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Transcript
Lola Rouvinez Mentor : Michael Frochaux RNA Polymerase II analysis in Drosophila Melanogaster Aim Most of the differences in nucleotides between organisms are situated in noncoding DNA regions. These non coding regions affect the expression levels of genes thus making phenotypes depending more on differential expression rather than genes mutation. This project aim is to study the behaviour of RNA polymerase II in different Drosophila melanogaster strain. RNA Polymerase II role The RNA polymerase II (RNA Pol II) is the enzymes that transcribes the DNA into messenger RNA (mRNA). The binding of the RNA Pol II to the gene, is dependant on other proteins called transcription of a gene by helping the polymerase to bind. By modulating the binding events, these factors modulate the expression of the gene where the Polymerase can start to transcribe the gene. Methods 1) ChIP The principle is that DNA-binding proteins in cells are cross-linked to the DNA that they are binding. By using a specific antibody, we can immunoprecipitate the protein–DNA complex. After the crosslinking, the cells are bursted and the DNA is broken into pieces by sonication. The DNA is purified with an antibody -pol II, then they are heated to reverse the crosslinking, and the DNA is separated from the proteins. We then verify the enrichment in the region, that we are interested in is targeted by a qPCR. 2) Bioinformatic The analysis pipeline is as follow a) b) c) d) Alignement to reference genome with bowtie2 Peak Calling with HOMER Peak profiling with HOMER Visualisation with UCSC genome browser Setup : the analysis was performed on Anti-RNA Pol II sample. Results RNA Pol II ChIP-seq analysis 1234 Agarose gel of the sonicated chromatin The smear of the chromatin extend from 200bp to 2000bp indicating a successful sonication. The target fragment length for library preparation is 200 bp, thus the amount of DNA to be extracted must be higher to compensate for the loss due to high length fragment. Legend : 1. anti-Cad chromatin 2. anti-Pol II chromatin 3. anti-Rel chroatin 4. Ladder Quantification of the DNA extracted 140317 Concentration unit ng/mL Pol II IP Pol II 1% input Pol II chrom 1 Pol II chrom 2 dilution 0,64 2,22 6,46 74,3 Concentration Volume ng/uL uL 103 0,06592 104 0,23088 105 0,6783 106 7,8758 Total amount ng 52 3,42784 53 12,23664 54 36,6282 55 433,169 Quantification of the DNA extracted The amount yielded is sufficient for library preparation although we have to take into account that some of this DNA is too big to be sequenced. Enrichment Sample Primer 140317 Pol II Fer1_0 140317 Pol II Fer1_1 140317 Pol II ChIP-Neg Adjsuted Pull down Enrichment Input over CN 18,441452 1,9165892606 4,2074248401 17,776681 1,1996492777 0,2827835297 11,2934685 0,4555254897 Enrichment of Fer1HCH genes show enrichment in Pol II binding region versus non binding region ChIP-Neg. Analysis of RNA Pol II binding sites Tags distribution near Pol II peaks This figure shows the distribution of tags near the RNA Pol II separated by their presence on either the positive strand and the negative strand. Combining the tags and looking at both the control and the IP experiment, we obtain the following figure. RNA Pol II peak profile Visualisation of Pol II ChIP-seq in UCSC genome browser Fer1HCH, used to measure the enrichment, show a highly enriched profile througout the gene, hinting that the gene was completely expressed Per exhibit a peak at the beginning of the coding region (TSS) but not afterwards. The gene expression is probably temporary posed. Discussion The enrichment and the profiling of RNA Pol II ChiP-seq are satisfying although the sonication leads to a large array of fragments. It could be useful to test different sonication protocol to optimize the process. The peak profiling of the RNA Pol II shows the expected pattern, showing that the data can be trusted. The visualisation in the genome browser is interesting to get some information, but it is less than sufficient. Moreover, the data only show a snapshot of the regulation and more experiment are needed to obtain a significant depth for the analysis. Conclusion Although the information provided by the RNA Pol II ChIP-seq is good, to obtain a better understanding of the regulation of genes, other experiments such as RNA-seq and chromatin mark ChIP-seq would complement perfectly this analysis. Finally I am grateful to the foundation « Schweizer Jugend Forscht » for this amazing opportunity and also to my mentor who helped me a lot to do this project.
