Major mouse placental compartments revealed by diffusion-weighted MRI, contrast-enhanced MRI, and fluorescence imaging.

Mammalian models, and mouse studies in particular, play a central role in our understanding of placental development. Magnetic resonance imaging (MRI) could be a valuable tool to further these studies, providing both structural and functional information. As fluid dynamics throughout the placenta are driven by a variety of flow and diffusion processes, diffusion-weighted MRI could enhance our understanding of the exchange properties of maternal and fetal blood pools--and thereby of placental function. These studies, however, have so far been hindered by the small sizes, the unavoidable motions, and the challenging air/water/fat heterogeneities, associated with mouse placental environments. The present study demonstrates that emerging methods based on the spatiotemporal encoding (SPEN) of the MRI information can robustly overcome these obstacles. Using SPEN MRI in combination with albumin-based contrast agents, we analyzed the diffusion behavior of developing placentas in a cohort of mice. These studies successfully discriminated the maternal from the fetal blood flows; the two orders of magnitude differences measured in these fluids' apparent diffusion coefficients suggest a nearly free diffusion behavior for the former and a strong flow-based component for the latter. An intermediate behavior was observed by these methods for a third compartment that, based on maternal albumin endocytosis, was associated with trophoblastic cells in the interphase labyrinth. Structural features associated with these dynamic measurements were consistent with independent intravital and ex vivo fluorescence microscopy studies and are discussed within the context of the anatomy of developing mouse placentas.

A moderate reduction of Bcl-x(L) expression protects against tumorigenesis; however, it also increases susceptibility to tissue injury.

Little consideration has been given to the possibility that there could be variations in protein expression that alter susceptibility to tumorigenesis without causing other obvious phenotypic effects. Therefore, we sought to determine if haploinsufficiency for the anti-apoptotic protein Bcl-x(L) would affect tumorigenesis. We chose to study Bcl-x(L) because although bcl-x+/- mice were thought to be phenotypically normal, we and others found that haploinsufficiency for Bcl-x(L) lowers fibroblast resistance to apoptosis in tissue culture. Since resistance to certain forms of apoptosis is required for tumor formation, this suggested that decreased Bcl-x(L) expression would afford protection against tumorigenesis. Indeed, we demonstrate here that bcl-x+/- mice are strikingly resistant to carcinogen-induced tumorigenesis. However, we found that they pay a price for their resistance in that they are more susceptible to clinically relevant forms of tissue injury--they suffer increased hepatic injury in a model of binge alcohol abuse and in response to TNF-alpha treatment. These findings are important because they suggest that even minor variations in Bcl-x(L) expression could affect susceptibility to cancer and other diseases. Additionally, they indicate that the potential for increased susceptibility to tissue injury must be considered in the design of chemopreventative and antineoplastic strategies that involve inhibition of Bcl-x(L) activity.