Mark P. Wentland

Cyclin-dependent kinase 8 mediates chemotherapy-induced tumor-promoting paracrine activities

Conventional chemotherapy not only kills tumor cells but also changes gene expression in treatment-damaged tissues, inducing production of multiple tumor-supporting secreted factors. This secretory phenotype was found here to be mediated in part by a damage-inducible cell-cycle inhibitor p21 (CDKN1A). We developed small-molecule compounds that inhibit damage-induced transcription downstream of p21. These compounds were identified as selective inhibitors of a transcription-regulating kinase CDK8 and its isoform CDK19. Remarkably, p21 was found to bind to CDK8 and stimulate its kinase activity. p21 and CDK8 also cooperate in the formation of internucleolar bodies, where both proteins accumulate. A CDK8 inhibitor suppresses damage-induced tumor-promoting paracrine activities of tumor cells and normal fibroblasts and reverses the increase in tumor engraftment and serum mitogenic activity in mice pretreated with a chemotherapeutic drug. The inhibitor also increases the efficacy of chemotherapy against xenografts formed by tumor cell/fibroblast mixtures. Microarray data analysis revealed striking correlations between CDK8 expression and poor survival in breast and ovarian cancers. CDK8 inhibition offers a promising approach to increasing the efficacy of cancer chemotherapy.

Opioids Activate Brain Analgesic Circuits Through Cytochrome P450/Epoxygenase Signaling

To assess the importance of brain cytochrome P450 (P450) activity in μ opioid analgesic action, we generated a mutant mouse with brain neuron–specific reductions in P450 activity; these mice showed highly attenuated morphine antinociception compared with controls. Pharmacological inhibition of brain P450 arachidonate epoxygenases also blocked morphine antinociception in mice and rats. Our findings indicate that a neuronal P450 epoxygenase mediates the pain-relieving properties of morphine.

3-Carboxamido analogues of morphine and naltrexone. synthesis and opioid receptor binding properties.

In response to the unexpectedly high affinity for opioid receptors observed in a novel series of cyclazocine analogues where the prototypic 8-OH was replaced by a carboxamido group, we have prepared the corresponding 3-CONH(2) analogues of morphine and naltrexone. High affinity (K(i)=34 and 1.7nM) for mu opioid receptors was seen, however, the new targets were 39- and 11-fold less potent than morphine and naltrexone, respectively.

Discovery of cryptophycin-1 and BCN-183577 : Examples of strategies and problems in the detection of antitumor activity in mice

Historically, many new anticancer agents were first detected in a prescreen; usually consisting of a molecular/biochemical target or a cellular cytotoxicity assay. The agent then progressed to in vivo evaluation against transplanted human or mouse tumors. If the investigator had a large drug supply and ample resources, multiple tests were possible, with variations in tumor models, tumor and drug routes, dose-decrements, dose-schedules, number of groups, etc. However, in most large programs involving several hundred in vivo tests yearly, resource limitations and drug supply limitations have usually dictated a single trial. Under such restrictive conditions, we have implemented a flexible in vivo testing protocol. With this strategy, the tumor model is dictated by in vitro cellular sensitivity; drug route by water solubility (with water soluble agents injected intravenously); dosage decrement by drug supply, dose-schedule by toxicities encountered, etc. In this flexible design, many treatment parameters can be changed during the course of treatment (e.g., dose and schedule). The discovery of two active agents are presented (Cryptophycin-1, and Thioxanthone BCN 183577). Both were discovered by the intravenous route of administration. Both would have been missed if they were tested intraperitoneally, the usual drug route used in discovery protocols. It is also likely that they would have been missed with an easy to execute fixed protocol design, even if injected IV.

Chapter 14. Quinolone Antibacterial Agents

Publisher Summary The renewed interest in quinolone antibacterials that began 5 years ago with the first descriptions of norfloxacin (NOR), pefloxacin (PEF), and enoxacin (ENO) has continued unabated. After two decades of only modest improvements in the antibacterial potency, the activity of the new fluoro- quinolones far surpasses that of the original quinolone, nalidixic acid (NAL, I). The most significant changes made in the quinolone nucleus, addition of fluorine and piperazine have provided these fluoroquinolones with activity against gram- negative bacteria that rivals that of the major classes of antibiotics. The increased potency of the new fluoroquinolones holds promise for a greatly expanded clinical use. This includes the potential for treatment of bacterial prostatitis, gastroenteritis, osteo-myelitis, some pneumonias and infections caused by multiply-resistant Enterobacteriaceae and methicillin-resistant staphylococci. Engagement in the R&D of quinolone antibacterials has resulted in clinical trials with at least eight different fluoroquinolones throughout the world, of which four have received approval for clinical use outside the US. Relative to the first commercially introduced fluoroquinolone, NOR, subsequent analogues have shown greater oral absorption (PEF, ENO) and increased serum. This chapter complements recent reviews describing the mechanism of action and resistance, toxicity, pharmacology and SARs of the quinolone antibacterials. The chapter discusses cirofloxacin (the most potent of the quinolone antibacterials), norfloxacin, ofloxacin, enoxacin, pefloxacin, amiflcucacin, difloxacin (A-56619), A-56620, CI-934, S-25930, S-25932, and other new quinolones—their usefulness against various microbes, and also the comparison of one compounds effectiveness to another.

8-Aminocyclazocine analogues: synthesis and structure-activity relationships.

Opioid binding affinities were assessed for a series of cyclazocine analogues where the prototypic 8-OH substituent of cyclazocine was replaced by amino and substituted-amino groups. For mu and kappa opioid receptors, secondary amine derivatives having the (2R,6R,11R)-configuration had the highest affinity. Most targets were efficiently synthesized from the triflate of cyclazocine or its enantiomers using Pd-catalyzed amination procedures.

Tumor Models and the Discovery and Secondary Evaluation of Solid Tumor Active Agents

AbstractEach independently arising tumor is a separate and unique biologic entity with its own unique histologic appearance, biologic behavior, and drug response profile. Thus, in drug discovery, no single tumor has been a perfect predictor for any other tumor. For this reason, new agents are evaluated in a variety of tumor models which is known as breadth of activity testing. In recent years, human tumors implanted in athymic nude mice and SCID mice have also become available for breadth of activity testing. In studies carried out in these laboratories, it was found that 10 human tumors metastasized in the SCID mice, but failed to metastasize in nude mice. In addition, tumor growth and tumor takes were superior in the SCID mice. The strengths and weaknesses of xenograft model systems are discussed. For example, most human tumor xenograft models are excessively sensitive to alkylating agents as well as to a new class of DNA binders (XE840 and XP315). Using human tumor models that are the least sensitive t...

Preparation of N-hydroxysuccinimido esters via palladium-catalyzed carbonylation of aryl triflates and halides

N-Hydroxysuccinimido esters of aromatic carboxylic acids (a.k.a. active esters) can be made using a potentially general, one-step procedure via Pd-catalyzed carbonylation of an aryl triflate or aryl iodide with CO and N-hydroxysuccinimide. Excellent yields (up to 94%) were observed when the reaction was done in DMSO at 70°C and 1 atmosphere of CO pressure.

Preclinical efficacy of thioxanthone SR271425 against transplanted solid tumors of mouse and human origin

A highly active and broadly active thioxanthone has been identified: N-[[1-[[2-(Diethylamino)ethyl]amino]-7-methoxy-9-oxo-9H-thioxanthen-4-yl] methylformamide (SR271425, BCN326862, WIN71425). In preclinical testing against a variety of subcutaneously growing solid tumors, the following %T/C and Log10 tumor cell kill (LK) values were obtained: Panc-03 T/C = 0, 5/5 cures; Colon-38 (adv. stage) T/C = 0, 3/5 cures, 4.9 LK; Mam-16/C T/C = 0, 3.5 LK; Mam-17/0 T/C = 0, 2.8 LK; Colon-26 T/C = 0, 1/5 cures, 3.2 LK; Colon-51 T/C= 0, 2.7 LK; Panc-02 T/C = 0, 3.1 LK; B16 Melanoma T/C = 13%, 4.0 LK; Squamous Lung-LC12 (adv. stage) T/C = 14%, 4.9 LK; BG-1 human ovarian T/C = 16%, 1.3 LK; WSU-Br1 human breast T/C = 25%, 0.8 LK. The agent was modestly active against doxorubicin (Adr)-resistant solid tumors: Mam-17/Adr T/C =23%, 0.8 LK; and Mam-16/C/Adr T/C = 25%, 1.0 LK, but retained substantial activity against a taxol-resistant tumor: Mam-16/C/taxol T/C = 3%, 2.4 LK. SR271425 was highly active against IV implanted leukemias, L1210 6.3 LK and AML1498 5.3 LK. The agent was equally active both by the IV and oral routes of administration, although requiring approximately 30% higher dose by the oral route. Based on its preclinical antitumor profile, it may be appropriate to evaluate SR271425 in clinical trials.

The antitumor activity of novel pyrazoloquinoline derivatives

Abstract Mammalian topoisomerase II inhibition activity has been identified in a series of novel pyrazoloquinoline derivatives; potency for two analogues containing cyclohexyl groups at the 2-position was comparable to the reference agents, mAMSA and VP-16. In several instances, topo II inhibition translated to a high level of in vitro cytotoxicity and murine antitumor activity.