Molecular and Cellular Aspects of Cirrhosis and How an Adenosine Derivative Could Revert Fibrosis

Hepatic fibrosis occurs in response to persistent liver damage and is characterized by an excessive accumulation of extracellular matrix. When the damage is prolonged, there is a chronic inflammation and persistent hepatic fibrosis eventually leads to cirrhosis, where in addition to the scar, there is an important vascular remodeling associated with portal hypertension and, if decompensated, leads to death or can develop hepatocellular carcinoma. We have been studying the pharmacologic functions of adenosine, finding that a derivative of this nucleoside, IFC-305, shows hepatoprotective effects in a CCl4-induced rat cirrhosis model where it reverses liver fibrosis through modulation of fibrosis-related genes and by ameliorating hepatic function. Furthermore, this compound has the property to rescue cell cycle inhibition in vivo, prevents hepatic stellate cell activation, modulates anti-inflammatory macrophage polarization, and favors a chromatin context that could decrease the genomic instability and characteristics of cirrhosis, enabling the recovery of gene expression profile. Here we show results that contribute to the comprehension of molecular and cellular mechanism of cirrhosis, give the opportunity to suggest biomarkers to the early diagnostic of this pathology, and constitute the fundaments to suggest IFC-305 as a coadjuvant for treatment of this disease

Gain of DNA methylation is enhanced in the absence of CTCF at the human retinoblastoma gene promoter

<p>Abstract</p> <p>Background</p> <p>Long-term gene silencing throughout cell division is generally achieved by DNA methylation and other epigenetic processes. Aberrant DNA methylation is now widely recognized to be associated with cancer and other human diseases. Here we addressed the contribution of the multifunctional nuclear factor CTCF to the epigenetic regulation of the human <it>retinoblastoma </it>(<it>Rb</it>) gene promoter in different tumoral cell lines.</p> <p>Methods</p> <p>To assess the DNA methylation status of the <it>Rb </it>promoter, genomic DNA from stably transfected human erythroleukemic K562 cells expressing a <it>GFP </it>reporter transgene was transformed with sodium bisulfite, and then PCR-amplified with modified primers and sequenced. Single- and multi-copy integrants with the CTCF binding site mutated were isolated and characterized by Southern blotting. Silenced transgenes were reactivated using 5-aza-2'-deoxycytidine and Trichostatin-A, and their expression was monitored by fluorescent cytometry. <it>Rb </it>gene expression and protein abundance were assessed by RT-PCR and Western blotting in three different glioma cell lines, and DNA methylation of the promoter region was determined by sodium bisulfite sequencing, together with CTCF dissociation and methyl-CpG-binding protein incorporation by chromatin immunoprecipitation assays.</p> <p>Results</p> <p>We found that the inability of CTCF to bind to the <it>Rb </it>promoter causes a dramatic loss of gene expression and a progressive gain of DNA methylation.</p> <p>Conclusions</p> <p>This study indicates that CTCF plays an important role in maintaining the <it>Rb </it>promoter in an optimal chromatin configuration. The absence of CTCF induces a rapid epigenetic silencing through a progressive gain of DNA methylation. Consequently, CTCF can now be seen as one of the epigenetic components that allows the proper configuration of tumor suppressor gene promoters. Its aberrant dissociation can then predispose key genes in cancer cells to acquire DNA methylation and epigenetic silencing.</p

An insulator embedded in the chicken α-globin locus regulates chromatin domain configuration and differential gene expression

Genome organization into transcriptionally active domains denotes one of the first levels of gene expression regulation. Although the chromatin domain concept is generally accepted, only little is known on how domain organization impacts the regulation of differential gene expression. Insulators might hold answers to address this issue as they delimit and organize chromatin domains. We have previously identified a CTCF-dependent insulator with enhancer-blocking activity embedded in the 5′ non-coding region of the chicken α-globin domain. Here, we demonstrate that this element, called the αEHS-1.4 insulator, protects a transgene against chromosomal position effects in stably transfected cell lines and transgenic mice. We found that this insulator can create a regulated chromatin environment that coincides with the onset of adult α-globin gene expression. Furthermore, such activity is in part dependent on the in vivo regulated occupancy of CTCF at the αEHS-1.4 element. Insulator function is also regulated by CTCF poly(ADP-ribosyl)ation. Our results suggest that the αEHS-1.4 insulator contributes in organizing the chromatin structure of the α-globin gene domain and prevents activation of adult α-globin gene expression at the erythroblast stage via CTCF

LA VÍA RB/E2F Y LA FAMILIA DE PROTEÍNAS REPRESORAS POLYCOMB EN EL DESARROLLO DE CÁNCER

El control adecuado del ciclo celular mediante la acción coordinada de la familia de factores de transcripción E2F resulta ser clave para la homeostasis celular. El entender su modo de acción desde una perspectiva epigenética resulta ser un tema de gran actualidad y cambia la visión de cómo es regulado el ciclo celular. Uno de los principales reguladores epigenéticos está conformado por el grupo de proteínas Polycomb (PcG), relacionadas con procesos patológicos como el cáncer, a través de la desregulación a nivel epigenético de genes supresores de tumores como BRCA1, p16 y p53, entre otros. Con relación a lo anterior, la regulación del gen supresor Retinoblastoma (Rb) ha sido ampliamente estudiado dada su importante participación como regulador negativo del ciclo celular, pero más reciente se ha demostrado que su modo de acción está relacionado con el grupo de proteínas PcG. Cada uno de los procesos que involucran a componentes de la familia de factores E2F, los miembros de Polycomb y la familia de proteína Rb, parecen ser en cierta medida independientes y, por ende, poco relacionados. Sin embargo, existen evidencias de una convergencia a nivel epigenético en la acción de estos conjuntos de moléculas reguladoras de la progresión del ciclo celular y su desregulación nos puede llevar a entender mejor su contribución al desarrollo de procesos patológicos como el cáncer

La vía Rb/E2F y la familia de proteínas represoras Polycomb en el desarrollo de cáncer

The coordinated contribution of the E2F-family of transcription factors is critical for the proper control of the cell cycle with consequences in the cellular homeostasis. Such kind of regulation requires a renewed vision of the control of the cell cycle through the basis of epigenetic mechanisms. One of such regulatory components is the Polycomb Group (PcG) of proteins which have been involved in cancer development through the anomalous regulation, at an epigenetic level, of tumour suppressor genes such as BRC1, p16, and p53, among others. In particular, the tumour suppressor gene Retinoblastoma (Rb) plays a central role in the regulation of the cell cycle and is regulated by PcG proteins. The relationship among E2F members, PcG and Rb has not been examined in detail. Here, we describe the epigenetic interaction among these proteins, their association with epigenetic processes and their contribution to cancer development.El control adecuado del ciclo celular mediante la acción coordinada de la familia de factores de transcripción E2F resulta ser clave para la homeostasis celular. El entender su modo de acción desde una perspectiva epigenética resulta ser un tema de gran actualidad y cambia la visión de cómo es regulado el ciclo celular. Uno de los principales reguladores epigenéticos está conformado por el grupo de proteínas Polycomb (PcG), relacionadas con procesos patológicos como el cáncer, a través de la desregulación a nivel epigenético de genes supresores de tumores como BRCA1, p16 y p53, entre otros. Con relación a lo anterior, la regulación del gen supresor Retinoblastoma (Rb) ha sido ampliamente estudiado dada su importante participación como regulador negativo del ciclo celular, pero más reciente se ha demostrado que su modo de acción está relacionado con el grupo de proteínas PcG. Cada uno de los procesos que involucran a componentes de la familia de factores E2F, los miembros de Polycomb y la familia de proteína Rb, parecen ser en cierta medida independientes y, por ende, poco relacionados. Sin embargo, existen evidencias de una convergencia a nivel epigenético en la acción de estos conjuntos de moléculas reguladoras de la progresión del ciclo celular y su desregulación nos puede llevar a entender mejor su contribución al desarrollo de procesos patológicos como el cáncer

Emerging Functions of lncRNA Loci beyond the Transcript Itself

Thousands of long noncoding RNAs (lncRNAs) are actively transcribed in mammalian genomes. This class of RNAs has important regulatory functions in a broad range of cellular processes and diseases. Numerous lncRNAs have been demonstrated to mediate gene regulation through RNA-based mechanisms. Simultaneously, non-functional lncRNA transcripts derived from the activity of lncRNA loci have been identified, which underpin the notion that a considerable fraction of lncRNA loci exert regulatory functions through mechanisms associated with the production or the activity of lncRNA loci beyond the synthesized transcripts. We particularly distinguish two main RNA-independent components associated with regulatory effects; the act of transcription and the activity of DNA regulatory elements. We describe the experimental approaches to distinguish and understand the functional mechanisms derived from lncRNA loci. These scenarios reveal emerging mechanisms important to understanding the lncRNA implications in genome biology