11 |
Molecular Regulation of Maternal Hepatic Adaptations to PregnancyJoonyong Lee (8786537) 01 May 2020 (has links)
The maternal liver exhibits robust adaptations to pregnancy to accommodate the metabolic needs of developing and growing placenta and fetus by largely unknown mechanisms. We found that achaete-scute homolog 1 (Ascl1), a basic helix-loop-helix transcription factor essential for neuronal development, is highly activated in maternal hepatocytes during the second half of gestation in mice. Our aim is to investigate whether and how Ascl1 plays a pregnancy-dependent role. We deleted the Ascl1 gene in the maternal liver using three independent mouse models from mid-gestation until term and identified multiple Ascl1-dependent phenotypes. When Ascl1 was deficient in maternal hepatocytes, maternal livers exhibited aberrant hepatocyte histology, fat accumulation, increased hepatocyte cell cycle, and enlarged size, accompanied by reduced albumin production and elevated levels of free fatty acids, ALT, and AST in the maternal blood, indicating maternal liver dysfunction. In the same situation, maternal spleen and pancreas displayed marked enlargement without an overt structural change; the placenta exhibited striking overgrowth with increased ALP production; and the cecal microbiome showed alterations in the relative abundance of several bacterial subpopulations. Moreover, litters born from maternal hepatic Ascl1 null mutated dam experienced abnormal postnatal growth after weaning. RNA-seq analysis revealed Ascl1-regulated genes in the maternal liver associated with Ascl1-dependent phenotypes. Of particular interest, we found that, in maternal hepatocytes, Ascl1 loss-of-function caused the activation of paternally imprinted gene insulin-like growth factor 2 (Igf2) encoding a major placental and fetal growth factor. IGF2 is also a known mitogen for hepatocytes and several hematopoietic lineages. Thus, IGF2 is a potential inducer of Ascl1-dependent phenotypes including placental overgrowth and maternal organ enlargement. Our studies revealed Ascl1 as a novel regulator of maternal liver physiology during pregnancy. Ascl1 activation in maternal hepatocytes is essential for normal placental growth and appropriate maternal organ adaptations, ensuring the health of both the mother and the fetus.<br>
|
12 |
The Regulation of Adult Neurogenesis by Rb Family ProteinsFong, Bensun Cambell 02 May 2022 (has links)
A complex regulatory framework underlies the generation of newborn neurons in the adult mammalian brain, including the lifelong maintenance of neural stem cell (NSC) quiescence and instructing NSC entry to and exit from quiescence. Future therapies targeting endogenous repair of the aging or afflicted brain, including neurodegenerative pathologies, rely on present efforts to define and characterize the mechanisms underlying the regulation of adult NSC fate. In this dissertation, we demonstrate a requirement for the Rb/E2F axis in the regulation of the molecular program instructing adult NSC quiescence and activation, with a potential role in the impaired hippocampal function observed in Alzheimer's disease pathology. While Rb plays a role in the production and survival of hippocampal newborn neurons, we identify a collective requirement for Rb family proteins — pRb, p107 and p130 — as well as their targets, E2F family transcriptional activators E2F1 and E2F3, in the regulation of NSC quiescence and activation. We further demonstrate that this is mediated through pivotal factors REST and ASCL1, identified as direct molecular targets of the Rb/E2F axis, and that REST inactivation can partially rescue NSC depletion following Rb family loss. We finally demonstrate impaired NSC activation and a return to quiescence in the 3xTG-AD model of Alzheimer's disease, with altered expression of Rb/E2F genes observed within cell population-specific defects. Ultimately, this work addresses the key issue of how transcriptional signatures of quiescence and activation among adult NSCs are co- ordinated with cell cycle control, and demonstrates that Rb family proteins serve as master regulators of the molecular program instructing adult NSC exit from and re-entry into quiescence.
|
13 |
Identification and characterization of Ascl1-expressing cells in maternal liver during pregnancyKumar, Sudhanshu 01 August 2014 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / During pregnancy, maternal liver exhibits robust growth to meet the metabolic demands of the developing placenta and fetus. Although hepatocyte hypertrophy and hyperplasia are seen in the maternal liver, the molecular and cellular mechanisms mediating the maternal hepatic adaptations to pregnancy is poorly understood. Previous microarray analysis revealed a most upregulated gene named Ascl1, a transcription factor essential for neural development, in the maternal liver at mid-gestation. The aims of the study were to (1) validate the activation of Ascl1 gene; (2) identify Ascl1-expressing cells; and (3) determine the fate of Ascl1-expressing cells, in the maternal liver during the course of gestation. Timed pregnancy was setup in mice and the maternal livers were collected at various stages of gestation. Maternal hepatic Ascl1 mRNA expression was evaluated by qRT-PCR and northern blotting. The results demonstrated that the transcript level of maternal hepatic Ascl1 is exponentially increased during the second half of pregnancy in comparison with a non-pregnant state. Using a Ascl1-GFP mouse model generated by others to monitor the behavior of neural progenitor cells, we found that maternal hepatic Ascl1-expressing cells are non-parenchymal cells, very small in size, and expanding during pregnancy. To map the fate of this cell population, we generated an in vivo tracing mouse model named Ascl1-CreERT2/ROSA26-LacZ. Using this model, we permanently labeled maternal hepatic Ascl1-expressing cells at midgestation by giving tamoxifen and analyzed the labeled cells in the maternal liver prior to parturition. We observed that the initial small Ascl1-expressing cells undergoing expansion at mid-gestation eventually became hepatocyte-like cells at the end stage of pregnancy. Taken together, our findings strongly suggest that Ascl1-expressing cells represent a novel population of hepatic progenitor cells and they can differentiate along hepatocyte lineage and contribute to pregnancy-induced maternal liver growth. Further studies are needed to firmly establish the nature and property of maternal hepatic Ascl1-expressing cells. At this stage, we have gained significant insights into the cellular mechanism by which the maternal liver adapts to pregnancy.
|
Page generated in 0.0187 seconds