Lost in translation: The search for an in vitro screen for spermatogenic toxicity.

The last two decades have seen an increasing search for in vitro models that can replace the use of animals for safety testing. We adapted the methods from a recent nonquantitative report of spermatogenesis occurring in ex vivo mouse testis explants and tried to develop them into a screening assay. The model consisted of small pieces of neonatal mouse testis (testis "chunks"), explanted and placed on pillars of agarose or chamber inserts, and cultured at the air-liquid interface. A peripheral torus-shaped zone in these explants would often contain tubules showing spermatogenesis, while the middle of each chunk was often necrotic, depending on the thickness of the tissue. The endpoint was histology: what proportion of tubules in the "permissive torus" actually contained healthy pachytene spermatocytes or spermatids? Extensive statistical modeling revealed that a useful predictive model required more than 60% of these tubules to show spermatogenesis. Separately, the logistics of running this as a predictive assay require that the controls consistently produce ≥ 60% tubules with pachytenes and round spermatids, and achieving this level of spermatogenesis reliably and consistently every week proved ultimately not possible. Extensive trials with various media additions and amendments proved incapable of maintaining the frequency of spermatogenic tubules at consistently ≥ 60%. Congruent with Schooler's "decline effect"; generally, the more often we ran these cultures, the worse the performance became. We hope that future efforts in this area may use our experience as a starting point on the way to a fully productive in vitro model of spermatogenesis.

Fishing for teratogens: a consortium effort for a harmonized zebrafish developmental toxicology assay.

A consortium of biopharmaceutical companies previously developed an optimized Zebrafish developmental toxicity assay (ZEDTA) where chorionated embryos were exposed to non-proprietary test compounds from 5 to 6 h post fertilization and assessed for morphological integrity at 5 days post fertilization. With the original 20 test compounds, this achieved an overall predictive value for teratogenicity of 88% of mammalian in vivo outcome [Gustafson, A. L., Stedman, D. B., Ball, J., Hillegass, J. M., Flood, A., Zhang, C. X., Panzica-Kelly, J., Cao, J., Coburn, A., Enright, B. P., et al. (2012). Interlaboratory assessment of a harmonized Zebrafish developmental toxicology assay-Progress report on phase I. Reprod. Toxicol. 33, 155-164]. In the second phase of this project, 38 proprietary pharmaceutical compounds from four consortium members were evaluated in two laboratories using the optimized method using either pond-derived or cultivated-strain wild-type Zebrafish embryos at concentrations up to 100µM. Embryo uptake of all compounds was assessed using liquid chromatography-tandem mass spectrometry. Twenty eight of 38 compounds had a confirmed embryo uptake of >5%, and with these compounds the ZEDTA achieved an overall predictive value of 82% and 65% at the two respective laboratories. When low-uptake compounds (≤ 5%) were retested with logarithmic concentrations up to 1000µM, the overall predictivity across all 38 compounds was 79% and 62% respectively, with the first laboratory achieving 74% sensitivity (teratogen detection) and 82% specificity (non-teratogen detection) and the second laboratory achieving 63% sensitivity (teratogen detection) and 62% specificity (non-teratogen detection). Subsequent data analyses showed that technical differences rather than strain differences were the primary contributor to interlaboratory differences in predictivity. Based on these results, the ZEDTA harmonized methodology is currently being used for compound assessment at lead optimization stage of development by 4/5 of the consortium companies.

Reproductive toxicity assessment of sunitinib, a multitargeted receptor tyrosine kinase inhibitor, in male and female rats.

BACKGROUND: Sunitinib (SUTENT, Pfizer Inc., New York, NY) is a multitargeted inhibitor of selected receptor tyrosine kinases, which produces an antiproliferative and antiangiogenic effect by blocking pathways fundamental to tumor growth and survival. We investigated the effects of sunitinib on male and female fertility and early embryonic development in the rat. METHODS: In the female fertility and early embryonic development phase, untreated males were paired with treated females dosed at 0 (control), 0.5, 1.5, and 5 mg/kg/day from 14 days premating, through mating, to gestation day 7. In the male fertility phase, the same males were then treated 58 days at doses of 0 (control), 1, 3, and 10 mg/kg/day, mated with untreated females, with continued daily dosing for a total of 74 days. RESULTS: There was no systemic toxicity- or treatment-related effects on fertility in female rats. Females exposed at 5 mg/kg/day had an increase in the number of early resorptions with associated decrease in viable embryos. In the males, body weight and food consumption were decreased at 10 mg/kg/day compared to the controls. Male reproductive capacity, as assessed by copulation, fertility, and conception indices, was not impacted at any dose level. Sperm morphology, concentration, and motility were also unaffected by treatment. CONCLUSIONS: There were no effects on male reproduction. An increase in corpora lutea and an increase in early resorptions with associated reduction in viable embryos was noted in the females dosed 5 mg/kg/day. Sunitinib at doses up to 1.5 and 10 mg/kg/day had no effects on female and male reproduction, respectively.