Andrea Pennati

Structural and functional diversity of ferredoxin-NADP(+) reductases

Although all ferredoxin-NADP(+) reductases (FNRs) catalyze the same reaction, i.e. the transfer of reducing equivalents between NADP(H) and ferredoxin, they belong to two unrelated families of proteins: the plant-type and the glutathione reductase-type of FNRs. Aim of this review is to provide a general classification scheme for these enzymes, to be used as a framework for the comparison of their properties. Furthermore, we report on some recent findings, which significantly increased the understanding of the structure-function relationships of FNRs, i.e. the ability of adrenodoxin reductase and its homologs to catalyze the oxidation of NADP(+) to its 4-oxo derivative, and the properties of plant-type FNRs from non-photosynthetic organisms. Plant-type FNRs from bacteria and Apicomplexan parasites provide examples of novel ways of FAD- and NADP(H)-binding. The recent characterization of an FNR from Plasmodium falciparum brings these enzymes into the field of drug design.

Design and application of a class of sensors to monitor Ca2+ dynamics in high Ca2+ concentration cellular compartments

Quantitative analysis of Ca2+ fluctuations in the endoplasmic/sarcoplasmic reticulum (ER/SR) is essential to defining the mechanisms of Ca2+-dependent signaling under physiological and pathological conditions. Here, we developed a unique class of genetically encoded indicators by designing a Ca2+ binding site in the EGFP. One of them, calcium sensor for detecting high concentration in the ER, exhibits unprecedented Ca2+ release kinetics with an off-rate estimated at around 700 s−1 and appropriate Ca2+ binding affinity, likely attributable to local Ca2+-induced conformational changes around the designed Ca2+ binding site and reduced chemical exchange between two chromophore states. Calcium sensor for detecting high concentration in the ER reported considerable differences in ER Ca2+ dynamics and concentration among human epithelial carcinoma cells (HeLa), human embryonic kidney 293 cells (HEK-293), and mouse myoblast cells (C2C12), enabling us to monitor SR luminal Ca2+ in flexor digitorum brevis muscle fibers to determine the mechanism of diminished SR Ca2+ release in aging mice. This sensor will be invaluable in examining pathogenesis characterized by alterations in Ca2+ homeostasis.

The ferredoxin‐NADP+ reductase/ferredoxin electron transfer system of Plasmodium falciparum

In the apicoplast of apicomplexan parasites, plastidic‐type ferredoxin and ferredoxin‐NADP+ reductase (FNR) form a short electron transport chain that provides reducing power for the synthesis of isoprenoid precursors. These proteins are attractive targets for the development of novel drugs against diseases such as malaria, toxoplasmosis, and coccidiosis. We have obtained ferredoxin and FNR of both Toxoplasma gondii and Plasmodium falciparum in recombinant form, and recently we solved the crystal structure of the P. falciparum reductase. Here we report on the functional properties of the latter enzyme, which differ markedly from those of homologous FNRs. In the physiological reaction, P. falciparum FNR displays a kcat five‐fold lower than those usually determined for plastidic‐type FNRs. By rapid kinetics, we found that hydride transfer between NADPH and protein‐bound FAD is slower in the P. falciparum enzyme. The redox properties of the enzyme were determined, and showed that the FAD semiquinone species is highly destabilized. We propose that these two features, i.e. slow hydride transfer and unstable FAD semiquinone, are responsible for the poor catalytic efficiency of the P. falciparum enzyme. Another unprecedented feature of the malarial parasite FNR is its ability to yield, under oxidizing conditions, an inactive dimeric form stabilized by an intermolecular disulfide bond. Here we show that the monomer–dimer interconversion can be controlled by oxidizing and reducing agents that are possibly present within the apicoplast, such as H2O2, glutathione, and lipoate. This finding suggests that modulation of the quaternary structure of P. falciparum FNR might represent a regulatory mechanism, although this needs to be verified in vivo.

Pathway of glycine betaine biosynthesis in Aspergillus fumigatus

ABSTRACT The choline oxidase (CHOA) and betaine aldehyde dehydrogenase (BADH) genes identified in Aspergillus fumigatus are present as a cluster specific for fungal genomes. Biochemical and molecular analyses of this cluster showed that it has very specific biochemical and functional features that make it unique and different from its plant and bacterial homologs. A. fumigatus ChoAp catalyzed the oxidation of choline to glycine betaine with betaine aldehyde as an intermediate and reduced molecular oxygen to hydrogen peroxide using FAD as a cofactor. A. fumigatus Badhp oxidized betaine aldehyde to glycine betaine with reduction of NAD+ to NADH. Analysis of the AfchoAΔ::HPH and AfbadAΔ::HPH single mutants and the AfchoAΔAfbadAΔ::HPH double mutant showed that AfChoAp is essential for the use of choline as the sole nitrogen, carbon, or carbon and nitrogen source during the germination process. AfChoAp and AfBadAp were localized in the cytosol of germinating conidia and mycelia but were absent from resting conidia. Characterization of the mutant phenotypes showed that glycine betaine in A. fumigatus functions exclusively as a metabolic intermediate in the catabolism of choline and not as a stress protectant. This study in A. fumigatus is the first molecular, cellular, and biochemical characterization of the glycine betaine biosynthetic pathway in the fungal kingdom.

Rescuing of the hydride transfer reaction in the Glu312Asp variant of choline oxidase by a substrate analogue.

In the active site of choline oxidase, Glu312 participates in binding the trimethylammonium group of choline, thereby positioning the alcohol substrate properly for efficient hydride transfer to the enzyme-bound flavin. Previous studies have shown that substitution of Glu312 with aspartate results in a perturbed mechanism of hydride transfer, with a 260-fold decrease in the rate associated with the mutation. Here, the reaction of alcohol oxidation catalyzed by the Glu312Asp enzyme has been investigated with 3-hydroxypropyl-trimethylamine (3-HPTA), a choline analogue with an extra methylene, as substrate. The results of the kinetic investigation using steady state and rapid reaction approaches showed that the impaired ability of the Glu312Asp enzyme to catalyze a hydride transfer reaction can be effectively, but not completely, rescued in the presence of an extra methylene group on the substrate that compensates for the equivalent shortening of the side chain on residue 312. This observation is consistent with choline oxidase having evolved to optimally catalyze the oxidation of choline.

Kinetics of heme transfer by the Shr NEAT domains of Group A Streptococcus

The hemolytic Group A Streptococcus (GAS) is a notorious human pathogen. Shr protein of GAS participates in iron acquisition by obtaining heme from host hemoglobin and delivering it to the adjacent receptor on the surface, Shp. Heme is then conveyed to the SiaABC proteins for transport across the membrane. Using rapid kinetic studies, we investigated the role of the two heme binding NEAT modules of Shr. Stopped-flow analysis showed that holoNEAT1 quickly delivered heme to apoShp. HoloNEAT2 did not exhibit such activity; only little and slow transfer of heme from NEAT2 to apoShp was seen, suggesting that Shr NEAT domains have distinctive roles in heme transport. HoloNEAT1 also provided heme to apoNEAT2, by a fast and reversible process. To the best of our knowledge this is the first transfer observed between isolated NEAT domains of the same receptor. Sequence alignment revealed that Shr NEAT domains belong to two families of NEAT domains that are conserved in Shr orthologs from several species. Based on the heme transfer kinetics, we propose that Shr proteins modulate heme uptake according to heme availability by a mechanism where NEAT1 facilitates fast heme delivery to Shp, whereas NEAT2 serves as a temporary storage for heme on the bacterial surface.

Involvement of Ionizable Groups in Catalysis of Human Liver Glycolate Oxidase

Glycolate oxidase is a flavin-dependent, peroxisomal enzyme that oxidizes α-hydroxy acids to the corresponding α-keto acids, with reduction of oxygen to H2O2. In plants, the enzyme participates in photorespiration. In humans, it is a potential drug target for treatment of primary hyperoxaluria, a genetic disorder where overproduction of oxalate results in the formation of kidney stones. In this study, steady-state and pre-steady-state kinetic approaches have been used to determine how pH affects the kinetic steps of the catalytic mechanism of human glycolate oxidase. The enzyme showed a Ping-Pong Bi-Bi kinetic mechanism between pH 6.0 and 10.0. Both the overall turnover of the enzyme (kcat) and the rate constant for anaerobic substrate reduction of the flavin were pH-independent at pH values above 7.0 and decreased slightly at lower pH, suggesting the involvement of an unprotonated group acting as a base in the chemical step of glycolate oxidation. The second-order rate constant for capture of glycolate (kcat/Kglycolate) and the Kd(app) for the formation of the enzyme-substrate complex suggested the presence of a protonated group with apparent pKa of 8.5 participating in substrate binding. The kcat/Koxygen values were an order of magnitude faster when a group with pKa of 6.8 was unprotonated. These results are discussed in the context of the available three-dimensional structure of GOX.

Effect of salt and pH on the reductive half-reaction of Mycobacterium tuberculosis FprA with NADPH.

Despite a number of studies, the formation of the Michaelis complexes between ferredoxin-NADP (+) reductases and NADP(H) eluded detailed investigations by rapid kinetic techniques because of their high formation rates. Moreover, the reversible nature of the reaction of hydride ion transfer between these enzymes and NADPH prevented the obtainment of reliable estimates of the rate constant of the hydride transfer step. Here we show that by working at a high salt concentration, the mechanism of the reaction with NADPH of FprA, a Mycobacterium tuberculosis homologue of adrenodoxin reductase, is greatly simplified, making it amenable to investigation by rapid reaction techniques. The approach presented herein allowed for the first time the observation of the formation of the Michaelis complex between an adrenodoxin reductase-like enzyme and NADPH, and the determination of the related rate constants for association and dissociation. Furthermore, the rate constant for the reaction of hydride ion transfer between NADPH and FAD could be unambiguously assessed. It is proposed that the approach described should be applicable to other ferredoxin reductase enzymes, providing a valuable experimental tool for the study of their kinetic properties.

Enzymatic oxidation of NADP+ to its 4‐oxo derivative is a side‐reaction displayed only by the adrenodoxin reductase type of ferredoxin‐NADP+ reductases

We have previously shown that Mycobacterium tuberculosis FprA, an NADPH‐ferredoxin reductase homologous to mammalian adrenodoxin reductase, promotes the oxidation of NADP+ to its 4‐oxo derivative 3‐carboxamide‐4‐pyridone adenine dinucleotide phosphate [Bossi RT, Aliverti A, Raimondi D, Fischer F, Zanetti G, Ferrari D, Tahallah N, Maier CS, Heck AJ, Rizzi M et al. (2002) Biochemistry41, 8807–8818]. Here, we provide a detailed study of this unusual enzyme reaction, showing that it occurs at a very slow rate (0.14 h−1), requires the participation of the enzyme‐bound FAD, and is regiospecific in affecting only the C4 of the NADP nicotinamide ring. By protein engineering, we excluded the involvement in catalysis of residues Glu214 and His57, previously suggested to be implicated on the basis of their localization in the three‐dimensional structure of the enzyme. Our results substantiate a catalytic mechanism for 3‐carboxamide‐4‐pyridone adenine dinucleotide phosphate formation in which the initial and rate‐determining step is the nucleophilic attack of the nicotinamide moiety by an active site water molecule. Whereas plant‐type ferredoxin reductases were unable to oxidize NADP+, the mammalian adrenodoxin reductase also catalyzed this unusual reaction. Thus, the 3‐carboxamide‐4‐pyridone adenine dinucleotide phosphate formation reaction seems to be a peculiar feature of the mitochondrial type of ferredoxin reductases, possibly reflecting conserved properties of their active sites. Furthermore, we showed that 3‐carboxamide‐4‐pyridone adenine dinucleotide phosphate is good ligand and a competitive inhibitor of various dehydrogenases, making this nucleotide analog a useful tool for the characterization of the cosubstrate‐binding site of NADPH‐dependent enzymes.