Molecular Cloning and Characterization of a Protein Farnesyltransferase from the Enteric Protozoan Parasite Entamoeba histolytica

Kumagai, Masahiro; Makioka, Asao; Takeuchi, Tsutomu; Nozaki, Tomoyoshi

doi:10.1074/jbc.m311478200

Cited by 29 publications

(29 citation statements)

References 44 publications

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“…this part of our study, we used the FTI-276 inhibitor that had been proven to inhibit EhFT. 4 When the concentration of E was zero, no P was formed and a single peak of S2 was detected ( Figure 2B, lower trace). In the presence of E but without I, S2 was converted in to P and, accordingly, two peaks were observed after P was separated from the remaining S2 ( Figure 2B, middle trace).…”

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confidence: 99%

“…In this proof-of-principle work, we applied the method to study inhibition of recently cloned protein farnesyltransferase (FT) from parasite Entamoeba histolytica (Eh); this enzyme is a potential therapeutic target for antiparasitic drugs. 3,4 We identified three previously unknown inhibitors of EhFT and proved that IMReSQ could be used for accurately ranking the potencies of inhibitors.…”

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confidence: 99%

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“Inject-Mix-React-Separate-and-Quantitate” (IMReSQ) Method for Screening Enzyme Inhibitors

et al. 2008

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Many enzymes involved in regulatory cellular processes are considered attractive therapeutic targets and their inhibitors are potential drug candidates.1 Screening of combinatorial libraries for enzyme inhibitors is pivotal to identifying hit compounds for the development of enzyme-targeting drugs. Here we introduce the first method for screening enzyme inhibitors which is applicable to regulatory enzymes and consumes only nanoliter volumes of the reactant solutions. We name the method inject-mix-react-separate-and-quantitate (IMReSQ). The concept of the method is shown in Figure 1. First, nanoliter volumes of substrate, candidate inhibitor, and enzyme solutions are injected separately (from microliter volumes in cupped vials) by pressure into a capillary as separate plugs without the need of nanoliterscale liquid handlers. Second, the plugs are mixed inside this capillary microreactor by transverse diffusion of laminar flow profiles (TDLFP). Third, the reaction mixture is incubated to form the enzymatic product. Fourth, the product is separated from the substrate inside the capillary by electrophoresis. Fifth, the amounts of the product and substrate are quantitated. In this proof-of-principle work, we applied the method to study inhibition of recently cloned protein farnesyltransferase (FT) from parasite Entamoeba histolytica (Eh); this enzyme is a potential therapeutic target for antiparasitic drugs.3,4 We identified three previously unknown inhibitors of EhFT and proved that IMReSQ could be used for accurately ranking the potencies of inhibitors.Methods for screening enzyme inhibitors can be divided into two broad categories: homogeneous, which monitor product formation without its physical separation from the substrate, and separation-based, which separate the product from the substrate by means of chromatography or electrophoresis prior to its quantitation. Recent advances in printing chemical libraries made it possible to transfer homogeneous methods from microtiter plates to microarrays, which require only nanoliter volumes of reagents.5 Microarrays, however, require substrates that do not fluoresce before being converted into fluorescent products. Such fluorogenic substrates are not available for the majority of regulatory enzymes, for example, prenyltransferases, glycosyltransferases, and kinases. In separation-based methods, simple fluorescently labeled substrates can be used instead of fluorogenic substrates. Fluorescently labeled substrates are available for many regulatory enzymes.6 If separation is carried out in a narrow-bore capillary, only nanoliter volumes of reaction mixtures are consumed. Because of the lack of a generic way of mixing solutions inside the capillary, however, the reaction mixture must be prepared in a vial outside the capillary with a volume of at least several microliters. This work was inspired by the insight that TDLFP can be used to mix nanoliter volumes of enzyme, substrate, and candidate inhibitor, injected into the capillary as separate plugs. Thus far, TDLFP had been ...

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“Inject-Mix-React-Separate-and-Quantitate” (IMReSQ) Method for Screening Enzyme Inhibitors

et al. 2008

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“…This includes a subset of the active site residues, suggesting distinct specificity of binding to CaaX peptide substrates and inhibitors between PFT enzymes from these different species [15,16,18,40]. PGGT-I β orthologs have not been identified in gene databases of T. brucei and Leishmania species.…”

Section: Inhibitor Studiesmentioning

confidence: 99%

“…These are consistent with the CaaX specificity of the T. cruzi PGGT-I (Table1). Alterations in the residues involving substrate interactions in PFT and PGGT-I subunits between protozoan and mammalian orthologs may cause substantial differences in binding specificity for the CaaX motif and smallmolecule inhibitors in protozoa and mammalian cells [15][16][17][18][19][20][21]40]. This suggests not only different selectivity of inhibitors against parasite PFT and PGGT-I from that of mammalian enzymes but also differential consequences of inhibitory effects of PGGT-I or PFT on cellular events in the parasites from those in mammalian cells.…”

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Protein geranylgeranyltransferase-I of Trypanosoma cruzi

Yokoyama

Gillespie

Voorhis

et al. 2008

Molecular and Biochemical Parasitology

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Protein geranylgeranyltransferase type I (PGGT-I) and protein farnesyltransferase (PFT) occur in many eukaryotic cells. Both consist of two subunits, the common αsubunit and a distinct β subunit. In the gene database of protozoa Trypanosoma cruzi, the causative agent of Chagas' disease, a putative protein that consists of 401 amino acids with ∼20% amino acid sequence identity to the PGGT-I β of other species was identified, cloned, and characterized. Multiple sequence alignments show that the T. cruzi ortholog contains all three of the zinc-binding residues and several residues uniquely conserved in the β subunit of PGGT-I. Co-expression of this protein and the α subunit of T. cruzi PFT in Sf9 insect cells yielded a dimeric protein that forms a tight complex selectively with [ 3 H] geranylgeranyl pyrophosphate, indicating a key characteristic of a functional PGGT-I. Recombinant T. cruzi PGGT-I ortholog showed geranylgeranyltransferase activity with distinct specificity toward the C-terminal CaaX motif of protein substrates compared to that of the mammalian PGGT-I and T. cruzi PFT. Most of the CaaX-containing proteins with X=Leu are good substrates of T. cruzi PGGT-I, and those with X=Met are substrates for both T. cruzi PFT and PGGT-I, whereas unlike mammalian PGGT-I, those with X=Phe are poor substrates for T. cruzi PGGT-I. Several candidates for T. cruzi PGGT-I or PFT substrates containing the C-terminal CaaX motif are found in the T. cruzi gene database. Among five C-terminal peptides of those tested, a peptide of a Ras-like protein ending with CVLL was selectively geranylgeranylated by T. cruzi PGGT-I. Other peptides with CTQQ (Tcj2 DNAJ protein), CAVM (TcPRL-1 protein tyrosine phosphatase), CHFM (a small GTPase like protein), and CQLF (TcRho1 GTPase) were specific substrates for T. cruzi PFT but not for PGGT-I. The mRNA and protein of the T. cruzi PGGT-I β ortholog were detected in three life-cycle stages of T. cruzi. Cytosol fractions from trypomastigotes (infectious mammalian stage) and epimastigotes (insect stage) were shown to contain levels of PGGT-I activity that are ∼100-fold lower than PFT activity. The CaaX mimetics known as PGGT-I inhibitors show very low potency against T. cruzi PGGT-I compared to the mammalian enzyme, suggesting the potential to develop selective inhibitors against the parasite enzyme.

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