Universal Toxicity Gene Signatures for Early Identification of Drug-Induced Tissue Injuries in Rats.

A new safety testing paradigm that relies on gene expression biomarker panels was developed to easily and quickly identify drug-induced injuries across tissues in rats prior to drug candidate selection. Here, we describe the development, qualification, and implementation of gene expression signatures that diagnose tissue degeneration/necrosis for use in early rat safety studies. Approximately 400 differentially expressed genes were first identified that were consistently regulated across 4 prioritized tissues (liver, kidney, heart, and skeletal muscle), following injuries induced by known toxicants.

A panel of urinary biomarkers to monitor reversibility of renal injury and a serum marker with improved potential to assess renal function.

The Predictive Safety Testing Consortium's first regulatory submission to qualify kidney safety biomarkers revealed two deficiencies. To address the need for biomarkers that monitor recovery from agent-induced renal damage, we scored changes in the levels of urinary biomarkers in rats during recovery from renal injury induced by exposure to carbapenem A or gentamicin. All biomarkers responded to histologic tubular toxicities to varied degrees and with different kinetics.

Diagnosis of drug-induced renal tubular toxicity using global gene expression profiles.

Toxicogenomics can measure the expression of thousands of genes to identify changes associated with drug induced toxicities. It is expected that toxicogenomics can be an alternative or complementary approach in preclinical drug safety evaluation to identify or predict drug induced toxicities. One of the major concerns in applying toxicogenomics to diagnose or predict drug induced organ toxicity, is how generalizable the statistical classification model is when derived from small datasets? Here we presented that a diagnosis of kidney proximal tubule toxicity, measured by pathology, can successfully be achieved even with a study design of limited number of training studies or samples.

5-fluorouracil forward mutation assay in Salmonella: determination of mutational target and spontaneous mutational spectra.

A forward mutation assay in Salmonella typhimurium that selects for 5-fluoruracil (FU) resistance has been developed. The two genes possibly involved in FU resistance, the uracil phosphoribosyl transferase gene (upp) and the uracil transport protein (uraA), have been cloned from S. typhimurium and sequenced.

Induced mutation spectra at the upp locus in Salmonella typhimurium: response of the target gene in the FU assay to mechanistically different mutagens.

A novel forward mutation assay has been developed in Salmonella typhimurium based on resistance to 5-fluorouracil (FU). The mutational target in the FU assay was determined to be the uracil phosphoribosyl transferase (upp) gene. To validate the upp gene as a suitable target for monitoring a variety of induced mutations, the mutational specificity was determined for five mechanistically different mutagens.

A low volume, high-throughput forward mutation assay in Salmonella typhimurium based on fluorouracil resistance.

A forward mutation assay based on 5-fluorouracil (FU) resistance has been developed using a strain of Salmonella typhimurium derived from the Ames strain TA100. The sensitivity of the assay benefits from the genetic characteristics present in the standard Ames strain that enhances the response to genotoxic agents. A mutation conferring resistance to 5-fluorouridine was also introduced into the test strain to avoid unwanted toxicity resulting from cross-feeding of 5-fluorouridine between wild-type and FU-resistant (FU(R)) cells during selection with FU.

Genotoxicity of naturally occurring indole compounds: correlation between covalent DNA binding and other genotoxicity tests.

3-Methylindole (3MI), melatonin (Mel), serotonin (Ser), and tryptamine (Tryp) were evaluated in vitro for their potential to induce DNA adducts, DNA strand breaks, chromosomal aberrations (Abs), inhibition of DNA synthesis, and mutations. All compounds produced DNA adducts in calf thymus DNA in the presence of rat liver S9. In cultured rat hepatocytes, all produced DNA adducts but none induced DNA strand breaks.