The Genome is Organized in Chromatin
Nucleosome Breathing, Opening, and Gaping
A model for gaining access to core DNA
Nucleosome movement catalyzed by nucleosome remodeling complexes alter nucleosome phasing
250 bp + SWI/SNF Position 1Position 2Chromatin remodeler 1 2 Native PAGE ATP Nucleosome Sliding
Nucleosome Sliding using Micrococcal nuclease digestion MNase core Linker T D M MNase 0.5kb 1kb
Silent vs. active chromatin show different micrococcal nuclease digestion patterns MNase Euchromatin heterochromatin More mobile nucleosome Strongly positioned nucleosome
Genome Analysis of Nucleosome Spacing linker Nucleosome
ISWI is a Nucleosome Spacing Factor The implication is that ISWI chromatin remodelers can organize chromatin into a more repressive configuration, OR a more active one Since yeast has two ISWI ATPases with different effects on chromatin in vitro, they may have evolved contrasting activities
EcoRV Bsp1286I Time In vivo nucleosome mobility assay Restriction enzyme accessibility 0 1.5’ 3’ 9’ 27’ 80’ 0’ t1
Nucleosome Positioning (Phasing) Positioning may affect which regions of DNA are in the linker and which face of DNA is exposed on the nucleosome surface Translationally Positioned Nucleosomes Displacement of the DNA by 10 bp changes the sequences that are in the more exposed linker regions but does not alter which face of the DNA is protected by the histone surface and which is exposed to the exterior regions
DNAse I digestion and chromatin remodeling
Rotational Positioning describes the ‘Exposure’ of DNA on the surface of the Nucleosome and Determines its Interactions with Proteins and other Factors. Rotational Positioning Nuclease resistant Any movement that differs from the helical repeat (~10.2 bp/turn) displaces DNA with reference to the histone Surface A translational movement of half a helical turn (e.g., 5 bp) will alter the surface exposure of a DNA sequence Nucleotides on the inside next to the histone octamer are more protected against nucleases than nucleotides on the outside.
Nucleosome movement during nucleosome remodeling alter nucleosome phasing
Histones can be modified by – Acetylation (Ac) – Ubiquitination (Ub) – Methylation (Me) – Phosphorylation (P) – Sumoylation (Su) Unwrapping of chromatin can be facilitated two phenomenon: Changes in DNA methylation within promoters, CpG islands, and genic/intergenic regions. Modification in histones or histone variants.
Histone Modification Map
Map Target Protein DNA Binding Sites and Methylated DNA Regions Using Robust Protocols Chromatin immunoprecipitation-on-chip (ChIPchip) is a powerful tool to map target protein DNA binding sites across entire genomes or within biologically important regions such as promoters. This method is used to map chromatin structure and DNA binding sites of transcription factors andpolymerases. Methylated DNA regions are accurately mapped using a combination of affinity-based enrichment, such as Methylated DNA Immunoprecipitation (MeDIP) or the Methylated CpG Island Recovery Assay (MIRA), followed by microarray analysis. CpG islands are genomic regions that contain dense clusters of CG dinucleotides that are often associated with gene promoters
Chromatin Immunoprecipitation-on-chip (ChIP-chip)
DNA Methylation (MeDIP-chip)
– A high throughput technology that allows detection of thousands of genes simultaneously – Principle: base-pairing hybridization Base-pairing – DNA: A-T and G-C – RNA: A-U and G-C – Much rely on computer aids – Central platform for functional genomics Microarray
Types of DNAmicroarraysand their uses What is measured depends on the chip design andthe laboratory protocol: –Expression Measure mRNA expression levels (usuallypolyadenylated mRNA) –Resequencing Detect changes in genomic regions of interest –Tiling Tiles probes over an entire genome for various applications (novel transcripts,ChIP, epigenetic modifications) –SNP Detect which knownSNPsare in the tested DNA
Affymetrix Microarray Gene Chips Two types of microarray chips cDNA chips: Probe cDNA (500~5,000 bases long) is immobilized oligo chip: Oligonucleotide (20~80-mer oligos) is synthesized either in situ (on-chip) or by conventional synthesis followed by on-chip immobilization
Clustering of entire yeast genome
The total genome activity of transcription factors and epigenetic modifications are far more complex than previously predicted. It is no longer sufficient to limit regulatory studies to promoter regions or defined genomic loci. To better understand the regulation of transcription, an unbiased, whole- genome approach is needed to reveals the full regulatory network activity of transcription factors and epigenetic modifications.
§ Mapping regions of transcription § Transcription factor binding sites § Sites of DNA methylation § Chromosomal origins of replication § RNA binding protein sites § LOH/ Chromosome copy numbers Affymetrix Tiling Arrays Universal Array for multiple applications
Surrogate Strategy Most expression arrays to date Annotation Strategy Exon arrays Splice variants Tiling strategy Unbiased look at the genome What is Tiling Array? Known Exons Unknown transcript 25-mer probes spaced every 35bp across an entire genome
High-Resolution Profiling of Histone Methylations in the Human Genome Histone Methylation near Transcription Start Sites
Histone Methylation Patterns of Active and Inactive Genes
ChIP on chip Cancer biology Developmental biology Immunology and infectious disease Plant research stress biology, transgenic research Application of Epigenetic control using Chip on chip