NADPH-FMN oxidoreductase FRP apoenzyme

The Vibrio harveyi NADPH-specific flavin reductase FRP follows a ping-pong mechanism but switches to a sequential mechanism in the luciferase-coupled reaction. The bound FMN co-isolated with FRP, while acting as a genuine cofactor in the single-enzyme reaction, functions in the luciferase-coupled reaction as a prebound substrate and is directly transferred to luciferase once it is reduced [Lei, B., and Tu, S.-C. (1998) Biochemistry 37, 14623-14629]. With the aim of better understanding the functions of FMN in the FRP holoenzyme, this study was undertaken to quantify and compare the thermodynamic properties of the binding of oxidized and reduced FMN by the FRP apoenzyme. By isothermal titration calorimetry (ITC) measurements in various buffers at pH 7.0 and 15-30 degrees C, the binding of FMN by apo-FRP was found to be noncooperative, exothermic, and primarily enthalpy driven. The binding free energy change (hence, the association constant) was nearly invariant over this temperature range. Significant conformational changes in FRP upon binding of FMN were indicated. Equilibrium bindings of reduced flavins by flavin-dependent proteins have rarely been studied. In this work, the thermodynamic properties of binding of reduced FMN by apo-FRP were found to closely resemble those of FMN binding under three sets of experimental conditions via ITC measurements and, in one case, fluorescence quenching. The kinetically deduced ping-pong mechanism of FRP is now supported by direct measurements of binding affinities of the oxidized and reduced FMN cofactors. These findings are also discussed in relation to the function of FRP as a reduced flavin donor in the FRP-luciferase couple.

Matrix cell adhesion activation by non-adhesion proteins

Cell adhesion to the extracellular matrix is important in many biological processes. Various ligands and cell surface receptors have been defined. In vitro cell adhesion to matrix proteins and to other 'adhesion' proteins is generally measured on plastic culture substrates. We have found that the presence of low levels of adhesion proteins, e.g. fibronectin, together with high concentrations of non-adhesion proteins, e.g. osteonectin, can promote cell attachment on plastic culture dishes. This promotion of adhesion occurs even when the concentrations of fibronectin, collagen and other adhesive proteins are too low to support cell attachment alone. Other non-adhesive proteins that have similar activity in 'triggering' the attachment of cells to low levels of adhesion molecules include bovine serum albumin (BSA) and cytochrome C. The non-adhesive protein must be added to the plate first, or together with the low amount of the adhesion protein, to 'activate' cell attachment. Adding the adhesion protein fibronectin to the plate first, followed by osteonectin, resulted in no 'activation' of attachment. The non-adhesive protein did not bind to the adhesive protein nor did it alter the level of adhesive protein binding to the substrate. The non-adhesive protein did, however, expose integrin-binding sites of the adhesive protein fibronectin. These data confirm and extend previous data by others demonstrating the role of non-adhesive proteins in regulating the conformation and cell adhesive activity of matrix adhesion proteins on plastic surfaces. Such findings might explain contradictions in the literature about the activity of 'adhesive proteins'.

Structure of Ptr ToxA: an RGD-containing host-selective toxin from Pyrenophora tritici-repentis

Tan spot of wheat (Triticum aestivum), caused by the fungus Pyrenophora tritici-repentis, has significant agricultural and economic impact. Ptr ToxA (ToxA), the first discovered proteinaceous host-selective toxin, is produced by certain P. tritici-repentis races and is necessary and sufficient to cause cell death in sensitive wheat cultivars. We present here the high-resolution crystal structure of ToxA in two different crystal forms, providing four independent views of the protein. ToxA adopts a single-domain, beta-sandwich fold of novel topology. Mapping of the existing mutation data onto the structure supports the hypothesized importance of an Arg-Gly-Asp (RGD) and surrounding sequence. Its occurrence in a single, solvent-exposed loop in the protein suggests that it is directly involved in recognition events required for ToxA action. Furthermore, the ToxA structure reveals a surprising similarity with the classic mammalian RGD-containing domain, the fibronectin type III (FnIII) domain: the two topologies are related by circular permutation. The similar topologies and the positional conservation of the RGD-containing loop raises the possibility that ToxA is distantly related to mammalian FnIII proteins and that to gain entry it binds to an integrin-like receptor in the plant host.

Dissociation of Human Copper-Zinc Superoxide Dismutase Dimers Using Chaotrope and Reductant

The dissociation of apo- and metal-bound human copper-zinc superoxide dismutase (SOD1) dimers induced by the chaotrope guanidine hydrochloride (GdnHCl) or the reductant Tris(2-carboxyethyl)phosphine (TCEP) has been analyzed using analytical ultracentrifugation. Global fitting of sedimentation equilibrium data under native solution conditions (without GdnHCl or TCEP) demonstrate that both the apo- and metal-bound forms of SOD1 are stable dimers. Sedimentation velocity experiments show that apo-SOD1 dimers dissociate cooperatively over the range 0.5-1.0 M GdnHCl. In contrast, metal-bound SOD1 dimers possess a more compact shape and dissociate at significantly higher GdnHCl concentrations (2.0-3.0 M). Reduction of the intrasubunit disulfide bond within each SOD1 subunit by 5-10 mM TCEP promotes dissociation of apo-SOD1 dimers, whereas the metal-bound enzyme remains a stable dimer under these conditions. The Cys-57 --> Ser mutant of SOD1, a protein incapable of forming the intrasubunit disulfide bond, sediments as a monomer in the absence of metal ions and as a dimer when metals are bound. Taken together, these data indicate that the stability imparted to the human SOD1 dimer by metal binding and the formation of the intrasubunit disulfide bond are mediated by independent molecular mechanisms. By combining the sedimentation data with previous crystallographic results, a molecular explanation is provided for the existence of different SOD1 macromolecular shapes and multiple SOD1 dimeric species with different stabilities.

Cloning and expression of p-hydroxyphenylacetate 3-hydroxylase from Acinetobacter baumannii: evidence of the divergence of enzymes in the class of two-protein component aromatic hydroxylases

The genes encoding for the reductase and oxygenase components of p-hydroxyphenylacetate 3-hydroxylase from Acinetobacter baumannii were cloned and expressed in an E. coli system. The recombinant enzymes were purified and shown to have the same catalytic properties as the native enzyme. Sequence analysis and biochemical studies indicate that the enzyme represents a novel prototype of enzyme in the two-protein component class of aromatic hydroxylases. The C2 component shows little similarity to other oxygenases in the same class, correlating with its uniquely broad flavin specificity. Analysis of the C1 reductase sequence indicates that the binding sites of flavin and NADH mainly reside in the N-terminal half while the C-terminal half may be responsible for HPA-stimulation of NADH oxidation.

Geminin Has Dimerization, Cdt1-binding, and Destruction Domains That Are Required for Biological Activity

Geminin is an unstable regulatory protein that affects both cell division and cell differentiation. Geminin inhibits a second round of DNA synthesis during S and G(2) phase by binding the essential replication protein Cdt1. Geminin is also required for entry into mitosis, either by preventing replication abnormalities or by down-regulating the checkpoint kinase Chk1. Geminin overexpression during embryonic development induces ectopic neural tissue, inhibits eye formation, and perturbs the segmental patterning of the embryo. In order to define the structural and functional domains of the geminin protein, we generated over 40 missense and deletion mutations and tested their phenotypes in biological and biochemical assays. We find that geminin self-associates through the coiled-coil domain to form dimers and that dimerization is required for activity. Geminin contains a typical bipartite nuclear localization signal that is also required for its destruction during mitosis. Nondegradable mutants of geminin interfere with DNA replication in succeeding cell cycles. Geminin's Cdt1-binding domain lies immediately adjacent to the dimerization domain and overlaps it. We constructed two nonbinding mutants in this domain and found that they neither inhibited replication nor permitted entry into mitosis, indicating that this domain is necessary for both activities. We identified several missense mutations in geminin's Cdt1 binding domain that were deficient in their ability to inhibit replication yet were still able to allow mitotic entry, suggesting that these are separate functions of geminin.