A novel cis-regulatory element regulates αD and αA-globin gene expression in chicken erythroid cells.

Background: Cis-regulatory elements (CREs) play crucial roles in regulating gene expression during erythroid cell differentiation. Genome-wide erythroid-specific CREs have not been characterized in chicken erythroid cells, which is an organism model used to study epigenetic regulation during erythropoiesis. Methods: Analysis of public genome-wide accessibility (ATAC-seq) maps, along with transcription factor (TF) motif analysis, CTCF, and RNA Pol II occupancy, as well as transcriptome analysis in fibroblasts and erythroid HD3 cells, were used to characterize erythroid-specific CREs. An α-globin CRE was identified, and its regulatory activity was validated in vitro and in vivo by luciferase activity and genome-editing assays in HD3 cells, respectively. Additionally, circular chromosome conformation capture (UMI-4C) assays were used to distinguish its role in structuring the α-globin domain in erythroid chicken cells. Results: Erythroid-specific CREs displayed occupancy by erythroid TF binding motifs, CTCF, and RNA Pol II, as well as an association with genes involved in hematopoiesis and cell differentiation. An α-globin CRE, referred to as CRE-2, was identified as exhibiting enhancer activity over αD and αA genes in vitro and in vivo. Induction of terminal erythroid differentiation showed that α-globin CRE-2 is required for the induction of αD and αA. Analysis of TF binding motifs at α-globin CRE-2 shows apparent regulation mediated by GATA-1, YY1, and CTCF binding. Conclusion: Our findings demonstrate that cell-specific CREs constitute a key mechanism that contributes to the fine-tuning gene regulation of erythroid cell differentiation and provide insights into the annotation and characterization of CREs in chicken cells.

A Bidirectional Non-Coding RNA Promoter Mediates Long-Range Gene Expression Regulation.

Recent evidence suggests that human gene promoters display gene expression regulatory mechanisms beyond the typical single gene local transcription modulation. In mammalian genomes, genes with an associated bidirectional promoter are abundant; bidirectional promoter architecture serves as a regulatory hub for a gene pair expression. However, it has been suggested that its contribution to transcriptional regulation might exceed local transcription initiation modulation. Despite their abundance, the functional consequences of bidirectional promoter architecture remain largely unexplored. This work studies the long-range gene expression regulatory role of a long non-coding RNA gene promoter using chromosome conformation capture methods. We found that this particular bidirectional promoter contributes to distal gene expression regulation in a target-specific manner by establishing promoter-promoter interactions. In particular, we validated that the promoter-promoter interactions of this regulatory element with the promoter of distal gene BBX contribute to modulating the transcription rate of this gene; removing the bidirectional promoter from its genomic context leads to a rearrangement of BBX promoter-enhancer interactions and to increased gene expression. Moreover, long-range regulatory functionality is not directly dependent on its associated non-coding gene pair expression levels.

Differential DNA methylation and CTCF binding between the ESR1 promoter a of MCF-7 and MDA-MB-231 breast cancer cells.

BACKGROUND: ESR1 is expressed by 60-70% of breast tumours. it's a good prognosis factor and the target of hormone therapy. Optimization of ESR1 reactivation therapy is currently ongoing. Here we probe if the transcription factor CTCF plays a role in the differential expression of ESR1 in the breast cancer cell lines MCF-7 (ESR1+) and MDA-MB-231 (ESR1-). METHODS AND RESULTS: Knockdown of CTCF in MCF-7 resulted in decreased ESR1 gene expression. CTCF binds to the promoter of ESR1 in MCF-7 but not in MDA-MB-231 cells. CTCF ESR1 binding sites are unmethylated in MCF7 but methylated in MDA-MB-231 cells. CONCLUSION: ESR1 expression in MCF7 cells is dependent on CTCF expression. CTCF can bind to specific regions of the promotor of ESR1 gene in MCF-7 cells but not in MDA-MB-231 cells, this correlates with the methylation status of these regions and could be involved in the transcriptional regulation of ESR1.

An Intronic Alu Element Attenuates the Transcription of a Long Non-coding RNA in Human Cell Lines.

Alu elements are primate-specific repeats and represent the most abundant type of transposable elements (TE) in the human genome. Genome-wide analysis of the enrichment of histone post-translational modifications suggests that human Alu sequences could function as transcriptional enhancers; however, no functional experiments have evaluated the role of Alu sequences in the control of transcription in situ. The present study analyses the regulatory activity of a human Alu sequence from the AluSx family located in the second intron of the long intergenic non-coding RNA Linc00441, found in divergent orientation to the RB1 gene. We observed that the Alu sequence acts as an enhancer element based on reporter gene assays while CRISPR-Cas9 deletions of the Alu sequence in K562 cells resulted in a marked transcriptional upregulation of Linc00441 and a decrease in proliferation. Our results suggest that an intragenic Alu sequence with enhancer activity can act as a transcriptional attenuator of its host lincRNA.

In situ dissection of domain boundaries affect genome topology and gene transcription in Drosophila.

Chromosomes are organized into high-frequency chromatin interaction domains called topologically associating domains (TADs), which are separated from each other by domain boundaries. The molecular mechanisms responsible for TAD formation are not yet fully understood. In Drosophila, it has been proposed that transcription is fundamental for TAD organization while the participation of genetic sequences bound by architectural proteins (APs) remains controversial. Here, we investigate the contribution of domain boundaries to TAD organization and the regulation of gene expression at the Notch gene locus in Drosophila. We find that deletion of domain boundaries results in TAD fusion and long-range topological defects that are accompanied by loss of APs and RNA Pol II chromatin binding as well as defects in transcription. Together, our results provide compelling evidence of the contribution of discrete genetic sequences bound by APs and RNA Pol II in the partition of the genome into TADs and in the regulation of gene expression in Drosophila.

CTCF knockout reveals an essential role for this protein during the zebrafish development.

Chromatin regulation and organization are essential processes that regulate gene activity. The CCCTC-binding factor (CTCF) is a protein with different and important molecular functions related with chromatin dynamics. It is conserved since invertebrates to vertebrates, posing it as a factor with an important role in the physiology. In this work, we aimed to understand the distribution and functional relevance of CTCF during the embryonic development of the zebrafish (Danio rerio). We generated a zebrafish specific anti-Ctcf antibody, and found this protein to be ubiquitous, through different stages and tissues. We used the CRISPR-Cas9 system to induce molecular alterations in the locus. This resulted in early lethality. We delayed the lethality performing knockdown morpholino experiments, and found an aberrant embryo morphology involving malformations in structures through all the length of the embryo. These phenotypes were rescued with human CTCF mRNA injections, showing the specificity of the morpholinos and a partial functional conservation between the fish and the human proteins. Lastly, we found that the pro-apoptotic genes p53 and bbc3/PUMA are deregulated in the ctcf morpholino-injected embryos. In conclusion, CTCF is a ubiquitous factor during the zebrafish development, which regulates the correct formation of different structures of the embryo, and its deregulation impacts on essential cell survival genes. Overall, this work provides a basis to look for the particular functions of CTCF in the different developing tissues and organs of the zebrafish.

Nematofauna of Rodents of the Families Heteromyidae and Cricetidae from the Mexican Plateau.

As a part of an ongoing project to inventory the helminth parasites of rodents in Mexico, 85 specimens of 2 families of rodents were collected from the Mexican Plateau: Cricetidae ( Neotoma sp., Neotoma leucodon , Onychomys arenicola , Peromyscus sp., Peromyscus eremicus , and Reithrodontomys sp.) and Heteromyidae ( Chaetodipus sp., Chaetodipus eremicus , Chaetodipus hispidus , Dipodomys merriami , Dipodomys ordii , Dipodomys ornatus, Dipodomys spectabilis , Liomys irroratus , Perognathus sp., and Perognathus flavus ). A total of 13 taxa of helminths were found: Heteromyoxyuris longejector, Heteromyoxyuris otomii, Heteromyoxyuris sp., Onchocercidae gen. sp. 1 and sp. 2, Physalopteridae gen. sp., Protospirura dipodomis, Pterygodermatites dipodomis, Subulura sp., Syphacia sp., Trichuris dipodomis, Vexillata liomyos, and Vexillata armande. The highest species richness was recorded in D. merriami (7 taxa). This study is the first report of nematodes from O. arenicola (Physalopteridae gen. sp.) and C. eremicus (H. longejector) and for V. liomyos from D. merriami . All reports of these species of nematodes represent new collection localities in Mexico.

Epigenetic silencing of miR-181c by DNA methylation in glioblastoma cell lines.

BACKGROUND: Post-transcriptional regulation by microRNAs is recognized as one of the major pathways for the control of cellular homeostasis. Less well understood is the transcriptional and epigenetic regulation of genes encoding microRNAs. In the present study we addressed the epigenetic regulation of the miR-181c in normal and malignant brain cells. METHODS: To explore the epigenetic regulation of the miR-181c we evaluated its expression using RT-qPCR and the in vivo binding of the CCCTC-binding factor (CTCF) to its regulatory region in different glioblastoma cell lines. DNA methylation survey, chromatin immunoprecipitation and RNA interference assays were used to assess the role of CTCF in the miR-181c epigenetic silencing. RESULTS: We found that miR-181c is downregulated in glioblastoma cell lines, as compared to normal brain tissues. Loss of expression correlated with a notorious gain of DNA methylation at the miR-181c promoter region and the dissociation of the multifunctional nuclear factor CTCF. Taking advantage of the genomic distribution of CTCF in different cell types we propose that CTCF has a local and cell type specific regulatory role over the miR-181c and not an architectural one through chromatin loop formation. This is supported by the depletion of CTCF in glioblastoma cells affecting the expression levels of NOTCH2 as a target of miR-181c. CONCLUSION: Together, our results point to the epigenetic role of CTCF in the regulation of microRNAs implicated in tumorigenesis.

A novel chromatin insulator regulates the chicken folate receptor gene from the influence of nearby constitutive heterochromatin and the ß-globin locus.

The three-dimensional architecture of genomes provides new insights about genome organization and function, but many aspects remain unsolved at the local genomic scale. Here we investigate the regulation of two erythroid-specific loci, a folate receptor gene (FOLR1) and the ß-globin gene cluster, which are separated by 16kb of constitutive heterochromatin. We found that in early erythroid differentiation the FOLR1 gene presents a permissive chromatin configuration that allows its expression. Once the transition to the next differentiation state occurs, the heterochromatin spreads into the FOLR1 domain, concomitant with the dissociation of CTCF from a novel binding site, thereby resulting in irreversible silencing of the FOLR1 gene. We demonstrate that the sequences surrounding the CTCF-binding site possess classical insulator properties in vitro and in vivo. In contrast, the chicken cHS4 ß-globin insulator present on the other side of the heterochromatic segment is in a constitutive open chromatin configuration, with CTCF constantly bound from the early stages of erythroid differentiation. Therefore, this study demonstrates that the 16kb of constitutive heterochromatin contributes to silencing of the FOLR1 gene during erythroid differentiation.

Experimental strategies to manipulate the cellular levels of the multifunctional factor CTCF.

Cellular homeostasis is the result of an intricate and coordinated combinatorial of biochemical and molecular processes. Among them is the control of gene expression in the context of the chromatin structure which is central for cell survival. Interdependent action of transcription factors, cofactors, chromatin remodeling activities, and three-dimensional organization of the genome are responsible to reach exquisite levels of gene expression. Among such transcription factors there is a subset of highly specialized nuclear factors with features resembling master regulators with a large variety of functions. This is turning to be the case of the multifunctional nuclear factor CCCTC-binding protein (CTCF) which is involved in gene regulation, chromatin organization, and three-dimensional conformation of the genome inside the cell nucleus. Technically its study has turned to be challenging, in particular its posttranscriptional interference by small interference RNAs. Here we describe three main strategies to downregulate the overall abundance of CTCF in culture cell lines.

CTCF regulates the human p53 gene through direct interaction with its natural antisense transcript, Wrap53.

The multifunctional CCCTC-binding factor (CTCF) protein exhibits a broad range of functions, including that of insulator and higher-order chromatin organizer. We found that CTCF comprises a previously unrecognized region that is necessary and sufficient to bind RNA (RNA-binding region [RBR]) and is distinct from its DNA-binding domain. Depletion of cellular CTCF led to a decrease in not only levels of p53 mRNA, as expected, but also those of Wrap53 RNA, an antisense transcript originated from the p53 locus. PAR-CLIP-seq (photoactivatable ribonucleoside-enhanced cross-linking and immunoprecipitation [PAR-CLIP] combined with deep sequencing) analyses indicate that CTCF binds a multitude of transcripts genome-wide as well as to Wrap53 RNA. Apart from its established role at the p53 promoter, CTCF regulates p53 expression through its physical interaction with Wrap53 RNA. Cells harboring a CTCF mutant in its RBR exhibit a defective p53 response to DNA damage. Moreover, the RBR facilitates CTCF multimerization in an RNA-dependent manner, which may bear directly on its role in establishing higher-order chromatin structures in vivo.

A long non-coding RNA promotes full activation of adult gene expression in the chicken α-globin domain.

Long non-coding RNAs (lncRNAs) were recently shown to regulate chromatin remodelling activities. Their function in regulating gene expression switching during specific developmental stages is poorly understood. Here we describe a nuclear, non-coding transcript responsive for the stage-specific activation of the chicken adult α(D) globin gene. This non-coding transcript, named α-globin transcript long non-coding RNA (lncRNA-αGT) is transcriptionally upregulated in late stages of chicken development, when active chromatin marks the adult α(D) gene promoter. Accordingly, the lncRNA-αGT promoter drives erythroid-specific transcription. Furthermore, loss of function experiments showed that lncRNA-αGT is required for full activation of the α(D) adult gene and maintenance of transcriptionally active chromatin. These findings uncovered lncRNA-αGT as an important part of the switching from embryonic to adult α-globin gene expression, and suggest a function of lncRNA-αGT in contributing to the maintenance of adult α-globin gene expression by promoting an active chromatin structure.

CTCF demarcates chicken embryonic α-globin gene autonomous silencing and contributes to adult stage-specific gene expression.

Genomic loci composed of more than one gene are frequently subjected to differential gene expression, with the chicken α-globin domain being a clear example. In the present study we aim to understand the globin switching mechanisms responsible for the epigenetic silencing of the embryonic π gene and the transcriptional activation of the adult α(D) and α(A) genes at the genomic domain level. In early stages, we describe a physical contact between the embryonic π gene and the distal 3' enhancer that is lost later during development. We show that such a level of regulation is achieved through the establishment of a DNA hypermethylation sub-domain that includes the embryonic gene and the adjacent genomic sequences. The multifunctional CCCTCC-binding factor (CTCF), which is located upstream of the α(D) gene promoter, delimits this sub-domain and creates a transition between the inactive sub-domain and the active sub-domain, which includes the adult α(D) gene. In avian-transformed erythroblast HD3 cells that are induced to differentiate, we found active DNA demethylation of the adult α(D) promoter, coincident with the incorporation of 5-hydroxymethylcytosine (5hmC) and concomitant with adult gene transcriptional activation. These results suggest that autonomous silencing of the embryonic π gene is needed to facilitate an optimal topological conformation of the domain. This model proposes that CTCF is contributing to a specific chromatin configuration that is necessary for differential α-globin gene expression during development.

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.

Chicken alpha-globin switching depends on autonomous silencing of the embryonic pi globin gene by epigenetics mechanisms.

Switching in hemoglobin gene expression is an informative paradigm for studying transcriptional regulation. Here we determined the patterns of chicken alpha-globin gene expression during development and erythroid differentiation. Previously published data suggested that the promoter regions of alpha-globin genes contain the complete information for proper developmental regulation. However, our data show a preferential trans-activation of the embryonic alpha-globin gene independent of the developmental or differentiation stage. We also found that DNA methylation and histone deacetylation play key roles in silencing the expression of the embryonic pi gene in definitive erythrocytes. However, drug-mediated reactivation of the embryonic gene during definitive erythropoiesis dramatically impaired the expression of the adult genes, suggesting gene competition or interference for enhancer elements. Our results also support a model in which the lack of open chromatin marks and localized recruitment of chicken MeCP2 contribute to autonomous gene silencing of the embryonic alpha-globin gene in a developmentally specific manner. We propose that epigenetic mechanisms are necessary for in vivo chicken alpha-globin gene switching through differential gene silencing of the embryonic alpha-globin gene in order to allow proper activation of adult alpha-globin genes.

A new species of Heteromyoxyuris (Nematoda: Oxyuridae), parasite of Perognathus flavus (Rodentia: Heteromyidae) from Mexico.

Heteromyoxyuris otomii n. sp., which inhabits the intestinal caecum of Perognathus flavus (Heteromyidae), in Zaragoza, Hidalgo, Mexico, is described. This new species differs from the 2 other congeneric species in the morphology and length of lateral alae in males. Heteromyoxyuris deserti has simple lateral alae located at both sides of the body, whereas in the new species, these structures are double at both sides; in contrast, lateral alae of Heteromyoxyuris longejector begin at the posterior half of the body, whereas they arise in the first third in the new species. Heteromyoxyuris longejector was found in 2 new host species, i.e., Perognathus amplus and Chaetodipus hispidus. This record represents the first record for the species in Mexico, increasing its geographic distribution.

Globin genes transcriptional switching, chromatin structure and linked lessons to epigenetics in cancer: a comparative overview.

At the present time research situates differential regulation of gene expression in an increasingly complex scenario based on interplay between genetic and epigenetic information networks, which need to be highly coordinated. Here we describe in a comparative way relevant concepts and models derived from studies on the chicken alpha- and beta-globin group of genes. We discuss models for globin switching and mechanisms for coordinated transcriptional activation. A comparative overview of globin genes chromatin structure, based on their genomic domain organization and epigenetic components is presented. We argue that the results of those studies and their integrative interpretation may contribute to our understanding of epigenetic abnormalities, from beta-thalassemias to human cancer. Finally we discuss the interdependency of genetic-epigenetic components and the need of their mutual consideration in order to visualize the regulation of gene expression in a more natural context and consequently better understand cell differentiation, development and cancer.

YY1 and GATA-1 interaction modulate the chicken 3'-side alpha-globin enhancer activity.

Studying the chicken alpha-globin domain as a model system of gene regulation, we have previously identified contiguous silencer-enhancer elements located on the 3'-side of the domain. To better characterize the enhancer we performed a systematic functional analysis to define its expression influence range and the ubiquitous and stage-specific transcriptional regulators interacting with this control element. In contrast to previous reports, we found that, in addition to a core element that includes three GATA-1 binding sites, the enhancer incorporates a 120 base-pair DNA fragment where EKLF, NF-E2 and a fourth GATA-1 factor could interact. Functional experiments demonstrate that the enhancer activity over the adult alpha(D) promoter is differentially regulated. We found that the transcriptional factor Ying Yang 1 (YY1) binds to the 120 base-pair DNA fragment and its effect over the enhancer activity is GATA-1-dependent. In addition, we characterize a novel physical interaction between GATA-1 and YY1 that influences the enhancer function. Experiments using a histone deacetylation inhibitor indicate that, in pre-erythroblasts, the enhancer down-regulation could be influenced by a closed chromatin conformation. Our observations show that the originally defined enhancer possesses a more complex composition than previously assumed. We propose that its activity is modulated through differential nuclear factor interactions and chromatin modifications at distinct erythroid stages.

Discrepancia diagnóstica clínico patológica. Revisión de 1000 casos de autopsia del Hospital General de México / Clinico pathological diagnostic discrepancy. Review of 1000 autopsies in the Hospital General de México

Con el objetivo de conocer la frecuecia de discrepancia entre los diagnósticos clínicos y los anatómicos en casos autopsiados y de conocer el grado de discrepancia de los mismos, se examinaron los protocolos de 1,000 autopsias consecutivas realizadas en el HGM. De cada caso se recabaron los siguientes datos: edad, sexo, servicio, días de estancia, análisis de laboratorio y gabinete, diagnósticos clínicos (DC) y diagnósticos anatómicos (DA). Se compararon los DA, las discrepancias entre ellos se clasificaron como leves (L) cuando la diferencia no influyó en la evolución del caso y como importantes (l) cuando ésta repercutió importantemente en la evolución del mismo. La frecuencia de discrepancia fue de 28.6 por ciento. De los casos discrepantes el 61.2 por ciento tuvieron l y el 38.8 por ciento fue L. La única variable que resultó estadísticamente significativa en la presencia o no de discrepancia fue la duración de la hospitalización. Los servicios en los que hubo mayor proporción de casos discrepantes fueron: Terapia Intensiva, Urgencias, Cirugía General, Neumología y Medicina Interna