4 research outputs found

    Discovery of Novel <i>Trypanosoma brucei</i> Phosphodiesterase B1 Inhibitors by Virtual Screening against the Unliganded TbrPDEB1 Crystal Structure

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    <i>Trypanosoma brucei</i> cyclic nucleotide phosphodiesterase B1 (TbrPDEB1) and TbrPDEB2 have recently been validated as new therapeutic targets for human African trypanosomiasis by both genetic and pharmacological means. In this study we report the crystal structure of the catalytic domain of the unliganded TbrPDEB1 and its use for the in silico screening for new TbrPDEB1 inhibitors with novel scaffolds. The TbrPDEB1 crystal structure shows the characteristic folds of human PDE enzymes but also contains the parasite-specific P-pocket found in the structures of <i>Leishmania major</i> PDEB1 and <i>Trypanosoma cruzi</i> PDEC. The unliganded TbrPDEB1 X-ray structure was subjected to a structure-based in silico screening approach that combines molecular docking simulations with a protein–ligand interaction fingerprint (IFP) scoring method. This approach identified six novel TbrPDEB1 inhibitors with IC<sub>50</sub> values of 10–80 μM, which may be further optimized as potential selective TbrPDEB inhibitors

    Catechol Pyrazolinones as Trypanocidals: Fragment-Based Design, Synthesis, and Pharmacological Evaluation of Nanomolar Inhibitors of Trypanosomal Phosphodiesterase B1

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    Trypanosomal phosphodiesterases B1 and B2 (TbrPDEB1 and TbrPDEB2) play an important role in the life cycle of <i>Trypanosoma brucei</i>, the causative parasite of human African trypanosomiasis (HAT), also known as African sleeping sickness. We used homology modeling and docking studies to guide fragment growing into the parasite-specific P-pocket in the enzyme binding site. The resulting catechol pyrazolinones act as potent TbrPDEB1 inhibitors with IC<sub>50</sub> values down to 49 nM. The compounds also block parasite proliferation (e.g., VUF13525 (<b>20b</b>): <i>T. brucei rhodesiense</i> IC<sub>50</sub> = 60 nM, <i>T. brucei brucei</i> IC<sub>50</sub> = 520 nM, <i>T. cruzi</i> = 7.6 ÎĽM), inducing a typical multiple nuclei and kinetoplast phenotype without being generally cytotoxic. The mode of action of <b>20b</b> was investigated with recombinantly engineered trypanosomes expressing a cAMP-sensitive FRET sensor, confirming a dose-response related increase of intracellular cAMP levels in trypanosomes. Our findings further validate the TbrPDEB family as antitrypanosomal target

    Targeting a Subpocket in <i>Trypanosoma brucei</i> Phosphodiesterase B1 (TbrPDEB1) Enables the Structure-Based Discovery of Selective Inhibitors with Trypanocidal Activity

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    Several trypanosomatid cyclic nucleotide phosphodiesterases (PDEs) possess a unique, parasite-specific cavity near the ligand-binding region that is referred to as the P-pocket. One of these enzymes, <i>Trypanosoma brucei</i> PDE B1 (TbrPDEB1), is considered a drug target for the treatment of African sleeping sickness. Here, we elucidate the molecular determinants of inhibitor binding and reveal that the P-pocket is amenable to directed design. By iterative cycles of design, synthesis, and pharmacological evaluation and by elucidating the structures of inhibitor-bound TbrPDEB1, hPDE4B, and hPDE4D complexes, we have developed 4a,5,8,8a-tetrahydrophthalazinones as the first selective TbrPDEB1 inhibitor series. Two of these, <b>8</b> (NPD-008) and <b>9</b> (NPD-039), were potent (<i>K</i><sub>i</sub> = 100 nM) TbrPDEB1 inhibitors with antitrypanosomal effects (IC<sub>50</sub> = 5.5 and 6.7 ÎĽM, respectively). Treatment of parasites with <b>8</b> caused an increase in intracellular cyclic adenosine monophosphate (cAMP) levels and severe disruption of <i>T. brucei</i> cellular organization, chemically validating trypanosomal PDEs as therapeutic targets in trypanosomiasis

    Neither mycorrhizal inoculation nor atmospheric CO<sub>2</sub> concentration has strong effects on pea root production and root loss

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    Chagas’ disease, caused by the protozoan parasite Trypanosoma cruzi, is the most common cause of cardiac-related deaths in endemic regions of Latin America. There is an urgent need for new safer treatments because current standard therapeutic options, benznidazole and nifurtimox, have significant side effects and are only effective in the acute phase of the infection with limited efficacy in the chronic phase. Phenotypic high content screening against the intracellular parasite in infected VERO cells was used to identify a novel hit series of 5-amino-1,2,3-triazole-4-carboxamides (ATC). Optimization of the ATC series gave improvements in potency, aqueous solubility, and metabolic stability, which combined to give significant improvements in oral exposure. Mitigation of a potential Ames and hERG liability ultimately led to two promising compounds, one of which demonstrated significant suppression of parasite burden in a mouse model of Chagas’ disease
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