To characterize the protein-DNA interaction profiles across different regions on the genome landscape, high-density microarrays are created and hybridization is used for the analysis of ChIP DNA (referred to as ChIP-on-chip). In brief, after reversal of the cross-links, ChIP-enriched DNA and control DNA will be amplified by PCR and fluorescently labeled with the cyanine dyes Cy5 and Cy3 for hybridization to the DNA microarrays containing probes that correspond to the genomic sequences of interest (Figure 2b). The ratio of the Cy5 to Cy3 fluorescence intensities measured for each DNA element provides a measure of the extent of the binding across the entire genomic regions covered in the array. Genomic loci with higher fluorescent intensity in the ChIP DNA than the control DNA will be considered enriched as the potential binding sites. Using this technique, the non-repeat sequences in the genome can be interrogated and many novel binding sites uncovered. For example, genes regulated by many TFs such as STE12 and GAL4p were characterized in detail in yeast systems and revealed new functional pathways regulated through multiple TF bindings 622.

Initially, array studies were limited to promoter regions amplified through PCR 23. Over the years, significant improvements have been made to the ChIP-on-chip procedures as well as the array designs. High-density oligonucleotide tiling arrays that represent the entire genome are now available and enable comprehensive mapping of protein-DNA interactions 62224.

Sequencing-based methods emerged as an alternative to genome-wide readouts of ChIP analysis, particularly for complex genomes. To determine the identities of ChIP DNA by sequencing methods, large numbers of sequence reads are required. As ChIP assay is only a process of enrichment, a significant amount of non-enriched background DNA will still be present in the ChIP DNA material. With a limited survey of the ChIP DNA pool, it is difficult to distinguish between genuine signal and noise. However, if the sampling of the DNA pool can be increased, the genuine ChIP-enriched sites can be defined by multiple overlapping ChIP fragments, whereas the non-specific regions will only be covered by random ChIP singletons. The bona fide sites can then be inferred by multiple mapped sequenced fragments.

Applying ChIP-based assays for components in the transcription machinery or TFs, their genomic targets and regulatory circuitries can be reconstructed 333435. One of the unique and intriguing findings from these genome-wide studies indicates that there are large numbers of identified target binding sites located outside of the previously annotated promoters and suggests that the functional regulatory elements of the genome are larger than previously envisioned. For example, over 30% of the estrogen receptor binding sites were found in the inter-genic regions at least 50 kb away from the neighbor genes 36. Such an observation raises interesting questions about the functional nature of these binding sites and about how to accurately correlate the genes and their corresponding regulatory regions. The genome-wide ChIP assay can also be used to uncover the sequences bound by specific TFs and characterize their binding site selection. Through the putative in vivo binding sites identified, the ab initio binding consensus sequences associated with the protein of interest can be efficiently derived 33. We have also gained insights into how TFs have evolved different mechanisms to elicit target gene responses. Some individual TFs can elicit multiple transcriptional responses, while different TFs can be recruited to the same target regions to trigger transcriptional activation leading to cell differentiation 33. In ESCs, key reprogramming factors and TFs involved in signaling pathways as well as self-renewal have been analyzed. Specifically, two clusters of genomic loci were found that were extensively targeted by multiple transcription factors in the ESC genome. The first cluster includes NANOG, OCT4, SOX2, SMAD1 and STAT3. The second cluster consists of c-Myc (MYC), n-Myc (MYCN), ZFX and E2F1. STAT3 and SMAD1 are major signaling components modulating the leukemia inhibitory factor (LIF) and bone morphogenetic protein (BMP) pathways. LIF and BMPs are protein factors required for the maintenance of the pluripotency state of ESCs. These results have shown that LIF and BMP signaling pathways are integrated into the ESC pluripotency maintenance TF cluster (OCT4, SOX2 and NANOG) through SMAD1 and STAT3; and multiple transcription factor clustering is the mechanism to recruit cell-specific enhancer targeting for lineage-specific transcription regulation.

In addition to TF binding, the ChIP assay can also be used to profile the distribution of the chromatin modification components, histone variants and modifications 10. One of the pioneering efforts was to understand the mechanisms by which histone modifications regulate transcription and chromatin organization. Starting in the yeast system, the application of ChIP assays demonstrated that histone acetylation was a critical link between chromatin structure and transcriptional activation 37. In mammalian genomes, Barski et al. have characterized the histone codes through profiling 20 lysine and arginine methylation modification patterns in histones, and identified the signatures for histone methylation patterns surrounding promoters, enhancers, insulators and transcribed regions 11. Among them, monomethylations of H3K27, H3K9, H4K20, H3K79 and H2BK5 were found to be associated with gene activation, while trimethylation of H3K27, H3K9 and H3K79 was linked to gene repression. In a study to investigate the types of histone modifications that underlie the chromatin properties to maintain the pluripotent nature of the ESC genome, Lander and colleagues un covered 109 domains showing overlapping opposing histone modification marks, termed 'bivalent domains', where large regions of H3K27me3 harbor smaller regions of H3K4me3 10. Following further characterization using a genome-wide ChIP-PET approach in human ESCs 9, H3K4me3 was found to be prevalent and occurred in nearly 70% of promoters in annotated genes, while H3K27me3 appears less occupied in promoter regions and forms a 'bivalent domain' by co-marking 10% of genes with H3K4me3. A large portion of genes that are important for mesoderm development, neuroectoderm and other developmental processes are among the genes co-modified by H3K4me3 and H3K27me3 9.

Through the applications of genome-wide ChIP analyses across different organisms, we learnt that TF binding sites are not necessarily conserved among species 3438 and that not all TF-chromatin interactions are functional 25. Using the binding regions of seven mammalian TFs (ESR1, TP53, MYC, RELA, POU5F1, SOX2 and CTCF) identified on a genome-wide scale, we found only a minority of sites appeared to be conserved at the sequence level, suggesting that evolution has adapted factor binding sites to aid the dynamic regulation of mammalian genomes.

Up to now, most studies using the ChIP assay have been focused on characterization of the DNA portions associated with the pulled-down ChIP material. Analysis of the proteins in their in vivo chromosomal context recovered from ChIP has only been reported recently 39. In addition to protein-DNA interactions, ChIP can also be used to study RNA-protein interactions, especially non-coding, nuclear RNA-directed epigenetic control 4041. Applying RNA immunoprecipitation followed by PCR (RIP-PCR), non-coding RNAs (ncRNAs), such as HOTAIR and Kcnq1ot1, have been shown to associate with Suz12 and G9a in primary human fibroblasts and mouse fetus, and these associations affect Hox genes as well as the expression of imprinting genes 4243. Although RIP has only been carried out in selected cells and at a limited scale, it is intriguing to suggest that there is a specific population of ncRNAs that acts in coordination with different components of histone and DNA modification machineries to achieve gene-expression control. Through further advancement in RIP-based analysis (Figure 3b), it will be interesting to determine their identity, specificity and impact on cell differentiation.

The recent expansion of ChIP technologies has enabled a better understanding of the interactions between TFs and the regulatory networks contributing to gene regulation. Surprisingly, these analyses have demonstrated that many TFs rarely bind to promoter regions compared with intergenic regions 36, suggesting critical roles for long-distance, promoter-enhancer interactions in regulating gene expression in mammalian cells 44. In some cases, it was found that the transcriptional activation involved distal control elements located hundreds of kilobases away, which are brought together through connecting DNA loops that allow physical interactions between the regulatory elements for gene expression 45. However, methods like ChIP-Seq can only reveal the functional genome in a linear fashion. Information on long-range interactions harnessed within the chromatin-protein complexes and how they impact transcriptional regulation is still lacking.

Initial efforts to characterize the distant interactions have been technically challenging and mostly limited to microscopy techniques, which are laborious and of poor resolution. Through formaldehyde cross-linking followed by proximity-based ligation, long-range chromosomal interactions can be captured and detected by PCR (chromatin conformation capture, 3C), microarray analysis or high-throughput sequencing (4C or 5C), with limited scale and selective bias 464748. Applying 3C in the human β-globin loci, various specific interactions between the genes and the regulatory elements were demonstrated 49. Although 3C and its variants are excellent tools to study complex interactions, these methods require prior knowledge of interacting candidates, hence cannot be used for genome-wide profiling for all chromatin interactions. As such, there is a need for approaches that reveal global chromatin interactions at the whole-genome scale in an unbiased and de novo manner. With the pair end ditag concept, we further explored the ability of PET to connect two ends of DNA and delineate their relationships to characterize interacting chromatins (chromatin interaction analysis by pair-end-ditagging; ChIA-PET) 50. In this approach, ChIP was performed with antibodies specific to the TF of interest. Specially designed short oligonucleotide linkers were ligated to the ends of each interacting DNA fragment, followed by second intra-molecular ligations to connect two interacting DNA fragments together. PETs from ligated DNA are extracted and analyzed by pair end ditag sequencing. The linear binding sites along genomic DNA can be revealed from self-ligation PETs and the interactions between the binding sites can be determined from inter/intra-chromatin ligating PETs (Figure 3a). Therefore, a single ChIA-PET experiment can generate two interrelated datasets, depending on the step at which the ligation occurs (before or after the de-cross-link). Such a feature, when supported by ultra-high-throughput sequencing, can reveal interactomes mediated by TFs or chromatin-modifying complexes. We expect that the mapping of the whole-genome interactome mediated by pertinent TFs or chromatin modifications will translate into knowledge that is critical for understanding the fundamental transcriptional regulation programs.