Brown adipose tissue (BAT) plays an important role in lipid and glucose metabolism in rodents and possibly also in humans. Identification of genes responsible for BAT function would shed light on underlying pathophysiological mechanisms of metabolic disturbances. Recent linkage analysis in the BXH/HXB recombinant inbred (RI) strains, derived from Brown Norway (BN) and spontaneously hypertensive rats (SHR), identified two closely linked quantitative trait loci (QTL) associated with glucose oxidation and glucose incorporation into BAT lipids in the vicinity of Wars2 (tryptophanyl tRNA synthetase 2 (mitochondrial)) gene on chromosome 2. The SHR harbors L53F WARS2 protein variant that was associated with reduced angiogenesis and Wars2 thus represents a prominent positional candidate gene. In the current study, we validated this candidate as a quantitative trait gene (QTG) using transgenic rescue experiment. SHR-Wars2 transgenic rats with wild type Wars2 gene when compared to SHR, showed more efficient
mitochondrial proteosynthesis and increased mitochondrial respiration, which was associated with increased glucose oxidation and incorporation into BAT lipids, and with reduced weight of visceral fat. Correlation analyses in RI strains showed that increased activity of BAT was associated with amelioration of insulin resistance in muscle and white adipose tissue. In summary, these results demonstrate important role of Wars2 gene in regulating BAT function and consequently lipid and glucose metabolism.
The long QT syndrome (LQTS) is a monogenic disorder characterized by prolongation of the QT interval on electrocardiogram and syncope or sudden death caused by polymorphic ventricular tachycardia (torsades de pointes). In general, mutations in cardiac ion channel genes (KCNQ1, KCNH2, SCN5A, KCNE1, KCNE2) have been identified as a cause for LQTS. About 50-60 % of LQTS patients have an identifiable LQTS causing mutation in one of mentioned genes. In a group of 12 LQTS patients with no identified mutations in these genes we have tested a hypothesis that other candidate genes could be involved in LQTS pathophysiology. SCN1B and KCND3 genes encode ion channel proteins, ANK2 gene encodes cytoskeletal protein interacting with ion channels. To screen coding regions of genes SCN1B, KCND3, and 10 exons of ANK2 following methods were used: PCR, SSCP, and DNA sequencing. Five polymorphisms were found in screened candid ate genes, 2 polymorphisms in KCND3 and 3 in SCN1B. None of found polymorphisms has coding effect nor is located close to splice sites or has any similarity to known splicing enhancer motifs. Polymorphism G246T in SCN1B is a novel one. No mutation directly causing LQTS was found. Molecular mechanism of LQTS genesis in these patients remains unclear., M. Raudenská, A. Bittnerová, T. Novotný, A. Floriánová, K. Chroust, R. Gaillyová, B. Semrád, J. Kadlecová, M. Šišáková, O. Toman, J. Špinar., and Obsahuje bibliografii a bibliografické odkazy
Souvislost mezi klidovou srdeční frekvencí a mortalitou je dobře zdokumentována u zdravých lidí i u pacientů s hypertenzí, srdečním selháním, nefatálním infarktem myokardu, metabolickým syndromem a u starých lidí. Klidová tachykardie přispívá také ke snížení délky života a je významným a nezávislým prediktorem kardiovaskulární morbidity a mortality [1]. Proto se zdá být rozumné snížit jak srdeční frekvenci, tak spotřebu kyslíku myokardem. Jednoduché měření klidové srdeční frekvence může poskytnou užitečné prognostické informace. Pro farmakologické ovlivnění srdeční frekvence jsou v současnosti nejčastěji používány betablokátory nebo blokátory kalciových kanálů (verapamil, diltiazem). V současné době máme nový lék, který selektivně inhibuje If kanály lokalizované v sinoatriálním uzlu myokardu a snižuje výhradně srdeční frekvenci., Miroslav Souček, and Lit. 16