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Three-dimensional maps of folded genomes Lieberman-Aiden et al., “Comprehensive mapping of long-range interactions reveals folding principles of the human.

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Presentation on theme: "Three-dimensional maps of folded genomes Lieberman-Aiden et al., “Comprehensive mapping of long-range interactions reveals folding principles of the human."— Presentation transcript:

1 Three-dimensional maps of folded genomes Lieberman-Aiden et al., “Comprehensive mapping of long-range interactions reveals folding principles of the human genome,” Science 2009, 326(5950):289-93 Presented by Hershel Safer in the group meeting of Ron Shamir’s group on 29.12.2010. 3D maps of folded genomes – Hershel Safer129 December 2010

2 Outline Context Some biological background Experimental technique & validation Findings 3D maps of folded genomes – Hershel Safer229 December 2010

3 Conformation enables interactions Activity in the cell’s nucleus depends on physical interactions: DNA functional elements can only interact if they are physically close in 3D space. So the 3D conformation of chromosomes determines possible interactions between two loci: Folding of individual chromosomes: interactions between loci on the same chromosome (intra-chromosomal) Relative locations of chromosomes: interactions between loci on different chromosomes (inter-chromosomal) We want to understand the 3D conformation of chromosomes so that we can identify potential interactions between DNA loci. 3D maps of folded genomes – Hershel Safer29 December 20103

4 Interactions imply conformation We don’t know how to model chromosome folding & localization well enough to do a good job of predicting interactions between DNA loci. This group investigated an experimental way to identify all interactions directly rather than via computational predictions. The direction of inference therefore becomes the opposite of that described on the previous slide: We wanted to use predictions of chromosomal conformation to infer interactions between loci. Instead, we use information about interactions to infer the 3D conformation (folded shape & relative locations). Knowing the conformations is of independent interest. 3D maps of folded genomes – Hershel SaferPage 429 December 2010

5 Previous work on identifying interactions A key method for identifying interactions has been Chromosome Conformation Capture (3C) [Dekker, Science 2002]. Formaldehyde fixation is a technique for cross-linking proteins to other proteins and to DNA. Formaldehyde fixation is used to cross-link genomic loci that are touching. It does this by using contacts between proteins that are bound to the DNA. The frequency of cross-linking between given pairs of regions is then determined using a somewhat complex series of experimental reactions. One step in the process is quantitative PCR. 3D maps of folded genomes – Hershel SaferPage 529 December 2010

6 Drawback of 3C & its extensions The PCR step uses a specific primer for each locus of interest. This means that 3C can only be used to identify interactions between pre-selected loci. 3C could be used on all possible loci for a genome of known sequence, but this would be a massive & wasteful undertaking. The goal of the work described in this paper is to develop a method for performing an unbiased genome-wide analysis of interactions between DNA loci. 3D maps of folded genomes – Hershel SaferPage 629 December 2010

7 Outline Context Some biological background Experimental technique & validation Findings 3D maps of folded genomes – Hershel Safer729 December 2010

8 Polymerase chain reaction (PCR) PCR amplification creates exponentially many copies of a piece of DNA in a linear number of steps. PCR was a major enabler of the biotechnology revolution. Kary Mullis received a Nobel prize in 1993 for his work on improving the technique. http://scienceblogs.com/insolence/2007/0 6/the_autism_omnibus_the_difference_be twee.php 3D maps of folded genomes – Hershel SaferPage 829 December 2010

9 Restriction enzymes / endonucleases A restriction enzyme is like a scissors that cuts double-stranded DNA at a specific pattern (the restriction site). http://users.rcn.com/jkimball.ma.ultranet/BiologyPages/R/RestrictionEnzymes.html 3D maps of folded genomes – Hershel SaferPage 929 December 2010

10 Restriction enzymes Restriction enzymes were another enabler of the biotechnology revolution: they enable creation of recombinant DNA. http://library.thinkquest.org/04apr/00217/en/products/recdna/about.html 3D maps of folded genomes – Hershel SaferPage 1029 December 2010

11 Biotin / steptavidin purification Biotin and streptavidin form a tight, irreversible complex. A DNA fragment is created with a high- affinity binding site for a protein of interest & a biotinylated nucleotide at one end. The protein binds to the DNA. The biotin binds to streptavidin that is immobilized on a bead. Unbound protein is washed away. The remaining complexes can be used to assay for binding activity. http://www.currentprotocols.com/protocol/mb1206 3D maps of folded genomes – Hershel SaferPage 1129 December 2010

12 Fluorescence in situ hybridization (FISH) Fluorescence in situ hybridization (FISH) is used to detect the presence or absence of specific DNA sequences on chromosomes and determine where on the chromosomes the sequence is located. FISH can also be used to detect and localize specific mRNAs in tissue samples, and so can be used to determine spatio-temporal patterns of gene expression within cells and tissues. 3D maps of folded genomes – Hershel SaferPage 1229 December 2010 FISH applications include genetic counseling, medicine, and species identification. (Wikipedia: FISH) http://www.mun.ca/biology/scarr/FISH_ chromosome_painting.html

13 Outline Context Some biological background Experimental technique & validation Findings 3D maps of folded genomes – Hershel Safer1329 December 2010

14 Experimental technique 3D maps of folded genomes – Hershel SaferPage 1429 December 2010

15 The data: Catalog of interacting pairs The interacting fragments were sequenced using Illumina paired- end sequencing with 76bp reads. Reads were aligned to the human hg18 reference sequence using Maq. If both ends of a pair aligned uniquely, the pair was kept. The catalog ended up with 8.4M read pairs. Of these, 6.7M represented interactions between loci >20kb apart (i.e., long- range contacts). 3D maps of folded genomes – Hershel SaferPage 1529 December 2010

16 Validation: Reads near HindIII sites Hi-C reads align near HindIII restriction sites with the correct orientation. 3D maps of folded genomes – Hershel SaferPage 1629 December 2010

17 Validation: Biological repeats Created genome-wide contact matrix M. Divided genome into 1Mb regions, set m ij = # ligation products between loci i and j. Repeated experiment with same restriction enzyme (HindIII), got essentially the same M (Pearson’s r=0.990). Repeated again with NcoI and again got same M (r=0.814). 3D maps of folded genomes – Hershel SaferPage 1729 December 2010

18 Validation: Intra-chromosomal contacts Chromosome territories: tendency of distant loci on a chromosome to be near each other in 3D. I n (s) = Probability of contact for pair of loci separated by s base pairs on chromosome n 3D maps of folded genomes – Hershel SaferPage 1829 December 2010 Decreasing on each chromosome, but Always >> than inter- chromosomal contact probability Confirms chromosome territories

19 Validation: Inter-chromosomal contacts 3D maps of folded genomes – Hershel SaferPage 1929 December 2010

20 Outline Context Some biological background Experimental technique & validation Findings 3D maps of folded genomes – Hershel Safer2029 December 2010

21 Proximity of chromosome territories Normalized contact matrix M*: divide each entry of M by genome-wide average contact probability at same distance. Loci that are nearby in space will likely share neighbors and have correlated interaction profiles. Compute correlation matrix C with c ij = Pearson correlation between M* i. and M*. j. 3D maps of folded genomes – Hershel SaferPage 2129 December 2010

22 Correlation maps for all chromosomes 3D maps of folded genomes – Hershel SaferPage 2229 December 2010

23 Chromosomal compartments Partitioned each chromosome into sets A and B such that intra- set contacts are enriched and inter-set contacts are depleted. The first PC corresponds to the plaid pattern, except On chromosomes 4 and 5, the first PC corresponds to the two chromosome arms, the second PC to the plaid pattern. 3D maps of folded genomes – Hershel SaferPage 2329 December 2010 The plaid patterns were consistent across chromosomes—can assign A and B so that: Sets on different chromosomes with the same label had correlated profiles. Sets with different labels had anti- correlated profiles.

24 Genome-wide compartments Can partition the entire genome into two spatial compartments such that interactions tend to occur within rather than across compartments, i.e., loci tend to be closer in 3D if they are in the same compartment than if they are not. Confirmed for specific cases using FISH. The paper explores differing characteristics of the compartments such as packing density, presence of genes, expression, and chromatin accessibility. Repeated the work with a different cell line. It also displayed two compartments with similar characteristics as in the first cell line, but with some loci in different compartments. 3D maps of folded genomes – Hershel SaferPage 2429 December 2010

25 Correlation at 1Mb vs. 100kb resolution 3D maps of folded genomes – Hershel SaferPage 2529 December 2010

26 Chromatin structure within compartments I(s) = Probability of intra-chromosomal contact for loci that are s bases apart, over the entire genome The graph exhibits power-law scaling for s between 500kb and 7Mb (log-log axes), slope = -1.08. This is the known size range for open and closed chromatin domains. Polymers often exhibit power-law dependencies. 3D maps of folded genomes – Hershel SaferPage 2629 December 2010

27 Polymer structure of chromosomal compartment The predominantly accepted model has been an equilibrium globule: compact, densely knotted Alternative model is fractal globule: formed by unentangled polymer as it crumples into a series of small globules. The small globules crumple into a series of larger globules, and the process iterates. After several rounds, a single multi-level globule is formed. The fractal globule is an appealing model because it does not have knots. This facilitates unfolding & refolding as necessary during the chromosome’s activities. 3D maps of folded genomes – Hershel SaferPage 2729 December 2010

28 Globular structures Fractal: Contiguous regions of the genome form spatial areas whose size corresponds to the length of the linear region Equilibrium: Highly knotted, little correlation between linear and spatial regions 3D maps of folded genomes – Hershel SaferPage 2829 December 2010

29 Self-similarity of fractal globule 3D maps of folded genomes – Hershel SaferPage 2929 December 2010

30 Predictions based on different globule models FeatureEquilibriumFractalObserved Scaling of contact probability with genomic distance s s -3/2 s -1 s -1.08 3D distance between pairs of loci s 1/2 s 1/3 3D maps of folded genomes – Hershel SaferPage 3029 December 2010

31 Conclusions At the scale of several megabases, the data are consistent with a fractal globule model for chromatin organization rather than an equilibrium globule model. Cannot rule out other models with regular organization. Could use the same approach at higher resolution by increasing the number of reads, and so map long-range interactions between specific DNA features such as enhancers and silencers. Increasing resolution by a factor of n requires increasing the number of reads by a factor of n 2. Can do this as sequencing technology and cost improve, or can use current technology to focus on subregions. 3D maps of folded genomes – Hershel SaferPage 3129 December 2010

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