Maurizio Losacco scite author profile

Integrating carbon nanoparticles (CNPs) with proteins to form hybrid functional assemblies is an innovative research area with great promise for medical, nanotechnology, and materials science. The comprehension of CNP-protein interactions requires the still-missing identification and characterization of the 'binding pocket' for the CNPs. Here, using Lysozyme and C60 as model systems and NMR chemical shift perturbation analysis, a protein-CNP binding pocket is identified unambiguously in solution and the effect of the binding, at the level of the single amino acid, is characterized by a variety of experimental and computational approaches. Lysozyme forms a stoichiometric 1:1 adduct with C60 that is dispersed monomolecularly in water. Lysozyme maintains its tridimensional structure upon interaction with C60 and only a few identified residues are perturbed. The C60 recognition is highly specific and localized in a well-defined pocket.

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Probing the Interaction of Cisplatin with the Human Copper Chaperone Atox1 by Solution and In-Cell NMR Spectroscopy

Arnesano

et al. 2011

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Among anticancer therapeutics, platinum-based drugs have a prominent role. They carry out their antitumor activity by forming stable adducts with DNA, thus interfering with replication and transcription processes. Cellular uptake of these drugs is tightly connected to copper transport. The major Cu(I) influx transporter Ctr1 has been found to mediate transport of cisplatin and its analogues. Evidence also suggests that ATP7A and ATP7B mediate cisplatin sequestration and efflux from cells, thus influencing drug resistance. The copper-chaperone Atox1, which normally binds Cu(I) via two cysteines and delivers the metal to ATP7A/B, has also been reported to interact with cisplatin in in vitro experiments. In the present investigation we apply a combined approach, using solution and in-cell NMR spectroscopy methods, to probe intracellular drug delivery and interaction of cisplatin with Atox1. The intracellular environment provides itself the suitable conditions for the preservation of the protein in its active form. Initially a {Pt(NH(3))(2)}-Atox1 adduct is formed. At longer reaction time we observed protein dimerization and loss of the ammines. Such a process is reminiscent of the copper-promoted formation of Atox1 dimers which have been proposed to be able to cross the nuclear membrane and act as a transcription factor. We also show that overexpression of Atox1 in E. coli reduces the amount of DNA platination and, consequently, the degree of cell filamentation.

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An Updated View of Cisplatin Transport

Arnesano

Losacco²,

Natile

2013

Eur J Inorg Chem

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Cisplatin, or cis-diamminedichloridoplatinum(II) cis-[PtCl2(NH3)2], is a platinum-based anticancer drug largely used for the treatment of various types of cancers, including ovarian and colorectal carcinomas, sarcomas, and lymphomas. Together with other platinum-based drugs, it triggers malignant cell death by binding to nuclear DNA, which appears to be the ultimate target. In addition to passive diffusion across the cell membrane, other transport mechanisms, including endocytosis and some active or facilitated transport, are currently proposed to play a pivotal role in the uptake of platinum-based drugs. In this microreview, we will give an updated view of the current literature regarding cisplatin transport and processing inside the cell, with special emphasis on the membrane copper transporter Ctr1 and the soluble copper chaperone Atox1

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Translocation of Platinum Anticancer Drugs by Human Copper ATPases ATP7A and ATP7B

et al. 2013

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Cisplatin, carboplatin, and oxaliplatin are widely used anticancer drugs. Their efficacy is strongly reduced by development of cell resistance, a phenomenon not entirely understood, with contribution of drug detoxification, defective accumulation, and efflux from the cell. Down-regulation of CTR1, responsible for Cu uptake by the cell, and up-regulation of the Cu-ATPases, ATP7A and ATP7B, which accept Cu from the cytosolic chaperone Atox1 and transfer the metal ion into the secretory pathway where it is incorporated into cuproenzymes, have been associated to augmented drug resistance. To gain information on translocation of Pt drugs by human Cu-ATPases, we performed electrical measurements on COS-1 cell microsomal fraction, enriched with recombinant ATP7A, ATP7B, and selected mutants, adsorbed on a solid supported membrane (SSM). The experimental results demonstrate that Pt drugs activate Cu-ATPases and undergo ATP-dependent translocation with a mechanism identical to that of Cu. We then used NMR spectroscopy and ESI-MS to determine the binding mode of these drugs to the first N-terminal metal binding domain of ATP7A (Mnk1).

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Methionine Can Favor DNA Platination by trans‐Coordinated Platinum Antitumor Drugs

Sletten

et al. 2009

Angew Chem Int Ed

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