ABSTRACT
RESUMEN Las microalgas son microorganismos fotosintéticos con gran potencial para abastecer las demandas energéticas mundiales. Sin embargo, los limitados conocimientos que se tienen de estos organismos, en particular a nivel molecular de los procesos metabólicos, han limitado su uso con estos propósitos. En esta investigación se ha realizado el análisis in silico de la subunidad alfa de la acetil-Coenzima A carboxilasa heteromérica (αACCasa), una enzima clave en la biosíntesis de lípidos de las microalgas Chlorella sp. y Scenedesmus sp. Asimismo, se ha medido la expresión de este gen en ambas especies cultivadas en medios deficientes de nitrógeno. Los resultados indican que la αACCasa muestra conservación estructural y funcional en ambas especies de microalgas y su mayor similitud genética con otras especies de microalgas. Asimismo, se ha mostrado que el nivel de expresión del gen se incrementa significativamente cuando las microalgas son cultivadas en ausencia de nitrógeno, lo cual se relaciona a su vez con una mayor acumulación de lípidos microalgales. En conclusión, el análisis in silico de la αACCasa de Chlorella sp. y Scenedesmus sp. presentan características estructurales, funcionales y evolutivas muy similares con otras especies de microalgas y plantas. Asimismo, el estudio revela que en ambas especies el gen se sobreexpresa cuando las microalgas son sometidas a estrés por deficiencia de nitrógeno, el cual se relaciona significativamente con la acumulación de lípidos totales en estas células.
ABSTRACT Microalgae are photosynthetic microorganisms with great potential to supply the world's energy demands. However, the limited knowledge of these organisms, particularly at the molecular level of metabolic processes, has limited their use to these purposes. In this investigation, the in silico analysis of the alpha subunit of the heteromeric acetyl-coenzyme A carboxylase (αACCase), a key enzyme in lipid biosynthesis of microalgae Chlorella sp. and Scenedesmus sp. was carried out. Also, the expression of this gene has been measured in both species cultivated in nitrogen-depleted media. Results indicate that αACCase shows structural and functional conservation in both species of microalgae and their greater genetic similarity with other species of microalgae. Also, it has been shown that the expression levels of this gene are significantly increased when the microalgae are cultured in the absence of nitrogen, which in turn is related to a greater accumulation of microalgal lipids. In conclusion, the in silico analysis of the Chlorella sp. and Scenedesmus sp. αACCase reveals structural, functional and evolutionary characteristics very similar to other microalgae and plant species. Also, the study reveals that in both species the gene is overexpressed when microalgae are subjected to nitrogen deficiency stress, which is significantly related to total lipids accumulation in these cells.
ABSTRACT
Polycomb repressive complex 2 (PRC2) is the epigenetic regulator that induces histone H3 lysine 27 methylation (H3K27me3) and silences specific gene transcription. Enhancer of zeste homolog 2 (EZH2) is an enzymatic subunit of PRC2, and evidence shows that EZH2 plays an essential role in cancer initiation, development, progression, metastasis, and drug resistance. EZH2 expression is indeed regulated by various oncogenic transcription factors, tumor suppressor miRNAs, and cancer-associated non-coding RNA. EZH2 activity is also controlled by post-translational modifications, which are deregulated in cancer. The canonical role of EZH2 is gene silencing through H3K27me3, but accumulating evidence shows that EZH2 methlyates substrates other than histone and has methylase-independent functions. These non-canonical functions of EZH2 are shown to play a role in cancer progression. In this review, we summarize current information on the regulation and roles of EZH2 in cancer. We also discuss various therapeutic approaches to targeting EZH2.
Subject(s)
Drug Resistance , Epigenomics , Gene Silencing , Histones , Lysine , Methylation , MicroRNAs , Neoplasm Metastasis , Polycomb Repressive Complex 2 , Protein Processing, Post-Translational , RNA, Untranslated , Transcription Factors , Transcription, GeneticABSTRACT
Glucocorticoid (GC) has important physiological and pharmacological effects, which are mainly mediated by the GC receptor (GR). As a ligand-dependent transcriptional factor, GR activity is regulated by phosphorylation as well as GC; it is subject to hormone-dependent and -independent phosphorylation on several serine and threonine residues, especially in the N terminus. The GR is phosphorylated by cell-specific kinases such as cyclin-dependent kinases (CDKs), glycogen synthase kinase 3β (GSK3J7beta;) and mitogen-activated protein kinases (MAPKs). Phosphorylation regulates signaling and transcriptional activity of GR, thereby modulates the response of cells to GC and may be involved in the development and progression of diseases. Here we reviewed the recent research on GR phosphorylation and its pathophysiological significance.
ABSTRACT
Los microARNs son ARN pequeños de aproximadamente 22 nucleótidos de longitud que participan en la regulación de muchos procesos celulares y, su alteración está asociada con el desarrollo de diferentes patologías, especialmente cáncer. Gracias al uso de las herramientas de bioinformática es posible determinar su distribución en el genoma y sus funciones en diferentes tejidos. La mayoría de microARNs son producidos en una vía canónica a partir de un transcripto primario largo, en un proceso secuencial de dos reacciones guiadas principalmente por dos enzimas, Drosha en el núcleo y Dicer en el citoplasma. Sin embargo, actualmente han sido descritas algunas vías no canónicas de generación de microARNs. El objetivo de esta revisión es describir el proceso de generación de microARNs y la maquinaria involucrada en su generación con el propósito de lograr alcanzar un mejor entendimiento de los diferentes procesos en los cuales están involucrados. Salud UIS 2011; 43 (3): 289-297.
MicroRNAs are small RNAs of approximately 22 nucleotides in length that participate in the regulation of many cellular processes and it alteration is associated with the development of different pathologies in particular, cancer. Using bioinformatics tools is possible determine their wide distribution in the genome and their functions in different tissues. Mostly of microRNAs are produced in a canonical way from a long primary transcript, in a sequential process of two reactions guided mostly by two enzymes: Drosha in the nucleus and Dicer in the cytoplasm. However, it has been described some pathways non-canonical for the generation of microRNAs. The aim of this review is to describe the generation process of microRNAs and the machinery involved in their generation for the purpose of achieving a better understanding of the different processes they are involved. Salud UIS 2011; 43 (3): 289-297.