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EDACC Quality Characterization for Various Epigenetic Assays Cristian Coarfa Bioinformatics Research Laboratory Molecular and Human Genetics Data Types Submitted To EDACC • • • • • • • • ChIP-Seq Methyl-C RRBS MRE-Seq MeDIP-Seq Chromatin Accessibility small RNA-Seq mRNA-Seq Quality Characterization How to measure the quality of mapped reads? Note: not quality of sequencing statistics on this are provided by the sequencer Most labs do some sort of visual inspection Metrics for characterizing level 2 data quality Apply it to various data types submitted to EDACC Enrichment Based Protocols ChIP-Seq, MeDIP-Seq, Chromatin Accessibility Methods implemented – PTIH (percent tags in hotspots) – iROC (integral of ROC) – Percent tags in peaks (FindPeaks) – Poisson enrichment metric Implemented in EDACC pipeline – Metrics computed on all submitted data PTIH (percent tags in hotspots) • Detect enriched regions using “hotspot” algorithm • PTIH = percentage of all tags that fall in hotspots Hotspot algorithm Scan statistic gauging enrichment with a z-score based on the binomial distribution. n tags 250 bp 50kb N tags Binomial distribution gives probability of seeing n tags in the small window given N tags total in the large window. This adjusts for local background fluctuations (due to CNV, for instance). PTIH values 0.48 0.19 0.72 0.48 PTIH values 0.48 0.19 0.72 0.48 Ratio of Tags in Peaks • Determine uniquely mapping reads • Use FindPeaks to call peaks • Count reads mapping into peaks – percentage of total mapped reads Poisson Based Enrichment Method • • • • • Determine uniquely mapping reads Remove duplicate reads Bin the reads into 1kb windows Infer parameters of a simple poisson distribution Filter enriched windows – p-value < 0.01 • Count reads mapping into enriched windows Next Step – Metrics Evaluation • • Metrics probe different features of data Use visual inspection to ascertain which (one or more) of the proposed methods captures useful aspects of data quality. ChIP-Seq/Chromatin Accessibility/FindPeaks QC Metrics • Collaborative efforts between centers • ~330 lanes of verified ChIP-Seq, MeDIPSeq, and Chromatin accesibility data • Accesible in Epigenome Atlas Going forward EDACC will run continuously on all submitted data Option to automatically flag data that fall below specified thresholds Include QC metrics in metadata For most data types we need further experience on what thresholds make sense Provide downstream users with this information Note that we are breaking new ground uniform quality scoring is not being performed by other major consortia (ENCODE, modENCODE) Pearson correlation for ChIP-Seq Histone Modification • Using raw density maps at 10kb resolution • Process – – – – – Select uniquely mapping reads Extend 200bp in mapping strand direction Remove monoclonal reads Build density map Pearson correlation with other submitted marks • Ideally: a mark correlates best with other experiments for the same assay • How well does Pearson correlation work ? – Help us identify 5 bad lanes, REMCs retracted the data PCA Analysis • 10kb windows on chr20 • PCA using Pearson correlation metric Input H3K36me3 H3K9me3 H3K79me1 H3K20me1 Pearson correlation metric H3K27me3 PCA 53.8% H3K4me3 H3K9ac H2AK5ac H2BK120ac H2BK12ac H2BK15ac H2BK20ac H3K14ac H3K18ac H3K23ac H3K27ac H3K4ac H3K56ac H4K5ac H4K8ac H4K91ac MRE-Seq • Reads are mapped onto reference genome • Uniquely mapping reads are kept • Build the fragment map of expecting mapping locations – based on the enzyme cocktail used • Count reads mapping within the expected digest fragments • 76-99% of reads map within expected fragment mRNA-Seq • • • • Reads are mapped onto reference genome Uniquely mapping reads are kept Count reads mapping within UCSC genes exons 70-90% of reads map within gene exons – UCSC known genes – Entrez genes Small RNA-Seq • • • • Trim adaptors Reads are mapped onto reference genome Reads mapping up to 100 locations are kept Count reads overlapping with known small RNAs – miRNAs, piRNAs, sno/scaRNAs, piRNAs, repeat RNAs • At least 30% of reads overlap with known small RNAs Bisulfite Sequencing • Map using Pash • Methyl-C – Genome wide – QC • C->T Conversion rates; typically 99% • RRBS – Enzyme cocktail – QC • Map within expected cut sites • Ratio varies 40%-90% QC for MeDIP-Seq Data Using Galaxy Exercise • Download the input MeDIP-Seq file from the workshop wiki • Determine the ratio of reads in peaks using FindPeaks in Galaxy