Dionissios Papaioannou scite author profile

Chloramphenicol (CAM) is the D-threo isomer of a small molecule, consisting of a p-nitrobenzene ring connected to a dichloroacetyl tail through a 2-amino-1,3-propanediol moiety. CAM displays a broad-spectrum bacteriostatic activity by specifically inhibiting the bacterial protein synthesis. In certain but important cases, it also exhibits bactericidal activity, namely against the three most common causes of meningitis, Haemophilus influenzae, Streptococcus pneumoniae and Neisseria meningitidis. Resistance to CAM has been frequently reported and ascribed to a variety of mechanisms. However, the most important concerns that limit its clinical utility relate to side effects such as neurotoxicity and hematologic disorders. In this review, we present previous and current efforts to synthesize CAM derivatives with improved pharmacological properties. In addition, we highlight potentially broader roles of these derivatives in investigating the plasticity of the ribosomal catalytic center, the main target of CAM.

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Structure, Biological Activity and Synthesis of Polyamine Analogues and Conjugates

Karigiannis

Papaioannou²

2000

Eur. J. Org. Chem.

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Conjugation with polyamines enhances the antibacterial and anticancer activity of chloramphenicol

et al. 2014

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Chloramphenicol (CAM) is a broad-spectrum antibiotic, limited to occasional only use in developed countries because of its potential toxicity. To explore the influence of polyamines on the uptake and activity of CAM into cells, a series of polyamine–CAM conjugates were synthesized. Both polyamine architecture and the position of CAM-scaffold substitution were crucial in augmenting the antibacterial and anticancer potency of the synthesized conjugates. Compounds 4 and 5, prepared by replacement of dichloro-acetyl group of CAM with succinic acid attached to N4 and N1 positions of N8,N8-dibenzylspermidine, respectively, exhibited higher activity than CAM in inhibiting the puromycin reaction in a bacterial cell-free system. Kinetic and footprinting analysis revealed that whereas the CAM-scaffold preserved its role in competing with the binding of aminoacyl-tRNA 3′-terminus to ribosomal A-site, the polyamine-tail could interfere with the rotatory motion of aminoacyl-tRNA 3′-terminus toward the P-site. Compared to CAM, compounds 4 and 5 exhibited comparable or improved antibacterial activity, particularly against CAM-resistant strains. Compound 4 also possessed enhanced toxicity against human cancer cells, and lower toxicity against healthy human cells. Thus, the designed conjugates proved to be suitable tools in investigating the ribosomal catalytic center plasticity and some of them exhibited greater efficacy than CAM itself.

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Kukoamine A analogs with lipoxygenase inhibitory activity

Hadjipavlou‐Litina

Garnelis

Athanassopoulos

et al. 2009

Journal of Enzyme Inhibition and Medicinal Chemistry

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Structure, Biological Activity and Synthesis of Polyamine Analogues and Conjugates

Karigiannis

Papaioannou²

2000

Eur. J. Org. Chem.

119

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The structure and the biological significance of naturally occurring and synthetic polyamine analogues and conjugates are presented and the available methodologies for their synthesis are described. These methodologies involve either the selective functionalization of the amino functions, using suitable protecting groups or acylating agents, or fragment synthesis protocols. The latter employ suitable amino components and simple reactions, like Michael addition to α,β‐unsaturated nitriles, alkylation of amines and sulfonamides, reductive alkylation and acylation followed by reduction of the thus‐obtained amides, as key‐reactions, or azides as key‐intermediates, for the assembly of the polyamine skeleton. Syntheses performed in solution as well as in the solid phase are discussed.

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