A dysmorphology score system for assessing embryo abnormalities in rat whole embryo culture.

BACKGROUND: The rodent whole embryo culture (WEC) system is a well-established model for characterizing developmental toxicity of test compounds and conducting mechanistic studies. Laboratories have taken various approaches in describing type and severity of developmental findings of organogenesis-stage rodent embryos, but the Brown and Fabro morphological score system is commonly used as a quantitative approach. The associated score criteria is based upon developmental stage and growth parameters, where a series of embryonic structures are assessed and assigned respective scores relative to their gestational stage, with a Total Morphological Score (TMS) assigned to the embryo. This score system is beneficial because it assesses a series of stage-specific anatomical landmarks, facilitating harmonized evaluation across laboratories. Although the TMS provides a quantitative approach to assess growth and determine developmental delay, it is limited to its ability to identify and/or delineate subtle or structure-specific abnormalities. Because of this, the TMS may not be sufficiently sensitive for identifying compounds that induce structure or organ-selective effects. METHOD: This study describes a distinct morphological score system called the "Dysmorphology Score System (DMS system)" that has been developed for assessing gestation day 11 (approximately 20-26 somite stage) rat embryos using numerical scores to differentiate normal from abnormal morphology and define the respective severity of dysmorphology of specific embryonic structures and organ systems. This method can also be used in scoring mouse embryos of the equivalent developmental stage. RESULT AND CONCLUSION: The DMS system enhances capabilities to rank-order compounds based upon teratogenic potency, conduct structure- relationships of chemicals, and develop statistical prediction models to support abbreviated developmental toxicity screens.

Embryo transfer experiments and ovarian transplantation identify the ovary as the only site in which nuclear receptor interacting protein 1/RIP140 action is crucial for female fertility.

Spatial and temporal regulation of gene expression by a number of different nuclear receptors is critical in female reproduction. In this study we investigated whether the nuclear receptor corepressor nuclear receptor interacting protein 1 (Nrip1)/RIP140, which is essential for ovulation, is also required for postovulatory events, leading to pregnancy and parturition. Expression analysis indicated that Nrip1 is present in the uterus in stromal and glandular epithelial cells, primary decidual cells, and subsequently in differentiating decidual cells at the anti-mesometrial side of the implantation site. It also indicated a temporal regulation of Nrip1 in the corpora lutea at different stages of pregnancy, with increased levels at midgestation at approximately d 9.5 postcoitum (pc). By performing both embryo and ovarian transfer experiments we demonstrate that, provided the block to ovulation is by-passed, Nrip1(-/-) mice are capable of establishing and maintaining pregnancies. However, although the majority of offspring derived from ovarian transplantation survived, approximately 50% of embryos were resorbed by d 13.5 pc after embryo transfer, and the majority of pups were stillborn or died soon thereafter. Thus, although Nrip1 is differentially expressed in the reproductive tract, we conclude that the ovary is the only site in which its action is essential for fertility, with a crucial role in ovulation and a secondary role in the maintenance of pregnancy.