Microfluidic Low-Input Fluidized-Bed Enabled ChIP-seq Device for Automated and Parallel Analysis of Histone Modifications.

Genome-wide epigenetic changes, such as histone modifications, form a critical layer of gene regulations and have been implicated in a number of different disorders such as cancer and inflammation. Progress has been made to decrease the input required by gold-standard genome-wide profiling tools like chromatin immunoprecipitation followed by sequencing (i.e., ChIP-seq) to allow scarce primary tissues of a specific type from patients and lab animals to be tested. However, there has been practically no effort to rapidly increase the throughput of these low-input tools. In this report, we demonstrate LIFE-ChIP-seq (low-input fluidized-bed enabled chromatin immunoprecipitation followed by sequencing), an automated and high-throughput microfluidic platform capable of running multiple sets of ChIP assays on multiple histone marks in as little as 1 h with as few as 50 cells per assay. Our technology will enable testing of a large number of samples and replicates with low-abundance primary samples in the context of precision medicine.

ChIPmentation: fast, robust, low-input ChIP-seq for histones and transcription factors.

Chromatin immunoprecipitation followed by sequencing (ChIP-seq) is widely used to map histone marks and transcription factor binding throughout the genome. Here we present ChIPmentation, a method that combines chromatin immunoprecipitation with sequencing library preparation by Tn5 transposase ('tagmentation'). ChIPmentation introduces sequencing-compatible adaptors in a single-step reaction directly on bead-bound chromatin, which reduces time, cost and input requirements, thus providing a convenient and broadly useful alternative to existing ChIP-seq protocols.

A microfluidic device for epigenomic profiling using 100 cells.

The sensitivity of chromatin immunoprecipitation (ChIP) assays poses a major obstacle for epigenomic studies of low-abundance cells. Here we present a microfluidics-based ChIP-seq protocol using as few as 100 cells via drastically improved collection of high-quality ChIP-enriched DNA. Using this technology, we uncovered many new enhancers and super enhancers in hematopoietic stem and progenitor cells from mouse fetal liver, suggesting that enhancer activity is highly dynamic during early hematopoiesis.

SraTailor: graphical user interface software for processing and visualizing ChIP-seq data.

Raw data from ChIP-seq (chromatin immunoprecipitation combined with massively parallel DNA sequencing) experiments are deposited in public databases as SRAs (Sequence Read Archives) that are publically available to all researchers. However, to graphically visualize ChIP-seq data of interest, the corresponding SRAs must be downloaded and converted into BigWig format, a process that involves complicated command-line processing. This task requires users to possess skill with script languages and sequence data processing, a requirement that prevents a wide range of biologists from exploiting SRAs. To address these challenges, we developed SraTailor, a GUI (Graphical User Interface) software package that automatically converts an SRA into a BigWig-formatted file. Simplicity of use is one of the most notable features of SraTailor: entering an accession number of an SRA and clicking the mouse are the only steps required to obtain BigWig-formatted files and to graphically visualize the extents of reads at given loci. SraTailor is also able to make peak calls, generate files of other formats, process users' own data, and accept various command-line-like options. Therefore, this software makes ChIP-seq data fully exploitable by a wide range of biologists. SraTailor is freely available at http://www.devbio.med.kyushu-u.ac.jp/sra_tailor/, and runs on both Mac and Windows machines.

Microplate-based platform for combined chromatin and DNA methylation immunoprecipitation assays.

BACKGROUND: The processes that compose expression of a given gene are far more complex than previously thought presenting unprecedented conceptual and mechanistic challenges that require development of new tools. Chromatin structure, which is regulated by DNA methylation and histone modification, is at the center of gene regulation. Immunoprecipitations of chromatin (ChIP) and methylated DNA (MeDIP) represent a major achievement in this area that allow researchers to probe chromatin modifications as well as specific protein-DNA interactions in vivo and to estimate the density of proteins at specific sites genome-wide. Although a critical component of chromatin structure, DNA methylation has often been studied independently of other chromatin events and transcription. RESULTS: To allow simultaneous measurements of DNA methylation with other genomic processes, we developed and validated a simple and easy-to-use high throughput microplate-based platform for analysis of DNA methylation. Compared to the traditional beads-based MeDIP the microplate MeDIP was more sensitive and had lower non-specific binding. We integrated the MeDIP method with a microplate ChIP assay which allows measurements of both DNA methylation and histone marks at the same time, Matrix ChIP-MeDIP platform. We illustrated several applications of this platform to relate DNA methylation, with chromatin and transcription events at selected genes in cultured cells, human cancer and in a model of diabetic kidney disease. CONCLUSION: The high throughput capacity of Matrix ChIP-MeDIP to profile tens and potentially hundreds of different genomic events at the same time as DNA methylation represents a powerful platform to explore complex genomic mechanism at selected genes in cultured cells and in whole tissues. In this regard, Matrix ChIP-MeDIP should be useful to complement genome-wide studies where the rich chromatin and transcription database resources provide fruitful foundation to pursue mechanistic, functional and diagnostic information at genes of interest in health and disease.

The next generation: using new sequencing technologies to analyse gene regulation.

Next generation sequencing (NGS) has pushed back the limitations of prior sequencing technologies to advance genomic knowledge infinitely by allowing cost-effective, rapid sequencing to become a reality. Genome-wide transcriptional profiling can be achieved using NGS with either Tag-Seq, in which short tags of cDNA represent a gene, or RNA-Seq, in which the entire transcriptome is sequenced. Furthermore, the level and diversity of miRNA within different tissues or cell types can be monitored by specifically sequencing small RNA. The biological mechanisms underlying differential gene regulation can also be explored by coupling chromatin immunoprecipitation with NGS (ChIP-Seq). Using this methodology genome-wide binding sites for transcription factors, RNAP II, epigenetic modifiers and the distribution of modified histones can be assessed. The superior, high-resolution data generated by adopting this sequencing technology allows researchers to distinguish the precise genomic location bound by a protein and correlate this with observed gene expression patterns. Additional methods have also been established to examine other factors influencing gene regulation such as DNA methylation or chromatin conformation on a genome-wide scale. Within any research setting, these techniques can provide relevant data and answer numerous questions about gene expression and regulation. The advances made by pairing NGS with strategic experimental protocols will continue to impact the research community.

Analysis of histone modifications in mouse neocortical neural progenitor-stem cells at various developmental stages.

Dynamic changes in histone modifications mediated by Polycomb group proteins can be indicative of the transition of gene repression mode during development. Here, we present methods for the isolation of mouse neocortical neural progenitor-stem cells (NPCs) and their culture, followed by chromatin immunoprecipitation quantitative PCR (ChIP-qPCR) techniques to examine changes in histone H2A ubiquitination patterns at various developmental stages. This protocol can be applied for both in vitro NPCs and NPCs directly isolated from mouse neocortices. For complete details on the use and execution of this protocol, please refer to (Tsuboi et al., 2018).

Automated microfluidic chromatin immunoprecipitation from 2,000 cells.

Chromatin immunoprecipitation (ChIP) is a powerful assay used to probe DNA-protein interactions. Traditional methods of implementing this assay are lengthy, cumbersome and require a large number of cells, making it difficult to study rare cell types such as certain cancer and stem cells. We have designed a microfluidic device to perform sensitive ChIP analysis on low cell numbers in a rapid, automated fashion while preserving the specificity of the assay. Comparing ChIP results for two modified histone protein targets, we showed our automated microfluidic ChIP (AutoChIP) from 2,000 cells to be comparable to that of conventional ChIP methods using 50,000-500,000 cells. This technology may provide a solution to the need for a high sensitivity, rapid, and automated ChIP assay, and in doing so facilitate the use of ChIP for many interesting and valuable applications.

DNA-enrichment microfluidic chip for chromatin immunoprecipitation.

Chromatin immunoprecipitation (ChIP) is a powerful and widely applied technique for detecting association of individual proteins with specific genomic regions; the technique requires several complex steps and is tedious. In this paper, we develop a microbead-packed microfluidic chip which eliminates most of the laborious, time-consuming, and skill-dependent processes of the ChIP procedure. A computational fluid dynamics model was established to analyze fluidic behavior in a microbead-packed microchannel. With the use of the new chip, a ChIP procedure was performed to purify the GAPDH (glyceraldehyde 3-phosphate dehydrogenase) gene from human embryonic kidney cells (cell line 293). The ChIP capability of the microfluidic chip was evaluated and compared with that of a commercial assay kit; the precipitation performance of both methods was almost identical as shown by quantitative measurement of DNA. However, our chip offers the advantage of low resin volume, and the experimental time is greatly reduced. In addition, our method is less dependent on individual technical skill. Therefore, we expect that our microfluidic chip-based ChIP method will be widely used in DNA-, gene-, and protein-related research and will improve experimental efficiency.

Chromatin immunoprecipitation (ChIP) methodology and readouts.

The identification of direct nuclear hormone receptor gene targets provides clues to their contribution to both development and cancer progression. Until recently, the identification of such direct target genes has relied on a combination of expression analysis and in silico searches for consensus binding motifs in gene promoters. Consensus binding motifs for transcription factors are often defined using in vitro DNA binding strategies. Such in vitro strategies fail to account for the many factors that contribute significantly to target selection by transcription factors in cells beyond the recognition of these short consensus DNA sequences. These factors include DNA methylation, chromatin structure, posttranslational modifications of transcription factors, and the cooperative recruitment of transcription factor complexes. Chromatin immunoprecipitation (ChIP) provides a means of isolating transcription factor complexes in the context of endogenous chromatin, allowing the identification of direct transcription factor targets. ChIP can be combined with site-specific PCR for candidate binding sites or alternatively with cloning, genomic microarrays or more recently direct high throughput sequencing to identify novel genomic targets. The application of ChIP-based approaches has redefined consensus binding motifs for transcription factors and provided important insights into transcription factor biology.

Combining chromatin immunoprecipitation and oligonucleotide tiling arrays (ChIP-Chip) for functional genomic studies.

Central to systems biology are genome-wide technologies and high-throughput experimental approaches. Completion of the sequencing of the human genome as well as those of a number of other higher eukaryotes now allows for the first time the mapping of all of the cis-regulatory regions of genes as well as the details of nucleosome position and modification. One approach to achieving this goal involves chromatin immunoprecipitation combined with DNA oligonucleotide tiling arrays (ChIP-chip). This allows for the identification of genomic regions bound by a given factor, its cistrome, or harboring a given epigenomic modification through hybridization on tiling arrays covering the entire genome or specific regions of interest. This technology offers an unbiased assessment of the potential biological function of any DNA associated factor or epigenomic mark. Through integration of ChIP-chip data with complementary genome-wide approaches including expression profiling, CGH and SNP arrays, novel paradigms of transcriptional regulation and chromatin structure are emerging.

ChIP-Chip: algorithms for calling binding sites.

Genome-wide ChIP-chip assays of protein-DNA interactions yield large volumes of data requiring effective statistical analysis to obtain reliable results. Successful analysis methods need to be tailored to platform specific characteristics such as probe density, genome coverage, and the nature of the controls. We describe the use of the respective software packages MAT and MA2C for the analysis of ChIP-chip data from one-color Affymetrix and two-color NimbleGen or Agilent tiling microarrays.

DNA microarrays: an introduction to the technology.

DNA microarrays allow the comprehensive genetic analysis of an organism or a sample. They are based on probes, which are immobilized in an ordered two-dimensional pattern on substrates, such as nylon membranes or glass slides. Probes are either spotted cDNAs or oligonucleotides and are designed to be specific for an organism, a gene, a genetic variant (mutation or polymorphism), or intergenic regions. Thus, they can be used for example for genotyping, expression analysis, or studies of protein-DNA interactions, and in the biomedical field they allow the detection of pathogens, antibiotic resistances, gene mutations and polymorphisms, and pathogenic states and can guide therapy. Microarrays, which cover the whole genome of an organism, are as well available as those which are focussed on genes related to a certain diagnostic application.

Analysis of Transcriptional Regulation in Bone Cells.

Transcription is a process by which the rate of RNA synthesis is regulated. Here we describe the techniques for carrying out promoter-reporter assays, electrophoretic mobility shift assays, chromosome conformation capture (3C) assays, chromatin immunoprecipitation assays, and CRISPR-Cas9 assay, five commonly used methods for studying and altering gene transcription.

Chop it, ChIP it, check it: the current status of chromatin immunoprecipitation.

Our understanding of the significance of interactions of proteins with DNA in the context of gene expression, cell differentiation or to some extent disease has immensely been enhanced by the advent of chromatin immunoprecipitation (ChIP). ChIP has been widely used to map the localization of post-translationally modified histones or histone variants on the genome or on a specific gene locus, or to map the association of transcription factors or chromatin modifying enzymes to the genome. In spite of its power, ChIP is a cumbersome procedure and typically requires large numbers of cells. This review outlines variations elaborated on the ChIP assay to shorten the procedure, make it suitable for small cell numbers and unravel the multiplicity of histone modifications on a single locus. In addition, the combination of ChIP assays with DNA microarray and high-throughput sequencing technologies has in recent years enabled the profiling of histone modifications and transcription factor occupancy sites throughout the genome and in a high-resolution manner throughout a genomic region of interest. We also review applications of ChIP to the mapping of histone modifications or transcription factor binding at the genome-wide level. Finally, we speculate on future perspectives opened by the combination of emerging ChIP-related technologies.

CoCo: a web application to display, store and curate ChIP-on-chip data integrated with diverse types of gene expression data.

MOTIVATION: CoCo, ChIP-on-Chip online, is an open-source web application that supports the annotation and curation of regulatory regions and associated target genes discovered in ChIP-on-chip experiments. CoCo integrates ChIP-on-chip results with diverse types of gene expression data (expression profiling, in situ hybridization) and displays them within a genomic context. Regulatory relationships between the transcription factor-bound regions and putative target genes can be stored and expanded throughout different sessions. AVAILABILITY: http://furlonglab.embl.de/methods/tools/coco.

Application of electrophoretic mobility shift assay and chromatin immunoprecipitation in the study of transcription in adipose cells.

Chromatin, long thought to be no more than a scaffold supporting DNA compaction inside the cell nucleus, has emerged in the last few years as a major regulatory element involved in the control of gene expression both acutely during interphase and programmatically throughout complex processes of development and differentiation. Adipogenesis is the result of an intertwined network of transcription factors and coregulators with chromatin-modifying activities and offers an excellent model for the study of transcriptional regulation. In this regard, electrophoretic mobility shift assay and immunoprecipitation of chromatin are complementary methods that can be used to study the binding of nuclear proteins to DNA and to characterize how these proteins interact with and modify chromatin to regulate gene expression and, more globally, cell differentiation. This chapter provides some strategies to perform these two assays using 3T3-L1 cells and rodent primary preadipocytes and adipocytes.

Identification of transcription factor target genes by ChIP display.

Transcription factors play pivotal roles in the control of cell growth and differentiation in health and disease. In the post-genomic era, it has become possible to locate the regions occupied by transcription factors throughout the genome, leading to better understanding of their mechanism of action and the genes that they regulate. All methods for transcription factor location analysis utilize chromatin immunoprecipitation (ChIP). Although ChIP was initially used to test whether a protein binds to a candidate promoter in living cells, newly developed methods allow the unbiased identification of novel targets of transcription factors. This chapter describes ChIP Display, an affordable method for transcription factor location analysis. Despite being relatively low throughput compared with alternative methods such as ChIP-chip and ChIP-SAGE, ChIP Display provides even small molecular biology laboratories with the opportunity to discover novel targets of any transcription factor, for which high-quality antibodies are available.

Chromatin immunoprecipitation assays: application of ChIP-on-chip for defining dynamic transcriptional mechanisms in bone cells.

Normal cell growth and differentiation of bone cells requires the sequential expression of cell type specific genes to permit lineage specification and development of cellular phenotypes. Transcriptional activation and repression of distinct sets of genes support the anabolic functions of osteoblasts and the catabolic properties of osteoclasts. Furthermore, metastasis of tumors to the bone environment is controlled by transcriptional mechanisms. Insights into the transcriptional regulation of genes in bone cells may provide a conceptual basis for improved therapeutic approaches to treat bone fractures, genetic osteopathologies, and/or cancer metastases to bone. Chromatin immunoprecipitation (ChIP) is a powerful technique to establish in vivo binding of transcription factors to the promoters of genes that are either activated or repressed in bone cells. Combining ChIP with genomic microarray analysis, colloquially referred to as "ChIP-on-chip," has become a valuable method for analysis of endogenous protein/DNA interactions. This technique permits assessment of chromosomal binding sites for transcription factors or the location of histone modifications at a genomic scale. This chapter discusses protocols for performing chromatin immunoprecipitation experiments, with a focus on ChIP-on-chip analysis. The information presented is based on the authors' experience with defining interactions of Runt-related (RUNX) transcription factors with bone-related genes within the context of the native nucleosomal organization of intact osteoblastic cells.

Identification of Response Elements on Promoters Using Site-Directed Mutagenesis and Chromatin Immunoprecipitation.

Proximal promoters are located upstream of the transcription start sites of genes, and they contain regulatory sequences on which bind different transcription factors for promoting colorectal cancer progression. Here we describe the comprehensive methodology used previously for the identification and functional characterization of MYC-responsive elements in the integrin α1 subunit (ITGA1) gene using a combination of in silico analysis, site-directed mutagenesis, and chromatin immunoprecipitation.