F. Di Pisa scite author profile

Flavonoids represent a potential source of new antitrypanosomatidic leads. Starting from a library of natural products, we combined target-based screening on pteridine reductase 1 with phenotypic screening on Trypanosoma brucei for hit identification. Flavonols were identified as hits, and a library of 16 derivatives was synthesized. Twelve compounds showed EC50 values against T. brucei below 10 μM. Four X-ray crystal structures and docking studies explained the observed structure-activity relationships. Compound 2 (3,6-dihydroxy-2-(3-hydroxyphenyl)-4H-chromen-4-one) was selected for pharmacokinetic studies. Encapsulation of compound 2 in PLGA nanoparticles or cyclodextrins resulted in lower in vitro toxicity when compared to the free compound. Combination studies with methotrexate revealed that compound 13 (3-hydroxy-6-methoxy-2-(4-methoxyphenyl)-4H-chromen-4-one) has the highest synergistic effect at concentration of 1.3 μM, 11.7-fold dose reduction index and no toxicity toward host cells. Our results provide the basis for further chemical modifications aimed at identifying novel antitrypanosomatidic agents showing higher potency toward PTR1 and increased metabolic stability.

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Time-lapse anomalous X-ray diffraction shows how Fe²⁺substrate ions move through ferritin protein nanocages to oxidoreductase sites

Pozzi

Pisa

Lalli

et al. 2015

Acta Cryst D Biol Crystallogr

108

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Ferritin superfamily protein cages reversibly synthesize internal biominerals, Fe2O3·H2O. Fe(2+) and O2 (or H2O2) substrates bind at oxidoreductase sites in the cage, initiating biomineral synthesis to concentrate iron and prevent potentially toxic reactions products from Fe(2+)and O2 or H2O2 chemistry. By freezing ferritin crystals of Rana catesbeiana ferritin M (RcMf) at different time intervals after exposure to a ferrous salt, a series of high-resolution anomalous X-ray diffraction data sets were obtained that led to crystal structures that allowed the direct observation of ferrous ions entering, moving along and binding at enzyme sites in the protein cages. The ensemble of crystal structures from both aerobic and anaerobic conditions provides snapshots of the iron substrate bound at different cage locations that vary with time. The observed differential occupation of the two iron sites in the enzyme oxidoreductase centre (with Glu23 and Glu58, and with Glu58, His61 and Glu103 as ligands, respectively) and other iron-binding sites (with Glu53, His54, Glu57, Glu136 and Asp140 as ligands) reflects the approach of the Fe(2+) substrate and its progression before the enzymatic cycle 2Fe(2+) + O2 → Fe(3+)-O-O-Fe(3+) → Fe(3+)-O(H)-Fe(3+) and turnover. The crystal structures also revealed different Fe(2+) coordination compounds bound to the ion channels located at the threefold and fourfold symmetry axes of the cage.

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Iron binding to human heavy-chain ferritin

Pozzi

Pisa

Bernacchioni

et al. 2015

Acta Crystallogr D Biol Crystallogr

105

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Maxi-ferritins are ubiquitous iron-storage proteins with a common cage architecture made up of 24 identical subunits of five α-helices that drive iron biomineralization through catalytic iron(II) oxidation occurring at oxidoreductase sites (OS). Structures of iron-bound human H ferritin were solved at high resolution by freezing ferritin crystals at different time intervals after exposure to a ferrous salt. Multiple binding sites were identified that define the iron path from the entry ion channels to the oxidoreductase sites. Similar data are available for another vertebrate ferritin: the M protein from Rana catesbeiana. A comparative analysis of the iron sites in the two proteins identifies new reaction intermediates and underlines clear differences in the pattern of ligands that define the additional iron sites that precede the oxidoreductase binding sites along this path. Stopped-flow kinetics assays revealed that human H ferritin has different levels of activity compared with its R. catesbeiana counterpart. The role of the different pattern of transient iron-binding sites in the OS is discussed with respect to the observed differences in activity across the species.

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Chemistry at the protein–mineral interface in L-ferritin assists the assembly of a functional (μ ³ -oxo)Tris[(μ ² -peroxo)] triiron(III) cluster

Pozzi

Ciambellotti

Bernacchioni

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

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X-ray structures of homopolymeric L-ferritin obtained by freezing protein crystals at increasing exposure times to a ferrous solution showed the progressive formation of a triiron cluster on the inner cage surface of each subunit. After 60 min exposure, a fully assembled (μ 3 -oxo)Tris[(μ 2 -peroxo)(μ 2 -glutamato-κO:κO′)](glutamato-κO)(diaquo)triiron(III) anionic cluster appears in human L-ferritin. Glu60, Glu61, and Glu64 provide the anchoring of the cluster to the protein cage. Glu57 shuttles incoming iron ions toward the cluster. We observed a similar metallocluster in horse spleen L-ferritin, indicating that it represents a common feature of mammalian L-ferritins. The structures suggest a mechanism for iron mineral formation at the protein interface. The functional significance of the observed patch of carboxylate side chains and resulting metallocluster for biomineralization emerges from the lower iron oxidation rate measured in the E60AE61AE64A variant of human L-ferritin, leading to the proposal that the observed metallocluster corresponds to the suggested, but yet unobserved, nucleation site of L-ferritin.L-ferritin | metallocluster | nucleation site | biomineralization | X-ray

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Comparative mapping of on-targets and off-targets for the discovery of anti-trypanosomatid folate pathway inhibitors

Panecka-Hofman

Pöhner

Spyrakis

et al. 2017

Biochimica et Biophysica Acta (BBA) - General Subjects

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F. Di Pisa

Profiling of Flavonol Derivatives for the Development of Antitrypanosomatidic Drugs

Time-lapse anomalous X-ray diffraction shows how Fe²⁺substrate ions move through ferritin protein nanocages to oxidoreductase sites

Iron binding to human heavy-chain ferritin

Chemistry at the protein–mineral interface in L-ferritin assists the assembly of a functional (μ ³ -oxo)Tris[(μ ² -peroxo)] triiron(III) cluster

Comparative mapping of on-targets and off-targets for the discovery of anti-trypanosomatid folate pathway inhibitors

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F. Di Pisa

Profiling of Flavonol Derivatives for the Development of Antitrypanosomatidic Drugs

Time-lapse anomalous X-ray diffraction shows how Fe2+substrate ions move through ferritin protein nanocages to oxidoreductase sites

Iron binding to human heavy-chain ferritin

Chemistry at the protein–mineral interface in L-ferritin assists the assembly of a functional (μ 3 -oxo)Tris[(μ 2 -peroxo)] triiron(III) cluster

Comparative mapping of on-targets and off-targets for the discovery of anti-trypanosomatid folate pathway inhibitors

Contact Info

Product

Resources

About

Time-lapse anomalous X-ray diffraction shows how Fe²⁺substrate ions move through ferritin protein nanocages to oxidoreductase sites

Chemistry at the protein–mineral interface in L-ferritin assists the assembly of a functional (μ ³ -oxo)Tris[(μ ² -peroxo)] triiron(III) cluster