Neurotoxicity studies with a tropomyosin-related kinase A inhibitor, ASP7962, on the sympathetic and sensory nervous systems in rats.

ASP7962 is a small molecule inhibitor for the nerve growth factor (NGF) receptor, tropomyosin-related kinase A (TrkA). NGF contributes to the survival of sensory and sympathetic neurons through TrkA receptor activation. Gross, microscopic, and quantitative effects to the nervous system were evaluated following oral ASP7962 administration to Sprague Dawley rats for 4 weeks and 13 weeks and after a recovery period. Histopathological findings included reversible neuronal atrophy but no neuronal death in the sympathetic ganglia (cervicothoracic ganglion, cranial mesenteric ganglion or superior [cranial] cervical ganglion). Stereological analysis showed reversible decreased ganglion volume and/or decreased neuron size in the superior (cranial) cervical ganglion in both the 4-week and the 13-week repeated dose studies. There were no test article related changes in the brain, dorsal root ganglia with spinal nerve roots or trigeminal ganglia and no functional deficits. ASP7962 did not cause any detectable dysfunction of the sympathetic and sensory nervous system in either study.

Changes in submaxillary gland gene expression in F344 rats by multiple dosing of theophylline.

Multiple exposure to theophylline, a phosphodiesterase (PDE) inhibitor, induces acinar hypertrophy in the salivary gland. This study examined the effect of theophylline on the gene expression of secretory proteins and phosphodiesterases in the submaxillary gland. Male F344 rats received saline or theophylline (50 mg/kg) intraperitoneally for 4 days. The gene expressions for the secretory protein, cystatin S (CysS), and PDE subfamilies 3A and 4D in the submaxillary gland were quantified using RT-PCR. Theophylline exposure resulted in a sustained increase in mRNA expression for CysS and PDE3A, but PDE4D gene expression was unchanged. Our results suggest that submaxillary hypertrophy is primarily caused by the enhanced transcription of CysS, and that the transcription of each PDE subfamily gene is regulated differently.

MuERV-L is one of the earliest transcribed genes in mouse one-cell embryos.

The expression pattern and function of the murine endogenous retrovirus-like (MuERV-L) gene in mouse preimplantation embryos was investigated. MuERV-L was rapidly transcribed from the beginning of S phase (8 h after fertilization) in the first cell cycle. MuERV-L expression was completely repressed when transcription from the zygotic genome was inhibited by alpha-amanitin. These results reveal that MuERV-L is transcribed from the zygotic genome and that it is expressed earlier than any other genes previously reported. In addition, MuERV-L was expressed even when the first round of DNA synthesis was inhibited by aphidicolin, suggesting that its expression is controlled by the zygotic clock. The function of MuERV-L in the development of mouse embryos was also examined using antisense oligonucleotides. The developmental competence of embryos was markedly suppressed after the 4-cell stage when they were treated with antisense oligonucleotides. This result suggests that MuERV-L plays an important role in the development of mouse embryos at the early preimplantation stage.