ChIA-PET

この項目「ChIA-PET」は途中まで翻訳されたものです。（原文：en:ChIA-PET） 翻訳作業に協力して下さる方を求めています。ノートページや履歴、翻訳のガイドラインも参照してください。要約欄への翻訳情報の記入をお忘れなく。（2010年11月）

ChIA-PET法（英: Chromatin Interaction Analysis by Paired-End Tag Sequencing、ペアエンドタグの配列解析によるクロマチン相互作用解析）は、クロマチン免疫沈降 (ChIP)を元にした濃縮、 Chromosome conformation capture(訳語未定), Paired-End Tags(ペアエンドタグ), および ultra-high-throughput sequencing(DNAシークエンシングおよび遺伝子参照) の組み合わせによって、染色体に含まれるDNA塩基配列の相互作用を全染色体にわたって決定するために開発された手法(Fullwood & Yijun, 2009)である。 遺伝子は、プロモーターなどの制御領域、インシュレーターなどの境界領域や転写因子結合領域(TFBS)など離れた領域からの制御も受けるばあいもある。制御領域と遺伝子本体の領域の動的相互作用を明らかにすることには、医学などの立場からみると遺伝子の働きの制御の本質的に重要な部分を理解する事になるという重要性がある(Maston et al., 2006)(訳注: 原文は、"Uncovering the interplay between regulatory regions and gene coding regions is essential for understanding the mechanisms governing gene regulation in health and disease")。 ChIA-PETは、染色体上での近接遠隔を問わない、TFBSやプロモーターと遺伝子本体の、他の手法では出来ない機能的な相互作用の同定が可能である。

ChIA-PETはまた、細胞のcell differentiation(分化), proliferation(細胞分裂), and 胚発生などの過程で働いている機構を明らかにする場合にも用いる事ができる。DNA結合性転写因子タンパクやプロモーター領域に対してChIA-PET interactomeマップを作成する事で、治療介入(therapeutic intervention)においてより良い標的を見つける事が可能である(Fullwood & Yijun, 2009)。

手法[編集]

ChIA-PET法は、クロマチン免疫沈降法(Kuo & Allis, 1999)および3C法を組み合わせた手法である(The ChIA-PET method combines ChIP-based methods (Kuo & Allis, 1999), and Chromosome_conformation_capture (3C), to extend the capabilities of both approaches.)。 ChIP-Seq法が転写因子結合領域(TFBS)を決定するのに広く用いられる手法である一方、染色体間の大域的相互作用の測定には3C法が用いられていた(Dekker et al., 2002)(ChIP-Sequencing (ChIP-Seq) is a popular method used to identify TFBS while 3C has been used to identify long-range chromatin interactions (Dekker et al., 2002).)。 However, both suffer from limitations when used independently to identify de-novo long-range interactions genome wide. While ChIP-Seq is typically used for genome-wide identification of TFBS (Barski et al., 2007; Wei et al., 2006), it provides only linear information of protein binding sites along the chromosomes (but not interactions between them), and suffers from high genomic background noise (false positives). Additionally, only a small amount of sequences generated by ChIP-Seq uniquely map to the genome, and an even smaller amount are functional TFBS (Johnson et al., 2007).

While 3C is capable of analyzing long-range chromatin interactions, it cannot be used genome wide and, like ChIP-Seq, also suffers from high levels of background noise. Since the noise increases in relation to the distance between interacting regions (max 100kb), laborious and tedious controls are required for accurate characterization of chromatin interactions (Dekker et al., 2006).

The ChIA-PET method successfully resolves the issues of non-specific interaction noise found in ChIP-Seq by sonicating the chip fragments in order to separate random attachments from specific interaction complexes. The next step, which is referred to as enrichment, reduces complexity for genome-wide analysis and adds specificity to chromatin interactions bound by pre-determined TFs (transcription factors). The ability of 3C approaches to identify long-range interactions is based on the theory of proximity ligation. In regards to DNA inter-ligation, fragments that are tethered by common protein complexes have greater kinetic advantages under dilute conditions, than those freely diffusing in solution or anchored in different complexes. ChIA-PET takes advantage of this concept by incorporating linker sequences onto the free ends of the DNA fragments tethered to the protein complexes. In order to build connectivity of the fragments tethered by regulatory complexes, the linker sequences are ligated during nuclear proximity ligation. Therefore, the products of linker-connected ligation can be analyzed by ultra-high-throughput PET sequencing and mapped to the reference genome. Since ChIA-PET is not dependent on specific sites for detection as 3C and 4C are, it allows unbiased, genome-wide de-novo detection of chromatin interactions (Fullwood et al., 2009).

Workflow[編集]

Wet-lab portion of the workflow[編集]

• Figure 1. Formaldehyde is used to cross-link the DNA-protein complexes. Sonication is used to break-up the chromatin and also to reduce non-specific interactions.
• Figure 2. A specific antibody of choice is used to enrich protein of interest bound chromatin fragments. ChIP material bound by the antibody are used to construct the ChIA-PET.

• Figure 3. Biotinylated oligonucleotide half-linkers containing flanking MmeI sites are used to connect proximity ligated DNA fragments. Two different linkers are designed (A and B) with specific nucleotide barcodes (CG or AT) for each of the two linker sequences.

• Figure 4. The linkers are ligated to the tethered DNA fragments.

• Figure 5. The linker fragments are ligated on the ChIP beads under dilute conditions. The purified DNA is then digested by MmeI, which cuts at a distance from its recognition site to release the tag-linker-tag structure.

• Figure 6. The biotinylated PETs are then immobilized on streptavidin-conjugated magnetic beads.

• Figure 7. PET sequences with AA (CG/CG) and BB (AT/AT) linker barcode composition are considered to be possible intra-complex ligation products, while the PET sequences with AB (CG/AT) linker composition are considered to be derived from chimeric ligation products between DNA fragments bounded in different chromatin complexes.

Dry-lab portion of the workflow[編集]

PET extraction, mapping, and statistical analyses

The PET tags are extracted and mapped to the reference human genome in-silico.

Identification of ChIP enriched peaks (binding sites)

Self-ligated PET are used for identifying ChIP enriched sites because they provide the most reliable mapping (20 + 20 bps) to the reference genome.

ChIP enrichment peak-finding algorithm

A called peak is considered a binding site if there are multiple overlapping self-ligated PETs.

The false discovery rate (FDR) is determined using statistical simulations to estimate the random background of PET-derived virtual DNA overlaps, and the estimated background noise.

Filtering of repetitive DNA (affects non-specific binding)

Satellite regions and binding sites present in regions with severe structural variations are removed.

ChIP enrichment count

The numbers of self-ligation and inter-ligation PETs (within + 250 bp window) are reported at each site. The total number of self-ligated and inter-ligated PETs at a specific site is called the ChIP enrichment count.

Figure 8. PET Classification: Uniquely aligned PET sequences can be classified by whether they are derived from one DNA fragment or two DNA fragments.

Self-ligation PETs

If the two tags of a PET are mapped on the same chromosome with the genomic span in the range of ChIP DNA fragments (less than 3 Kb), with expected self-ligation orientation and on the same strand, they are considered to be derived from a self-ligation of a single ChIP DNA fragment, and considered a self-ligation PET.

Inter-ligation PETs

If a PET does not fit into these criteria, then the PET most likely resulted from a ligation product between two DNA fragments and refered to as an inter-ligation PET. The two tags of an inter-ligation PETs do not have fixed tag orientations, might not be found on the same strands, might have any genomic span, and might not map to the same chromosome.

Intrachromosomal inter-ligation PETs

If the two tags of an inter-ligation PET are mapped in the same chromosome but with a span > 3 Kb in any orientation, then these PETs are called intrachromosomal inter-ligation PETs.

Interchromosomal inter-ligation PETs

PETs which are mapped to different chromosomes are called interchromosomal inter-ligation PETs.

Figure 9. Proposed mechanism showing how distal regulatory elements can initiate long-range chromatin interactions involving promoter regions of target genes.

The interactions form DNA loop structures with multiple TFBS at the anchoring center. Small loops might package genes near the anchoring center in a tight sub-compartment, which could increase the local concentration of regulatory proteins for enhanced transcriptional activation. This mechanism might also enhance transcription efficiency, allowing RNA pol II to cycle the tight circular gene templates. The large interaction loops are more likely to link together distant genes at either end of the loop residing near anchor sites for coordinated regulation, or could separate genes in long loops to prevent their activation. Adapted from Fullwood et al. (2009).

特徴[編集]

長所[編集]

• ChIA-PET is an unbiased, whole-genome and de-novo approach for long-range chromatin interaction analysis.
• A ChIA-PET experiment is capable of providing two global datasets: The protein factor binding sites (self-ligated PETs); and The interactions between the binding sites (inter-ligated PETs).
• ChIA-PET involves ChIP to reduce the complexity for genome-wide analysis and adds specificity to chromatin interactions bound by specific factors of interest.
• ChIA-PET is compatible with tag-based next-generation sequencing approaches such as Roche 454 pyrosequencing, Illumina GA, ABI SOLiD, and Helicos.
• ChIA-PET is applicable to many different protein factors involved in transcriptional regulation or chromatin structural conformation.
• ChIA-PET analysis can be applied to chromatin interactions involved in a particular nuclear process. By using general TFs such as RNA Polymerase II, it may be possible to identify all chromatin interactions involved in transcription regulation. Further, the use of protein factors involved in DNA replication or chromatin structure would allow identification of all interactions due to DNA replication and chromatin structural modification (Fullwood et al., 2009).

短所[編集]

• It is well established that cis and trans-regulatory complexes contain unique combinations of proteins based on cell and tissue specific conditions (Dekker et al., 2006). While identification of single, functional TFBS is a significant advancement, the use of ChIA-PET to identify individual proteins in a complex would require guess work and multiple experiments to identify each interacting protein. This would be a costly and time consuming endevour.
• ChIA-PET is limited by the quality, purity, and specificity of the antibodies used (Fullwood et al., 2009).
• ChIA-PET is dependent on identification of sequences that can be mapped to the reference sequence (ref).
• ChIA-PET requires the use of peak-calling computer algorithms to organize and map PET reads to the reference genome. Because of variations between software platforms, results can vary depending on which program is used.
• Although repetitive DNA regions can be associated with gene regulation (Polak & Domany, 200), they need to be removed as they can affect the data (Fullwood et al., 2009).

歴史[編集]

Fullwood et al. (2009), used ChIA-PET to detect and map the chromatin interaction network mediated by oestrogen receptor alpha (ER-alpha) in human cancer cells. The resulting global chromatin interactome map revealed that remote ER-alpha-binding sites were also anchored to gene promoters through long-range chromatin interactions suggesting that ER-alpha functions by extensive chromatin looping in order to bring genes together for coordinated transcriptional regulation.

解析ソフトウェア[編集]

Software typically used in a ChIA-PET experiment[編集]

ELAND

Maps ChIP enriched DNA fragments to the reference human genome.^[1]

Eisen software

Determines gene expression levels based on hierarchical clustering.^[2]

RepeatMasker

In-silico masking of repetitive elements.^[3]

Monte Carlo simulation

Used to estimate the false discovery rates.^[4]

PET-Tool

A software suite for processing and managing of Paired-End di-Tag sequence data.^[5]

Alternatives[編集]

• Chromatin Immunoprecipitation

  ChIP-Seq, ChIP-PET, ChIP-SAGE, ChIP-CHIP.

• Chromasome Conformation Capture

  2-C, 3-C, 4-C, 5-C.

• Paired End Tags

  PET.

脚注[編集]

参考文献[編集]

出典は列挙するだけでなく、脚注などを用いてどの記述の情報源であるかを明記してください。記事の信頼性向上にご協力をお願いいたします。（2013年7月）

• Barski et al., (2007). High-resolution profiling of histone methylations in the human genome. Cell. (129); 823–37.
• Dekker, (2002). Capturing chromosome conformation. Science. (295); 1306–1311.
• Dekker, (2006). The three ‘C’ s of chromosome conformation capture: controls, controls, controls. Nat. Methods. (3); 17–21.
• Fullwood et al., (2009). An oestrogen-receptor-α bound human chromatin interactome. Nature. (462); 58-64.
• Fullwood & Yijun, (2009). ChIP-based methods for the identification of long-range chromatin interactions. J Cell Biochem. 107(1); 30–39.
• Johnson et al., (2007). Genome-wide mapping of in vivo protein-DNA interactions. Science. (316); 1497–502.
• Kuo & Allis, (1999). In-vivo cross-linking and immunoprecipitation for studying dynamic Protein: DNA associations in a chromatin environment. Methods. (19); 425–33.
• Maston et al., (2006). Transcriptional Regulatory Elements in the Human Genome. Annu. Rev: Genomics. Hum Genet. (7); 29–59.
• Polak & Domany, (2006). Alu elements contain many binding sites for transcription factors and may play a role in regulation of developmental processes. BMC Genomics. (7); 133.
• Wei et al., (2006). A global map of p53 transcription-factor binding sites in the human genome. Cell. (124); 207–19.

外部リンク[編集]

• ChIA-PET Genome Browser

  This browser is for viewing the data from Fullwood et al. (2009), and includes a custom Whole Genome Interaction Viewer which provides a macroscopic picture of binding sites and interactions along with a whole genome landscape.