Molecular Factors Influencing Feed Efficiency in Mature Beef Cows

Wood, Katharine

12 July 2013

Identifying molecular mechanisms regulating cellular energy utilization may lead to increased understanding of maintenance energy cost and improved feed efficiency in beef cows. Three experiments were conducted to characterize measures of residual feed intake (RFI) in pregnant beef cows; to examine the effects of moderate dietary restriction on visceral organ mass and proteins relating to energy metabolism; and to investigate the influence of pregnancy on visceral organ mass and proteins relating to energy metabolism. The first experiment combined data from five experiments using 321 pregnant Angus × Simmental cows. Including ultrasound fat measures and diet/management information increased the feed intake prediction model R2 by 7.3% and > 20%, respectively. Individual experiment RFI models varied greatly in accuracy. In the second experiment, 22 pregnant beef cows were fed at 85% (LOW; n=11) or 140% (HIGH; n=11) of net energy requirements during mid- to late-gestation. Tissue samples from liver, kidney, muscle, ruminal papillae, pancreas, and small intestinal muscosa were collected. Western blots were conducted to quantify abundance of: proliferating cell nuclear antigen, ATP synthase, ubiquitin, and Na/K+ ATPase for all tissues; peroxisome proliferator-activated receptor gamma, peroxisome proliferator-activated receptor gamma coactivator 1 alpha (PGC-1α), and 5’-adenosine monophosphate-activated protein kinase and phosphorylated-AMPK (pAMPK) for liver, muscle, and rumen; phosphoenolpyruvate carboxykinase for liver and kidney; and uncoupling protein 2 for liver. Cows fed HIGH had greater (P ≤ 0.04) ADG and final BW than cows fed LOW. Ubiquitin abundance in muscle was greater (P = 0.009) in cows fed LOW, and PCG-1α in liver was greater (P = 0.03) in cows fed HIGH. In the third experiment, 18 pregnant (PREG; n =9) or non-pregnant (OPEN; n=9) Angus × Simmental cows were fed for ad libitum intake during mid- to late-gestation. Tissues were weighed and collected and analyzed for protein abundance as described in the second experiment. Liver mass was lower (P ≤ 0.02), abundance of Na+/K+-ATPase was greater (P =0.04) and rumen pAMPK abundance was increased (P = 0.006) in PREG cows. These experiments indicate that measuring RFI in pregnant cows may pose some challenges, and nutrient restriction and pregnancy can influence molecular factors influencing feed efficiency. / Financial support was provided by Canadian Beef Cattle Industry Science Cluster, through funding provided by the Beef Cattle Research Council and Agriculture and Agri-Food Canada, Agriculture Adaptation Council-Farm Innovation Program, Ontario Ministry of Agriculture, Food and Rural Affairs, and the Ontario Cattleman’s Association.

beef cow

cellular energy metabolism

feed intake

feed efficiency

visceral organ mass

pregnancy

The transcriptional cofactor PCAF as mediator of the interplay between p53 and HIF-1 alpha and its role in the regulation of cellular energy metabolism

Rajendran, Ramkumar

January 2011

Energy production is a very important function for the cells to maintain homeostasis, survive and proliferate. Cellular energy can be produced either through oxidative phosphorylation (OXPHOS) in the presence of oxygen or glycolysis in its absence. Cancer cells, even in the presence of oxygen prefer to produce energy through glycolysis and this confers them a survival advantage. Energy metabolism has recently attracted the interest of several laboratories as targeting the pathways for energy production in cancer cells could be an efficient anticancer treatment. For that purpose the role of various transcription factors in determining the pathway of energy production has been investigated extensively and there is evidence to suggest that oncogenic transcription factors promote glycolysis whereas tumour suppressors demote it. In line with this notion, the master regulator of cellular response to hypoxia, the Hypoxia Inducible Factor 1 (HIF-1) has been shown to induce the expression of a variety of genes encoding enzymes involved in glucose metabolism as well as OXPHOS favouring energy production through glucose metabolism in hypoxic cells. The tumour suppressor p53 on the other hand inhibits glycolysis and stimulates OXPHOS. One of the pathways through which p53 exerts these effects, is by inducing the inhibitor of glycolysis TIGAR and the cytochrome c oxidase assembly factor SCO2 gene expression under DNA damage conditions. However, the regulation of the expression of these genes in hypoxic conditions has been only partially elucidated. We hypothesised that under hypoxic conditions, TIGAR and SCO2 gene expression might be differentially regulated in cells bearing mutated p53 and in these cells the involvement of HIF-1 could be crucial. Indeed under hypoxia mimicking conditions, the TIGAR and SCO2 protein and mRNA levels were found to be modulated differentially in p53 wild type and mutant cell lines. The bioinformatics analysis revealed the presence of hypoxia responsive elements (HREs) within the regulatory region of the promoters of TIGAR and SCO2 genes. Firefly reporter assays and chromatin immunoprecipitation (ChIP) assays have indicated that HIF-1 plays a crucial role in the regulation of TIGAR gene expression. The direct involvement of HIF-1 in the regulation of SCO2 gene expression requires further investigation. We and others have recently reported that PCAF is a common cofactor for p53 and HIF-1α, regulating the protein stability and transcription target selectivity of both transcription factors thereby orchestrating the balance between life and death in cancer cells. We hypothesised that PCAF plays a similar role in the regulation of cellular energy metabolism by differentially targeting HIF-1α and p53 to the promoter of TIGAR and SCO2 genes. In this study we present evidence to support the notion that PCAF plays an import role in the regulation of TIGAR and SCO2 gene expression under hypoxic mimicking conditions. This conclusion was supported by assessing the functional consequences of PCAFwt and PCAFΔHAT overexpression on the intracellular lactate production, cellular oxygen consumption, NAD+/NADH ratio and ROS generation in cells under hypoxia mimicking conditions.

571.6

Untersuchungen zu Wirkungen einer eingeschränkten Energiesynthese auf Funktionen von humanen Immunzellen

Tripmacher, Robert

17 May 2005

Hintergrund: Die Funktion von Immunzellen hängt von einer konstanten und ausreichenden Energieversorgung ab, die über die OXPHOS in den Mitochondrien und die Glykolyse im Zytosol realisiert wird. Die wichtigsten Substrate dafür sind Sauerstoff und Glukose. Fragestellung: Bei schweren Erkrankungen oder in Entzündungsgebieten ist die zelluläre Energieversorgung stark beeinträchtigt, weil in der Mikroumgebung der Zelle Sauerstoff und Nährstoffe inadäquat bereitgestellt werden. Ziel war herauszufinden, ob und wie humane Immunzellen ihre Lebensfähigkeit und funktionellen Aktivitäten unter solchen Umständen aufrechterhalten. Methoden: Humane CD4+ T-Zellen und CD14+ Monozyten wurden durch MACS aus peripherem Blut gesunder Spender isoliert. Die Sauerstoffverbrauchsmessung mittels Clark-Elektrode war Maß der oxidativen Energiebildung, die mit Myxothiazol und Glukoseentzug gehemmt wurde. Die CD3/CD28-stimulierte T-Zell-Proliferation wurde durchflußzytometrisch mittels CFDA SE analysiert. Basierend auf dem Paraformaldehyd-Saponin-Prozedere wurde die Zytokinsynthese ebenfalls am FACS bewertet, nachdem die T-Zellen in Anwesenheit von Brefeldin A mit PMA/Ionomycin stimuliert wurden. Mit einem käuflichen Testsystem (FACS-Technik) wurde die monozytäre Phagozytose untersucht. Die HIF-1alpha-Expression wurde nach PMA-Ionomycin-Stimulation von Myxothiazol-behandelten T-Zellen auf mRNA- und Proteinebene gemessen. Ergebnisse: Bei Glukoseanwesenheit waren alle untersuchten Immunfunktionen trotz vollständig gehemmter OXPHOS unbeeinträchtigt. Erst bei gleichzeitigem Glukoseentzug, der per sé Proliferation und Phagozytose signifikant beeinträchtigte, waren sie signifikant vermindert. Es wird vermutet, daß T-Zellen die Energieverluste mit einem überschießenden Effekt ihres Sauerstoffverbrauchs und stark angetriebener Glykolyse kompensieren. HIF-1alpha ist dabei nicht entscheidend für die Umschaltung auf anaerobe Energiesynthese. Schlußfolgerung: Die Daten quantifizieren die Energieanforderungen der funktionellen Aktivität in hochgereinigten humanen Immunzellfraktionen. Es wurde nachgewiesen, daß sich Immunzellen unerwartet lange an eine massiv beeinträchtigte Energetik adaptieren können und ihre spezifischen Funktionen aufrechterhalten. / Background: The function of immune cells is dependent upon a constant and adequate supply of energy. Energy is formed via OXPHOS in the mitochondria and via cytosolic glycolysis. Oxygen and glucose are the main substrates for energy synthesis. Objective: In severe diseases or in inflamed areas cellular energy supply is significantly impaired due to inadequate supply of cellular microenvironment with oxygen and nutrients. The aim of this study was to answer the question, whether and how human immune cells maintain viability and functional activity under these circumstances. Methods: Human CD4+ T cells and CD14+ monocytes were isolated by MACS from peripheral blood of healthy donors. The extent of oxidative energy formation was determined via measurement of oxygen consumption using a Clark type electrode. Energy production was restricted in glucose-free cell culture medium and by gradually inhibited OXPHOS using myxothiazol. T cell proliferation was flow-cytometrically analysed using CFDA SE after stimulation with CD3 and CD28 antibodies. Cytokine synthesis was assessed by flow-cytometrical immunofluorescence and the paraformaldehyde-saponin procedure after stimulation of T cells with PMA/ionomycin in the presence of brefeldin A. Phagocytosis of monocytes was measured using a commercial test system (FACS technique). HIF-1alpha expression was assessed by semiquantitative PCR and immunoblot after the stimulation of myxothiazol treated T cells with PMA/ionomycin. Results: In glucose-containing medium all investigated immune functions were unaffected even under complete suppression of OXPHOS. Only when OXPHOS and glycolysis were simultaneously and almost completely suppressed a significant decrease was found. Glucose deprivation per se caused both a significantly reduced proliferation and phagocytosis. It is supposed, that T cells are able to compensate for an energy deficit by an excess of oxygen consumption and strongly induced glycolysis. However, HIF-1alpha was found to be not crucial for switching to anaerobic energy synthesis. Conclusion: These data quantify the energy requirement of functional activity in highly purified human immune cell fractions. An unexpectedly high adaptive potential of immune cells to maintain specific functions even under massively impaired energetic conditions could be demonstrated.

CD4+ T-Zellen

CD14+ Monozyten

zellulärer Energiestoffwechsel

simulierter Sauerstoffmangel

Glukoseentzug

intrazelluläre Zytokinsynthese

T-Zell-Proliferation

Phagozytoseaktivität

HIF-1alpha

CD4+ T cells

CD14+ monocytes

cellular energy metabolism

mimicked oxygen deficiency

glucose deprivation

intracellular cytokine synthesis

T cell proliferation

phagocytotic activity

HIF-1alpha

610 Medizin

33 Medizin

WX 3500

WF 9900

ddc:610