Heart and Liver Defects and Reduced Transforming Growth Factor β2 Sensitivity in Transforming Growth Factor β Type III Receptor-Deficient Embryos

The type III transforming growth factor β (TGFβ) receptor (TβRIII) binds both TGFβ and inhibin with high affinity and modulates the association of these ligands with their signaling receptors. However, the significance of TβRIII signaling in vivo is not known. In this study, we have sought to determine the role of TβRIII during development. We identified the predominant expression sites of ΤβRIII mRNA as liver and heart during midgestation and have disrupted the murine TβRIII gene by homologous recombination. Beginning at embryonic day 13.5, mice with mutations in ΤβRIII developed lethal proliferative defects in heart and apoptosis in liver, indicating that TβRIII is required during murine somatic development. To assess the effects of the absence of TβRIII on the function of its ligands, primary fibroblasts were generated from TβRIII-null and wild-type embryos. Our results indicate that TβRIII deficiency differentially affects the activities of TGFβ ligands. Notably, TβRIII-null cells exhibited significantly reduced sensitivity to TGFβ2 in terms of growth inhibition, reporter gene activation, and Smad2 nuclear localization, effects not observed with other ligands. These data indicate that TβRIII is an important modulator of TGFβ2 function in embryonic fibroblasts and that reduced sensitivity to TGFβ2 may underlie aspects of the TβRIII mutant phenotype

Regional proton nuclear magnetic resonance spectroscopy differentiates cortex and medulla in the isolated perfused rat kidney

Volume-localized proton nuclear magnetic resonance spectroscopy was used as an assay of regional biochemistry in the isolated perfused rat kidney. This model eliminated artifacts caused by respiratory and cardiac motion experienced in vivo. Immersion of the kidney under its venous effluent reduced the susceptibility artifacts evoked by tissue-air interfaces. The rapid acquisition with relaxation enhancement imaging sequence was used for scout imaging. This gave excellent spatial resolution of the cortex, outer medulla, and inner medulla. Spectra were then acquired in 10 minutes using the volume-selective multipulse spectroscopy sequence from voxels with a volume of approximately 24 mu L located within the cortical or medullary regions. Spectral peaks were assigned by the addition of known compounds to the perfusion medium and by comparison with spectra of protein-free extracts of cortex and medulla. The medullary region spectra were characterized by signals from the osmolytes betaine, glycerophosphorylcholine, and inositol. The spectra from the cortex were more complex and contained lesser contributions from osmolytes