Transgenic animal models in toxicology: historical perspectives and future outlook.

Transgenic animal models are powerful tools for developing a more detailed understanding on the roles of specific genes in biological pathways and systems. Applications of these models have been made within the field of toxicology, most notably for the screening of mutagenic and carcinogenic potential and for the characterization of toxic mechanisms of action. It has long been a goal of research toxicologists to use the data from these models to refine hazard identification and characterization to better inform human health risk assessments.

Doxorubicin and vinorelbine act independently via p53 expression and p38 activation respectively in breast cancer cell lines.

In the treatment of breast cancer, combination chemotherapy is used to overcome drug resistance. Combining doxorubicin and vinorelbine in the treatment of patients with metastatic breast cancer has shown high response rates; even single-agent vinorelbine in patients previously exposed to anthracyclines results in significant remission. Alterations in protein kinase-mediated signal transduction and p53 mutations may play a role in drug resistance with cross-talk between signal transduction and p53 pathways.

The role of signal transduction in cancer treatment and drug resistance.

Drug resistance in the treatment of cancer still remains a major clinical challenge, in part due to an insufficient understanding of the pathways by which these drugs interact with the mechanisms underlying cellular behaviour and cancer pathogenesis. Signal transduction involves cell differentiation, proliferation and cell death with alterations in these mechanisms being involved in the pathogenesis of cancer. It has been postulated that such pathways could be linked to anti-cancer drug resistance.

Methyl iodide toxicity in rat cerebellar granule cells in vitro: the role of glutathione.

The monohalomethane methyl iodide (MeI) is toxic to a number of organ systems including the central nervous system. Clinical symptoms of neurotoxicity suggest that the cerebellum is the target within the brain, and we have now modelled the toxicity of MeI in cultured rat cerebellar granule cells. Cytotoxicity is maximal 24 h after a 5 min exposure to MeI, and the EC50 for MeI under these conditions was calculated to be 1.

Investigations of the pathways of toxicity of methyl iodide in the rat nasal cavity.

The monohalomethane methyl iodide (MeI) is a site specific toxin within the nasal cavity of the rat, selectively damaging the olfactory epithelium (OE) whilst respiratory epithelium (RE) is spared. The aim of this study was to investigate the rates and routes of metabolism of MeI within the nasal cavity, in order to understand the reasons for the observed site-selectivity. Cytosolic glutathione S-transferases (GSTs) of both OE and RE catalysed the conjugation of MeI with glutathione (GSH), but rates were 4-fold higher in OE than RE.

The role of glutathione S-transferase- and cytochrome P450-dependent metabolism in the olfactory toxicity of methyl iodide in the rat.

The aim of this study was to investigate the role of metabolic activation in the olfactory toxicity of methyl iodide (MeI). Adult male rats were exposed via nose-only inhalation to 100 ppm MeI for 0-6 h, and non-protein sulphydryl (NP-SH) concentrations determined in selected tissues. Depletion of NP-SH occurred in all tissues, but was most marked and rapid in the respiratory epithelium of the nasal cavity and the kidney.