Do in vitro assays in rat primary neurons predict drug-induced seizure liability in humans?

Drug-induced seizures contribute to the high attrition rate of pharmaceutical compounds in development. The assessment of drug-induced seizure liability generally occurs in later phases of development using low throughput and intensive in vivo assays. In the present study, we evaluated the potential of an in vitro assay for detecting drug-induced seizure risk compared to evaluation in rats in vivo. We investigated the effects of 8 reference drugs with a known seizurogenic risk using micro-electrode array (MEA) recordings from freshly-dissociated rat primary neurons cultured on 48-well dishes for 28 days, compared to their effects on the EEG in anesthetized rats. In addition, we evaluated functional responses and mRNA expression levels of different receptors in vitro to understand the potential mechanisms of drug-induced seizure risk. Combining the functional MEA in vitro data with concomitant gene expression allowed us to identify several potential molecular targets that might explain the drug-induced seizures occurring in both rats and humans. Our data 1) demonstrate the utility of a group of MEA parameters for detecting potential drug-induced seizure risk in vitro; 2) suggest that an in vitro MEA assay with rat primary neurons may have advantages over an in vivo rat model; and 3) identify potential mechanisms for the discordance between rat assays and human seizure risk for certain seizurogenic drugs.

Application of optical action potentials in human induced pluripotent stem cells-derived cardiomyocytes to predict drug-induced cardiac arrhythmias.

INTRODUCTION: Human induced pluripotent stem cell-derived cardiomyocytes (hiPS-CMs) are emerging as new and human-relevant source in vitro model for cardiac safety assessment that allow us to investigate a set of 20 reference drugs for predicting cardiac arrhythmogenic liability using optical action potential (oAP) assay. METHODS: Here, we describe our examination of the oAP measurement using a voltage sensitive dye (Di-4-ANEPPS) to predict adverse compound effects using hiPS-CMs and 20 cardioactive reference compounds. Fluorescence signals were digitized at 10kHz and the records subsequently analyzed off-line. Cells were exposed to 30min incubation to vehicle or compound (n=5/dose, 4 doses/compound) that were blinded to the investigating laboratory. Action potential parameters were measured, including rise time (Trise) of the optical action potential duration (oAPD). RESULTS: Significant effects on oAPD were sensitively detected with 11 QT-prolonging drugs, while oAPD shortening was observed with ICa-antagonists, IKr-activator or ATP-sensitive K+ channel (KATP)-opener. Additionally, the assay detected varied effects induced by 6 different sodium channel blockers. The detection threshold for these drug effects was at or below the published values of free effective therapeutic plasma levels or effective concentrations by other studies. DISCUSSION: The results of this blinded study indicate that OAP is a sensitive method to accurately detect drug-induced effects (i.e., duration/QT-prolongation, shortening, beat rate, and incidence of early after depolarizations) in hiPS-CMs; therefore, this technique will potentially be useful in predicting drug-induced arrhythmogenic liabilities in early de-risking within the drug discovery phase.

EfficientAgrobacterium-mediated transformation and recovery of transgenic plants from pear (Pyrus communis L.).

An efficient and reproducible method was established for genetic transformation of one pear variety (Conferénce) usingAgrobacterium tumefaciens-mediated gene transfer. Wounded leaves of in vitro micropropagated plants were cocultivated with the disarmed strain EHA101 harbouring the binary vector pFAJ3000 carrying the chimaericnptII andgus genes. The protocol included a 3-6 month dark period on a regeneration medium solidified with gelrite, which contained 100 mg/l kanamycin. Up to 42% of inoculated leaves produced transformed buds or bud clusters. Expression, presence and integration of transgenes was confirmed by a histochemical test, polymerase chain reaction and Southern blot hybridisation, respectively. The transgenec plants could be successfully acclimatized in the glasshouse. This transformation procedure was also successfully applied to two other pear varieties, namely Doyenné du Cornice and Passe-Crassane, albeit at much lower transformation rates.

Agrobacterium-mediated transformation of apple (Malus x domestica Borkh.): an assessment of factors affecting regeneration of transgenic plants.

We have previously developed a protocol for efficient gene transfer and regeneration of transgenic calli following cocultivation of apple (cv. Jonagold) explants with Agrobacterium tumefaciens (De Bondt et al. 1994, Plant Cell Reports 13: 587-593). Now we report on the optimization of postcultivation conditions for efficient and reproducible regeneration of transgenic shoots from the apple cultivar Jonagold. Factors which were found to be essential for efficient shoot regeneration were the use of gelrite as a gelling agent and the use of the cytokinin-mimicing thidiazuron in the selective postcultivation medium. Improved transformation efficiencies were obtained by combining the hormones thidiazuron and zeatin and by using leaf explants from in vitro grown shoots not older than 4 weeks after multiplication. Attempts to use phosphinothricin acetyl transferase as a selectable marker were not successful. Using selection on kanamycin under optimal postcultivation conditions, about 2% of the leaf explants developed transgenic shoots or shoot clusters. The presence and expression of the transferred genes was verified by ß-glucuronidase assays and Southern analysis. The transformation procedure has also been succesfully applied to several other apple cultivars.

Agrobacterium-mediated transformation of apple (Malus x domestica Borkh.): an assessment of factors affecting gene transfer efficiency during early transformation steps.

The factors influencing transfer of an intron - containing ß-glucuronidase gene to apple leaf explants were studied during early steps of an Agrobacterium tumefaciens-mediated transformation procedure. The gene transfer process was evaluated by counting the number of ß-glucuronidase expressing leaf zones immediately after cocultivation, as well as by counting the number of ß-glucuronidase expressing calli developing on the explants after 6 weeks of postcultivation in the presence of 50 mg/l kanamycin. Of three different tested disarmed A. tumefaciens strains, EHA101(pEHA101) was the most effective for apple transformation. Cocultivation of leaf explants with A. tumefaciens on a medium with a high cytokinin level was more conducive to gene transfer than cocultivation on media with high auxin concentrations. Precultivation of leaf explants, prior to cocultivation, slightly increased the number of ß-glucuronidase expressing zones measured immediately after cocultivation, but it drastically decreased the number of transformed calli appearing on the explants 6 weeks after infection. Other factors examined were: Agrobacterium cell density during infection, bacterial growth phase, nature of the carbon source, explant age, and explant genotype.