Label-retaining liver cancer cells are relatively resistant to sorafenib.

OBJECTIVE: The standard therapy for advanced hepatocellular carcinoma (HCC) is sorafenib, with most patients experiencing disease progression within 6 months. Label-retaining cancer cells (LRCC) represent a novel subpopulation of cancer stem cells (CSC). The objective was to test whether LRCC are resistant to sorafenib. METHODS: We tested human HCC derived LRCC and non-LRCC before and after treatment with sorafenib. RESULTS: LRCC derived from human HCC are relatively resistant to sorafenib. The proportion of LRCC in HCC cell lines is increased after sorafenib while the general population of cancer cells undergoes growth suppression. We show that LRCC demonstrate improved viability and toxicity profiles, and reduced apoptosis, over non-LRCC. We show that after treatment with sorafenib, LRCC upregulate the CSC marker aldehyde dehydrogenase 1 family, wingless-type MMTV-integration-site family, cell survival and proliferation genes, and downregulate apoptosis, cell cycle arrest, cell adhesion and stem cells differentiation genes. This phenomenon was accompanied by non-uniform activation of specific isoforms of the sorafenib target proteins extracellular-signal-regulated kinases and v-akt-murine-thymoma-viral-oncogene homologue (AKT) in LRCC but not in non-LRCC. A molecular pathway map for sorafenib treated LRCC is proposed. CONCLUSIONS: Our results suggest that HCC derived LRCC are relatively resistant to sorafenib. Since LRCC can generate tumours with as few as 10 cells, our data suggest a potential role for these cells in disease recurrence. Further investigation of this phenomenon might provide novel insights into cancer biology, cancer recurrence and drug resistance with important implications for the development of novel cancer therapies based on targeting LRCC.

Discovery of a novel series of nonacidic benzofuran EP1 receptor antagonists.

We describe the discovery and optimization of a novel series of benzofuran EP(1) antagonists, leading to the identification of 26d, a novel nonacidic EP(1) antagonist which demonstrated efficacy in preclinical models of chronic inflammatory pain.

Interprofessional education: cooperation among osteopathic medicine, pharmacy, and physician assistant students to recognize medical errors.

Thirty-nine volunteer students from 3 health science colleges at Touro University California participated in an exercise designed to promote interprofessional collaboration. In the event, thirteen 3-person multidisciplinary teams of students identified potential medical errors in a series of case-based scenarios. In an immediate postevent survey, 33 of 39 respondents (85%) indicated that the exercise marked the first time that they had worked on clinical problems with students from other health professions. All respondents agreed that interprofessional education was useful and necessary. A 6-month follow-up survey had 24 respondents, 9 of whom (38%) indicated that the experience helped them in interprofessional communications in their clinical rotations. Twenty-two respondents (92%) recalled that all team members were involved in the selection of answers. Respondents reported that team answer selections were made by consensus (12 [50%]), by accepting the opinion of an "expert" on the team (9 [38%]), or by majority vote (3 [13%]). Since this exercise, there has been a surge of interprofessional activities at Touro University California, including steps toward the implementation of campus-wide interprofessional education.

Drug reprofiling using zebrafish identifies novel compounds with potential pro-myelination effects.

Treatment of the autoimmune demyelinating disease multiple sclerosis (MS) requires therapies that both limit and repair damage. While several immunomodulatory treatments exist to limit damage there are currently no treatments that promote the regenerative process of remyelination. A rapid way of screening potential pro-remyelination compounds is therefore required. The use of larval zebrafish in a drug reprofiling screen allows rapid in vivo screening and has been used successfully in the past as an efficient way of identifying new indications for existing drugs. A novel screening platform for potential pro-myelination compounds was developed using zebrafish larvae. Two percent of compounds screened from reprofiling libraries altered oligodendrocyte lineage cell recruitment and/or proliferation, as measured by the numbers of dorsally migrated spinal cord olig2(+) cells. Selective screening identified three compounds that altered levels of myelination, as measured by whole larvae myelin basic protein (mbp) transcript levels; the src family kinase inhibitor PP2, a biogenic amine and a thioxanthene. As well as many previously unrecognised compounds, identified compounds included those with previously known effects on myelin and/or the oligodendrocyte lineage, such as a PPAR agonist, steroid hormones and src family kinase inhibitors. As well as providing methods for further assessment of potentially beneficial compounds, this screen has highlighted 25 targets that are able to alter oligodendrocyte lineage cell recruitment or proliferation and/or mbp transcript levels in vivo and are worthy of further investigation for their potential effects on remyelination.

Serum S100A6 concentration predicts peritoneal tumor burden in mice with epithelial ovarian cancer and is associated with advanced stage in patients.

BACKGROUND: Ovarian cancer is the 5th leading cause of cancer related deaths in women. Five-year survival rates for early stage disease are greater than 94%, however most women are diagnosed in advanced stage with 5 year survival less than 28%. Improved means for early detection and reliable patient monitoring are needed to increase survival. METHODOLOGY AND PRINCIPAL FINDINGS: Applying mass spectrometry-based proteomics, we sought to elucidate an unanswered biomarker research question regarding ability to determine tumor burden detectable by an ovarian cancer biomarker protein emanating directly from the tumor cells. Since aggressive serous epithelial ovarian cancers account for most mortality, a xenograft model using human SKOV-3 serous ovarian cancer cells was established to model progression to disseminated carcinomatosis. Using a method for low molecular weight protein enrichment, followed by liquid chromatography and mass spectrometry analysis, a human-specific peptide sequence of S100A6 was identified in sera from mice with advanced-stage experimental ovarian carcinoma. S100A6 expression was documented in cancer xenografts as well as from ovarian cancer patient tissues. Longitudinal study revealed that serum S100A6 concentration is directly related to tumor burden predictions from an inverse regression calibration analysis of data obtained from a detergent-supplemented antigen capture immunoassay and whole-animal bioluminescent optical imaging. The result from the animal model was confirmed in human clinical material as S100A6 was found to be significantly elevated in the sera from women with advanced stage ovarian cancer compared to those with early stage disease. CONCLUSIONS: S100A6 is expressed in ovarian and other cancer tissues, but has not been documented previously in ovarian cancer disease sera. S100A6 is found in serum in concentrations that correlate with experimental tumor burden and with clinical disease stage. The data signify that S100A6 may prove useful in detecting and/or monitoring ovarian cancer, when used in concert with other biomarkers.

Discovery of GSK345931A: An EP(1) receptor antagonist with efficacy in preclinical models of inflammatory pain.

Herein we describe the medicinal chemistry programme to identify a potential back-up compound to the EP(1) receptor antagonist GW848687X. This work started with the lipophilic 1,2-biaryl benzene derivative 4 which displayed molecular weight of 414.9g/mol and poor in vivo metabolic stability in the rat and resulted in the identification of compound 7i (GSK345931A) which demonstrated good metabolic stability in the rat and lower molecular weight (381.9g/mol). In addition, 7i (GSK345931A) showed measurable CNS penetration in the mouse and rat and potent analgesic efficacy in acute and sub-chronic models of inflammatory pain.

Zebrafish based assays for the assessment of cardiac, visual and gut function--potential safety screens for early drug discovery.

INTRODUCTION: Safety pharmacology is integral to the non-clinical safety assessment of new chemical entities prior to first administration to humans. The zebrafish is a well established model organism that has been shown to be relevant to the study of human diseases. The potential role of zebrafish in safety pharmacology was evaluated using reference compounds in three models assessing cardiac, visual and intestinal function. METHODS: Compound toxicity was first established in zebrafish to determine the non toxic concentration of a blinded set of 16 compounds. In the cardiac assay, zebrafish larvae at 3 days post fertilisation (d.p.f.) were exposed to compounds for 3 h before measurement of the atrial and ventricular rates. To investigate visual function, the optomotor response was assessed in 8 d.p.f. larvae following a 5 day compound exposure. In the intestinal function assay, the number of gut contractions was measured in 7 d.p.f. larvae after a 1 h compound exposure. Finally, compound uptake was determined for 9 of the 16 compounds to measure the concentration of compound absorbed by the zebrafish larvae. RESULTS: Seven compounds out of nine produced an expected effect that was statistically significant in the cardiac and visual functions assays. In the gut contraction assay, six out of ten compounds showed a statistically significant effect that was also the expected result whilst two displayed anticipated but non-significant effects. The compound uptake method was used to determine larval tissue concentrations and allowed the identification of false negatives when compound was poorly absorbed into the zebrafish. DISCUSSION: Overall, results generated in three zebrafish larvae assays demonstrated a good correlation between the effects of compounds in zebrafish and the data available from other in vivo models or known clinical adverse effects. These results suggest that for the cardiac, intestinal and visual function, zebrafish assays have the potential to predict adverse drug effects and supports their possible role in early safety assessment of novel compounds.

Non-associative learning in larval zebrafish.

Habituation, where a response is reduced when exposed to a continuous stimulus is one of the simplest forms of non-associative learning and has been shown in a number of organisms from sea slugs to rodents. However, very little has been reported in the zebrafish, a model that is gaining popularity for high-throughput compound screens. Furthermore, since most of the studies involving learning and memory in zebrafish have been conducted in adults, we sought to determine if zebrafish larvae could display non-associative learning and whether it could be modulated by compounds identified in previous rodent studies. We demonstrated that zebrafish larvae (7 days post fertilization) exhibit iterative reduction in a startle response to a series of acoustic stimuli. Furthermore, this reduction satisfied criteria for habituation: spontaneous recovery, more rapid reductions in startle to shorter intertrial intervals and dishabituation. We then investigated the pathways mediating this behavior using established compounds in learning and memory. Administration of rolipram (PDE4 inhibitor), donepezil (acetylcholinesterase inhibitor), and memantine (N-methyl-D-aspartic acid (NMDA) receptor antagonist) all increased the acoustic startle response and decreased habituation in the larvae, similar to previous rodent studies. Further studies demonstrated that NMDA blocked the memantine response and the effect of donepezil was blocked by mecamylamine but not atropine suggesting that the donepezil response was mediated by nicotinic rather than muscarinic receptors. Zebrafish larvae possess numerous advantages for medium to high-throughput screening; the model described herein therefore offers the potential to screen for additional compounds for further study on cognition function.

Zebrafish offer the potential for a primary screen to identify a wide variety of potential anticonvulsants.

The search for novel anticonvulsants requires appropriate model systems in which to test hypotheses through focused compound screening or genetic manipulation, or conduct black box screening of large numbers of compounds or potential genetic modifiers. Many models are currently in existence that subserve particular roles in achieving these aims, but all have their limitations. Zebrafish have been suggested as an additional model of epilepsy, but their optimum role is unclear. They are more amenable to high throughput analysis, but are more genetically removed from humans than rodents. We therefore sought to develop assay methodology applicable to medium/high throughput screening using an automated tracking system to measure the amount of movement induced by exposure to the proconvulsant, pentylene tetrazole (PTZ). We then used this system to explore how many known anti-epileptic drugs (AEDs) would be detected when running such a screen. We were able to detect suppression of PTZ-induced excessive movements with 13 out of 14 standard AEDs. A parallel sedation and toxicity screen suggested these effects were due to direct anti-epileptic effect, although non-specific effects cannot be fully excluded. These results suggest zebrafish may be a useful high throughput primary screen to pick up potential novel AEDs.

High-throughput in vivo screening for bone anabolic compounds with zebrafish.

Osteoporosis and diseases of bone loss are a major public health problem for the present and the future since longevity and prevalence of the disease are increasing in all parts of the world. The bisphosphonates, widely used in the treatment of osteoporosis, act by inhibiting bone resorption. However, there are few agents that promote or increase bone formation in patients who have suffered substantial bone loss. To facilitate the identification of novel anabolic therapies, the authors have developed a rapid, high-throughput in vivo screen using larval zebrafish (Danio rerio) in which they are able to identify agents with anabolic effects in the skeleton within a 6-day time period. Vitamin D3 analogs and intermittent parathyroid hormone (PTH) result in dose-dependent increases in the formation of mineralized bone, whereas continuous exposure to PTH results in net bone loss. Because this model is fast, economical, and genetically tractable, it provides a powerful adjunct to mammalian models for the identification of new anabolic bone agents and offers the potential for genetic elucidation of pathways important in osteoblastic activity.

Zebrafish as a pharmacological tool: the how, why and when.

Zebrafish combine the relevance of a vertebrate with the scalability of an invertebrate. They can live in 96-well plate format and readily absorb chemicals from the water. These features have stimulated the use of zebrafish by medical researchers to model human disease and then assess the action of compounds in a whole organism. Examples of the power of this system have been illustrated with the cloning of zebrafish human ether-a-go-go-related gene (HERG), which shows near 100% homology in key domains, and the associated ability to identify drugs that prolong the QT interval both rapidly and with tiny amounts (micrograms) of compound.