Developmental regulation of insulin-like growth factor II mRNA in different rat tissues

Insulin-like growth factor II (IGF-II) is present at high levels in fetal and early neonatal rat plasma, and decreases profoundly following birth. In the present study, the levels of IGF-II RNA in different rat tissues at different ages were determined by hybridization to a rat IGF-II cDNA probe. IGF-II RNA was present in 11 of 13 fetal or neonatal tissues examined: at higher levels in muscle, skin, lung, liver, intestine, and thymus; at lower levels in brain stem, heart, cerebral cortex, kidney, and hypothalamus; and undetectable in spleen and pancreas (although the latter RNA was partially degraded). In each tissue, Northern blot hybridization revealed the presence of six IGF-II RNAs: 6, 4, 3.8, 2.2, 1.7, and 1.2 kilobase pairs, consistent with results previously observed in the BRL-3A rat liver cell line and attributed to alternative RNA processing. Although differences in the relative abundance of these RNAs were observed in different tissues, the same size species occurred in all tissues with the 4-kilobase pair RNA the most abundant species. RNAs from the different tissues were examined at six developmental ages (days 16 and 21 of gestation; days 2, 11, 22, and 75 after birth) by hybridization to slot blots and Northern blots. In lung, thymus, kidney, and brain stem, IGF-II RNA was expressed at higher levels in the fetus than after birth, whereas in muscle, skin, liver, heart, and intestine, the high fetal levels of IGF-II RNA continued through day 11 or day 22 after birth. IGF-II RNA persisted into adulthood in cerebral cortex and hypothalamus. Although the significance of these tissue-specific differences in the developmental regulation of the expression of IGF-II RNA remains to be established, they exhibit intriguing temporal correlations with major maturational events in some tissues such as lung and muscle.     

Developmental regulation of the intrathymic T cell precursor population

The maturation potential of CD4-8- thymocytes purified from mice of different developmental ages was examined in vivo after intrathymic injection. As previously reported, 14-day fetal CD4-8- thymocytes produced fewer CD4+ than CD8+ progeny in peripheral lymphoid tissues, resulting in a CD4+:CD8+ ratio of less than or equal to 1.0. In contrast, adult CD4-8- thymocytes generated CD4+ or CD8+ peripheral progeny in the proportions found in the normal adult animal (CD4+:CD8+ = 2 to 3). Here we have shown that CD4-8- precursor cells from the 17-day fetal thymus also produced peripheral lymphocytes with low CD4+:CD8+ ratios. Precursors from full term fetuses produced slightly higher CD4+:CD8+ ratios (1.1-1.6) and precursors from animals three to 4 days post-birth achieved CD4+:CD8+ ratios intermediate between those produced by fetal and adult CD4-8- thymocytes. Parallel changes in the production of alpha beta TCR+ peripheral progeny were observed. Fetal CD4-8- thymocytes generated fewer alpha beta TCR+ progeny than did adult CD4-8- thymocytes. However, peripheral lymphocytes arising from either fetal or adult thymic precursors showed similar proportions of gamma delta TCR+ cells. The same pattern of progeny was observed when fetal CD4-8- thymocytes matured in an adult or in a fetal thymic stromal environment. In contrast to fetal thymic precursors, fetal liver T cell precursors resembled adult CD4-8- thymocytes by all parameters measured. These results suggest that fetal thymic precursors are intrinsically different from both adult CD4-8- thymocytes and fetal liver T cell precursors. Moreover, they lead to the hypothesis that the composition of the peripheral T cell compartment is developmentally regulated by the types of precursors found in the thymus. A model is proposed in which migration of adult-like precursors from the fetal liver to the thymus approximately at birth triggers a transition from the fetal to the adult stages of intrathymic T cell differentiation.     

Tissue-specific variation in C4 and Slp gene regulation.

C4 and Slp are highly homologous mouse genes that differ in function and regulation. Allelic variants exist in quantitative regulation of C4 and in hormonal regulation of Slp. We have examined expression in several tissues, including liver and peritoneal macrophages which are the major sites of synthesis, using a probe that allows direct comparison of C4 and Slp mRNAs. Correctly-sized and initiated RNA, within an order of magnitude of liver levels, is found in mammary gland, lung, spleen, and kidney; lower levels are detectable in testis, brain, heart and submaxillary gland. By comparing expression in congenic mouse strains differing in C4 and Slp loci, regulation of these genes is seen to vary in different tissues. This provides a well-defined genetic system in which to examine cis-acting sequences and trans-acting factors that result in tissue-specific patterns of gene regulation.     

Biodistribution of Small Interfering RNA at the Organ and Cellular Levels after Lipid Nanoparticle-mediated Delivery

Chemically stabilized small interfering RNA (siRNA) can be delivered systemically by intravenous injection of lipid nanoparticles (LNPs) in rodents and primates. The biodistribution and kinetics of LNP–siRNA delivery in mice at organ and cellular resolution have been studied using immunofluorescence (IF) staining and quantitative polymerase chain reaction (qPCR). At 0.5 and 2 hr post tail vein injection of Cy5-labeled siRNA encapsulated in LNP, the organ rank-order of siRNA levels is liver > spleen > kidney, with only negligible accumulation in duodenum, lung, heart, and brain. Similar conclusions were drawn by using qPCR to measure tissue siRNA levels as a secondary end point. siRNA levels in these tissues decreased by more than 10-fold after 24 hr. Within the liver, LNPs delivered siRNA to hepatocytes, Kupffer cells, and sinusoids in a time-dependent manner, as revealed by IF staining and signal quantitation methods established using OPERA/Columbus software. siRNA first accumulated in liver sinusoids and trafficked to hepatocytes by 2 hr post dose, corresponding to the onset of target mRNA silencing. Fluorescence in situ hybridization methods were used to detect both strands of siRNA in fixed tissues. Collectively, the authors have implemented a platform to evaluate biodistribution of siRNA across cell types and across tissues in vivo, with the objective of elucidating the pharmacokinetic and pharmacodynamic relationship to guide optimization of delivery vehicles.     

Allocation of resources in an European cyprinid during maturation period as measured by nucleic acids

Changes in the nucleic acid levels of different tissues during a regular gonadal maturation were used to investigate the sex-related size differences in Iberian barbel, Barbus sclateri. Gonadal DNA concentration was associated with gonadal development in both sexes. There was a decline in DNA when ovaries were ripe. In contrast, the maximum size of the testes was related with highest gonadal DNA concentrations. Gonadal growth was not related with liver RNA : DNA ratios of male, while it was with female ratios. White muscle DNA concentrations indicate that somatic cell volume decreased during gonadal growth in both sexes. This suggests the translocation of several elements toward the gonad. Moreover, during gonadal maturation period adult barbel showed no change in their somatic growth. However, males apparently were in poorer metabolic condition (lower muscle RNA : DNA ratio) than females. Females may have allocated additional energy to self-maintenance rather than to breeding effort and it might influenced the cumulative annual growth. One might reasonably assume that there is a trade-off between investment in current versus future reproductive success in female. This result was not seen in males.     

The tissue-specific expression and developmental regulation of two nuclear genes encoding rat mitochondrial proteins. Medium chain acyl-CoA dehydrogenase and mitochondrial malate dehydrogenase

To study the regulation of nuclear genes which encode mitochondrial enzymes involved in oxidative metabolism, absolute levels of mRNA encoding rat medium chain acyl-CoA dehydrogenase (MCAD) and rat mitochondrial malate dehydrogenase (mMDH) were determined in developing and adult male rat tissues. MCAD mRNA is expressed in a variety of adult male tissues with highest steady state levels in heart, adrenal, and skeletal muscle and lowest levels in brain, lung, and testes. In comparison, steady state levels of mMDH mRNA in adult male rat tissues were similar to those of MCAD mRNA in heart, small intestine, adrenal, and skeletal muscle but markedly different in brain, stomach, and testes. Thus, the steady-state levels of MCAD and mMDH mRNA are highest in adult tissues with high energy requirements. Dot blot analysis of RNA prepared from late fetal, suckling, and weaning rat heart, liver, and brain demonstrated the presence of MCAD and mMDH mRNA during the fetal period in all three tissues. Both MCAD and mMDH mRNA levels increased 2-2.5-fold at birth followed by a decline during the first postnatal week in heart and liver. The patterns of accumulation of these mRNAs in heart and liver during the weaning and early adult periods were also similar, although the absolute levels were significantly different. Brain MCAD mRNA levels were consistently low (less than 0.1 pg/micrograms total cellular RNA) throughout the developmental stages. However, brain mMDH mRNA levels exhibited a marked increase during the weaning period, reaching a peak concentration which is higher than the level of mMDH mRNA in heart and liver at any point during development. These results indicate that the level of expression of the nuclear genes encoding MCAD and mMDH is tissue-specific and developmentally regulated. The patterns of MCAD and mMDH mRNA accumulation parallel the changes in energy metabolism which occur during development and among adult tissues.