Size-dependent renal filtration model explains human pharmacokinetics of a functional nanoparticle: The SPAGOPIX-01 clinical trial.

The pharmacokinetics in patients dosed with the nanoparticle-based MRI contrast agent SN132D is explained by a size dependent clearance mechanism and this behavior was modeled numerically. Blood samples from 14 patients were analyzed for silicon (a component of the nanoparticle) by ICP-OES. The pharmacokinetic model has only one free parameter and relies on a measured size distribution of the contrast agent and well-established properties of the renal and cardiovascular systems. The model fits well (R2 = 0.9910) with experimental data from samples taken from ten minutes to two weeks after start of infusion. These results support that the cut-off diameter for human renal filtration is 5.5 nm. The agreement between experiment and model implies that there is little or no plasma protein binding to the nanoparticles.

The structure of Lactococcus lactis thioredoxin reductase reveals molecular features of photo-oxidative damage.

The NADPH-dependent homodimeric flavoenzyme thioredoxin reductase (TrxR) provides reducing equivalents to thioredoxin, a key regulator of various cellular redox processes. Crystal structures of photo-inactivated thioredoxin reductase (TrxR) from the Gram-positive bacterium Lactococcus lactis have been determined. These structures reveal novel molecular features that provide further insight into the mechanisms behind the sensitivity of this enzyme toward visible light. We propose that a pocket on the si-face of the isoalloxazine ring accommodates oxygen that reacts with photo-excited FAD generating superoxide and a flavin radical that oxidize the isoalloxazine ring C7α methyl group and a nearby tyrosine residue. This tyrosine and key residues surrounding the oxygen pocket are conserved in enzymes from related bacteria, including pathogens such as Staphylococcus aureus. Photo-sensitivity may thus be a widespread feature among bacterial TrxR with the described characteristics, which affords applications in clinical photo-therapy of drug-resistant bacteria.

Lactococcus lactis thioredoxin reductase is sensitive to light inactivation.

Thioredoxin, involved in numerous redox pathways, is maintained in the dithiol state by the nicotinamide adenine dinucleotide phosphate-dependent flavoprotein thioredoxin reductase (TrxR). Here, TrxR from Lactococcus lactis is compared with the well-characterized TrxR from Escherichia coli. The two enzymes belong to the same class of low-molecular weight thioredoxin reductases and display similar kcat values (∼25 s(-1)) with their cognate thioredoxin. Remarkably, however, the L. lactis enzyme is inactivated by visible light and furthermore reduces molecular oxygen 10 times faster than E. coli TrxR. The rate of light inactivation under standardized conditions (λmax=460 nm and 4 °C) was reduced at lowered oxygen concentrations and in the presence of iodide. Inactivation was accompanied by a distinct spectral shift of the flavin adenine dinucleotide (FAD) that remained firmly bound. High-resolution mass spectrometric analysis of heat-extracted FAD from light-damaged TrxR revealed a mass increment of 13.979 Da, relative to that of unmodified FAD, corresponding to the addition of one oxygen atom and the loss of two hydrogen atoms. Tandem mass spectrometry confined the increase in mass of the isoalloxazine ring, and the extracted modified cofactor reacted with dinitrophenyl hydrazine, indicating the presence of an aldehyde. We hypothesize that a methyl group of FAD is oxidized to a formyl group. The significance of this not previously reported oxidation and the exceptionally high rate of oxygen reduction are discussed in relation to other flavin modifications and the possible occurrence of enzymes with similar properties.

Lactococcus lactis TrxD represents a subgroup of thioredoxins prevalent in Gram-positive bacteria containing WCXDC active site motifs.

Three protein disulfide reductases of the thioredoxin superfamily from the industrially important Gram-positive Lactococcus lactis (LlTrxA, LlTrxD and LlNrdH) are compared to the "classical" thioredoxin from Escherichia coli (EcTrx1). LlTrxA resembles EcTrx1 with a WCGPC active site motif and other key residues conserved. By contrast, LlTrxD is more distantly related and contains a WCGDC motif. Bioinformatics analysis suggests that LlTrxD represents a subgroup of thioredoxins from Gram-positive bacteria. LlNrdH is a glutaredoxin-like electron donor for ribonucleotide reductase class Ib. Based on protein-protein equilibria LlTrxA (E°'=-259mV) and LlNrdH (E°'=-238mV) show approximately 10mV higher standard state redox potentials than the corresponding E. coli homologues, while E°' of LlTrxD is -243mV, more similar to glutaredoxin than "classical" thioredoxin. EcTrx1 and LlTrxA have high capacity to reduce insulin disulfides and their exposed active site thiol is alkylated at a similar rate at pH 7.0. LlTrxD on the other hand, is alkylated by iodoacetamide at almost 100 fold higher rate and shows no activity towards insulin disulfides. LlTrxA, LlTrxD and LlNrdH are all efficiently reduced by NADPH dependent thioredoxin reductase (TrxR) from L. lactis and good cross-reactivity towards E. coli TrxR was observed with LlTrxD as the notable exception.

Global expression analysis of the yeast Lachancea (Saccharomyces) kluyveri reveals new URC genes involved in pyrimidine catabolism.

Pyrimidines are important nucleic acid precursors which are constantly synthesized, degraded, and rebuilt in the cell. Four degradation pathways, two of which are found in eukaryotes, have been described. One of them, the URC pathway, has been initially discovered in our laboratory in the yeast Lachancea kluyveri. Here, we present the global changes in gene expression in L. kluyveri in response to different nitrogen sources, including uracil, uridine, dihydrouracil, and ammonia. The expression pattern of the known URC genes, URC1-6, helped to identify nine putative novel URC genes with a similar expression pattern. The microarray analysis provided evidence that both the URC and PYD genes are under nitrogen catabolite repression in L. kluyveri and are induced by uracil or dihydrouracil, respectively. We determined the function of URC8, which was found to catalyze the reduction of malonate semialdehyde to 3-hydroxypropionate, the final degradation product of the pathway. The other eight genes studied were all putative permeases. Our analysis of double deletion strains showed that the L. kluyveri Fui1p protein transported uridine, just like its homolog in Saccharomyces cerevisiae, but we demonstrated that is was not the only uridine transporter in L. kluyveri. We also showed that the L. kluyveri homologs of DUR3 and FUR4 do not have the same function that they have in S. cerevisiae, where they transport urea and uracil, respectively. In L. kluyveri, both of these deletion strains grew normally on uracil and urea.

The barley grain thioredoxin system - an update.

Thioredoxin (Trx) reduces disulfide bonds and play numerous important functions in plants. In cereal seeds, cytosolic h-type Trx facilitates the release of energy reserves during the germination process and is recycled by NADPH-dependent Trx reductase. This review presents a summary of the research conducted during the last 10 years to elucidate the structure and function of the barley seed Trx system at the molecular level combined with proteomic approaches to identify target proteins.

Dissecting molecular interactions involved in recognition of target disulfides by the barley thioredoxin system.

Thioredoxin reduces disulfide bonds, thus regulating activities of target proteins in various biological systems, e.g., inactivation of inhibitors of starch hydrolases and proteases in germinating plant seeds. In the three-dimensional structure of a complex with barley α-amylase/subtilisin inhibitor (BASI), two loops in barley thioredoxin h2 (HvTrxh2), containing an invariant cis-proline ((86)EAMP(89)) and a conserved glycine ((104)VGA(106)), surround the active site cysteines ((45)WCGPC(49)) and contribute to binding of BASI through backbone-backbone hydrogen bonds [Maeda, K., Hägglund, P., Finnie, C., Svensson, B., and Henriksen, A. (2006) Structure 14, 1701-1710]. This study involves mutational analysis of key amino acid residues from these two loops in reactions with three protein disulfide substrates, BASI, barley glutathione peroxidase, and bovine insulin as well as with NADPH-dependent barley thioredoxin reductase. HvTrxh2 M88G and M88A adjacent to the invariant cis-proline lost efficiency in both BASI disulfide reduction and recycling by thioredoxin reductase. These effects were further pronounced in M88P lacking a backbone NH group. Remarkably, HvTrxh2 E86R in the same loop displayed overall retained catalytic properties, with the exception of a 3-fold increased activity toward BASI. From the (104)VGA(106) loop, a backbone hydrogen bond donated by A106 appears to be important for target disulfide recognition as A106P lost 90% activity toward BASI but was efficiently recycled by thioredoxin reductase. The findings support important roles in target recognition of backbone-backbone hydrogen bond and electrostatic interactions and are discussed in relation to earlier structural and functional studies of thioredoxins and related proteins.

Kinetic and thermodynamic properties of two barley thioredoxin h isozymes, HvTrxh1 and HvTrxh2.

Barley thioredoxin h isozymes 1 (HvTrxh1) and barley thioredoxin h isozymes 2 (HvTrxh2) show distinct spatiotemporal distribution in germinating seeds. Using a novel approach involving measurement of bidirectional electron transfer rates between Escherichia coli thioredoxin, which exhibits redox-dependent fluorescence, and the barley isozymes, reaction kinetics and thermodynamic properties were readily determined. The reaction constants were approximately 60% higher for HvTrxh1 than HvTrxh2, while their redox potentials were very similar. The primary nucleophile, CysN, of the active site Trp-CysN-Gly-Pro-CysC motif has an apparent pKa of 7.6 in both isozymes, as found by iodoacetamide titration, but showed approximately 70% higher reactivity in HvTrxh1, suggesting significant functional difference between the isozymes.

A second pathway to degrade pyrimidine nucleic acid precursors in eukaryotes.

Pyrimidine bases are the central precursors for RNA and DNA, and their intracellular pools are determined by de novo, salvage and catabolic pathways. In eukaryotes, degradation of uracil has been believed to proceed only via the reduction to dihydrouracil. Using a yeast model, Saccharomyces kluyveri, we show that during degradation, uracil is not reduced to dihydrouracil. Six loci, named URC1-6 (for uracil catabolism), are involved in the novel catabolic pathway. Four of them, URC3,5, URC6, and URC2 encode urea amidolyase, uracil phosphoribosyltransferase, and a putative transcription factor, respectively. The gene products of URC1 and URC4 are highly conserved proteins with so far unknown functions and they are present in a variety of prokaryotes and fungi. In bacteria and in some fungi, URC1 and URC4 are linked on the genome together with the gene for uracil phosphoribosyltransferase (URC6). Urc1p and Urc4p are therefore likely the core components of this novel biochemical pathway. A combination of genetic and analytical chemistry methods demonstrates that uridine monophosphate and urea are intermediates, and 3-hydroxypropionic acid, ammonia and carbon dioxide the final products of degradation. The URC pathway does not require the presence of an active respiratory chain and is therefore different from the oxidative and rut pathways described in prokaryotes, although the latter also gives 3-hydroxypropionic acid as the end product. The genes of the URC pathway are not homologous to any of the eukaryotic or prokaryotic genes involved in pyrimidine degradation described to date.

Comparative genomics reveals novel biochemical pathways.

How well do we understand which enzymes are involved in the primary metabolism of the cell? A recent study using comparative genomics and postgenomics approaches revealed a novel pathway in the most studied organism, Escherichia coli. The analysis of a new operon consisting of seven previously uncharacterized genes thought to be involved in the degradation of nucleic acid precursors shows the impact of comparative genomics on the discovery of novel pathways and enzymes.

Mechanism of flavin reduction in the class 1A dihydroorotate dehydrogenase from Lactococcus lactis.

Dihydroorotate dehydrogenases (DHODs) oxidize dihydroorotate (DHO) to orotate (OA) using the FMN prosthetic group to abstract a hydride equivalent from C6 and a protein residue (cysteine for class 1A DHODs) to deprotonate C5. The fundamental question of whether the scission of the two DHO C-H bonds is concerted or stepwise was addressed for the class 1A enzyme from Lactococcus lactis by determining kinetic isotope effects (KIEs) on flavin reduction in anaerobic stopped-flow experiments. Isotope effects were determined at two pH values. At pH 7.0, KIEs were approximately 2-fold for DHO labeled singly at the 5-position or the 6-position and approximately 4-fold for DHO labeled at both the 5- and 6-positions. At pH 8.5, the KIEs observed for DHO labeled at the 5-position, the 6-position, and the 5- and 6-positions were approximately 2-, approximately 3-, and approximately 6-fold, respectively. These isotope effects are consistent with a concerted oxidation of DHO. The pH dependence of reduction was also determined, and a pKa of 8.3 was found. This pKa can be attributed to the ionization of the active site cysteine which deprotonates C5 of DHO during the reaction. To further investigate the importance of the active site base, two site-directed mutants were also studied: Cys130Ala (removal of the active site base) and Cys130Ser (replacement with the active site base used by class 2 DHODs). Both mutant enzymes exhibited binding affinities for DHO similar to that of the wild-type enzyme. Reduction of both mutants was extremely slow compared to that of the wild type; the rate of reduction increased with pH, showing no sign of a plateau. Interestingly, double-deuterium isotope effects on the Cys130Ser mutant also showed a concerted mechanism for flavin reduction.

Measuring intracellular redox conditions using GFP-based sensors.

Recent years have seen the development of methods for analyzing the redox conditions in specific compartments in living cells. These methods are based on genetically encoded sensors comprising variants of Green Fluorescent Protein in which vicinal cysteine residues have been introduced at solvent-exposed positions. Several mutant forms have been identified in which formation of a disulfide bond between these cysteine residues results in changes of their fluorescence properties. The redox sensors have been characterized biochemically and found to behave differently, both spectroscopically and in terms of redox properties. As genetically encoded sensors they can be expressed in living cells and used for analysis of intracellular redox conditions; however, which parameters are measured depends on how the sensors interact with various cellular redox components. Results of both biochemical and cell biological analyses will be discussed.

Mechanistic insight provided by glutaredoxin within a fusion to redox-sensitive yellow fluorescent protein.

Redox-sensitive yellow fluorescent protein (rxYFP) contains a dithiol disulfide pair that is thermodynamically suitable for monitoring intracellular glutathione redox potential. Glutaredoxin 1 (Grx1p) from yeast is known to catalyze the redox equilibrium between rxYFP and glutathione, and here, we have generated a fusion of the two proteins, rxYFP-Grx1p. In comparison to isolated subunits, intramolecular transfer of reducing equivalents made the fusion protein kinetically superior in reactions with glutathione. The rate of GSSG oxidation was thus improved by a factor of 3300. The reaction with GSSG most likely takes place entirely through a glutathionylated intermediate and not through transfer of an intramolecular disulfide bond. However, during oxidation by H(2)O(2), hydroxyethyl disulfide, or cystine, the glutaredoxin domain reacted first, followed by a rate-limiting (0.13 min(-)(1)) transfer of a disulfide bond to the other domain. Thus, reactivity toward other oxidants remains low, giving almost absolute glutathione specificity. We have further studied CPYC --> CPYS variants in the active site of Grx1p and found that the single Cys variant had elevated oxidoreductase activity separately and in the fusion. This could not be ascribed to the lack of an unproductive side reaction to glutaredoxin disulfide. Instead, slower alkylation kinetics with iodoacetamide indicates a better leaving-group capability of the remaining cysteine residue, which can explain the increased activity.

Structure of the bifunctional dCTP deaminase-dUTPase from Methanocaldococcus jannaschii and its relation to other homotrimeric dUTPases.

The bifunctional dCTP deaminase-dUTPase (DCD-DUT) from Methanocaldococcus jannaschii catalyzes the deamination of the cytosine moiety in dCTP and the hydrolysis of the triphosphate moiety forming dUMP, thereby preventing uracil from being incorporated into DNA. The crystal structure of DCD-DUT has been determined to 1.88-A resolution and represents the first known structure of an enzyme catalyzing dCTP deamination. The functional form of DCD-DUT is a homotrimer wherein the subunits are composed of a central distorted beta-barrel surrounded by two beta-sheets and four helices. The trimeric DCD-DUT shows structural similarity to trimeric dUTPases at the tertiary and quaternary levels. There are also additional structural elements in DCD-DUT compared with dUTPase because of a longer primary structure. Four of the five conserved sequence motifs that create the active sites in dUTPase are found in structurally equivalent positions in DCD-DUT. The last 25 C-terminal residues of the 204-residue-long DCD-DUT are not visible in the electron density map, but, analogous to dUTPases, the C terminus is probably ordered, closing the active site upon catalysis. Unlike other enzymes catalyzing the deamination of cytosine compounds, DCD-DUT is not exploiting an enzyme-bound metal ion such as zinc or iron for nucleophile generation. The active site contains two water molecules that are engaged in hydrogen bonds to the invariant residues Ser118, Arg122, Thr130, and Glu145. These water molecules are potential nucleophile candidates in the deamination reaction.

Lactococcus lactis dihydroorotate dehydrogenase A mutants reveal important facets of the enzymatic function.

Dihydroorotate dehydrogenases (DHODs) are flavoenzymes catalyzing the oxidation of (S)-dihydroorotate to orotate in the biosynthesis of UMP, the precursor of all other pyrimidine nucleotides. On the basis of sequence, DHODs can be divided into two classes, class 1, further divided in subclasses 1A and 1B, and class 2. This division corresponds to differences in cellular location and the nature of the electron acceptor. Herein we report a study of Lactococcus lactis DHODA, a representative of the class 1A enzymes. Based on the DHODA structure we selected seven residues that are highly conserved between both main classes of DHODs as well as three residues representing surface charges close to the active site for site-directed mutagenesis. The availability of both kinetic and structural data on the mutant enzymes allowed us to define the roles individual structural segments play in catalysis. We have also structurally proven the presence of an open active site loop in DHODA and obtained information about the interactions that control movements of loops around the active site. Furthermore, in one mutant structure we observed differences between the two monomers of the dimer, confirming an apparent asymmetry between the two substrate binding sites that was indicated by the kinetic results.

A bifunctional dCTP deaminase-dUTP nucleotidohydrolase from the hyperthermophilic archaeon Methanocaldococcus jannaschii.

By the sequential action of dCTP deaminase and dUTPase, dCTP is converted to dUMP, the precursor of thymidine nucleotides. In addition, dUTPase has an essential role as a safeguard against uracil incorporation in DNA. The putative dCTP deaminase (MJ0430) and dUTPase (MJ1102) from the hyperthermophilic archaeon Methanocaldococcus jannaschii were overproduced in Escherichia coli. Unexpectedly, we found the MJ0430 protein capable of both reactions, i.e. hydrolytic deamination of the cytosine ring and hydrolytic cleavage of the phosphoanhydride bond between the alpha- and beta-phosphates. When the reaction was followed by thin layer chromatography using [3H]dCTP as substrate, dUMP and not dUTP was identified as a reaction product. In the presence of unlabeled dUTP, which acted as an inhibitor, no label was transferred from [3H]dCTP to the pool of dUTP. This finding strongly suggests that the two consecutive steps of the reaction are tightly coupled within the enzyme. The hitherto unknown bifunctionality of the MJ0430 protein appears beneficial for the cells because the toxic intermediate dUTP is never released. The MJ0430 protein also catalyzed the hydrolysis of dUTP to dUMP but with a low affinity for the substrate (Km >100 micro m). According to limited proteolysis, the C-terminal residues constitute a flexible region. The other protein investigated, MJ1102, is a specific dUTPase with a Km for dUTP (0.4 micro m) comparable in magnitude with that found for previously characterized dUTPases. Its physiological function is probably to degrade dUTP derived from other reactions in nucleotide metabolism.

The dimeric dihydroorotate dehydrogenase A from Lactococcus lactis dissociates reversibly into inactive monomers.

The flavoenzyme dihydroorotate dehydrogenase A from Lactococcus lactis is a homodimeric protein of 311 residues/subunit, and the two active sites are positioned at a distance from the dimer interface. To promote formation of the monomeric form of the enzyme, we changed the residues involved in formation of two salt bridges formed between the residues Glu206 of the one polypeptide and Lys296 of the other polypeptide. The mutant enzymes formed inactive precipitates when cells were grown at 37 degrees C, but remained soluble and active when cells were grown at 25 degrees C. The salt bridges were not needed for activity, because the mutant enzymes in which one of the residues was converted to an alanine (E206A or K296A) retained almost full activity. The mutant enzymes in which the charge of one of the residues of the salt bridge was inverted (i.e., E206K or K296E) were severely impaired. The double mutant E206K-K296E, which has the possibility of forming salt bridges in the opposite orientation of the wild type, was fully active in concentrated solutions, but dissociated into inactive monomers upon dilution. The K(D) for the dimer to monomer dissociation reaction was 12 microM, and dimer formation was favored by the product, orotate, or by high ionic strength, indicating that the hydrophobic interactions are important for the subunit contacts. Wild-type dihydroorotate dehydrogenase A was similarly found to dissociate into inactive monomers, but with a K(D) for dissociation equal to 0.12 microM. These results imply that the dimeric state is necessary for activity of the enzyme.

E. coli dihydroorotate dehydrogenase reveals structural and functional distinctions between different classes of dihydroorotate dehydrogenases.

The flavoenzymes dihydroorotate dehydrogenases (DHODs) catalyze the fourth and only redox step in the de novo biosynthesis of UMP. Enzymes belonging to class 2, according to their amino acid sequence, are characterized by having a serine residue as the catalytic base and a longer N terminus. The structure of class 2 E. coli DHOD, determined by MAD phasing, showed that the N-terminal extension forms a separate domain. The catalytic serine residue has an environment differing from the equivalent cysteine in class 1 DHODs. Significant differences between the two classes of DHODs were identified by comparison of the E. coli DHOD with the other known DHOD structures, and differences with the class 2 human DHOD explain the variation in their inhibitors.