Long QT syndrome (LQTS) is closely associated with syncope, seizure, and sudden death but LQTS is frequently misdiagnosed as epilepsy. LQTS and epilepsy both belong to the group of ion channelopathies that manifest in the heart and brain. Therefore, genetic analysis of genes associated with potassium and sodium homeostasis and electrical disorders may reveal a link between epilepsy and lethal cardiac arrhythmia. Here, the authors report a young woman who suffered recurrent seizure episodes and syncopes that occurred while walking and also during rest. She showed electroencephalogram abnormalities and a pathological prolonged QTc interval in electrocardiogram. The patient and the patient's asymptomatic family members underwent genetic screening of the three genes most frequently associated with LQTS: KCNQ1, KCNH2, and SCN5A. The patient and the family members did not show DNA alterations in the genes KCNQ1 and SCN5A associated with LQT-1 and LQT-3, respectively. However, the patient showed a de novo mutation 2587T→C in exon 10 of KCNH2 gene associated with LQT-2. The mutation caused a stop codon substitution (R863X) in the HERG channel, leading to a 296-amino acid deletion. The patient's asymptomatic relatives did not show the KCNH2 gene mutation. R863X alteration in HERG channel may be involved in both prolonged QTc interval and epilepsy. This fact raises the possibility that R863X alteration in KCNH2-encoded potassium channel may confer susceptibility for epilepsy and cardiac LQT-2 arrhythmia.
Acute coronary syndromes (ACS) are associated with platelet activation. The aim of the present study was to study the protein expression level associated with glycolysis, oxidative stress, cytoskeleton and cell survival in platelets obtained during an ACS. Platelets from 42 coronary ischemic patients, divided into patients admitted within 24 h after the onset of chest pain (ACS group; n=16) and patients with stable coronary ischemic disease (CAD, n=26), were analyzed using proteomics. The expression levels of proteins involved in cellular cytoskeleton (F-actin capping, β-tubulin, α-tubulin isotypes 1 and 2, vinculin, vimentin and two Ras-related protein Rab-7b isotypes), glycolysis pathway (glyceraldehyde-3-phosphate dehydrogenase, lactate dehydrogenase and two pyruvate kinase isotypes) and cellular-related antioxidant system (manganese superoxide dismutase) and even the expression and activity of glutathione-S-transferase were significantly reduced in platelets from ACS patients compared to CAD patients. Moreover, reduction in the expression of proteins associated with cell survival such as proteasome subunit β type 1 was also observed in ACS platelets compared with CAD platelets. Principal component and logistic regression analysis suggested the existence of factors (proteins) expressed in the platelets inversely associated with acute coronary ischemia. In summary, these results suggest the existence of circulating antioxidant, cytoskeleton and glycolytic-"bewildered" platelets during the acute phase of a coronary event.
J. Neurochem. (2012) 121, 314–325. Abstract Stroke patients have a high risk of vascular recurrence. Biomarkers related to vascular recurrence, however, remain to be identified. The aim of the study was to identify, through proteomic analysis, plasma biomarkers associated with vascular recurrence within one year after the first ischemic stroke. This is a substudy (n = 134) of a large prospective multicenter study of post‐stroke patients with an ischemic stroke. Plasma samples were obtained at inclusion. Among the identified proteins, only plasma levels of desmoplakin I were associated with protection against a new vascular event (Odds ratio: 0.64; 95% CI: 0.46–0.89; p = 0.009) after adjustment for hypercholesterolemia, statins and previous atherothrombotic stroke subtype. A greater number of patients without vascular recurrence had been treated with statins within three months of the recent ischemic stroke. Only patients who had been taking statins for 3 months after the ischemic stroke and did not suffer vascular recurrence over a follow‐up year, have higher levels of desmoplakin I at the time of inclusion (Odds ratio 0.49; 95% CI: 0.28–0.86; p = 0.013). Increased desmoplakin I levels, determined within 1–3 months of the first ischemic stroke, could be a biomarker for statin responsiveness against a new vascular event in post‐ischemic stroke patients taking statins early (1–3 months) after the ischemic stroke.
Hypertension is a widely prevalent and important risk factor for cardiovascular diseases that increase with aging. The hallmark of hypertension in the elderly is increased vascular dysfunction. However, the molecular mechanisms by which increased blood pressure leads to vascular injury and impaired endothelial function are not well defined. In the present paper, we will analyze several mechanisms described in the scientific literature involved in hypertension in the elderly as endothelial dysfunction, increased oxygen delivery to tissues, inflammation, cellular apoptosis, and increased concentration of active metabolites. Also, we will focus on new molecular mechanisms involved in hypertension such as telomeres shortening, progenitor cells, circulating microparticles, and epigenetic factors that have appeared as possible causes of hypertension in the elderly. These molecular mechanisms may elucidate different origin for hypertension in the elderly and provide us with new targets for hypertension treatment.
AIMFurther to its pivotal role in haemostasis, factor Xa (FXa) promotes effects on the vascular wall. The purpose of the study was to evaluate if FXa modifies the expression level of energy metabolism and oxidative stress-related proteins in femoral arteries obtained from type 2 diabetic patients with end-stage vasculopathy. METHODSFemoral arteries were obtained from 12 type 2 diabetic patients who underwent leg amputation. Segments from the femoral arteries were incubated in vitro alone and in the presence of 25 nmol l −1 FXa and 25 nmol l −1 FXa + 50 nmol l −1 rivaroxaban. RESULTSIn the femoral arteries, FXa increased triosephosphate isomerase and glyceraldehyde-3-phosphate dehydrogenase isotype 1 expression but decreased pyruvate dehydrogenase expression. These facts were accompanied by an increased content of acetyl-CoA. Aconitase activity was reduced in FXa-incubated femoral arteries as compared with control. Moreover, FXa increased the protein expression level of oxidative stress-related proteins which was accompanied by an increased malonyldialdehyde arterial content. The FXa inhibitor, rivaroxaban, failed to prevent the reduced expression of pyruvate dehydrogenase induced by FXa but reduced acetyl-CoA content and reverted the decreased aconitase activity observed with FXa alone. Rivaroxaban + FXa but not FXa alone increased the expression level of carnitine palmitoyltransferase I and II, two mitochondrial long chain fatty acid transporters. Rivaroxaban also prevented the increased expression of oxidative stress-related proteins induced by FXa alone. CONCLUSIONSIn femoral isolated arteries from type 2 diabetic patients with end-stage vasculopathy, FXa promoted disruption of the aerobic mitochondrial metabolism. Rivaroxaban prevented such effects and even seemed to favour long chain fatty acid transport into mitochondria. WHAT IS ALREADY KNOWN ABOUT THIS SUBJECT• Factor Xa (FXa) modifies the vascular wall which suggests that FXa is a modulator of vascular function.• Patients with type 2 diabetes mellitus have an increased risk of cardiovascular events associated with thrombotic and pro-coagulant conditions.• In diabetes, abnormalities in vascular energy metabolism contribute to vascular dysfunction and higher risk of cardiovascular events WHAT THIS STUDY ADDS• FXa stimulates the glycolytic pathway in diabetic arteries but not to pyruvate anaerobic catabolism.• There is no involvement of long chain fatty acid beta oxidation as alternative source to increase acetyl-CoA in FXa-incubated arteries. • FXa changes the expression level of glucose oxidation-related proteins suggesting disruption of mitochondrial metabolism.
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