Wild-Type Phosphoribosylpyrophosphate Synthase (PRS) from Mycobacterium tuberculosis: A Bacterial Class II PRS?

The 5-phospho-α-D-ribose 1-diphosphate (PRPP) metabolite plays essential roles in several biosynthetic pathways, including histidine, tryptophan, nucleotides, and, in mycobacteria, cell wall precursors. PRPP is synthesized from α-D-ribose 5-phosphate (R5P) and ATP by the Mycobacterium tuberculosis prsA gene product, phosphoribosylpyrophosphate synthase (MtPRS). Here, we report amplification, cloning, expression and purification of wild-type MtPRS. Glutaraldehyde cross-linking results suggest that MtPRS predominates as a hexamer, presenting varied oligomeric states due to distinct ligand binding. MtPRS activity measurements were carried out by a novel coupled continuous spectrophotometric assay. MtPRS enzyme activity could be detected in the absence of Pi. ADP, GDP and UMP inhibit MtPRS activity. Steady-state kinetics results indicate that MtPRS has broad substrate specificity, being able to accept ATP, GTP, CTP, and UTP as diphosphoryl group donors. Fluorescence spectroscopy data suggest that the enzyme mechanism for purine diphosphoryl donors follows a random order of substrate addition, and for pyrimidine diphosphoryl donors follows an ordered mechanism of substrate addition in which R5P binds first to free enzyme. An ordered mechanism for product dissociation is followed by MtPRS, in which PRPP is the first product to be released followed by the nucleoside monophosphate products to yield free enzyme for the next round of catalysis. The broad specificity for diphosphoryl group donors and detection of enzyme activity in the absence of Pi would suggest that MtPRS belongs to Class II PRS proteins. On the other hand, the hexameric quaternary structure and allosteric ADP inhibition would place MtPRS in Class I PRSs. Further data are needed to classify MtPRS as belonging to a particular family of PRS proteins. The data here presented should help augment our understanding of MtPRS mode of action. Current efforts are toward experimental structure determination of MtPRS to provide a solid foundation for the rational design of specific inhibitors of this enzyme

A transcriptomic analysis of Echinococcus granulosus larval stages:implications for parasite biology and host adaptation

The cestode Echinococcus granulosus--the agent of cystic echinococcosis, a zoonosis affecting humans and domestic animals worldwide--is an excellent model for the study of host-parasite cross-talk that interfaces with two mammalian hosts. To develop the molecular analysis of these interactions, we carried out an EST survey of E. granulosus larval stages. We report the salient features of this study with a focus on genes reflecting physiological adaptations of different parasite stages.We generated ~10,000 ESTs from two sets of full-length enriched libraries (derived from oligo-capped and trans-spliced cDNAs) prepared with three parasite materials: hydatid cyst wall, larval worms (protoscoleces), and pepsin/H(+)-activated protoscoleces. The ESTs were clustered into 2700 distinct gene products. In the context of the biology of E. granulosus, our analyses reveal: (i) a diverse group of abundant long non-protein coding transcripts showing homology to a middle repetitive element (EgBRep) that could either be active molecular species or represent precursors of small RNAs (like piRNAs); (ii) an up-regulation of fermentative pathways in the tissue of the cyst wall; (iii) highly expressed thiol- and selenol-dependent antioxidant enzyme targets of thioredoxin glutathione reductase, the functional hub of redox metabolism in parasitic flatworms; (iv) candidate apomucins for the external layer of the tissue-dwelling hydatid cyst, a mucin-rich structure that is critical for survival in the intermediate host; (v) a set of tetraspanins, a protein family that appears to have expanded in the cestode lineage; and (vi) a set of platyhelminth-specific gene products that may offer targets for novel pan-platyhelminth drug development.This survey has greatly increased the quality and the quantity of the molecular information on E. granulosus and constitutes a valuable resource for gene prediction on the parasite genome and for further genomic and proteomic analyses focused on cestodes and platyhelminths

Pulse Proteolysis and Precipitation for Target Identification

In recent years, phenotypic screening has assumed a leading role in drug discovery efforts. However, development of new drugs from bioactive compounds obtained in screening campaigns requires identification of the cellular targets responsible for their biological activities. A new energetics-based method for target identification is presented: pulse proteolysis and precipitation for target identification (PePTID). In this method, proteins incubated with or without a ligand and submitted to a brief proteolytic pulse are directly analyzed and compared using a label-free semiquantitative mass spectrometry strategy, dispensing the SDS-PAGE readout and greatly improving the throughput. As a proof-of-concept, we applied the PePTID method to identify ATP-binding proteins in <i>Mycobacterium smegmatis</i>, a model system for <i>Mycobacterium tuberculosis</i>, the etiological agent of tuberculosis

Pulse Proteolysis and Precipitation for Target Identification

In recent years, phenotypic screening has assumed a leading role in drug discovery efforts. However, development of new drugs from bioactive compounds obtained in screening campaigns requires identification of the cellular targets responsible for their biological activities. A new energetics-based method for target identification is presented: pulse proteolysis and precipitation for target identification (PePTID). In this method, proteins incubated with or without a ligand and submitted to a brief proteolytic pulse are directly analyzed and compared using a label-free semiquantitative mass spectrometry strategy, dispensing the SDS-PAGE readout and greatly improving the throughput. As a proof-of-concept, we applied the PePTID method to identify ATP-binding proteins in <i>Mycobacterium smegmatis</i>, a model system for <i>Mycobacterium tuberculosis</i>, the etiological agent of tuberculosis

Pulse Proteolysis and Precipitation for Target Identification

In recent years, phenotypic screening has assumed a leading role in drug discovery efforts. However, development of new drugs from bioactive compounds obtained in screening campaigns requires identification of the cellular targets responsible for their biological activities. A new energetics-based method for target identification is presented: pulse proteolysis and precipitation for target identification (PePTID). In this method, proteins incubated with or without a ligand and submitted to a brief proteolytic pulse are directly analyzed and compared using a label-free semiquantitative mass spectrometry strategy, dispensing the SDS-PAGE readout and greatly improving the throughput. As a proof-of-concept, we applied the PePTID method to identify ATP-binding proteins in <i>Mycobacterium smegmatis</i>, a model system for <i>Mycobacterium tuberculosis</i>, the etiological agent of tuberculosis

'Hammondia heydorni' from the Arabian mountain gazelle and red fox in Saudi Arabia

Feces from 15 dogs at 2 different foxhound kennels in the U.K. were examined microscopically for the presence of oocysts of Neospora caninum. One sample containing approximately 400 candidate oocysts per gram was positive in a polymerase chain reaction (PCR) using N. caninum-specific primers. In a sample taken 4 mo later from the same hound, N. caninum oocysts were again detected visually and by PCR. This is the third reported case of a dog naturally excreting oocysts of N. caninum and suggests that oocyst excretion can occur over a relatively long period of time in some circumstances or that reshedding may occur