Meredith Morris

A target-based high throughput screen yields Trypanosoma brucei hexokinase small molecule inhibitors with antiparasitic activity

Background The parasitic protozoan Trypanosoma brucei utilizes glycolysis exclusively for ATP production during infection of the mammalian host. The first step in this metabolic pathway is mediated by hexokinase (TbHK), an enzyme essential to the parasite that transfers the γ-phospho of ATP to a hexose. Here we describe the identification and confirmation of novel small molecule inhibitors of bacterially expressed TbHK1, one of two TbHKs expressed by T. brucei, using a high throughput screening assay. Methodology/Principal Findings Exploiting optimized high throughput screening assay procedures, we interrogated 220,233 unique compounds and identified 239 active compounds from which ten small molecules were further characterized. Computation chemical cluster analyses indicated that six compounds were structurally related while the remaining four compounds were classified as unrelated or singletons. All ten compounds were ∼20-17,000-fold more potent than lonidamine, a previously identified TbHK1 inhibitor. Seven compounds inhibited T. brucei blood stage form parasite growth (0.03≤EC50<3 µM) with parasite specificity of the compounds being demonstrated using insect stage T. brucei parasites, Leishmania promastigotes, and mammalian cell lines. Analysis of two structurally related compounds, ebselen and SID 17387000, revealed that both were mixed inhibitors of TbHK1 with respect to ATP. Additionally, both compounds inhibited parasite lysate-derived HK activity. None of the compounds displayed structural similarity to known hexokinase inhibitors or human African trypanosomiasis therapeutics. Conclusions/Significance The novel chemotypes identified here could represent leads for future therapeutic development against the African trypanosome.

The anti-trypanosomal agent lonidamine inhibits Trypanosoma brucei hexokinase 1

Glycolysis is essential to the parasitic protozoan Trypanosoma brucei. The first step in this metabolic pathway is mediated by hexokinase, an enzyme that transfers the gamma-phosphate of ATP to a hexose. The T. brucei genome (TREU927/4 GUTat10.1) encodes two hexokinases (TbHK1 and TbHK2) that are 98% identical at the amino acid level. Our previous efforts have revealed that TbHK2 is an important regulator of TbHK1 in procyclic form parasites. Here, we have found through RNAi that TbHK1 is essential to the bloodstream form parasite. Silencing the gene for 4 days reduces cellular hexokinase approximately 60% and leads to parasite death. Additionally, we have found that the recombinant enzyme is inhibited by lonidamine (IC(50)=850 microM), an anti-cancer drug that targets tumor hexokinases. This agent also inhibits HK activity from whole parasite lysate (IC(50)=965 microM). Last, lonidamine is toxic to cultured bloodstream form parasites (LD(50)=50 microM) and procyclic form parasites (LD(50)=180 microM). Interestingly, overexpression of TbHK1 protects PF parasites from lonidamine. These studies provide genetic evidence that TbHK1 is a valid therapeutic target while identifying a potential molecular target of the anti-trypanosomal agent lonidamine.

Assembly of heterohexameric trypanosome hexokinases reveals that hexokinase 2 is a regulable enzyme.

Glycolysis is essential to Trypanosoma brucei, the protozoan parasite that causes African sleeping sickness in humans and nagana in cattle. Hexokinase (HK), the first enzyme in glycolysis, catalyzes the phosphorylation of glucose to form glucose 6-phosphate. T. brucei harbors two HKs that are 98% identical at the amino acid level, T. brucei hexokinase 1 (TbHK1) and TbHK2. Recombinant TbHK1 (rTbHK1) has HK activity, whereas rTbHK2 does not. Unlike other eukaryotic HKs, TbHK1 is not subject to inhibition by ADP and glucose 6-phosphate. However, TbHK1 is inhibited by myristate, a critical fatty acid in T. brucei biology. We report here that rTbHKs, similar to authentic TbHK, form oligomers. Myristate dissociated these assemblies when incubated with either ATP or glucose. Furthermore, oligomer disruption was reversible by removal of myristate. Mixing of rTbHK1 and rTbHK2 monomers followed by reassembly yielded enzyme with an ∼3-fold increase in specific activity compared with similarly treated rTbHK1 alone. Surprisingly, reassembly of rTbHK2 with an inactive rTbHK1 variant yielded an active HK, revealing for the first time that rTbHK2 is competent for HK activity. Finally, pyrophosphate inhibits active reassembled rTbHK2 oligomers but not oligomeric rTbHK1, suggesting that the two enzymes have distinct regulatory mechanisms.

Activity of a Second Trypanosoma brucei Hexokinase Is Controlled by an 18-Amino-Acid C-Terminal Tail

ABSTRACT Trypanosoma brucei expresses two hexokinases that are 98% identical, namely, TbHK1 and TbHK2. Homozygous null TbHK2−/− procyclic-form parasites exhibit an increased doubling time, a change in cell morphology, and, surprisingly, a twofold increase in cellular hexokinase activity. Recombinant TbHK1 enzymatic activity is similar to that of other hexokinases, with apparent Km values for glucose and ATP of 0.09 ± 0.02 mM and 0.28 ± 0.1 mM, respectively. The kcat value for TbHK1 is 2.9 × 104 min−1. TbHK1 can use mannose, fructose, 2-deoxyglucose, and glucosamine as substrates. In addition, TbHK1 is inhibited by fatty acids, with lauric, myristic, and palmitic acids being the most potent (with 50% inhibitory concentrations of 75.8, 78.4, and 62.4 μM, respectively). In contrast to TbHK1, recombinant TbHK2 lacks detectable enzymatic activity. Seven of the 10 amino acid differences between TbHK1 and TbHK2 lie within the C-terminal 18 amino acids of the polypeptides. Modeling of the proteins maps the C-terminal tails near the interdomain cleft of the enzyme that participates in the conformational change of the enzyme upon substrate binding. Replacing the last 18 amino acids of TbHK2 with the corresponding residues of TbHK1 yields an active recombinant protein with kinetic properties similar to those of TbHK1. Conversely, replacing the C-terminal tail of TbHK1 with the TbHK2 tail inactivates the enzyme. These findings suggest that the C-terminal tail of TbHK1 is important for hexokinase activity. The altered C-terminal tail of TbHK2, along with the phenotype of the knockout parasites, suggests a distinct function for the protein.

Quercetin, a fluorescent bioflavanoid, inhibits Trypanosoma brucei hexokinase 1

Hexokinases from the African trypanosome, Trypanosoma brucei, are attractive targets for the development of anti-parasitic drugs, in part because the parasite utilizes glycolysis exclusively for ATP production during the mammalian infection. Here, we have demonstrated that the bioflavanoid quercetin (QCN), a known trypanocide, is a mixed inhibitor of Trypanosoma brucei hexokinase 1 (TbHK1) (IC(50) = 4.1 ± 0.8μM). Spectroscopic analysis of QCN binding to TbHK1, taking advantage of the intrinsically fluorescent single tryptophan (Trp177) in TbHK1, revealed that QCN quenches emission of Trp177, which is located near the hinge region of the enzyme. ATP similarly quenched Trp177 emission, while glucose had no impact on fluorescence. Supporting the possibility that QCN toxicity is a consequence of inhibition of the essential hexokinase, in live parasites QCN fluorescence localizes to glycosomes, the subcellular home of TbHK1. Additionally, RNAi-mediated silencing of TbHK1 expression expedited QCN induced death, while over-expressing TbHK1 protected trypanosomes from the compound. In summary, these observations support the suggestion that QCN toxicity is in part attributable to inhibition of the essential TbHK1.

Trypanosoma brucei AMP-activated kinase subunit homologs influence surface molecule expression

The African trypanosome, Trypanosoma brucei, can gauge its environment by sensing nutrient availability. For example, procyclic form (PF) trypanosomes monitor changes in glucose levels to regulate surface molecule expression, which is important for survival in the tsetse fly vector. The molecular connection between glycolysis and surface molecule expression is unknown. Here we partially characterize T. brucei homologs of the beta and gamma subunits of the AMP-activated protein kinase (AMPK), and determine their roles in regulating surface molecule expression. Using flow cytometry and mass spectrometry, we found that TbAMPKbeta or TbAMPKgamma-deficient parasites express both of the major surface molecules, EP- and GPEET-procyclin, with the latter being a form that is expressed when glucose is low such as in the tsetse fly. Last, we have found that the putative scaffold component of the complex, TbAMPKbeta, fractionates with organellar components and colocalizes in part with a glycosomal marker as well as the flagellum of PF parasites.

Glycolysis in the African Trypanosome: Targeting Enzymes and Their Subcellular Compartments for Therapeutic Development

Subspecies of the African trypanosome, Trypanosoma brucei, which cause human African trypanosomiasis, are transmitted by the tsetse fly, with transmission-essential lifecycle stages occurring in both the insect vector and human host. During infection of the human host, the parasite is limited to using glycolysis of host sugar for ATP production. This dependence on glucose breakdown presents a series of targets for potential therapeutic development, many of which have been explored and validated as therapeutic targets experimentally. These include enzymes directly involved in glucose metabolism (e.g., the trypanosome hexokinases), as well as cellular components required for development and maintenance of the essential subcellular compartments that house the major part of the pathway, the glycosomes.

Environmentally-regulated glycosome protein composition in the African trypanosome

ABSTRACT Trypanosomes compartmentalize many metabolic enzymes in glycosomes, peroxisome-related microbodies that are essential to parasite survival. While it is understood that these dynamic organelles undergo profound changes in protein composition throughout life cycle differentiation, the adaptations that occur in response to changes in environmental conditions are less appreciated. We have adopted a fluorescent-organelle reporter system in procyclic Trypanosoma brucei by expressing a fluorescent protein (FP) fused to a glycosomal targeting sequence (peroxisome-targeting sequence 2 [PTS2]). In these cell lines, PTS2-FP is localized within import-competent glycosomes, and organelle composition can be analyzed by microscopy and flow cytometry. Using this reporter system, we have characterized parasite populations that differ in their glycosome composition. In glucose-rich medium, two parasite populations are observed; one population harbors glycosomes bearing the full repertoire of glycosome proteins, while the other parasite population contains glycosomes that lack the usual glycosome-resident proteins but do contain the glycosome membrane protein TbPEX11. Interestingly, these cells lack TbPEX13, a protein essential for the import of proteins into the glycosome. This bimodal distribution is lost in low-glucose medium. Furthermore, we have demonstrated that changes in environmental conditions trigger changes in glycosome protein composition. These findings demonstrate a level of procyclic glycosome diversity heretofore unappreciated and offer a system by which glycosome dynamics can be studied in live cells. This work adds to our growing understanding of how the regulation of glycosome composition relates to environmental sensing.

Peptide-targeted delivery of a pH sensor for quantitative measurements of intraglycosomal pH in live Trypanosoma brucei.

Studies of dynamic changes in organelles of protozoan parasite Trypanosoma brucei have been limited, in part because of the difficulty of targeting analytical probes to specific subcellular compartments. Here we demonstrate application of a ratiometric probe for pH quantification in T. brucei glycosomes. The probe consists of a peptide encoding the peroxisomal targeting sequence (F-PTS1, acetyl-CKGGAKL) coupled to fluorescein, which responds to pH. When incubated with living parasites, the probe is internalized within vesicular structures that colocalize with a glycosomal marker. Inhibition of uptake of F-PTS1 at 4 °C and pulse-chase colocalization with fluorescent dextran suggested that the probe is initially taken up by non-receptor-mediated endocytosis but is subsequently transported separately from dextran and localized within glycosomes, prior to the final fusion of labeled glycosomes and lysosomes as part of glycosomal turnover. Intraorganellar measurements and pH calibration with F-PTS1 in T. brucei glycosomes indicate that the resting glycosomal pH under physiological conditions is 7.4 ± 0.2. However, incubation in glucose-depleted buffer triggered mild acidification of the glycosome over a period of 20 min, with a final observed pH of 6.8 ± 0.3. This glycosomal acidification was reversed by reintroduction of glucose. Coupling of ratiometric fluorescent sensors and reporters to PTS peptides offers an invaluable tool for monitoring in situ glycosomal response(s) to changing environmental conditions and could be applied to additional kinetoplastid parasites.

Glycerol-3-phosphate alters trypanosoma brucei hexokinase activity in response to environmental change

Background: Mechanisms of regulation of an essential African trypanosome hexokinase are poorly understood. Results: Glycerol 3-phosphate levels increase upon starvation and prevent cellular and recombinant hexokinase from pH-dependent inactivation. Conclusion: Glycerol 3-phosphate prevents pH inactivation-triggered exposure of an inhibitory nucleotide-binding site. Significance: Identifying how an essential parasite enzyme is regulated may reveal new therapeutic avenues. The African trypanosome, Trypanosoma brucei, compartmentalizes some metabolic enzymes within peroxisome-like organelles called glycosomes. The amounts, activities, and types of glycosomal enzymes are modulated coincident with developmental and environmental changes. Pexophagy (fusion of glycosomes with acidic lysosomes) has been proposed to facilitate this glycosome remodeling. Here, we report that, although glycosome-resident enzyme T. brucei hexokinase 1 (TbHK1) protein levels are maintained during pexophagy, acidification inactivates the activity. Glycerol 3-phosphate, which is produced in vivo by a glycosome-resident glycerol kinase, mitigated acid inactivation of lysate-derived TbHK activity. Using recombinant TbHK1, we found that glycerol 3-P influenced enzyme activity at pH 6.5 by preventing substrate and product inhibition by ATP and ADP, respectively. Additionally, TbHK1 inhibition by the flavonol quercetin (QCN) was partially reversed by glycerol 3-P at pH 7.4, whereas at pH 6.5, enzyme activity in the presence of QCN was completely maintained by glycerol 3-P. However, glycerol 3-P did not alter the interaction of QCN with TbHK1, as the lone Trp residue (Trp-177) was quenched under all conditions tested. These findings suggest potential novel mechanisms for the regulation of TbHK1, particularly given the acidification of glycosomes that can be induced under a variety of parasite growth conditions.