Current medicinal chemistry. Anti-cancer agents最新文献

The anthracycline group of compounds are amongst the most effective chemotherapy agents currently in use for cancer treatment. They are generally classified as topoisomerase II inhibitors but also have a variety of other targets in cells. It has been known for some years that the anthracyclines are capable of forming DNA adducts, but the relevance and extent of these DNA adducts in cells and their role in causing cell death has remained obscure. When the adduct structure was solved, it became clear that formaldehyde was an absolute requirement for adduct formation. This led to a renewed interest in the capacity of anthracyclines to form DNA adducts, and there are now several ways in which adduct formation can be facilitated in cells. These involve strategies to provide the requisite formaldehyde in the form of anthracycline-formaldehyde conjugates, and the use of formaldehyde-releasing drugs in combination with anthracyclines. Of particular interest is the new therapeutic compound AN-9 that releases both butyric acid and formaldehyde, leading to efficient anthracycline-DNA adduct formation, and synergy between the two compounds. Targeted formation of adducts using anthracycline-formaldehyde conjugates tethered to cell surface targeted molecules is now also possible. Some of the cellular consequences of these adducts have now been studied, and it appears that their formation can overcome anthracycline-resistance mechanisms, and that they are more efficient at inducing apoptosis than when functioning primarily through impairment of topoisomerase II. The clinical application of the use of anthracyclines as DNA adduct forming agents is now being explored.

CDK2 is an attractive target for the design of new therapeutic antitumor agent. Numerous CDK2 inhibitors have been discovered and their crystallographic structures either in complex with CDK2 or CDK2/Cyclin A have been published. This review aims to summarize the publicly available structural characterization of CDK2/(Cyclin A) -- ligand complexes and to highlight the similarities among the binding modes of structurally diverse inhibitors.

A substantial number of experimental and epidemiological studies support an important role for the phosphatidylinositol 3-kinase (PI3K)/protein kinase B (PKB) pathway in the biology of human cancers. Components of this signaling cascade have been found to be deregulated in a wide range of solid tumors and hematologic malignancies, and extensive anti-cancer therapeutic programs are now devoted to the identification of agents that specifically block this molecular pathway. This article focuses on the current knowledge of the alterations of the PI3K/PKB pathway in cancer cells and ongoing drug discovery efforts to therapeutically target it. Particular emphasis is placed on medicinal chemistry activities to identify and develop compounds able to modulate the kinase activity of its main molecular components.

Steroid sulfatase (STS) is the only well characterized enzyme in human cells that is capable to desulfate estrone 3-sulfate (E1S) and dehydroepiandrosterone sulfate (DHEAS) as a first step in the conversion of these precursors to active hormones. STS has been found to be highly expressed in estrogen-dependent breast tumors in post-menopausal women and is regarded as a crucial component of the local estrogen production that is required for tumor growth and survival. Inhibitors of STS are expected to block the intra-tumoral estrogen synthesis and, therefore, are considered as potential new therapeutic agents for the treatment of estrogen-dependent cancers of the breast and the endometrium. In this review, we give an overview on the current status in the field of medicinal chemistry of STS inhibitors. Newer developments comprise potent aryl sulfamate-based irreversible inhibitors, and several types of reversible inhibitors. Other directions include compounds with dual mode of action, such as compounds that block both STS and aromatase, or act as STS inhibitors and antiproliferative or antiangiogenic agents at the same time. In particular, these agents featuring an extended mode of action hold promise to be included in the armamentarium to fight endocrine-dependent cancer.

Mapping and sequencing the genetic blueprint in human, mice, yeast and other model organisms has created challenges and opportunities for chemistry, biology and human medicine. An understanding of the function of each of the approximately 25,000 genes in humans, and the biological circuitry that controls these genes will be driven in part by new technologies from the world of chemistry. Many cellular events that lead to cancer and the progression of human disease represent aberrant gene expression. Small molecules that can be programmed to mimic transcription factors and bind a large repertoire of DNA sequences in the human genome would be useful tools in biology and potentially in human medicine. Polyamides are synthetic oligomers programmed to read the DNA double helix. They are cell permeable, bind chromatin and have been shown to downregulate endogenous genes in cell culture.

Etoposide is an important chemotherapeutic agent that is used to treat a wide spectrum of human cancers. It has been in clinical use for more than two decades and remains one of the most highly prescribed anticancer drugs in the world. The primary cytotoxic target for etoposide is topoisomerase II. This ubiquitous enzyme regulates DNA under- and overwinding, and removes knots and tangles from the genome by generating transient double-stranded breaks in the double helix. Etoposide kills cells by stabilizing a covalent enzyme-cleaved DNA complex (known as the cleavage complex) that is a transient intermediate in the catalytic cycle of topoisomerase II. The accumulation of cleavage complexes in treated cells leads to the generation of permanent DNA strand breaks, which trigger recombination/repair pathways, mutagenesis, and chromosomal translocations. If these breaks overwhelm the cell, they can initiate death pathways. Thus, etoposide converts topoisomerase II from an essential enzyme to a potent cellular toxin that fragments the genome. Although the topoisomerase II-DNA cleavage complex is an important target for cancer chemotherapy, there also is evidence that topoisomerase II-mediated DNA strand breaks induced by etoposide and other agents can trigger chromosomal translocations that lead to specific types of leukemia. Given the central role of topoisomerase II in both the cure and initiation of human cancers, it is imperative to further understand the mechanism by which the enzyme cleaves and rejoins the double helix and the process by which etoposide and other anticancer drugs alter topoisomerase II function.

Competition dialysis is a powerful new tool for the discovery of ligands that bind to nucleic acids with structural- or sequence-selectivity. The method is based on firm thermodynamic principles and is simple to implement. In the competition dialysis experiment, an array of nucleic acid structures and sequences is dialyzed against a common test ligand solution. After equilibration, the amount of ligand bound to each structure or sequence is determined spectrophotometrically. Since all structures and sequences are in equilibrium with the same free ligand concentration, the amount bound is directly proportional to the ligand binding affinity. Competition dialysis thus provides a direct and quantitative measure of selectivity, and unambiguously identifies which of the structures or sequences within the sample array that are preferred by a particular ligand. Following the introduction of the method, competition dialysis has been used worldwide to probe a variety of ligand-nucleic acid interactions. This contribution will focus on new analytical approaches for extracting information from the database that resulted from the first-generation competition dialysis assay, in which binding data was gathered for the interaction of 126 compounds with 13 different structures and sequences. Such global analyses allow identification of compounds with unique types of binding selectivity.

The alkaloid camptothecin is the prototypical DNA topoisomerase I poison. This core structure has formed the basis for two marketed antitumor agents and numerous clinical candidates, and has been the focus of many synthetic and medicinal chemistry studies. Recent reports have furthered our understanding of the roles played by the D and E rings of camptothecin in stabilization of the enzyme-DNA-camptothecin ternary complex. Important parameters for further study and optimization include the facility of E-ring lactone hydrolysis and the prospects for replacing the E ring with more stable structures, the role of the 14-CH group in binary complex binding, and the effect of ternary complex dynamics on the expression of cytotoxicity by the camptothecins.

Triplex-forming oligonucleotides (TFOs) bind in the major groove of duplex DNA at polypurine/ polypyrimidine stretches in a sequence-specific manner. The binding specificity of TFOs makes them potential candidates for use in directed genome modification. A number of studies have shown that TFOs can introduce permanent changes in a target sequence by stimulating a cell's inherent repair pathways. TFOs have also been demonstrated to inhibit gene expression providing a possible role for these compounds in cancer therapy. This review summarizes the dual roles of TFOs for use in delivering DNA reactive compounds to a specific site in the genome or for introducing permanent changes in the target sequence through the introduction of an altered helical structure. In addition to compiling the ways in which TFOs have been successfully utilized, this review will explore conflicting reports of TFO bioactivity focusing on the variables which affect the efficacy in vitro of TFO mediated genomic modification which in turn may represent the obstacles encountered using TFOs to modulate gene expression in vivo.

Aminoglycosides, traditional RNA binders, were found to be a new class of triple helical nucleic acid-stabilizing ligands. Neomycin, of all the aminoglycosides, has shown the most significant effects in stabilizing DNA, RNA, and hybrid triple helices. When compared with minor groove binders or intercalators, neomycin excels at triple helical stabilization in most cases. Molecular modeling studies suggest that neomycin reaches into the larger Watson-Hoogsteen groove. The charge and shape complementarity are the key factors in neomycin-triplex recognition. By conjugating neomycin with intercalators such as BQQ (a potent triple helix intercalating agent designed by Hélène), we have progressed in developing more potent triple helix stabilizing ligands. The design of such dual or even triple recognition ligands opens a new paradigm for recognition of triple helix nucleic acids. The article herein presents studies of neomycin as the first molecule that can selectively stabilize nucleic acid triplex structures. These studies are supported by our recent discovery that neomycin prefers to bind to A-like conformations, of which triple helix structures are known to display some characteristics. These findings will contribute to the development of a new series of triplex-specific ligands, and may contribute to either antisense or antigene therapies.