Intercalators are the most important group of compounds that interact reversibly with the DNA double helix. Some of them are valuable drugs currently used for the treatment of ovarian and breast cancers and acute leukemias, while many others are in different phases of clinical trials. Intercalating agents share common structural features such as the presence of planar polyaromatic systems which bind by insertion between DNA base-pairs, with a marked preference for 5'-pyrimidine-purine-3' steps. The chromophores are linked to basic chains that might also play an important role in the affinity and selectivity shown by these compounds. Bisintercalators have two potential intercalating ring systems connected by linkers which can vary in length and rigidity. Nowadays it is well accepted that the antitumor activity of intercalators is closely related to the ability of these compounds to stabilize the DNA-intercalator-topoisomerase II ternary complex. In this work we have carried out a revision of small organic molecules that bind to the DNA molecule via intercalation, and exert their antitumor activity through a proven topoisomerase II inhibition. We have tried to give a general overview of the most recent results in this area, paying special attention to compounds that are currently under clinical trials. Among those are naphthalimides, a group of compounds that has been developed in our laboratory since the 70's.
Naphthalimides are a class of compounds with high antitumor activity upon a variety of murine and human tumor cells. These compounds bind to DNA by intercalation of the chromophore and two of them, mitonafide and amonafide, were used in clinical trials. The therapeutic properties of these lead drugs were improved by designing bisintercalating agents. One of these, elinafide, showed intense in vitro and in vivo activity and is currently being used in clinical trials against solid tumors. In this paper, the history of elinafide is described.
Matrix metalloproteinases (MMPs) are important targets for pathological conditions such as arthritis, chronic obstructive pulmonary disease, and cancer. The failure of the first broad-spectrum MMP inhibitors in clinical trials has led researchers to address the selectivity as one of their main objectives. The S1' pocket has been widely used to modulate the selectivity of these enzymes because it displays the highest variability in length and shape among MMPs. In this review, we encourage medicinal chemists to also consider the dynamics of this pocket as an important parameter to achieve the desired selectivity. To support this proposal, we collect examples from the literature where the flexibility of the S1' pocket was highlighted as a relevant and significant issue affecting selectivity. We also review the experimental studies on the dynamics of this pocket.
Matrix metalloproteinases (MMPs) are a family of zinc- and calcium-dependent endopeptidases which are secreted or anchored in the cell membrane and are capable of degrading the multiple components of the extracellular matrix (ECM). MMPs are frequently overexpressed or highly activated in numerous human diseases. Owing to the important role of MMPs in human diseases, many MMP inhibitors (MMPIs) have been developed as novel therapeutics, and some of them have entered clinical trials. However, so far, only one MMPI (doxycycline) has been approved by the FDA. Therefore, the evaluation of the activity of a specific subset of MMPs in human diseases using clinically relevant imaging techniques would be a powerful tool for the early diagnosis and assessment of the efficacy of therapy. In recent years, numerous MMPIs labeled imaging agents have emerged. This article begins by providing an overview of the MMP subfamily and its structure and function. The latest advances in the design of subtype selective MMPIs and their biological evaluation are then summarized. Subsequently, the potential use of MMPI-labeled diagnostic agents in clinical imaging techniques are discussed, including positron emission tomography (PET), single-photon emission computed tomography (SPECT) and optical imaging (OI). Finally, this article concludes with future perspectives and clinical utility.
Pyrazolopyridazine 1a was identified in a high-throughput screening carried out by BASF Bioresearch Corp. (Worcester, MA) as a potent inhibitor of CDK1/cyclin B and shown to have selectivity for the CDK family. Analogues of the lead compound have been synthesized and their antitumor activities have been tested. A molecular model of the complex between the lead compound and the CDK2 ATP binding site has been built using a combination of conformational search and automated docking techniques. The stability of the resulting complex has been assessed by molecular dynamics simulations and the experimental results obtained for the synthesized analogues have been rationalized on the basis of the proposed binding mode for compound 1a. As a result of the SAR study, monofuryl 1o has been synthesized and is one of the most active compounds against CDK1 of this series.
Amonafide- and elinafide-related mono and bisintercalators, modified by the introduction of a pi-excedent furan or thiophene ring fused to the naphthalimide moiety, have been synthesized. These compounds have shown an interesting antitumor profile. The best compound, 9, was 2.5-fold more potent than elinafide against human colon carcinoma cells (HT-29). Molecular dynamic simulations and physicochemical experiments have demonstrated that these compounds are capable of forming stable DNA complexes. These results, together with those previously reported by us for imidazo- and pyrazinonaphthalimide analogues, have prompted us to propose that the DNA binding process does not depend on the electronic nature of the fused heterocycle.
Bisnaphthalimides represent a promising group of DNA-targeted anticancer agents. In this series, the lead compounds elinafide and bisnafide have reached clinical trials, and the search for more potent analogues remains a priority. In the course of a medicinal chemistry program aimed at discovering novel antitumor drugs based on the naphthalimide skeleton, different dimeric molecules containing two tetracyclic neutral DNA intercalating chromophores were synthesized. The naphthalimide unit has been fused to a benzene ring (azonafide derivatives), an imidazole, a pyrazine, or, as reported here, a furan ring which increases the planar surface of the chromophore and enhances its stacking properties. We report a detailed investigation of the DNA binding capacity of the dimeric molecule MCI3335 composed of two furonaphthalimide units connected by a 12 A long amino alkyl linker [(CH(2))(2)-NH-(CH(2))(3)-NH-(CH(2))(2)] identical to that of elinafide. Qualitative and quantitative binding studies, in particular using surface plasmon resonance, establish that the dimer binds considerably more tightly to DNA (up to 1000 times) than the corresponding monomer and exhibits a higher sequence selectivity for GC-rich sequences. DNase I footprinting experiments attest that the dimer, and to a lesser extent the monomer, preferentially intercalate at GC sites. The strong binding interaction between the drugs and DNA perturbs the relaxation of supercoiled DNA by topoisomerases, but the test compounds do not promote DNA cleavage by topoisomerase I or II. Despite the lack of poisoning effect toward topoisomerase II, MCI3335 displays a very high cytotoxicity toward CEM human leukemia cells, with an IC(50) in the low nanomolar range, approximately 4 times inferior to that of the reference drug elinafide. Confocal microscopy observations indicate that the monomer shows a stronger tendency to accumulate in the cell nuclei than the dimer. The extremely high cytotoxic potential of MCI3335 is attributed to its enhanced capacity to bind to DNA and to inhibit DNA synthesis, as evidenced by flow cytometry experiments using the BrdU assay. The results provide novel mechanistic information that furthers the understanding of the structure-activity relationships in the bisnaphthalimide series and identify MCI3335 as a novel lead compound for further preclinical investigations.
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