What is known: Liver-to-body mass-ratio is held constant by a phenomenon named the ?hepatostat? [1]. When liver is damaged, an ensuing state of systemic hepatic insufficiency induces regenerative proliferation. A regulatory axis has been uncovered that is dependent on levels of circulating bile acids (BA), which are both synthesized and recycled by hepatocytes. BAs reclaimed from the gut enter the circulation and activate the farnesyl-X-receptor (FXR) in enterocytes (mice) or other cells (human). This induces secretion of FGF15/19 into the enterohepatic circulation [2-4]. At the liver, FGFR-signaling in hepatocytes feedback-regulates BA production by repressing CYP7A1 expression [5] and modulates bioenergetic pathways [6]. In a less-well understood process, BAs and FGF15/19 also coordinately regulate pro- and anti-regeneration activities in the liver. The balance of these activities determines whether the hepatocytes proliferate [7-9]. New insights: It is becoming increasingly recognized that redox signaling participates in many physiological functions. We recently reported that livers of mice in which hepatocytes lack both thioredoxin reductase-1 and glutathione reductase (TR/GR-null) - the entry points to the two major cytosolic antioxidant systems - are 2.1- fold larger than normal [10], suggesting these mice have a mis-calibrated hepatostat. These mice also have elevated BA levels. Surprisingly however, neither cholesterol-free diets nor inhibition of cholesterol synthesis to limit BA precursors, nor treatment with cholestyramine to increase fecal BA excretion, normalize circulating BAs. This suggests that, along with having a defective hepatostat in which pro-regeneration activities predominate, systemic feedback regulation of BA synthesis is disrupted in mice with TR/GR-null livers. What is proposed: Because the TR/GR-null condition is restricted to hepatocytes, we predict that FXR- induced production of FGF15 in enterocytes is normal. We hypothesize that hepatostat- and BA feedback- signals are redox-regulated and therefore disrupted in TR/GR-null hepatocytes. To test this hypothesis, we propose two specific aims:
Aim 1, to assess enterocytic FGF15 production and hepatocytic activity of FGF15- induced signaling cascades in WT or TR/GR-null livers.
Aim 2, to assess protein-Cys modifications on components of the FGFR4-dependent pathways in these livers and determine which of these affect signaling and gene expression outcomes that regulate the hepatostat. Anticipated outcomes and value: BAs function in lipid digestion, toxin-excretion, and the hepatostat. In turn, lipid catabolism, toxin exposure, and regeneration are each associated with increased oxidative stress. In this Exploratory Project, we hypothesize that there are previously unrecognized redox-regulated components on the BA/hepatostat axis that ensure appropriate coordination of these activities with the cellular redox status. Modulation of this could be helpful in therapies addressing liver injuries or toxic exposures.

Public Health Relevance

Unlike most organs, mammalian liver is capable of full regeneration following loss of even the majority of its mass. Recent studies reveal components of the mechanism by which the liver `senses' its own size and, in response, coordinates regenerative growth to ensure a very precise liver:body mass-ratio. Our mouse models reveal a critical role for redox signaling in regulating liver size, which is investigated mechanistically here.

Agency
National Institute of Health (NIH)
Institute
National Institute on Aging (NIA)
Type
Exploratory/Developmental Grants (R21)
Project #
5R21AG055022-02
Application #
9357491
Study Section
Hepatobiliary Pathophysiology Study Section (HBPP)
Program Officer
Macchiarini, Francesca
Project Start
2016-09-30
Project End
2018-04-30
Budget Start
2017-05-15
Budget End
2018-04-30
Support Year
2
Fiscal Year
2017
Total Cost
$145,800
Indirect Cost
$29,700
Name
Montana State University - Bozeman
Department
Microbiology/Immun/Virology
Type
Schools of Earth Sciences/Natur
DUNS #
625447982
City
Bozeman
State
MT
Country
United States
Zip Code
59717
Dagnell, Markus; Schmidt, Edward E; Arnér, Elias S J (2018) The A to Z of modulated cell patterning by mammalian thioredoxin reductases. Free Radic Biol Med 115:484-496
Petersen, Dennis R; Saba, Laura M; Sayin, Volkan I et al. (2018) Elevated Nrf-2 responses are insufficient to mitigate protein carbonylation in hepatospecific PTEN deletion mice. PLoS One 13:e0198139
Miller, Colin G; Holmgren, Arne; Arnér, Elias S J et al. (2018) NADPH-dependent and -independent disulfide reductase systems. Free Radic Biol Med 127:248-261
Poet, Greg J; Oka, Ojore Bv; van Lith, Marcel et al. (2017) Cytosolic thioredoxin reductase 1 is required for correct disulfide formation in the ER. EMBO J 36:693-702
Johansson, Katarina; Cebula, Marcus; Rengby, Olle et al. (2017) Cross Talk in HEK293 Cells Between Nrf2, HIF, and NF-?B Activities upon Challenges with Redox Therapeutics Characterized with Single-Cell Resolution. Antioxid Redox Signal 26:229-246
Cortese-Krott, Miriam M; Koning, Anne; Kuhnle, Gunter G C et al. (2017) The Reactive Species Interactome: Evolutionary Emergence, Biological Significance, and Opportunities for Redox Metabolomics and Personalized Medicine. Antioxid Redox Signal 27:684-712
Akaike, Takaaki; Ida, Tomoaki; Wei, Fan-Yan et al. (2017) Cysteinyl-tRNA synthetase governs cysteine polysulfidation and mitochondrial bioenergetics. Nat Commun 8:1177
Cheng, Qing; Arnér, Elias S J (2017) Selenocysteine Insertion at a Predefined UAG Codon in a Release Factor 1 (RF1)-depleted Escherichia coli Host Strain Bypasses Species Barriers in Recombinant Selenoprotein Translation. J Biol Chem 292:5476-5487
Prigge, Justin R; Coppo, Lucia; Martin, Sebastin S et al. (2017) Hepatocyte Hyperproliferation upon Liver-Specific Co-disruption of Thioredoxin-1, Thioredoxin Reductase-1, and Glutathione Reductase. Cell Rep 19:2771-2781
Lan, Aixian; Li, Wenjun; Liu, Yao et al. (2016) Chemoprevention of oxidative stress-associated oral carcinogenesis by sulforaphane depends on NRF2 and the isothiocyanate moiety. Oncotarget 7:53502-53514

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