New Insights into rice pyrimidine catabolic enzymes.

Introduction: Rice is a primary global food source, and its production is affected by abiotic stress, caused by climate change and other factors. Recently, the pyrimidine reductive catabolic pathway, catalyzed by dihydropyrimidine dehydrogenase (DHPD), dihydropyrimidinase (DHP) and ß-ureidopropionase (ß-UP), has emerged as a potential participant in the abiotic stress response of rice. Methods: The rice enzymes were produced as recombinant proteins, and two were kinetically characterized. Rice dihydroorotate dehydrogenase (DHODH), an enzyme of pyrimidine biosynthesis often confused with DHPD, was also characterized. Salt-sensitive and salt-resistant rice seedlings were subjected to salt stress (24 h) and metabolites in leaves were determined by mass spectrometry. Results: The OsDHPD sequence was homologous to the C-terminal half of mammalian DHPD, conserving FMN and uracil binding sites, but lacked sites for Fe/S clusters, FAD, and NADPH. OsDHPD, truncated to eliminate the chloroplast targeting peptide, was soluble, but inactive. Database searches for polypeptides homologous to the N-terminal half of mammalian DHPD, that could act as co-reductants, were unsuccessful. OsDHODH exhibited kinetic parameters similar to those of other plant DHODHs. OsDHP, truncated to remove a signal sequence, exhibited a kcat/Km = 3.6 x 103 s-1M-1. Osb-UP exhibited a kcat/Km = 1.8 x 104 s-1M-1. Short-term salt exposure caused insignificant differences in the levels of the ureide intermediates dihydrouracil and ureidopropionate in leaves of salt-sensitive and salt-resistant plants. Allantoin, a ureide metabolite of purine catabolism, was found to be significantly higher in the resistant cultivar compared to one of the sensitive cultivars. Discussion: OsDHP, the first plant enzyme to be characterized, showed low kinetic efficiency, but its activity may have been affected by truncation. Osb-UP exhibited kinetic parameters in the range of enzymes of secondary metabolism. Levels of two pathway metabolites were similar in sensitive and resistant cultivars and appeared to be unaffected by short-term salt exposure."

Hydrophilic Interaction Liquid Chromatography Coupled to Mass Spectrometry and Multivariate Analysis of the De Novo Pyrimidine Pathway Metabolites.

In this study, we describe the optimization of a Hydrophilic Interaction Liquid Chromatography coupled to mass spectrometry (HILIC-MS) method for the evaluation of 14 metabolites related to the de novo synthesis of pyrimidines (dnSP) while using multivariate analysis, which is the metabolic pathway for pyrimidine nucleotide production. A multivariate design was used to set the conditions of the column temperature, flow of the mobile phase, additive concentration, gradient rate, and pH of the mobile phase in order to attain higher peak resolution and ionization efficiency in shorter analysis times. The optimization process was carried out while using factorial fractional designs, Box-Behnken design and central composite design while using two zwitterionic columns, ZIC-p-HILIC and ZIC-HILIC, polymeric, and silica-based columns, respectively. The factors were evaluated while using resolution (R), retention factor (k), efficiency of the column (N), and peak height (h) as the response variables. The best optimized conditions were found with the ZIC-p-HILIC column: elution gradient rate 2 min., pH 7.0, temperature 45 °C, mobile phase flow of 0.35 mL min-1, and additive (ammonium acetate) concentration of 6 mM. The total analysis time was 28 min. The ZIC-p-HILIC LC-MS method yielded satisfactory results for linearity of calibration curves, limit of detection (LOD), and limit of quantification (LOQ). The method has been shown to be appropriate for the analysis of dnSP on samples of tomato plants that were infected with Phytophthora infestans.

Phytophthora infestans Dihydroorotate Dehydrogenase Is a Potential Target for Chemical Control - A Comparison With the Enzyme From Solanum tuberosum.

The oomycete Phytophthora infestans is the causal agent of tomato and potato late blight, a disease that causes tremendous economic losses in the production of solanaceous crops. The similarities between oomycetes and the apicomplexa led us to hypothesize that dihydroorotate dehydrogenase (DHODH), the enzyme catalyzing the fourth step in pyrimidine biosynthetic pathway, and a validated drug target in treatment of malaria, could be a potential target for controlling P. infestans growth. In eukaryotes, class 2 DHODHs are mitochondrially associated ubiquinone-linked enzymes that catalyze the fourth, and only redox step of de novo pyrimidine biosynthesis. We characterized the enzymes from both the pathogen and a host, Solanum tuberosum. Plant DHODHs are known to be class 2 enzymes. Sequence analysis suggested that the pathogen enzyme (PiDHODHs) also belongs to this class. We confirmed the mitochondrial localization of GFP-PiDHODH showing colocalization with mCherry-labeled ATPase in a transgenic pathogen. N-terminally truncated versions of the two DHODHs were overproduced in E. coli, purified, and kinetically characterized. StDHODH exhibited a apparent specific activity of 41 ± 1 µmol min-1 mg-1, a kcat app of 30 ± 1 s-1, and a Km app of 20 ± 1 µM for L-dihydroorotate, and a Km app= 30 ± 3 µM for decylubiquinone (Qd). PiDHODH exhibited an apparent specific activity of 104 ± 1 µmol min-1 mg-1, a kcat app of 75 ± 1 s-1, and a Km app of 57 ± 3 µM for L-dihydroorotate, and a Km app of 15 ± 1 µM for Qd. The two enzymes exhibited different activities with different quinones and napthoquinone derivatives, and different sensitivities to compounds known to cause inhibition of DHODHs from other organisms. The IC50 for A77 1726, a nanomolar inhibitor of human DHODH, was 2.9 ± 0.6 mM for StDHODH, and 79 ± 1 µM for PiDHODH. In vivo, 0.5 mM A77 1726 decreased mycelial growth by approximately 50%, after 92 h. Collectively, our findings suggest that the PiDHODH could be a target for selective inhibitors and we provide a biochemical background for the development of compounds that could be helpful for the control of the pathogen, opening the way to protein crystallization.

A CTP Synthase Undergoing Stage-Specific Spatial Expression Is Essential for the Survival of the Intracellular Parasite Toxoplasma gondii.

Cytidine triphosphate synthase catalyzes the synthesis of cytidine 5'-triphosphate (CTP) from uridine 5'-triphosphate (UTP), the final step in the production of cytidine nucleotides. CTP synthases also form filamentous structures of different morphologies known as cytoophidia, whose functions in most organisms are unknown. Here, we identified and characterized a novel CTP synthase (TgCTPS) from Toxoplasma gondii. We show that TgCTPS is capable of substituting for its counterparts in the otherwise lethal double mutant (ura7Δ ura8Δ) of Saccharomyces cerevisiae. Equally, recombinant TgCTPS purified from Escherichia coli encodes for a functional protein in enzyme assays. The epitope-tagged TgCTPS under the control of its endogenous promoter displays a punctate cytosolic distribution, which undergoes spatial reorganization to form foci or filament-like structures when the parasite switches from a nutrient-replete (intracellular) to a nutrient-scarce (extracellular) condition. An analogous phenotype is observed upon nutrient stress or after treatment with a glutamine analog, 6-diazo-5-oxo-L-norleucine (DON). The exposure of parasites to DON disrupts the lytic cycle, and the TgCTPS is refractory to a genetic deletion, suggesting an essential requirement of this enzyme for T. gondii. Not least, this study, together with previous studies, supports that CTP synthase can serve as a potent drug target, because the parasite, unlike human host cells, cannot compensate for the lack of CTP synthase activity.

Pyrimidine Pathway-Dependent and -Independent Functions of the Toxoplasma gondii Mitochondrial Dihydroorotate Dehydrogenase.

Dihydroorotate dehydrogenase (DHODH) mediates the fourth step of de novo pyrimidine biosynthesis and is a proven drug target for inducing immunosuppression in therapy of human disease as well as a rapidly emerging drug target for treatment of malaria. In Toxoplasma gondii, disruption of the first, fifth, or sixth step of de novo pyrimidine biosynthesis induced uracil auxotrophy. However, previous attempts to generate uracil auxotrophy by genetically deleting the mitochondrion-associated DHODH of T. gondii (TgDHODH) failed. To further address the essentiality of TgDHODH, mutant gene alleles deficient in TgDHODH activity were designed to ablate the enzyme activity. Replacement of the endogenous DHODH gene with catalytically deficient DHODH gene alleles induced uracil auxotrophy. Catalytically deficient TgDHODH localized to the mitochondria, and parasites retained mitochondrial membrane potential. These results show that TgDHODH is essential for the synthesis of pyrimidines and suggest that TgDHODH is required for a second essential function independent of its role in pyrimidine biosynthesis.

Pyrimidine Metabolism: Dynamic and Versatile Pathways in Pathogens and Cellular Development.

The importance of pyrimidines lies in the fact that they are structural components of a broad spectrum of key molecules that participate in diverse cellular functions, such as synthesis of DNA, RNA, lipids, and carbohydrates. Pyrimidine metabolism encompasses all enzymes involved in the synthesis, degradation, salvage, interconversion and transport of these molecules. In this review, we summarize recent publications that document how pyrimidine metabolism changes under a variety of conditions, including, when possible, those studies based on techniques of genomics, transcriptomics, proteomics, and metabolomics. First, we briefly look at the dynamics of pyrimidine metabolism during nonpathogenic cellular events. We then focus on changes that pathogen infections cause in the pyrimidine metabolism of their host. Next, we discuss the effects of antimetabolites and inhibitors, and finally we consider the consequences of genetic manipulations, such as knock-downs, knock-outs, and knock-ins, of pyrimidine enzymes on pyrimidine metabolism in the cell.

De novo pyrimidine biosynthesis in the oomycete plant pathogen Phytophthora infestans.

The oomycete Phytophthora infestans, causal agent of the tomato and potato late blight, generates important economic and environmental losses worldwide. As current control strategies are becoming less effective, there is a need for studies on oomycete metabolism to help identify promising and more effective targets for chemical control. The pyrimidine pathways are attractive metabolic targets to combat tumors, virus and parasitic diseases but have not yet been studied in Phytophthora. Pyrimidines are involved in several critical cellular processes and play structural, metabolic and regulatory functions. Here, we used genomic and transcriptomic information to survey the pyrimidine metabolism during the P. infestans life cycle. After assessing the putative gene machinery for pyrimidine salvage and de novo synthesis, we inferred genealogies for each enzymatic domain in the latter pathway, which displayed a mosaic origin. The last two enzymes of the pathway, orotate phosphoribosyltransferase and orotidine-5-monophosphate decarboxylase, are fused in a multi-domain enzyme and are duplicated in some P. infestans strains. Two splice variants of the third gene (dihydroorotase) were identified, one of them encoding a premature stop codon generating a non-functional truncated protein. Relative expression profiles of pyrimidine biosynthesis genes were evaluated by qRT-PCR during infection in Solanum phureja. The third and fifth genes involved in this pathway showed high up-regulation during biotrophic stages and down-regulation during necrotrophy, whereas the uracil phosphoribosyl transferase gene involved in pyrimidine salvage showed the inverse behavior. These findings suggest the importance of de novo pyrimidine biosynthesis during the fast replicative early infection stages and highlight the dynamics of the metabolism associated with the hemibiotrophic life style of pathogen.

Biochemical and molecular characterization of the pyrimidine biosynthetic enzyme dihydroorotate dehydrogenase from Toxoplasma gondii.

The pyrimidine biosynthesis pathway in the protozoan pathogen Toxoplasma gondii is essential for parasite growth during infection. To investigate the properties of dihydroorotate dehydrogenase (TgDHOD), the fourth enzyme in the T. gondii pyrimidine pathway, we expressed and purified recombinant TgDHOD. TgDHOD exhibited a specific activity of 84U/mg, a k(cat) of 89s(-1), a K(m)=60µM for l-dihydroorotate, and a K(m)=29µM for decylubiquinone (Q(D)). Quinones lacking or having short isoprenoid side chains yielded lower k(cat)s than Q(D). As expected, fumarate was a poor electron acceptor for this family 2 DHOD. The IC(50)s determined for A77-1726, the active derivative of the human DHOD inhibitor leflunomide, and related compounds MD249 and MD209 were, 91µM, 96µM, and 60µM, respectively. The enzyme was not significantly affected by brequinar or TTFA, known inhibitors of human DHOD, or by atovaquone. DSM190, a known inhibitor of Plasmodium falciparum DHOD, was a poor inhibitor of TgDHOD. TgDHOD exhibits a lengthy 157-residue N-terminal extension, consistent with a potential organellar targeting signal. We constructed C-terminally c-myc tagged TgDHODs to examine subcellular localization of TgDHOD in transgenic parasites expressing the tagged protein. Using both exogenous and endogenous expression strategies, anti-myc fluorescence signal colocalized with antibodies against the mitochondrial marker ATPase. These findings demonstrate that TgDHOD is associated with the parasite's mitochondrion, revealing this organelle as the site of orotate production in T. gondii. The TgDHOD gene appears to be essential because while gene tagging was successful at the TgDHOD gene locus, attempts to delete the TgDHOD gene were not successful in the KU80 background. Collectively, our study suggests that TgDHOD is an excellent target for the development of anti-Toxoplasma drugs.

Caracterizaciónppreliminar de compuestos antiliteriales producidos por bacteriias ácido lácticas nativas / Partialcharacterrization of antilisterial compounds prouced by native lactic acid bacteria

Objetivo. Caracterizar los metabolitos producidos por bacterias ácido lácticas nativas con capacidad antilisterial. Materiales y métodos. Se analizaron 42 muestras tomadas de alimentos y equipos procesadores de alimentos, de donde se aislaron bacterias ácido lácticas, las cuales se identificaron por medio de pruebas bioquímicas. Se evaluó la actividad antagónica de las cepas aisladas frente a 17 cepas de L. monocytogenes pertenecientes a los serotipos 4b, 4e, y 3b utilizando la técnica de la gota y doble capa. Se obtuvieron extractos crudos para la caracterización de los metabolitos inhibitorios del crecimiento de las cepas de L. monocytogenes, los cuales fueron tratados con catalasa, ácido clorhídrico, proteinasa K y temperaturas de 95°C y 121°C. El peso molecular de las proteínas se aproximó utilizando la técnica de electroforesis SDS-PAGE y bioensayos. Resultados. De un total de 250 aislamientos se lograron identificar 75 cepas de bacterias ácido lácticas. La evaluación de la actividad antagónica indicó que los metabolitos inhibitorios producidos por las bacterias ácido lácticas no actuaban de igual manera frente a las diferentes cepas de L. monocytogenes. Sin embargo, se encontró que tres de los aislamientos nativos identificados como Lactobacillus spp., Leuconostoc spp. y Enterococcus spp. presentaban una mejor actividad antilisterial debido a que sintetizan proteínas o metabolitos de peso molecular menor a 7600 Da. Conclusiones. En los alimentos distribuidos en Colombia existen cepas de bacterias ácido lácticas con potencial bioprotector.

Objective. Characterization of antilisterial compounds produced by native lactic acid bacteria. Materials and methods. Lactic acid bacteria (LAB) were isolated from 42 samples collected from foods and food processing equipment. Identification of LAB species was assessed by biochemical reactions. The antilisterial activities of the isolates were tested against 17 L. monocytogenes strains belonging to 4b, 4e and 3b serotypes, by the agar differed spot on the lawn technique. Crude extracts were subjected to catalase, proteinase K, hydrochloric acid and high temperature (95°C and 121°C) treatments in order to characterize the antilisterial compounds. The molecular weights were estimated by SDS-PAGE and bioassays were performed. Results. Seventy five strains were identified out of 250 lactic acid bacteria isolates. The inhibitory compounds produced by LAB displayed dissimilar activities against the different L. monocytogenes strains. Furthermore, three native isolates identified as Lactobacillus spp., Leuconostoc spp. and Enterococcus spp. showed improved antilisterial effect due to the production of compounds with molecular weight below 7600 Da. Conclusions. We demonstrated the presence of native lactic acid bacteria with potential as biocontrolers in foods distributed in Colombia.

Cloning and preliminary characterization of the dihydroorotase from Toxoplasma gondii.

A full-length dihydroorotase (DHOase) sequence was cloned from a Toxoplasma gondii tachyzoite cDNA library. The sequence had a calculated molecular mass of 44.2 kDa and a pI of 5.72, and was most similar to type IIa DHOases. A recombinant protein was expressed and purified with a yield of approximately 20 mg L(-1) of cell culture. Polyclonal antibodies raised against purified recombinant protein reacted with a band of the expected molecular mass in tachyzoite extracts. Specific activities of 18.3 micromol/min/mg in the biosynthetic direction and 18.4 micromol/min/mg in the degradative direction, with K(m, carbamyl aspartate) = 323 microM and K(m, dihydroorotate) = 64.3 microM, were measured for purified recombinant protein. Size exclusion chromatography/laser light scattering showed a single, monodisperse peak with a molecular mass of 45.6 kDa, suggesting that the native protein is a monomer.

Cloning and expression of the dihydroorotate dehydrogenase from Toxoplasma gondii.

A full-length dihydroorotate dehydrogenase (DHODase) sequence was cloned from a Toxoplasma gondii tachyzoite cDNA library. The sequence was most similar to family 2 DHODases, and had a calculated molecular mass of 65.1 kDa. The full-length and two N-terminally truncated T. gondii DHODase sequences were expressed as recombinant proteins. One of the truncated sequences complemented a DHODase-deficient bacterial host.

Molecular cloning, recombinant expression and partial characterization of the aspartate transcarbamoylase from Toxoplasma gondii.

A cDNA coding for a monofunctional aspartate transcarbamoylase (ATCase) was isolated from a Toxoplasma gondii tachyzoite cDNA library using a complementation method. The calculated molecular mass of the deduced amino acid sequence was 46.8 kDa, with a predicted pI of 7.1. Size exclusion chromatography/laser-light scattering showed a single, monodisperse peak with molecular mass of 144 kDa. Amino acid sequence alignments revealed that active site residues of the Escherichia coli ATCase catalytic chain were conserved in the T. gondii sequence, and the latter shared 26-33% overall sequence identity with other ATCases. A recombinant enzyme was overexpressed in E. coli, and was purified with a yield of approximately 0.8 mg l(-1) culture. The temperature dependence of the recombinant enzyme was similar to that of native ATCase in T. gondii extracts. The K(m)'s for aspartate and carbamoyl phosphate were 7.82 mM, and 67.6 microM, respectively. The V(max) was 23900 micromol h(-1) mg(-1). Pyrimidine nucleotides had no significant effect on the enzyme's activity. N-phosphonoacetyl-L-aspartate (PALA) inhibited the enzyme with K(i)=0.38 microM. The T. gondii ATCases contained two additional sequences of approximately 24 residues each, which are not found in other ATCases. One of these sequences was susceptible to proteolysis by elastase.