Physiological functions of D-amino acid oxidases: from yeast to humans

D-Amino acid oxidase (DAAO) is a FAD-containing flavoenzyme that catalyzes the oxidative deamination of D-isomers of neutral and polar amino acids. This enzymatic activity has been identified in most eukaryotic organisms, the only exception being plants. In the various organisms in which it does occur, DAAO fulfills distinct physiological functions: from a catabolic role in yeast cells, which allows them to grow on D-amino acids as carbon and energy sources, to a regulatory role in the human brain, where it controls the levels of the neuromodulator D-serine. Since 1935, DAAO has been the object of an astonishing number of investigations and has become a model for the dehydrogenase-oxidase class of flavoproteins. Structural and functional studies have suggested that specific physiological functions are implemented through the use of different structural elements that control access to the active site and substrate/product exchange. Current research is attempting to delineate the regulation of DAAO functions in the contest of complex biochemical and physiological networks.

Competition between C-terminal tyrosine and nicotinamide modulates pyridine nucleotide affinity and specificity in plant ferredoxin-NADP(+) reductase

Chloroplast ferredoxin-NADP(+) reductase has a 32,000-fold preference for NADPH over NADH, consistent with its main physiological role of NADP(+) photoreduction for de novo carbohydrate biosynthesis. Although it is distant from the 2'-phosphoryl group of NADP(+), replacement of the C-terminal tyrosine (Tyr(308) in the pea enzyme) by Trp, Phe, Gly, and Ser produced enzyme forms in which the preference for NADPH over NADH was decreased about 2-, 10-, 300-, and 400-fold, respectively. Remarkably, in the case of the Y308S mutant, the k(cat) value for the NADH-dependent activity approached that of the NADPH-dependent activity of the wild-type enzyme. Furthermore, difference spectra of the NAD(+) complexes revealed that the nicotinamide ring of NAD(+) binds at nearly full occupancy in the active site of both the Y308G and Y308S mutants. These results correlate well with the k(cat) values obtained with these mutants in the NADH-ferricyanide reaction. The data presented support the hypothesis that specific recognition of the 2'-phosphate group of NADP(H) is required but not sufficient to ensure a high degree of discrimination against NAD(H) in ferredoxin-NADP(+) reductase. Thus, the C-terminal tyrosine enhances the specificity of the reductase for NADP(H) by destabilizing the interaction of a moiety common to both coenzymes, i.e. the nicotinamide.

Probing the function of the invariant glutamyl residue 312 in spinach ferredoxin-NADP+ reductase

Ferredoxin-NADP+ reductase, the prototype of a large family of structurally related flavoenzymes, pairs single electrons carried by ferredoxin I and transfers them as a hydride to NADP+. Four mutants of the enzyme, in which Glu-312 was replaced with Asp, Gln, Leu, and Ala to probe the role of the residue charge, size, and polarity in the enzyme activity, have been heterologously expressed, purified, and characterized through steady-state, rapid kinetic studies, ligand-binding experiments, and three-dimensional structure determination by x-ray crystallography. The E312L mutant was the only one that was almost inactive (approximately 1%), whereas unexpectedly the E312A reductase was 10-100% active with the various acceptors tested. Rapid kinetic absorption spectroscopy studies demonstrated that flavin reduction by NADPH was impaired in the mutants. Furthermore, NADP(H) binding was partially perturbed. These functional and structural studies lead us to conclude that Glu-312 does not fulfil the role of proton donor during catalysis, but it is required for proper binding of the nicotinamide ring of NADP(H). In addition, its charge modulates the two one-electron redox potentials of the flavin to stabilize the semiquinone form.

Diffusion-controlled DNA recognition by an unfolded, monomeric bZIP transcription factor

Basic leucine zipper (bZIP) transcription factors are dimers that recognize mainly palindromic DNA sites. It has been assumed that bZIP factors have to form a dimer in order to bind to their target DNA. We find that DNA binding of both monomeric and dimeric bZIP transcription factor GCN4 is diffusion-limited and that, therefore, the rate of dimerization of the bZIP domain does not affect the rate of DNA recognition and GCN4 need not dimerize in order to bind to its specific DNA site. The results have implications for the mechanism by which bZIP transcription factors find their target sites for transcriptional regulation.

On the role of the acidic cluster Glu 92-94 of spinach ferredoxin I

The role of the acidic cluster Glu 92-94 of spinach ferredoxin I in the interaction both with the photosystem I multisubunit complex and the ferredoxin-NADP+ reductase, either membrane-bound or purified, was studied by kinetic characterization of site-directed mutants. Three mutants of ferredoxin have been produced to evaluate the effects of elimination of one or two negative charges in the three specific positions of the acidic cluster. Kinetic characterization of the ferredoxin mutants E92A/E93A, E93A and E93A/E94A as electron carriers in the photosynthetic electron transport chain, allowed to establish that the two latter mutants were nearly indistinguishable from the wild-type protein in their ability to be photoreduced by photosystem I and as electron donor to the reductase in the NADP+ photoreduction with thylakoid membranes. The E92A/E93A ferredoxin mutant behaved very similarly to E92 mutants previously characterized. Thus, the elimination of the carboxyl groups adjacent to residue 92 did not further impaired ferredoxin I main function, i.e., as an electron carrier in NADP+ photoreduction. The two double mutants showed a reduced rate in the cross-linking of ferredoxin to the reductase promoted by a soluble carbodiimide, indicating an involvement of the acidic cluster in the formation of the active covalent complex between the two proteins.

Recombinant wild-type and mutant complexes of ferredoxin and ferredoxin:NADP+ reductase studied by isothermal titration calorimetry

The interaction of spinach ferredoxin:NADP+ reductase (FNR) with ferredoxin (Fd) is driven by a favorable change of entropy and shows almost no change in enthalpy. The change in heat capacity between the free proteins and the complex is -0.47 +/- 0.1 kJ mol(-1) K(-1), a value indicating a relatively small surface area buried in the complex. A single proton is taken up from the environment when the ferredoxin:FNR complex forms. In the complex, the protonated residue(s) is (are) probably located in the vicinity of E92 of Fd because charge reversal in Fd(E92K) quenches protonation. Substitution of K88 by Q in FNR(K88Q) destabilizes the complex by a 7 kJ mol(-1) reduction in binding entropy, which indicates that dehydration of the complex interface contributes to stability.

Mutations of Glu92 in ferredoxin I from spinach leaves produce proteins fully functional in electron transfer but less efficient in supporting NADP+ photoreduction

Ferredoxin I in spinach chloroplasts fulfils the role of distributing electrons of low redox potential produced by photosystem I to several metabolic routes, NADP+ reduction being the major output. To investigate the role of Glu92, which is conserved in the chloroplast-type ferredoxins, mutations of this residue to either Gln, Ala or Lys were obtained through site-directed mutagenesis. A Glu93Ala mutant was also designed. The four mutants of ferredoxin I were overproduced in Escherichia coli, purified and characterised. The different migration in nondenaturing gel electrophoresis of wild-type and mutant proteins confirmed that the desired mutation was present in the expressed proteins. Spectral and physical properties of the mutants were similar to those of wild-type ferredoxin; electron-transfer properties were, however, quite different in the case of the mutants at position 92. Unexpectedly, these mutant ferredoxins were found to be twice as active as the wild-type protein in supporting the NADPH--cytochrome c reductase reaction catalysed by ferredoxin--NADP+ reductase. However, interactions of the mutant ferredoxins with the isolated thylakoid membranes deprived of endogenous ferredoxin showed that the mutants were less capable of supporting NADP+ photoreduction than the wild-type protein: both V and the apparent Km for reduced ferredoxin were influenced. On the other hand, the Kd values for the complex between oxidised ferredoxin and the reductase, measured at low ionic strength, were substantially changed only in the case of the Glu-->Lys mutation. With this mutant the rate of cross-linking between the two proteins induced by a carbodiimide was also decreased. It was found that the redox potentials of the iron-sulfur cluster of the mutants were more positive by 73-93 mV than that of ferredoxin I. Thus, the behavior of the ferredoxin mutants can be rationalised in terms of the effect of the side-chain replacement on the electrochemical properties of the [2Fe-2S] cluster and of an impairment in the interaction with the reductase under physiological conditions.

Spinach ferredoxin i: overproduction in Escherichia coli and purification

Ferredoxin I is the most abundant form of photosynthetic-type ferredoxin present in spinach chloroplasts. A cDNA clone encoding the precursor of spinach ferredoxin I has been engineered to synthesize the mature form of the plant protein in Escherichia coli. Among several different plasmid constructions, the expression system based on phage T7 promoter (vector pET-11d) was found to be the most efficient for spinach ferredoxin overproduction. Upon induction, ferredoxin I accounted for about 2.5% of soluble E. coli protein. A rapid procedure for the purification of the recombinant protein, which yielded at least 1 mg of homogeneous ferredoxin I per gram of cells (fresh wt), was developed. The recombinant protein was found to be identical to ferredoxin I isolated from spinach, both by mass spectrometry analysis and by N-terminal protein sequencing, indicating in vivo removal of the N-terminal methionine. Ferredoxin I was synthesized as the holoprotein, correctly assembled with the [2Fe-2S] cluster as judged by its absorption spectrum, and was fully active in the assay with its physiological partner (ferredoxin-NADP+ reductase). The expression system described here is amenable to the structure-function relationship study of spinach ferredoxin I through site-directed mutagenesis and NMR spectroscopy.

The role of cysteine residues of spinach ferredoxin-NADP+ reductase As assessed by site-directed mutagenesis

To investigate the functional role of the cysteine residues present in the spinach ferredoxin-NADP+ oxidoreductase, we individually replaced each of the five cysteine residues with serine using site-directed mutagenesis. All of the mutant reductases were correctly assembled in Escherichia coli except for the C42S mutant protein. C114S and C137S mutant enzymes apparently showed structural and kinetic properties very similar to those of the wild-type reductase. However, C272S and C132S mutations yielded enzymes with a decreased catalytic activity in the ferredoxin-dependent reaction (14 and 31% of the wild type, respectively). Whereas the C132S was fully competent in the diaphorase reaction, the C272S mutant flavoprotein showed a 35-fold reduction in catalytic efficiency with respect to the wild-type enzyme (0.4 versus 14.28 microM-1 s-1) due to a substantial decrease of kcat. NADP+ binding by the C272S mutant enzyme was apparently quantitatively the same (Kd = 37 microM) but qualitatively different, as shown by the differential spectrum. Stopped-flow experiments showed that the enzyme-FAD reduction rate was considerably decreased in the C272S mutant reductase, along with a much lower yield of the charge-transfer transient species. It is inferred from these data that the charge transfer (FAD-NADPH) between the reductase and NADPH is required for hydride transfer from the pyridine nucleotide to flavin to occur with a rate compatible with catalysis.

Glutamate synthase genes of the diazotroph Azospirillum brasilense. Cloning, sequencing, and analysis of functional domains

A 10-kilobase EcoRI fragment of Azospirillum brasilense genomic DNA was cloned in Escherichia coli. Two open reading frames of 4548 and 1446 base pairs (bp) were identified within the fragment as the structural genes for the alpha and beta subunits (gltB and gltD, respectively) of A. brasilense GltS. The organization of the gltBD region of A. brasilense differs from that of the corresponding region in E. coli: in A. brasilense, gltD is upstream relative to gltB, and its stop codon is separated by 141 bp from the first ATG of gltB. The deduced amino acid sequences reveal a high similarity with GltS from E. coli and with the ferredoxin-dependent GltS from maize. Binding domains for flavin cofactors and NADPH, a domain for glutamine binding and activation, and cysteine clusters for iron-sulfur centers formation were tentatively identified on the basis of sequence comparison with flavoproteins, pyridine nucleotide-dependent enzymes, amidotransferases, and iron-sulfur proteins.