Rowett Research Institute

About: Rowett Research Institute is a based out in . It is known for research contribution in the topics: Rumen & Population. The organization has 2986 authors who have published 4459 publications receiving 239472 citations.

Hypothalamic thyroid hormone catabolism acts as a gatekeeper for the seasonal control of body weight and reproduction.

Abstract: Seasonal adaptations in physiology exhibited by many animals involve an interface between biological timing and specific neuroendocrine systems, but the molecular basis of this interface is unknown. In this study of Siberian hamsters, we show that the availability of thyroid hormone within the hypothalamus is a key determinant of seasonal transitions. The expression of the gene encoding type III deiodinase (Dio3) and Dio3 activity in vivo (catabolism of T4 and T3) is dynamically and temporally regulated by photoperiod, consistent with the loss of hypothalamic T3 concentrations under short photoperiods. Chronic replacement of T3 in the hypothalamus of male hamsters exposed to short photoperiods, thus bypassing synthetic or catabolic deiodinase enzymes located in cells of the ependyma of the third ventricle, prevented the onset of short-day physiology: hamsters maintained a long-day body weight phenotype and failed to undergo testicular and epididymal regression. However, pelage moult to a winter coat was n...

Impact of folate deficiency on DNA stability

Abstract: Convincing evidence links folate deficiency with colorectal cancer incidence. Currently, it is believed that folate deficiency affects DNA stability principally through two potential pathways. 5,10-Methylenetetrahydrofolate donates a methyl group to uracil, converting it to thymine, which is used for DNA synthesis and repair. If folate is limited, imbalances in the DNA precursor pool occur, and uracil may be misincorporated into DNA. Subsequent misincorporation and repair may lead to double strand breaks, chromosomal damage and cancer. Moreover, folate affects gene expression by regulating cellular S-adenosylmethionine (SAM) levels. 5-Methyltetrahydrofolate serves as methyl donor in the remethylation of homocysteine to methionine, which in turn is converted to SAM. SAM methylates specific cytosines in DNA, and this regulates gene transcription. As a consequence of folate deficiency, cellular SAM is depleted, which in turn induces DNA hypomethylation and potentially induces proto-oncogene expression leading to cancer. Data from several model systems supporting these mechanisms are reviewed here. There is convincing evidence that folate modulates both DNA synthesis and repair and DNA hypomethylation with altered gene expression in vitro. The data from in vivo experiments in rodents is more difficult to interpret because of variations in the animal and experimental systems used and the influence of tissue specificity and folate metabolism. Most importantly, the confounding effects of nutrient-gene interactions, together with the identification of polymorphisms in key enzyme systems and the influence that these have on folate metabolism and DNA stability, must be considered when interpreting evidence from human studies.

Hepatic iodothyronine 5'-deiodinase. The role of selenium.

Abstract: Selenium (Se) deficiency decreased by 8-fold the activity of type 1 iodothyronine 5′-deiodinase (ID-I) in hepatic microsomal fractions from rats. Solubilized hepatic microsomes from rats injected with 75Se-labelled Na2SeO3 4 days before killing were found by chromatography on agarose gels to contain a 75Se-containing fraction with ID-I activity. PAGE of this fraction under reducing conditions, followed by autoradiography, revealed a single 75Se-containing protein (Mr 27,400 +/- 300). This protein could also be labelled with 125I-bromoacetyl reverse tri-iodothyronine, an affinity label for ID-I. The results suggest that hepatic ID-I is a selenoprotein or has an Se-containing subunit essential for activity.

Leptin: fundamental aspects.

Abstract: The discovery of leptin, the product of the ob gene, has led to major developments in understanding the regulation of energy balance. It is now recognised that leptin is produced in several organs additional to white adipose tissue, including brown fat, the placenta and fetal tissues (such as heart and bone/cartilage). The hormone has multiple functions-in inhibiting food intake, in the stimulation/maintenance of energy expenditure, as a signal to the reproductive system and as a 'metabolic' hormone influencing a range of processes (for example, insulin secretion, lipolysis, sugar transport). The production of leptin by white fat is subject to a number of regulatory influences, including insulin and glucocorticoids (which are stimulatory), and fasting and beta-adrenoceptor agonists (which are inhibitory). A key role in the regulation of leptin production by white fat is envisaged for the sympathetic system, operating through beta3-adrenoceptors. The leptin receptor gene is widely expressed, with the several splice variants exhibiting different patterns of expression. The long form variant (Ob-Rb) is expressed particularly in the hypothalamus, although it is being increasingly identified in other tissues. Leptin exerts its central effects through several neuroendocrine systems, including neuropeptide Y, glucagon-like peptide-1, melanocortins, corticotrophin releasing hormone (CRH) and cocaine- and amphetamine-regulated transcript (CART). In essence, the leptin system now appears highly complex, the hormone being involved in a range of physiological processes in a manner far transcending the initial lipostatic concept. This complexity may reduce the potential of the leptin system as a target for anti-obesity therapy.