Genomic studies of transcription factor–DNA interactions

Genomic studies of transcription factor–DNA interactions

Genomic studies of transcription factor–DNA interactions Devanjan Sikder and Thomas Kodadek A central issue in the regulation of gene expression is th...

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Genomic studies of transcription factor–DNA interactions Devanjan Sikder and Thomas Kodadek A central issue in the regulation of gene expression is the physical association of transcription factors with relevant promoter sequences. Recently, technological advances have allowed researchers to analyze these processes on a genomic scale. In particular, the combination of the chromatin immunoprecipitation (ChIP) technique with microarray analysis (the ‘ChIP to chip’ experiment) is providing a wealth of new and surprising data on transcription factor–chromatin interactions. These advances are reviewed here. We also discuss future challenges in the area. Addresses Departments of Internal Medicine and Molecular Biology, Center for Biomedical Inventions, University of Texas Southwestern Medical Center, 5323 Harry Hines Blvd, Dallas, Texas 75390-8573, USA Corresponding authors: Sikder, D ([email protected]); Kodadek, T ([email protected])

Current Opinion in Chemical Biology 2005, 9:38–45 This review comes from a themed issue on Proteomics and genomics Edited by Benjamin F Cravatt and Thomas Kodadek Available online 8th January 2005 1367-5931/$ – see front matter # 2005 Elsevier Ltd. All rights reserved. DOI 10.1016/j.cbpa.2004.12.008

Introduction Most biological processes are regulated at the level of transcription. In mammalian cells, the transcription of almost every gene is regulated by several positive and negative transcription factors that recognize specific DNA sequences near the target gene, often in promoter regions that are located upstream of the transcriptional start site. Transcription factor–DNA association in a living cell is a complex process [1]. The genome is vast and the DNA is packaged into a variety of chromatin structures that determine its accessibility to a protein [2]. Furthermore, most transcription factors interact with other sequencespecific binding proteins, chromatin remodeling and modification complexes and the general transcription machinery. Any or all of these protein–protein interactions may affect the DNA-binding characteristics of the factor of interest. Thus, while detailed in vitro studies of DNA–protein interactions have provided, and will continue to provide, useful information, it is clear that studies of transcription factor–DNA interactions in living cells are critical to understanding transcriptional regulation (or any Current Opinion in Chemical Biology 2005, 9:38–45

other nuclear process). As described below, this field has undergone a revolution recently, largely because of the development of the so-called ‘ChIP to chip’ assay, which combines the powerful technique of chromatin immunoprecipitation with DNA microarray analysis. Before considering these recent advances, however, it is worthwhile to review briefly earlier work and thinking in this area, which has set the stage for the modern era.

Early days Until quite recently, the analysis of transcription factor– DNA interactions in living cells at anything close to a genomic scale was a very challenging proposition. This was due largely to limitations in analytical techniques. A good example is the pioneering study of Mark Biggin and colleagues of Drosophila regulators Even-skipped (Eve), Fushi tarazu (Ftz) and Zeste [3]. These proteins, which are part of a large superfamily of homeodomain factors, provided a conundrum for early functional genomics researchers. In vitro, homeodomain proteins exhibit quite modest sequence specificity, often as little as 3–4 base pairs [4]. Simple arithmetic would suggest that there must be a massive number of sites in the Drosophila genome that would fit this description. So how could these proteins achieve specific binding to the promoters that they regulate? First, it is important to note that there is an inherent bias in this question. It was assumed that there must exist mechanisms in the cell that elaborate the very modest intrinsic DNA-binding specificity of homeodomain proteins. The alternative explanation, that large amounts of these homeodomain proteins were produced and are scattered all over the genome, was not given much credibility. Biggin and co-workers analyzed Ftz and Eve distribution in Drospophila early embryos using UV cross-linking and Southern analysis [3]. This was a heroic effort. UV crosslinking is a relatively low-efficiency process for most dsDNA-binding proteins and the DNA in the product cannot be amplified by PCR. Thus, a great deal of material must be brought through this protocol to analyze the products. The upside is that this procedure provides at least a semi-quantitative measure of protein–DNA associations along the DNA. The surprising result of these studies was that while Ftz and Eve were found associated with the promoters they regulate, as expected, lower levels of occupancy could also be detected at many sites on the genome, a conclusion to which the transcription community was quite resistant. However, several careful subsequent experiments proved Biggin correct. For example, it was found that an embyro contained >50 000 molecules of Eve and Ftz, which explains www.sciencedirect.com

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how they can be scattered across the genome, yet still occupy specific promoter sites. This is not to say that all transcription factors evince such modest specificity in vivo or that they exist at such high levels. For example, the well-studied Gal4 transcription factor of Saccharomyces cerevisiae exists at very low copy number ( 60 dimers per cell; T Kodadek and SA Johnston, unpublished data) and has much higher specificity than homeodomain factors, recognizing sequences of the form 50 -CGGN11CCG, where N can be A, C, T or G, although the protein has some preferences with regard to this central sequence [5]. Furthermore, Gal4 binds to promoters in concert with the general transcription apparatus [6], further enhancing its specificity for GAL promoters. Nonetheless, even in this system, association of the transcription factor with sites outside of traditional promoters is observed [7]. In all of these systems, from the lowest specificity homeodomain to the more discriminating factors, it will be extremely interesting to examine the functional consequence of activator binding at these extra-promoter sites.

The ChIP to chip assay The mapping of transcription factor binding sites on large swaths of the genome has undergone a revolution over the past few years, largely due to the development of the ‘ChIP to chip’ technique. This process, which in principle can provide a genome-wide view of protein–DNA interactions, is an elaboration of the venerable chromatin immunoprecipitation (ChIP) technique. In the ChIP protocol (see Figure 1a), cells or tissues are treated with formaldehyde, a cell-permeable small molecule that can mediate protein– protein and protein–DNA cross-linking through Schiff base formation. If one wishes to increase the degree of protein–protein cross-linking (for example to better observe indirect protein–DNA interactions in this assay), more efficient protein–protein cross-linking by dimethyl adipimidate can be done first, followed by formaldehyde treatment [8]. Next, the cells are lysed, the chromatin is isolated and sheared into 200–1000 base pair fragments, usually by sonication. The protein of interest is then immunoprecipitated using a specific antibody and any DNA that is cross-linked to it will be co- immunoprecipitated. Although the amount of cross-linked DNA is small, it can be detected by first reversing the cross-links through incubation in a low pH buffer (which hydrolyzes the Schiff base adducts), then amplifying the region of interest using appropriate PCR primers. This is the major advantage of the ChIP technique over other protocols for visualizing DNA–protein interactions in cells; the cross-link is readily reversible and the DNA can be amplified by PCR. The ChIP to chip version of this protocol [9] (Figure 1b) differs only in the post-IP steps. In this case, one does not amplify a particular co-immunoprecipitated DNA with defined primers, but instead endeavors to analyze many www.sciencedirect.com

or even all of the DNAs enriched during the IP step. Briefly, the following steps are employed to do this. The DNA released after reversal of the cross-link is repaired using a DNA polymerase to produce blunt ends. A common linker is then ligated to each DNA. All of the DNA sequences present are then amplified using PCR primers complementary to the common linkers. During this step, fluorescent labels are incorporated through the addition of labeled nucleotide triphosphates [10]. Alternatively, aminoallyl-substituted nucleotides are sometimes incorporated, allowing subsequent attachment of activated ester derivatives of fluorescent dyes post-amplification [11]. This protocol is applied to both the total DNA, which is labeled with one color dye (often Cy3), as well as the DNA sample enriched in the immunoprecipitation, which is labeled with a different color fluor (often Cy5). These two samples are then mixed and hybridized to a microarray composed of nucleic acid probes that represent the regions of the genome that one would like to probe for binding of the transcription factor of interest. In this type of two-color experiment, binding of the protein to a region of DNA is inferred if the intensity of the immunoprecipitated DNA exceeds significantly that of the intensity of the total DNA (i.e. an enrichment has occurred in the immunoprecipitation). It is up to the investigator to determine what ‘significantly’ means (i.e. how much of an enrichment is required to score a loci as a site of protein binding). In summary, the ChIP to chip experiment employs a simple strategy for amplifying unknown pieces of DNA through the attachment of common linkers (a well-used strategy in molecular biology) and then employs the power of microarray technology to conduct the analysis. This is one of the few cases in proteomics where one can bring to bear the full power of genomics technology, in that it reports a property of a protein (the DNA-binding factor) indirectly through a nucleic acid readout.

DNA microarrays for ChIP to chip assays The ideal microarray for a ChIP to chip experiment would contain DNA probes that would allow whole genome coverage. These do not currently exist for the simple reason that too many probes would be required. The human genome, for example, contains around 3  109 base pairs. Given that the inherent resolution of the ChIP assay is  500 bp (defined by the average fragment size after shearing the chromatin), one would like to have a DNA probe for approximately 100 bp region of DNA to ensure redundant coverage (not all DNA probes work well). Thus, an array of over 10 million features would be required. This exceeds the capacity of even the most advanced chip-making capabilities available today. What kind of arrays are available? First, it is worthwhile to review briefly the two basic types of DNA microarrays. The first arrays were created by spotting DNAs onto polylysine-modified glass slides (for a review, see [12]). Current Opinion in Chemical Biology 2005, 9:38–45

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Figure 1

(a)

(b)

Input DNA

IP enriched DNA

T4 DNA pol Repaired ends T4 DNA ligase Linker ligation Cross-linking X

dTTP

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dATP dCTP LM-PCR and labeling

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dATP dGTP

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dGTP

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DNA elution Current Opinion in Cell Biology

Procedure for genome-wide association study. (a) Chromatin immunoprecipitation. Cells are grown under the desired experimental conditions. Protein–protein and protein–DNA interactions are trapped using a cross-linking agent, usually formaldehyde. Following cell lysis, DNA is mechanically sheared and then immunoprecipitated using an antibody or a combination of antibodies against a protein of interest. Cross-links are reversed at low pH. Following deproteinization, DNA is purified. (b) ChIP to chip experiment. Staggered ends of input (non-enriched DNA) and IP-enriched DNA are repaired using T4 DNA polymerase and then ligated to unidirectional linkers. During ligation mediated PCR (LM-PCR), input DNA is labeled with a fluorophore (Cy3), while IP-enriched DNA is labeled with a different fluorescent dye (Cy5). Cy3- and Cy5-labeled DNA pools are mixed and hybridized to a microarray and analyzed.

This is now most often done using synthetic oligonucleotides 50–80 residues long. Obviously, however many probes one wishes to have equals the number of synthetic oligonucleotides (or PCR products) one must spot onto slides. The arrays are made using pin spotting robots that transfer a solution of the DNA from a 384-well plate to the microscope slide. Due to the inevitable spreading of the liquid on the plate, feature sizes below 100 microns are difficult to achieve. This and other practical considerations limit the density of spotted arrays to approximately 20 000–30 000 features. A fundamentally different type of approach to the construction of oligonucleotide arrays is to synthesize the oligomers in situ on the array. There are several ways to do this, the most important being photolithography [13]. These chips, marketed commercially by Affymetrix, can be of much higher density, with the most advanced containing up to two million features. A further advantage of Affymetrix-style chips over spotted arrays is that they are more reproducible [14], as physical spotting can produce a variety of artifacts, such as non-homogenous spots, carryover of one probe onto another feature Current Opinion in Chemical Biology 2005, 9:38–45

(through incomplete washing of pins), etc. Therefore, it is fair to say that most genomics researchers prefer to use Affymetrix arrays if possible. However, these chips are quite expensive. Furthermore, the process by which they are made, which requires micromachined physical masks for the photolithographic chemistry, is not particularly flexible. Rather it is good for making a large number of a few types of arrays. Since most of the emphasis in the microarray community to date has been on gene expression profiling, most chips contain probes to coding sequences in the genome rather than promoters or other extragenic regions. ‘Tiling’ arrays produced photolithographically [15] and suitable for unbiased ChIP to chip analyses (i.e. not focused on coding regions) are just beginning to become available and most of the work has been done with custom-made spotted arrays. However, certain technical advances in the construction of these arrays, such as digital photolithography, and the increasing importance of transcription factor mapping are likely to make these tools much more available in the future. This is fortunate, because the availability of suitable arrays remains the greatest limiting factor in making this powerful tool accessible to large numbers of laboratories. www.sciencedirect.com

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Applications of the ChIP to chip assay The first ChIP to chip experiments were reported at more or less the same time by the Young and Brown groups. Both studied transcription-factor–chromatin binding in the yeast S. cerevisiae. Yeast is a good model system for many reasons, one of which is that its genome is much smaller than that of mammals, allowing microarrays to be produced that provide genome-wide coverage. Young’s group [10] mapped binding sites for Gal4 and Ste12 and identified pathways regulated by these transcription factors in yeast. Brown and co-workers, who were instrumental in the development of spotted DNA microarray technology, conducted similar experiments on the yeast cell cycle transcription factors SBF and MBF [16]. Since that time, a great deal of work has been done on yeast transcription factors [17,18,19], culminating with the publication by Young’s group of the genome-wide association map for 106 epitope-tagged transcription factors [20]. These data, combined with expression analysis datasets [21], provide a rich overview of transcriptional regulation in this simple eukaryotic organism. This technology was later applied to mammalian systems. Initial studies addressing recruitment of Max, Gata1, E2f and Rb transcription factors necessarily surveyed only a small fraction of the genome [22–24] due to the limitations of the available arrays mentioned above as well as the incomplete nature of the genome annotation effort, which has improved steadily, allowing more and more promoter regions to be identified [25,26,27]. In mapping the cMyc binding sites, Li et al. [25] used arrays that had one spot per regulatory region, each of which was about 0.9 kB. This design would, however, fail to report inter-

actions that involve further upstream regions. At the other extreme, to map GATA-1 binding sites, Snyder’s group [22] used arrays that represented the entire 75 kb promoter region of b-globulin dissected into 1 kB fragments. Although this was a small array it had unbiased representation of the entire b-globulin locus. Owing to the complexity of the mammalian genome and the limited understanding of eukaryotic promoters, it was harder to construct promoter arrays. Because CpG islands are frequently associated with promoters [28], Farnham’s group and others employed arrays that represented PCR-amplified CpG islands to map binding sites for Rb, E2F, Suz12 and methylated histones [23,27,29,30]. A comprehensive list of studies that have been carried out to date appears in Table 1. These studies highlighted the potential regulatory roles mediated by the transcription factors on the target genes. Yet another theme that emerged was that the transcription factor binding sites were both prevalent and functional on non-consensus sites as well [24]. This raised the fundamental question of whether using promoter-focused arrays to study genomic transcription factor–DNA association was introducing an unjustified bias. With this in mind, Snyder’s group employed microarrays that represented virtually all the non-repetitive sequences of chromosome 22 to generate association profiles for NF-kB [31]. In addition to expected binding sites, NF-kB was found to bind many non-consensus sequences. But the most surprising result was that more than 40% of the observed binding sites were mapped to non-coding regions and pseudogenes. It could be that these biding events have no functional consequence [32] and simply

Table 1 Genome-wide protein–DNA association studies. Protein

Array type

Species

Reference

Gal4 Ste12 p53, cMyc, Sp1 RNA pol III H3 lys9 methylation CREB NfkB E2F HNF RSC ORC and MCM H2B, H3 and H4 acetylation H3 and H4 acetylation, H3 dimethylation Acetylation of H3 and H4, Di and tri- methylation of H3 SBF, NBF GATA1 cMyc, Max Rb Suz12, H3 Lys27 Rap1 HSF

Intergenic regions Intergenic regions Tiling array Ch. 21 and 22 PCR-amplified intergenic regions CpG microarrays Non-repetitive chromosome 22 sequences Tiling array chromosome 22 CpG Island; PCR amplified intergenic regions 13 000 Promoter regions Intergenic regions Intergenic sequences and open reading frames Intergenic regions Intergenic and coding regions cDNA array and non-repetitive sequence from chromosome 2L Intergenic regions Tiling array, b-globin locus Intergenic regions CpG microarray Tiling, CpG island and oligonucleotide promoter arrays ORFs and intergenic regions Intergenic regions

S. cerevisiae S. cerevisiae Human S. cerevisiae Human Human Human Human Human S. cerevisiae S. cerevisiae S. cerevisiae S. cerevisiae Drosophila

[10] [10,55] [15] [56] [30] [57] [31] [29,58] [59] [60] [61] [62] [63] [64]

S. cerevisiae Human Human Human Human S. cerevisiae S. cerevisiae

[16] [22] [25] [23] [27] [65] [66]

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reflect the fact that these sequences exist in the cell and transcription factor binding to them is not detrimental and therefore has not been selected against. To test this idea, Cawley et al. [15] asked if these sites of activator binding were also sites of transcription. The authors combined tiled arrays across non-repeat genomic sequences of chromosomes 21 and 22 with chromatin immunoprecipitation to map occupancy sites for Sp1, cMyc and p53. Only about one-fifth of the sites mapped were coincident with promoters while one-third of the binding sites were in non-coding regions. They further demonstrated that the non-coding sites associated with transcription factors were regulatory regions for noncoding RNA (nc-RNA). Comparison of binding and expression studies revealed that these transcription-factor binding sites and the corresponding nc-RNAs were evolutionarily constrained in the human and mouse genomes. Further work by the authors suggests that expression of these non-coding RNAs is regulated by the bound transcription factors in response to external stimuli. By the time Cawley et al. [15] undertook their research, existing evidence suggested that non-translated RNAs are actively transcribed, accounting for 98% of the entire transcriptional activity of a cell [33,34]. This suggested that non-coding DNA may be endowed with critical regulatory functions, which is supported by their evolutionary conservation [34–36] and their association with development and diseases [37–41]. The significance of Cawley’s observation lies in the finding that transcription from nc-RNA is regulated in the same manner as that of the coding regions, and this was achieved by integrating ChiP to chip assay with expression studies. Another useful application of ChIP to chip assays is the analysis of the effect of post-translational modifications on DNA-associated proteins. This has been brought to bear most powerfully for mapping the distribution of modified histones in the genome and correlating these data with patterns of gene expression derived using microarrays in their ‘traditional’ way [18,27,42]. These types of studies are bound to increase in importance as we discover further post-translational modifications of functional consequence in regulating transcription and as better antibodies become available to recognize modified proteins or the modifications themselves. Post-translational modifications of DNA-binding proteins are often reversible and sometimes result in epigenetic regulations such as positional effects [43], gene silencing [44,45], and global demethylation and methylation [46]. Because these effects are mediated by acetylases, deacetylases, methylases, etc., not surprisingly, they were also the first to be included in transcriptional profiling. Thus, genetic and chemical perturbations of histone deacetylases (HDACs) were performed to identify targets of these players [47]. For example, Grunstein’s group Current Opinion in Chemical Biology 2005, 9:38–45

generated genome-wide maps for HDAC activity by probing for sites that were hyperacetylated upon HDAC disruption [18]. Coupling association maps with genomewide expression studies allowed them to segregate direct targets from the ripple effects observed in a previous study [47]. Several groups generated histone acetylation and methylation maps [42,48] in an effort to correlate these modifications with corresponding transcriptional activity. Hyperacetylation of H3 and H4 and hypermethylation of H3 appear to be common themes employed to activate transcription; conversely, the same sites are deacetylated and hypomethylated to inactivate gene transcription [49]. Do these modifications occur on intergenic regions or the coding regions? While global correlation between methylation and demethylation clearly appears to involve the coding region [42,49], location of acetylation and deacetylation appears to be an issue. A study by Bernstein et al. [42] found the highest correlation between histone acetylation of intergenic regions and transcriptional activity. By contrast, Roh et al. [50] found that the highest acetylation levels are not associated with promoters, but the 50 coding region. Nevertheless these studies clearly demonstrate the significance of employing global mapping techniques in investigating differential effects of post-translational modifications. A direct application of such studies would be the identification of genes silenced by histone modification in carcinogenesis [30]. The significance of such profiling for transcription regulatory proteins is indisputable but such studies have been strikingly lacking. Studies on differential modification of the same protein in diseased and healthy states will provide enormous information and open up new avenues for therapy and further research.

Future directions It is a safe bet that the ChIP to chip assay, with its ability to provide a genomic view of protein–DNA interactions, will only grow in importance and utility. As mentioned above, a critical issue is the development of suitable microarrays to support these studies. Increasing commercial interest in the ChIP to chip application and advances in digital photolithographic synthesis of DNA microarrays [51,52] will speed progress. Another issue, common to almost all aspects of proteomics, is the need for large numbers of high affinity and high specificity protein-binding agents. ChIP to chip assays can only be performed when good antibodies are available. This application is particularly demanding, since the antibody must be capable of recognizing the native protein. Many antibodies, even those that work well for western blots, fail this more rigorous test. Again, however, it is fortunate that major strides are being made in higher-throughput antibody production [53]. Another issue, which is perhaps less obvious, is the need for alternative protein–DNA cross-linking methodologies. The use of formaldehyde has two limitations. First, because this reagent cross-links both proteins with each www.sciencedirect.com

Genomic studies of transcription factor–DNA interactions Sikder and Kodadek 43

other as well as to DNA, ChIP experiments report direct as well as indirect binding of proteins to DNA. A method that produced only protein–DNA cross-links would be a valuable complement, allowing these scenarios to be distinguished. One possibility would be laser-induced UV cross-linking [54] if conditions could be devised to reverse the cross-link, allowing the DNA to be amplified. Another problem with using formaldehyde, a general fixative, is so much material is cross-linked to the DNA that it is extremely difficult to employ restriction enzymes to digest the chromatin sample. This is unfortunate, since cleavage of the chromatin at specific positions would greatly increase the resolution of the technique. Physical shearing of the DNA produces random fragments with an average size of  500 bp, defining the limit of the resolution of the current method. This is a particularly important issue in organisms such as yeast with relatively compact genomes.

Conclusion In summary, the development of the ChIP to chip assay has provided an extraordinarily powerful tool for the analysis of DNA–protein interactions in living cells or tissues on a global scale. In the near future, further advances in microarray construction and the increased availability of useful antibodies will increase the utility of this approach even more. Genomic profiling of transcription factor-binding sites, histone modifications, etc. will almost certainly emerge as a central tool in understanding the systems biology of gene regulation in eukaryotic cells. In addition, studies of the genomic distribution of nuclear proteins that are not sequence-specific DNA binders, such as general transcription machinery, the proteasome and its component pieces, DNA replication and repair complexes, etc. will shed new light on fundamental aspects of basic genome function and maintenance. Already, the realization that the majority of transcription factors examined to date are localized outside of promoter sequences has contributed significantly to our growing realization of the importance of abundant non-coding small RNAs in the cell.

Acknowledgements Work in our laboratory on genomic analysis of transcription proteins was funded by a grant from the National Institute of Health GM066380 and the NHLBI UT-Southwestern Center for Proteomics Research Contract (NO1-HV-28185).

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