Glycosomes: A comprehensive view of their metabolic roles in T. brucei

Peroxisomes are single-membrane cellular organelles, present in most eukaryotic cells and organisms from human to yeast, fulfilling essential metabolic functions in lipid metabolism, free radical detoxification, differentiation, development, morphogenesis, etc. Interestingly, the protozoan parasite species Trypanosoma contains peroxisome-like organelles named glycosomes, which lack hallmark peroxisomal pathways and enzymes, such as catalase. Glycosomes are the only peroxisome-like organelles containing most enzymatic steps of the glycolytic pathway as well as enzymes of pyrimidine biosynthesis, purine salvage and biosynthesis of nucleotide sugars. We present here an overview of the glycosomal metabolic peculiarities together with the current view of the raison d'être of this unique metabolic peroxisomal sequestration.     

Purine nucleotide metabolism in phytohemagglutinin-induced human T lymphocytes

The comprehensive studies of purine nucleotide metabolism were done in nonstimulated and phytohemagglutinin (PHA)-stimulated human peripheral blood T lymphocytes. Nonstimulated lymphocytes synthesize nucleotides in two alternative pathways: via biosynthesis de novo and salvage pathways. Although synthesis of triphosphonucleosides in unstimulated lymphocytes was the predominant pathway, interconversion of monophosphonucleosides was also active. Exposure of cells to PHA affects differently various pathways of nucleotide metabolism. The most marked changes observed were rapid activation of purine salvage within minutes after exposure to PHA, and significant increase of 5-phosphoribosyl-1-pyrophosphate levels. In addition, significant increases were found in de novo purine biosynthesis, nucleotide interconversions, and RNA and DNA synthesis, whereas catabolism of nucleotides remained unchanged. These results indicate that PHA activation of T lymphocytes causes a rapid synthesis of nucleotides which may be required immediately for increases in energy metabolism and later as the precursors of nucleic acid synthesis.     

Comparative genomics of nucleotide metabolism: a tour to the past of the three cellular domains of life

Background

Nucleotide metabolism is central to all biological systems, due to their essential role in genetic information and energy transfer, which in turn suggests its possible presence in the last common ancestor (LCA) of Bacteria, Archaea and Eukarya. In this context, elucidation of the contribution of the origin and diversification of de novo and salvage pathways of nucleotide metabolism will allow us to understand the links between the enzymatic steps associated with the LCA and the emergence of the first metabolic pathways.

Results

In this work, the taxonomical distribution of the enzymes associated with nucleotide metabolism was evaluated in 1,606 complete genomes. 151 sequence profiles associated with 120 enzymatic reactions were used. The evaluation was based on profile comparisons, using RPS-Blast. Organisms were clustered based on their taxonomical classifications, in order to obtain a normalized measure of the taxonomical distribution of enzymes according to the average of presence/absence of enzymes per genus, which in turn was used for the second step, to calculate the average presence/absence of enzymes per Clade.

Conclusion

From these analyses, it was suggested that divergence at the enzymatic level correlates with environmental changes and related modifications of the cell wall and membranes that took place during cell evolution. Specifically, the divergence of the 5-(carboxyamino) imidazole ribonucleotide mutase to phosphoribosylaminoimidazole carboxylase could be related to the emergence of multicellularity in eukaryotic cells. In addition, segments of salvage and de novo pathways were probably complementary in the LCA to the synthesis of purines and pyrimidines. We also suggest that a large portion of the pathway to inosine 5’-monophosphate (IMP) in purines could have been involved in thiamine synthesis or its derivatives in early stages of cellular evolution, correlating with the fact that these molecules may have played an active role in the protein-RNA world. The analysis presented here provides general observations concerning the adaptation of the enzymatic steps in the early stages of the emergence of life and the LCA.

Electronic supplementary material

The online version of this article (doi:10.1186/1471-2164-15-800) contains supplementary material, which is available to authorized users.     

An Enzymatic Platform for the Synthesis of Isoprenoid Precursors

The isoprenoid family of compounds is estimated to contain ∼65,000 unique structures including medicines, fragrances, and biofuels. Due to their structural complexity, many isoprenoids can only be obtained by extraction from natural sources, an inherently risky and costly process. Consequently, the biotechnology industry is attempting to genetically engineer microorganisms that can produce isoprenoid-based drugs and fuels on a commercial scale. Isoprenoid backbones are constructed from two, five-carbon building blocks, isopentenyl 5-pyrophosphate and dimethylallyl 5-pyrophosphate, which are end-products of either the mevalonate or non-mevalonate pathways. By linking the HMG-CoA reductase pathway (which produces mevalonate) to the mevalonate pathway, these building block can be synthesized enzymatically from acetate, ATP, NAD(P)H and CoA. Here, the enzymes in these pathways are used to produce pathway intermediates and end-products in single-pot reactions and in remarkably high yield, ∼85%. A strategy for the regio-specific incorporation of isotopes into isoprenoid backbones is developed and used to synthesize a series of isotopomers of diphosphomevalonate, the immediate end-product of the mevalonate pathway. The enzymatic system is shown to be robust and capable of producing quantities of product in aqueous solutions that meet or exceed the highest levels achieved using genetically engineered organisms in high-density fermentation.     

The Role of Gene Duplication in the Evolution of Purine Nucleotide Salvage Pathways

Purine nucleotides are formed de novo by a widespread biochemical route that may be of monophyletic origin, or are synthesized from preformed purine bases and nucleosides through different salvage pathways. Three monophyletic sets of purine salvage enzymes, each of which catalyzes mechanistically similar reactions, can be identified: (a) adenine-, xanthine-, hypoxanthine- and guanine-phosphoribosyltransferases, which are all homologous among themselves, as well as to nucleoside phosphorylases; (b) adenine deaminase, adenosine deaminase, and adenosine monophophate deaminase; and (c) guanine reductase and inosine monophosphate dehydrogenase. These homologies support the idea that substrate specificity is the outcome of gene duplication, and that the purine nucleotide salvage pathways were assembled by a patchwork process that probably took place before the divergence of the three cell domains (Bacteria, Archaea, and Eucarya). Based on the ability of adenine PRTase to catalyze the condensation of PRPP with 4-aminoimidazole-5-carboxamide (AICA), a simpler scheme of purine nucleotide biosynthesis is presented. This hypothetical route requires the prior evolution of PRPP biosynthesis. Since it has been argued that PRPP, nucleosides, and nucleotides are susceptible to hydrolysis, they are very unlikely prebiotic compounds. If this is the case, it implies that many purine salvage pathways appeared only after the evolution of phosphorylated sugar biosynthetic pathways made ribosides available.     

Dicer-independent,Ago2-mediated microRNA biogenesis in vertebrates

A canonical biogenesis pathway involving sequential cleavage by the Drosha and Dicer RNAse III enzymes governs the maturation of most animal microRNAs. However, there exist a variety of alternative miRNA biogenesis pathways, most of which bypass Drosha processing. Recently, three groups described for the first time a vertebrate microRNA pathway that bypasses Dicer cleavage. This mechanism was characterized with respect to the highly conserved vertebrate gene mir-451, for which Drosha processing yields a short (42 nucleotide) hairpin that is directly loaded into Ago2, the sole vertebrate “Slicer” Argonaute. Ago2-mediated cleavage of this hairpin yields a 30 nucleotide intermediate, whose 3′ end is resected to generate the dominantly cloned ∼23 nucleotide mature miR-451. Knowledge of this pathway provides an unprecedented tool with which to express microRNAs and small interfering RNAs in Dicer mutant cells. More generally, the mir-451 backbone constitutes a new platform for gene silencing that complements existing shRNA technology.Key words: mir-451, Ago2, Slicer, Dicer-independent, erythropoiesis     

Diverse strategies adopted by nature for regulating purine biosynthesis via fine-tuning of purine metabolic enzymes

Purine nucleotides, generated by de novo synthesis and salvage pathways, are essential for metabolism and act as building blocks of genetic material. To avoid an imbalance in the nucleotide pool, nature has devised several strategies to regulate/tune the catalytic performance of key purine metabolic enzymes. Here, we discuss some recent examples, such as stress-regulating alarmones that bind to select pathway enzymes, huge ensembles like dynamic metabolons and self-assembled filaments that highlight the layered fine-control prevalent in the purine metabolic pathway to fulfill requisite purine demands. Examples of enzymes that turn-on only under allosteric control, are regulated via long-distance communication that facilitates transient conduits have additionally been explored.     

DNA assembler,an in vivo genetic method for rapid construction of biochemical pathways

The assembly of large recombinant DNA encoding a whole biochemical pathway or genome represents a significant challenge. Here, we report a new method, DNA assembler, which allows the assembly of an entire biochemical pathway in a single step via in vivo homologous recombination in Saccharomyces cerevisiae. We show that DNA assembler can rapidly assemble a functional d-xylose utilization pathway (∼9 kb DNA consisting of three genes), a functional zeaxanthin biosynthesis pathway (∼11 kb DNA consisting of five genes) and a functional combined d-xylose utilization and zeaxanthin biosynthesis pathway (∼19 kb consisting of eight genes) with high efficiencies (70–100%) either on a plasmid or on a yeast chromosome. As this new method only requires simple DNA preparation and one-step yeast transformation, it represents a powerful tool in the construction of biochemical pathways for synthetic biology, metabolic engineering and functional genomics studies.     

Relative importance of alternative pathways of purine nucleotide biosynthesis in Ehrlich ascites tumor cells in vivo.

Several alternative pathways of purine nucleotide synthesis coexist in cells and the relative importance of each pathway for maintaining purine nucleotide concentrations in cells have been studied. Specific inhibitors were used to block these synthetic routes in Ehrlich ascites tumor cells in vivo and the effect of inhibiting each pathway was evaluated by measuring intracellular purine nucleotide concentrations by high-speed liquid chromatography. The results of this study indicate that adenosine triphosphate and guanosine triphosphate concentrations of Ehrlich ascites tumor cells are maintained primarily by purine biosynthesis de novo although other pathways do make significant contributions.     

Metabolism of xanthine and hypoxanthine in the tea plant (Thea sinensis L.).

1. The metabolism of xanthine and hypoxanthine in excised shoot tips of tea was studied with micromolar amounts of [2(-14)C]xanthine or [8(-14)C]hypoxanthine. Almost all of the radioactive compounds supplied were utilized by tea shoot tips by 30 h after their uptake. 2. The main products of [2(-14)C]xanthine and [8(-14)C]hypoxanthine metabolism in tea shoots were urea, allantoin and allantoic acid. There was also incorporation of the label into theobromine, caffeine and RNA purine nucleotides. 3. The results indicate that tea plants can catabolize purine bases by the same pathways as animals. It is also suggested that tea plants have the ability to snythesize purine nucleotides from glycine by the pathways of purine biosynthesis de novo and from hypoxanthine and xanthine by the pathway of purine salvage. 4. The results of incorporation of more radioactivity from [8(-14)C]hypoxanthine than from [2(-14)C]xanthine into RNA purine nucleotides and caffeine suggest that hypoxanthine is a more effective precursor of caffeine biosynthesis than xanthine. The formation of caffeine from hypoxanthine is a result of nucleotide synthesis via the pathway of purine salvage.     

Cytokinin biosynthesis and interconversion

To maintain hormone homeostasis, the rate of cytokinin biosynthesis, interconversion, and degradation is regulated by enzymes in plant cells. Cytokinins can be synthesized via direct (de novo) or indirect (tRNA) pathways. In the de novo pathway, a cytokinin nucleotide is synthesized from 5'-AMP and isopentenyl pyrophosphate; a key enzyme which catalyzes this synthesis has been isolated from plant tissues, slime mold, and some microorganisms. Studies on the in vitro synthesis of the isopentenyl side chain of cytokinin in tRNA demonstrated that the isopentenyl group was derived from mevalonate, and turnover of the cytokinin-containing tRNA may serve as a minor source of free cytokinins in plant cells. The interconversion of cytokinin bases, nucleosides and nucleotides is a major feature of cytokinin metabolism; and enzymes that regulate the interconversion have been identified. The N⁶-side chain and purine moiety of cytokinins are often modified and some of the enzymes involved in the modifications have been isolated. Most of the cytokinin metabolites have been characterized but very few enzymes regulating their metabolism have been purified to homogeneity. It remains a significant challenge to isolate plant genes involved in the regulation of cytokinin biosynthesis, interconversion and degradation.     

Evolutionary origin and functional diversification of aminotransferases

Aminotransferases (ATs) are pyridoxal 5′-phosphate–dependent enzymes that catalyze the transamination reactions between amino acid donor and keto acid acceptor substrates. Modern AT enzymes constitute ∼2% of all classified enzymatic activities, play central roles in nitrogen metabolism, and generate multitude of primary and secondary metabolites. ATs likely diverged into four distinct AT classes before the appearance of the last universal common ancestor and further expanded to a large and diverse enzyme family. Although the AT family underwent an extensive functional specialization, many AT enzymes retained considerable substrate promiscuity and multifunctionality because of their inherent mechanistic, structural, and functional constraints. This review summarizes the evolutionary history, diverse metabolic roles, reaction mechanisms, and structure–function relationships of the AT family enzymes, with a special emphasis on their substrate promiscuity and multifunctionality. Comprehensive characterization of AT substrate specificity is still needed to reveal their true metabolic functions in interconnecting various branches of the nitrogen metabolic network in different organisms.     

Effect of short-term salt stress on the metabolic profiles of pyrimidine, purine and pyridine nucleotides in cultured cells of the mangrove tree, Bruguiera sexangula

To investigate the short‐term (3 h) effect of salt on the metabolism of purine, pyrimidine and pyridine nucleotides in mangrove (Bruguiera sexangula) cells, we examined the uptake and overall metabolism of radiolabelled intermediates involved in the de novo pathways and substrates of salvage pathways for nucleotide biosynthesis in the presence and absence of 100 mM NaCl. Uptake by the cells of substrates for the salvage pathways was much faster than uptake of intermediates of the de novo pathways. The activity of the de novo pyrimidine biosynthesis estimated by [2‐¹⁴C]orotate metabolism was not significantly affected by the salt. About 20–30% of [2‐¹⁴C]uridine, [2‐¹⁴C]uracil and more than 50% of [2‐¹⁴C]cytidine were salvaged for pyrimidine nucleotide biosynthesis. However, substantial quantities of these compounds were degraded to ¹⁴CO₂ via β‐ureidopropionate (β‐UP), and degradation of β‐UP was increased by the salt. The activities of the de novo pathway, estimated by [2‐¹⁴C] 5‐aminoimidazole‐4‐carboxamide ribonucleoside, and the salvage pathways from [8‐¹⁴C]adenosine and [8‐¹⁴C]guanosine for the purine nucleotide biosynthesis were not influenced by the salt. Most [8‐¹⁴C]hypoxanthine was catabolised to ¹⁴CO₂, and other purine compounds are also catabolised via xanthine. Purine catabolism was stimulated by the salt. [³H]Quinolinate, [carbonyl‐¹⁴C]nicotinamide and [carboxyl‐¹⁴C]nicotinic acid were utilised for the biosynthesis of pyridine nucleotides. The salvage pathways for pyridine nucleotides were significantly stimulated by the salt. Trigonelline was synthesised from all pyridine precursors that were examined; its synthesis was also stimulated by the salt. We discuss the physiological role of the salt‐stimulated reactions of nucleotide metabolism.     

Thiamine in plants: Aspects of its metabolism and functions

Thiamine diphosphate (vitamin B₁) plays a fundamental role as an enzymatic cofactor in universal metabolic pathways including glycolysis, the pentose phosphate pathway, and the tricarboxylic acid cycle. In addition, thiamine diphosphate has recently been shown to have functions other than as a cofactor in response to abiotic and biotic stress in plants. Recently, several steps of the plant thiamine biosynthetic pathway have been characterized, and a mechanism of feedback regulation of thiamine biosynthesis via riboswitch has been unraveled. This review focuses on these most recent advances made in our understanding of thiamine metabolism and functions in plants. Phenotypes of plant mutants affected in thiamine biosynthesis are described, and genomics, proteomics, and metabolomics data that have increased further our knowledge of plant thiamine metabolic pathways and functions are summarized. Aspects of thiamine metabolism such as catabolism, salvage, and transport in plants are discussed.     

The origin and evolution of modern metabolism

One fundamental goal of current research is to understand how complex biomolecular networks took the form that we observe today. Cellular metabolism is probably one of the most ancient biological networks and constitutes a good model system for the study of network evolution. While many evolutionary models have been proposed, a substantial body of work suggests metabolic pathways evolve fundamentally by recruitment, in which enzymes are drawn from close or distant regions of the network to perform novel chemistries or use different substrates. Here we review how structural and functional genomics has impacted our knowledge of evolution of modern metabolism and describe some approaches that merge evolutionary and structural genomics with advances in bioinformatics. These include mining the data on structure and function of enzymes for salient patterns of enzyme recruitment. Initial studies suggest modern metabolism originated in enzymes of nucleotide metabolism harboring the P-loop hydrolase fold, probably in pathways linked to the purine metabolic subnetwork. This gateway of recruitment gave rise to pathways related to the synthesis of nucleotides and cofactors for an ancient RNA world. Once the TIM beta/alpha-barrel fold architecture was discovered, it appears metabolic activities were recruited explosively giving rise to subnetworks related to carbohydrate and then amino acid metabolism. Remarkably, recruitment occurred in a layered system reminiscent of Morowitz's prebiotic shells, supporting the notion that modern metabolism represents a palimpsest of ancient metabolic chemistries.     

Analysis of the Arabidopsis cytosolic proteome highlights subcellular partitioning of central plant metabolism

The plant cell cytosol is a dynamic and complex intracellular matrix that, by definition, contains no compartmentalization. Nonetheless, it maintains a wide variety of biochemical networks and often links metabolic pathways across multiple organelles. There have been numerous detailed proteomic studies of organelles in the model plant Arabidopsis thaliana, although no such analysis has been undertaken on the cytosol. The cytosolic protein fraction from cell suspensions of Arabidopsis thaliana was isolated and analyzed using offline strong cation exchange liquid chromatography and LC-MS/MS. This generated a robust set of 1071 cytosolic proteins. Functional annotation of this set revealed major activities in protein synthesis and degradation, RNA metabolism and basic sugar metabolism. This included an array of important cytosol-related functions, specifically the ribosome, the set of tRNA catabolic enzymes, the ubiquitin-proteasome pathway, glycolysis and associated sugar metabolism pathways, phenylpropanoid biosynthesis, vitamin metabolism, nucleotide metabolism, an array of signaling and stress-responsive molecules, and NDP-sugar biosynthesis. This set of cytosolic proteins provides for the first time an extensive analysis of enzymes responsible for the myriad of reactions in the Arabidopsis cytosol and defines an experimental set of plant protein sequences that are not targeted to subcellular locations following translation and folding in the cytosol.     

Plastid-associated Porphobilinogen Synthase from Toxoplasma gondii: KINETIC AND STRUCTURAL PROPERTIES VALIDATE THERAPEUTIC POTENTIAL*

Apicomplexan parasites (including Plasmodium spp. and Toxoplasma gondii) employ a four-carbon pathway for de novo heme biosynthesis, but this pathway is distinct from the animal/fungal C4 pathway in that it is distributed between three compartments: the mitochondrion, cytosol, and apicoplast, a plastid acquired by secondary endosymbiosis of an alga. Parasite porphobilinogen synthase (PBGS) resides within the apicoplast, and phylogenetic analysis indicates a plant origin. The PBGS family exhibits a complex use of metal ions (Zn²⁺ and Mg²⁺) and oligomeric states (dimers, hexamers, and octamers). Recombinant T. gondii PBGS (TgPBGS) was purified as a stable ∼320-kDa octamer, and low levels of dimers but no hexamers were also observed. The enzyme displays a broad activity peak (pH 7–8.5), with a K_m for aminolevulinic acid of ∼150 μm and specific activity of ∼24 μmol of porphobilinogen/mg of protein/h. Like the plant enzyme, TgPBGS responds to Mg²⁺ but not Zn²⁺ and shows two Mg²⁺ affinities, interpreted as tight binding at both the active and allosteric sites. Unlike other Mg²⁺-binding PBGS, however, metal ions are not required for TgPBGS octamer stability. A mutant enzyme lacking the C-terminal 13 amino acids distinguishing parasite PBGS from plant and animal enzymes purified as a dimer, suggesting that the C terminus is required for octamer stability. Parasite heme biosynthesis is inhibited (and parasites are killed) by succinylacetone, an active site-directed suicide substrate. The distinct phylogenetic, enzymatic, and structural features of apicomplexan PBGS offer scope for developing selective inhibitors of the parasite enzyme based on its quaternary structure characteristics.     

Genetical and biochemical evidence that a novel dinucleoside polyphosphate coordinates salvage and de novo nucleotide biosynthetic pathways in mammalian cells

Studies with ‘wild type’ Chinese hamster ovary cells and mutant derivatives defective in purine salvage and $\text{de novo}$ nucleotide biosynthesis pathways have brought to light the possibility that an unusual dinucleoside polyphosphate, HS-3 (see appendix) is a crucial regulator of these two pathways. Three antitumor drugs, methotrexate, 5-fluorouracil and azaserine as well as L-glutamine, purines and pyrimidines were used to define the loci of HS-3 metabolism. Wild type and salvage pathways mutants accumulated HS-3 in the absence of glutamine. $\text{De novo}$ pathways mutant accumulated HS-3 only when purine was absent. Depletion of HS-3 was induced in wild type and $\text{de novo}$ mutant cell lines by purine compounds. Salvage pathways mutants did not cause depletion of HS-3 when supplied with purines or pyrimidines, except 5-fluorouracil. Data indicate that HS-3 is probably synthesised when an early step in purine nucleotide synthesis is blocked and depleted when the salvage pathways are operative. HS-3 may be an important factor in certain diseases involving nucleotide metabolism.