Project description:Fine-tuning of transcriptional responses can be critical for long-term outcomes in response to an environmental challenge. The circadian protein Nocturnin belongs to a family of proteins that include exonucleases, endonucleases, and phosphatases and is most closely related to the CCR4 family of deadenylases that regulate the cellular transcriptome via control of poly(A) tail length of RNA transcripts. In this study, we investigate the role of Nocturnin in regulating the transcriptional response and downstream metabolic adaptations during cold exposure in brown adipose tissue. We find that Nocturnin exhibits dual localization within the cytosol and mitochondria, and loss of Nocturnin causes changes in expression of networks of mRNAs involved in mitochondrial function. Furthermore, Nocturnin-/- animals display significantly elevated levels of tricarboxylic acid cycle intermediates, indicating that they have distinct metabolic adaptations during a prolonged cold exposure. We conclude that cold-induced stimulation of Nocturnin levels can regulate long-term metabolic adaptations to environmental challenges.

Project description:Digested dietary fats are taken up, processed and transported by enterocytes to supply the body with lipids. Most absorbed lipids are assembled into pre-chylomicrons in the endoplasmic reticulum (ER) of enterocytes, which are then transported to the Golgi for maturation and subsequent secretion to the circulation. The role of mitochondria in regulating intestinal lipid transport remains unknown. Here we show that mitochondrial dysfunction in enterocytes inhibits chylomicron production and the transport of dietary lipids to peripheral organs. Mice with intestinal epithelial cell (IEC)-specific ablation of the mitochondrial-specific aspartyl - tRNA synthetase DARS2, as well as of the respiratory chain subunit SDHA or the assembly factor COX10 failed to thrive and showed massive accumulation of lipids within large lipid droplets (LDs) in enterocytes of the proximal small intestine (SI). Feeding a fat-free diet inhibited the formation of LDs in DARS2-deficient enterocytes, showing that accumulating lipids derive mostly from digested fat. Furthermore, metabolic tracing studies revealed impaired transport of dietary lipids to peripheral organs in mice lacking DARS2 in IECs. Moreover, DARS2-deficient enterocytes showed a distinct lack of mature chylomicrons concomitant with a disorganisation of the Golgi apparatus, suggesting that impaired ER to Golgi trafficking underlies impaired chylomicron production and secretion. Taken together, these results revealed a vital role of mitochondria in regulating dietary lipid transport in enterocytes, which is relevant for understanding the intestinal and nutritional defects observed in patients with mitochondrial defects.

Project description:Bl6 mice were fed with New Western diet 1 (NWD1) or Americal Instititue of Nutrition 76A (AIN76A or AIN) diet from weaning for 3 months. Single intestinal epithelial cells were FACS isolated by the Epcam+, CD45- , and subject to scACTAseq assay.

Project description:We determined the actively translated mRNA induced/repressed by a Dietary Restriction intervention specifically in the differentiated enterocytes of the intestine. For this, we did a "genetic dissection" by expressing a tagged ribosomal subunit (RpL13A-His6FLAG) under the control of the tissue specific Myo1A-GAL4 driver, targetting its expression exclusively to the intestinal enterocytes. By performing a anti-flag pulldown we are then able to enrich our mRNA pool for transcripts that are directly bound to ribosomes and being actively translated. In this manner, we become one step closer to protein synthesis while profiling gene expression.

Project description:Female mammals produce milk to feed their newborn offspring before teeth develop and permit the consumption of solid food. Intestinal enterocytes dramatically alter their biochemical signature during the suckling-to-weaning transition. The transcriptional repressor Blimp1 is strongly expressed in immature enterocytes in utero, but these are gradually replaced by Blimp1(-) crypt-derived adult enterocytes. Here we used a conditional inactivation strategy to eliminate Blimp1 function in the developing intestinal epithelium. There was no noticeable effect on gross morphology or formation of mature cell types before birth. However, survival of mutant neonates was severely compromised. Transcriptional profiling experiments reveal global changes in gene expression patterns. Key components of the adult enterocyte biochemical signature were substantially and prematurely activated. In contrast, those required for processing maternal milk were markedly reduced. Thus, we conclude Blimp1 governs the developmental switch responsible for postnatal intestinal maturation.

Project description:Nuclear receptors (NRs) control cell fate and regulate tissue function. Some of the NRs are expressed in a circadian and tissue-specific manner. Clock genes are part of the circadian network and fine-tune gene expression in adipose and skeletal tissues. Pparg, a master transcription factor that determines adipogenesis, exhibits a circadian expression pattern in white adipose tissue and liver. Here we report the finding that the message and protein for a peripheral clock gene, nocturnin, is markedly upregulated with Pparg activation in adipocytes and bone marrow stromal cells. Nocturnin is also expressed in relatively high amounts in other tissues that may have physiologic relevance for bone, including the brain and hypothalamus. Of importance, we found polymorphic strain differences in bone marrow nocturnin expression that relate to phenotypic determinants of skeletal acquisition. Defining the function of nocturnin in peripheral tissues should provide new insights into lineage allocation and the intimate relationship between nuclear receptors and physiologic timekeeping.

Project description:Fine-tuning of transcriptional responses can be critical for long-term outcomes in response to an environmental challenge. The circadian protein Nocturnin belongs to a family of proteins that include exonucleases, endonucleases and phosphatases and is most closely related to the CCR4 family of deadenylases that regulate the cellular transcriptome via control of polyA tail length of RNA transcripts. In this study, we investigate the role of Nocturnin in regulating the transcriptional response and downstream metabolic adaptations during cold exposure in brown adipose tissue. We find that Nocturnin exhibits dual localization within the cytosol and mitochondria, and loss of Nocturnin causes changes in expression of networks of mRNAs involved in mitochondrial function. Furthermore, Nocturnin-/- animals display significantly elevated levels of TCA cycle intermediates indicating that they have distinct metabolic adaptations during a prolonged cold exposure. We conclude that cold-induced stimulation of Nocturnin levels can regulate long-term metabolic adaptations to environmental challenges.

Project description:Here we show that the Drosophila nuclear receptor E78A regulates transcription in adult animals facilitating dietary lipid uptake. E78A mutant adults are viable with normal developmental timing, locomotor activity, female fecundity, but have significantly reduced stored triglycerides. This reduction in whole body triglyceride stores appears to originate from the midgut, using neutral lipid stainings we determined lipid levels in the midgut were greatly reduced. Upon examining our RNA-seq analysis we found that a gastric lipase, CG17192, is transcriptionally coordinated by E78A. CG17192 is expressed in an adult, intestinal specific fashion within control flies, and has a human ortholog. Through dietary supplementation and genetic testing we determined that the whole body hypolipidemia seen within E78A mutants is dependent on CG17192 expression within the intestine. Restoration of this lipase in the intestine of mutant flies is sufficient to restore normal lipid levels. Our data support the model that E78A contributes to a transcriptional regulation of the gastric lipase, CG17192, thus directing dietary triglyceride uptake in the adult fly.

Project description:Dietary induced epigenetic reprogram in mouse intestinal enterocytes

Project description:Drosophila melanogaster curled, one of the first fly mutants described by T. H. Morgan >90 years ago, is the founding member of a series of curled wing phenotype mutants widely used as markers in fruit fly genetics. The expressivity of the wing phenotype is environmentally modulated, suggesting that the mutation affects the metabolic status of cells rather than a developmental control gene. However, the molecular identity of any of the curled wing marker mutant genes is still unknown. In a screen for starvation-responsive genes, we previously identified the single fly homolog of the vertebrate nocturnin genes, which encode cytoplasmic deadenylases that act in the post-transcriptional control of genes by poly(A) tail removal of target mRNAs prior to their degradation. Here we show that curled encodes Drosophila Nocturnin and that the gene is required at pupal stage for proper wing morphogenesis after eclosion of the fly. Despite the complex ontogenetic expression pattern of the gene, curled is not expressed in the developing wing, and wing-specific curled knockdown mediated by RNAi does not result in the curled wing phenotype, indicating a tissue-nonautonomous, systemic mode of curled gene function. Our study not only presents an entry point into the functional analysis of invertebrate nocturnins but also paves the way for the identification of the still elusive Nocturnin target mRNAs by genetic suppressor screens on the curled wing phenotype.