Marc Pudlo scite author profile

Arginase (EC 3.5.3.1) is the bimanganese enzyme that converts L-arginine into ornithine and urea. This enzyme was discovered more than a century ago and early α-amino acids were identified as weak inhibitors. It was only during the 90s, after nitric oxide (NO) was reported as one of the most important biological mediators and when tight interrelation of arginase and NO synthase was found, that the development of arginase inhibitors was accelerated. The regulation of arginase activity by the N-hydroxy-L-arginine (3, NOHA) intermediate of the NO synthesis was the starting point of the N-hydroxy-nor-arginine (21, nor-NOHA) that proved to be the first micromolar inhibitor. The previously known manganese and arginase binding by borate inspired the 2(S)-amino-6-boronohexanoic acid (39, ABH) and S-(2-boronoethyl)-L-cysteine (40, BEC) now both considered as reference compounds in arginase inhibition. The high-resolution crystal structure of arginase and molecular modeling has rendered possible the recent design of (53) the strongest α,α-disubstituted derivatives of ABH. Simultaneously, traditional medicinal plants have contributed as a source of molecular diversity to the discovery of arginase inhibitors. This rational, step-by-step approach serves as guide in the present review where emphasis is placed on structure activity relationships. Highlights exhaustive review on arginase inhibitors highlight is made on rational approach to conception and structure activity relationships evaluation model is systematically mentioned with results.

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Nanovectorization of TRAIL with Single Wall Carbon Nanotubes Enhances Tumor Cell Killing

Zakaria

Picaud

Rattier

et al. 2015

Nano Lett.

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Tumor necrosis factor-related apoptosis-inducing ligand (TRAIL or Apo2L) is a member of the tumor necrosis factor (TNF) superfamily. This type II transmembrane protein is able to bound specifically to cancer cell receptors (i.e., TRAIL-R1 (or DR4) and TRAIL-R2 (or DR5)) and to induce apoptosis without being toxic for healthy cells. Because membrane-bound TRAIL induces stronger receptor aggregation and apoptosis than soluble TRAIL, we proposed here to vectorize TRAIL using single-walled carbon nanotubes (SWCNTs) to mimic membrane TRAIL. Owing to their exceptional and revolutional properties, carbon nanotubes, especially SWCNTs, are used in a wide range of physical or, now, medical applications. Indeed due to their high mechanical resistance, their high flexibility and their hydrophobicity, SWCNTs are known to rapidly diffuse in an aqueous medium such as blood, opening the way of development of new drug nanovectors (or nanocarriers). Our TRAIL-based SWCNTs nanovectors proved to be more efficient than TRAIL alone death receptors in triggering cancer cell killing. These NPTs increased TRAIL pro-apoptotic potential by nearly 20-fold in different Human tumor cell lines including colorectal, nonsmall cell lung cancer, or hepatocarcinomas. We provide thus a proof-of-concept that TRAIL nanovector derivatives based on SWCNT may be useful to future nanomedicine therapies.

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Novel Tacrine‐Grafted Ugi Adducts as Multipotent Anti‐Alzheimer Drugs: A Synthetic Renewal in Tacrine–Ferulic Acid Hybrids

et al. 2014

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Herein we describe the design, multicomponent synthesis, and biological, molecular modeling and ADMET studies, as well as in vitro PAMPA-blood-brain barrier (BBB) analysis of new tacrine-ferulic acid hybrids (TFAHs). We identified (E)-3-(hydroxy-3-methoxyphenyl)-N-{8[(7-methoxy-1,2,3,4-tetrahydroacridin-9-yl)amino]octyl}-N-[2-(naphthalen-2-ylamino)2-oxoethyl]acrylamide (TFAH 10 n) as a particularly interesting multipotent compound that shows moderate and completely selective inhibition of human butyrylcholinesterase (IC50 =68.2 nM), strong antioxidant activity (4.29 equiv trolox in an oxygen radical absorbance capacity (ORAC) assay), and good β-amyloid (Aβ) anti-aggregation properties (65.6 % at 1:1 ratio); moreover, it is able to permeate central nervous system (CNS) tissues, as determined by PAMPA-BBB assay. Notably, even when tested at very high concentrations, TFAH 10 n easily surpasses the other TFAHs in hepatotoxicity profiling (59.4 % cell viability at 1000 μM), affording good neuroprotection against toxic insults such as Aβ1-40 , Aβ1-42 , H2 O2 , and oligomycin A/rotenone on SH-SY5Y cells, at 1 μM. The results reported herein support the development of new multipotent TFAH derivatives as potential drugs for the treatment of Alzheimer's disease.

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Donepezil–Ferulic Acid Hybrids as Anti-Alzheimer Drugs

et al. 2015

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Background: Due to the complex nature of Alzheimer's disease, there is a renewed and growing search for multitarget drugs. Results: Donepezil–ferulic acid hybrids (DFAHs) were prepared by the one-pot Ugi-4CR in low-to-moderate yields. DFAHs are potent antioxidant agents, showing oxygen radical absorbance capacity values in the range 4.80–8.71 trolox equivalents, quite higher compared with those recorded for ferulic acid and melatonin. From the ChEs inhibition studies, we conclude that DFAH 8, bearing an ethylene linker, and DFAH 12, bearing a propylene linker, both substituted with a melatonin motif, are the most potent inhibitors, in the nanomolar range. Conclusion: We have identified DFAH 8 as a very potent antioxidant, and totally selective equineButyrylCholinEsterase (eqBuChE) inhibitor.

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Marc Pudlo

Arginase Inhibitors: A Rational Approach Over One Century

Nanovectorization of TRAIL with Single Wall Carbon Nanotubes Enhances Tumor Cell Killing

Novel Tacrine‐Grafted Ugi Adducts as Multipotent Anti‐Alzheimer Drugs: A Synthetic Renewal in Tacrine–Ferulic Acid Hybrids

Donepezil–Ferulic Acid Hybrids as Anti-Alzheimer Drugs

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