ABSTRACT
β-Thalassemia caused by abnormal coding of the β-globin gene is the most common hemoglobinopathy in many Asian countries. The in-depth study of the molecular basis and epigenetic mechanism of globin gene expression is the key to explore a new treatment for thalassemia. In this study, FAIRE (formaldehyde-assisted isolation of regulatory elements), 3C (chromosome conformation capture) and ChIP (Chromatin Immunoprecipitation) were used to investigate the three-dimensional interaction network of β-globin family gene loci and the molecular mechanism of functional regulation of gene expression during rapamycin-induced chromatin remodeling in CD4+ T cells. The results showed that the opening degree of globin gene chromatin, the interaction frequency between the gene promoter region and the regulatory element LCR (Locus control regions), and the enrichment efficiency of CTCF (CCCTC-binding factor) in the gene promoter region changed differently during the change of rapamycin treatment concentration from low to high, which led to the same change trend of the gene expression pattern. At the 10 nmol/ L concentration, chromatin accessibility and gene expression decreased (P < 0. 05). At 20 nmol/ L and 50 nmol/ L concentrations, chromatin accessibility increased and gene expression was up-regulated (P < 0. 05). In this study, the molecular mechanism of gene expression regulation of the β-globin family was expounded through this dynamic change process. Our work provides a theoretical and clinical practice basis for clinical precision treatment.
ABSTRACT
Chromatin accessibility is one of the important indicators to evaluate the stability of chromatin structure, which is used to evaluate the binding ability of chromatin binding factors to chromosome DNA. It plays an important role in different nuclear processes, including gene transcription regulation and DNA damage repair. Abnormal regulation of chromatin accessibility is closely related to the occurrence and development of a variety of diseases, including tumors and neurodegenerative diseases. Therefore, exploration of this attribute has become a hot spot in the field of life science and disease. More and more new technologies came into being, such as chromatin conformation capture, high-throughput sequencing, and the combination of these two technologies. With the progress of technology, more and more factors involved in the regulation of chromosome accessibility have been found and summarized, including nucleosome occupation, histone modification and non-coding RNA. A number of large-scale genomic data have drawn the chromatin accessibility map of a variety of diseases, which provides data support for revealing the relationship between the occurrence and development of diseases and chromatin accessibility. Meanwhile, with the development of single-cell chromatin accessibility sequencing technology, the investigation for division of cell types at chromatin level was achieved, which makes up for the deficiency of solely relying on gene expression for cell type division. This review will explain the development and prospect of the research about chromatin accessibility from the aspects of chromatin composition and accessibility, factors affecting chromatin accessibility, detection methods of chromatin accessibility, and its roles in cancer, briefly.
ABSTRACT
Objective • To detect the genome-wide profiling of chromatin accessibility in human monocytes after stimulated with interferon α (IFNα). Methods • Blood samples were collected from a healthy donor. Assay for transposase-accessible chromatin using sequencing (ATAC-seq) technique was performed to detect the chromatin accessibility. Bioinformatic tools were used for enrichment analysis and visual analysis. Results • With the treatment of IFNα, there were 430 significant up-regulated regions, and 442 significant down-regulated regions. Most of the accessible regions were located at promoters and the adjacent areas of the genes, followed by the intergenic areas and introns. The enrichment analysis showed that the genes related with up-regulated regions were enriched to interferon relevant pathways or anti-virus reactions. To visualize the corresponding chromatin regions, it showed that the intensity of ATAC-seq signal was significantly enhanced at the promoters and transcriptional start sites of effect or interferon-stimulated genes (ISGs) after IFNα stimulation; while for the regulatory ISGs, there was a certain degree of accessibility before stimulation, and the signal intensity was mildly improved. The motif analysis showed significant enrichment of interferon-stimulated response element and interferon regulatory factor in up-regulated regions. Conclusion • Chromatin accessibility of human monocytes has characteristic changes after typeinterferon stimulation and makes preparation for downstream gene expression.
ABSTRACT
After the initial enthusiasm of the human genome project, it became clear that without additional data pertaining to the epigenome, i.e., how the genome is marked at specific developmental periods, in different tissues, as well as across individuals and species-the promise of the genome sequencing project in understanding biology cannot be fulfilled. This realization prompted several large-scale efforts to map the epigenome, most notably the Encyclopedia of DNA Elements (ENCODE) project. While there is essentially a single genome in an individual, there are hundreds of epigenomes, corresponding to various types of epigenomic marks at different developmental times and in multiple tissue types. Unprecedented advances in next-generation sequencing (NGS) technologies, by virtue of low cost and high speeds that continue to improve at a rate beyond what is anticipated by Moore's law for computer hardware technologies, have revolutionized molecular biology and genetics research, and have in turn prompted innovative ways to reduce the problem of measuring cellular events involving DNA or RNA into a sequencing problem. In this article, we provide a brief overview of the epigenome, the various types of epigenomic data afforded by NGS, and some of the novel discoveries yielded by the epigenomics projects. We also provide ample references for the reader to get in-depth information on these topics.