The number and periodicity of seizures induce cardiac remodeling and changes in micro-RNA expression in rats submitted to electric amygdala kindling model of epilepsy.

Generalized tonic-clonic seizures (GTCS) are the main risk factor for sudden unexpected death in epilepsy (SUDEP). Also, among the several mechanisms underlying SUDEP there is the cardiac dysfunction. So, we aimed to evaluate the impact of the number of seizures on heart function and morphology in rats with epilepsy. Rats were randomized into three groups: Sham (without epilepsy), 5 S, and 10 S groups, referred as rats with epilepsy with a total of 5 or 10 GTCS, respectively. Epilepsy was induced by electrical amygdala kindling. The ventricular function was analyzed by the Langendorff technique and challenged by ischemia/reperfusion protocol. Cardiac fibrosis and hypertrophy were analyzed by histology. We also analyzed cardiac metalloproteinases (MMP2 and MMP9), ERK 1/2 and phosphorylated ERK1/2 (P-ERK) by western blot; microRNA-21 and -320 by RT-PCR; and oxidative stress (TBARS, catalase activity and nitrite) by biochemical analysis. Only the 5S group presented decreased values of ventricular function at before ischemia/reperfusion (baseline): intraventricular systolic pressure, developed intraventricular pressure, positive and negative dP/dt. During ischemia/reperfusion protocol, the variation of the ventricular function did not differ among groups. Both 5S and 10S groups had increased cardiomyocyte hypertrophy and fibrosis compared to Sham, but in the 5S group, these alterations were higher than in the 10S group. The 5S group increased in microRNA-21 and decreased in microRNA-320 expression compared to Sham and the 10S group. The 10S group increased in MMP9 and decreased in P-ERK/ERK expression, and increased in nitrite content compared to both Sham and the 5S group. Therefore, seizures impair cardiac function and morphology, probably through microRNA modulation. The continuation of seizures seems to exert a preconditioning-like stimulus that fails to compensate the cardiac tissue alteration.

The new world of RNAs.

One of the major developments that resulted from the human genome sequencing projects was a better understanding of the role of non-coding RNAs (ncRNAs). NcRNAs are divided into several different categories according to size and function; however, one shared feature is that they are not translated into proteins. In this review, we will discuss relevant aspects of ncRNAs, focusing on two main types: i) microRNAs, which negatively regulate gene expression either by translational repression or target mRNA degradation, and ii) small interfering RNAs (siRNAs), which are involved in the biological process of RNA interference (RNAi). Our knowledge regarding these two types of ncRNAs has increased dramatically over the past decade, and they have a great potential to become therapeutic alternatives for a variety of human conditions.

Quantificação de diferentes microRNAs no sistema nervoso central: implicações nos mecanismos de desenvolvimento e processos fisiopatologicos / Quantification of microRNAs in the central nervoussystem: implications

MicroRNAs são moléculas recém-descobertas de RNA não-codificadores que possuem de 21 a 24 nucleotídeos e que regulam a expressão após a transcrição dos genes alvo. Essa regulação pode ser realizada através da inibição da tradução ou da degradação do RNA mensageiro. Os miRNAs estão envolvidos em vários processo biológicos como, diferenciação celular e desenvolvimento embrionário, além de apresentarem expressão tecido e tempo-específica. Eles podem regular a expressão de pelo menos 1/3 de todos os genes humanos e estão envolvidos com a regulação do metabolismo e da apoptose. Os miRNAs são a chave como reguladores pós-transcricionais da neurogênese; estudos mostram que eles possuem a expressão associada com a transição entre proliferação e diferenciação e também tem expressão constitutiva em neurônios maduros, evidenciando o envolvimento dessas moléculas com o desenvolvimento do sistema nervoso central (SNC). Outros miRNAs estão sendo estudados e verifica-se que eles agem como reguladores de genes envolvidos em doenças como Alzheimer, Parkinson e, provavelmente, também devam possuir um papel na regulação das epilepsias. No primeiro trabalho, apresentado no segundo capítulo, investigamos o papel dos miRNAs no desenvolvimento do SNC através da quantificação de 104 miRNAs em cérebros em desenvolvimento de camundongos. No segundo trabalho, apresentado no terceiro capítulo, para analisarmos o papel dos miRNAs na epilepsia de lobo temporal, verificamos se havia presença de miRNAs com expressão diferenciada entre tecidos removidos de pacientes que se submeteram a cirurgia de hipocampectomia e tecidos normais provenientes de autópsias. Para ambos os experimentos, foram extraídos os RNAs dos tecidos e quantificados por PCR em tempo real com o kit MicroRNA Assay baseado em iniciadores com estrutura em stem loop. Nos camundongos, análises de bioinformática encontraram quatro cluster de acordo com a expressão dos miRNAs...

MicroRNAs are a new class of small RNA molecules (21-24 nucleotide-long) that negatively regulate gene expression either by translational repression or target mRNA degradation. It is believed that about 30% of all human genes are targeted by these molecules. MiRNAs are involved in many important biological processes including cell differentiation, embryonic development and central nervous system formation, besides they showed specific temporal-space expression. They can regulate 1/3 of human genes and are involved in metabolism and apoptosis. miRNAs are the key as neurogenesis postranscriptional regulation; studies previous indicates miRNA expression associate with proliferation and differentiation in development of central nervous system (CNS) and housekeeping expression in mature neurons. They are involved in several diseases as Alzkeimer's and Parkinson and may have a role in epilepsy regulation. In second chapter, we analyze the miRNA expression in mouse brain during four stages of CNS development; in third chapter, we analyze hippocampal tissue of four patients who underwent selective resection of the mesial temporal structures for the treatment of clinically refractory seizures. In addition we used control samples from autopsy (n=4) for comparison. In both experiments, total RNA was isolated from tissues and used in real-time PCR reactions with TaqMan¿ microRNA assays (Applied Biosystems) to quantify 104 (mouse brain) or 157 (human tissue) different miRNAs...