Transcriptional regulatory code of a eukaryotic genome Harbison CT et al. Nature, 2004, Vol. 431, pp. 99-104 Milica Volar 3 March 2005.

Slides:

Advertisements

Similar presentations

Lecture 8 Transcription Initiation Prokaryotic Eukaryotic Reading: Chapter 4 ( ) Chapter 11 Molecular Biology syllabus web siteweb site.

Advertisements

Chromatin Immunoprecipitation and the Chip on Chip technique. Fredrik Fagerström Billai B E A- Core Facility for Bioinformatics and Expression Analysis.

Outline Questions from last lecture? P. 40 questions on Pax6 gene Mechanism of Transcription Activation –Transcription Regulatory elements Comparison between.

Combined analysis of ChIP- chip data and sequence data Harbison et al. CS 466 Saurabh Sinha.

20,000 GENES IN HUMAN GENOME; WHAT WOULD HAPPEN IF ALL THESE GENES WERE EXPRESSED IN EVERY CELL IN YOUR BODY? WHAT WOULD HAPPEN IF THEY WERE EXPRESSED.

Section 8.6: Gene Expression and Regulation

Indiana University Bloomington, IN Junguk Hur Computational Omics Lab School of Informatics Differential location analysis A novel approach to detecting.

Control of Gene Expression Big Idea 3: Living systems store, retrieve, transmit, and respond to info essential to life processes.

Bryan Heck Tong Ihn Lee et al Transcriptional Regulatory Networks in Saccharomyces cerevisiae.

Organization of DNA Within a Cell from Lodish et al., Molecular Cell Biology, 6 th ed. Fig meters of DNA is packed into a 10  m diameter cell.

ChIP-chip Data, Model and Analysis Ying Nian Wu Dept. Of Statistics UCLA Joint with Ming Zheng, Leah Barrera, Bing Ren.

Mapping protein-DNA interactions by ChIP-seq Zsolt Szilagyi Institute of Biomedicine.

Gene Expression and Regulation

Kristen Horstmann, Tessa Morris, and Lucia Ramirez Loyola Marymount University March 24, 2015 BIOL398-04: Biomathematical Modeling Lee, T. I., Rinaldi,

* only 17% of SNPs implicated in freshwater adaptation map to coding sequences Many, many mapping studies find prevalent noncoding QTLs.

Finish up array applications Move on to proteomics Protein microarrays.

ChIP-on-Chip and Differential Location Analysis Junguk Hur School of Informatics October 4, 2005.

Chromatin Immunoprecipitation DNA Sequencing (ChIP-seq)

Vidyadhar Karmarkar Genomics and Bioinformatics 414 Life Sciences Building, Huck Institute of Life Sciences.

Microarrays and Their Uses Brad Windle, Ph.D

10/17/05 D Dobbs ISU - BCB 444/544X: Genes & Genomes1 10/17/05 Genes & Genomes (formerly Gene Prediction - 1)

Outline Group Reading Quiz #2 on Thursday (covers week 5 & 6 readings Chromosome Territories Chromatin Organization –Histone H1 Mechanism of Transcription.

Eukaryotic Genomes 15 November, 2002 Text Chapter 19.

Control of Gene Expression Year 13 Biology. Exceptions to the usual Protein Synthesis Some viruses contain RNA and no DNA. RNA is therefore replicated.

Prokaryotic cells turn genes on and off by controlling transcription.

The end replication problem: -DNA polymerase requires an OH group to attach bases too -There is no OH group at the extreme 5’ end of the lagging strand.

Lecture-5 ChIP-chip and ChIP-seq

Eukaryotic Genomes 11 November, 2005 Text Chapter 19.

MCB 317 Genetics and Genomics MCB 317 Topic 10, part 6 A Story of Transcription.

Homework #2 is due 10/17 Bonus #1 is due 10/24 Exam key is online Office hours: M 10/ :30am 2-5pm in Bio 6.

STAT115 STAT225 BIST512 BIO298 - Intro to Computational Biology.

Gene Expression & Regulation Chapter 8.6. KEY CONCEPT Gene expression is carefully regulated in both prokaryotic and eukaryotic cells.

Additional high-throughput sequencing techniques (finding all functional elements of genome) June 15, 2017.

Il principio della ChIP: arricchimento selettivo della frazione di cromatina contenente una specifica proteina La ChIP può anche esser considerata.

Warm-Up (1/4) Explain how a cell expresses a gene.

PCR & visualise products on gel

Control of Gene Expression

Control of Gene Expression

Regulation of Gene Expression

Chromatin Regulation September 20, 2017.

Schematic of the Cell Cycle of Eukaryotic Cells

Control of Gene Expression

Prokaryotic cells turn genes on and off by controlling transcription.

Budding yeast has a small genome of approximately 6000 genes.

more regulating gene expression

Prokaryotic cells turn genes on and off by controlling transcription.

Regulation of Gene Expression

Regulation of Gene Expression

Chapter 12.5 Gene Regulation.

The Operon Hypothesis The Operon Hypothesis was developed by 2 researchers: Jacob and Monod It explains how genes are regulated in prokaryotes. They received.

Eukaryote Regulation and Gene Expression

RNA and Chromosome Structure

A New Map for Navigating the Yeast Epigenome

Control of Gene Expression in Eukaryotic cells

Claudia Sala, David C. Grainger, Stewart T. Cole Cell Host & Microbe

Prokaryotic cells turn genes on and off by controlling transcription.

More Division of Labor at the Eukaryotic Replication Fork

Inferring chromatin organization.

Prokaryotic cells turn genes on and off by controlling transcription.

Xinyang Zhao, P.Shannon Pendergrast, Nouria Hernandez Molecular Cell

Non coding DNA Coding Not all DNA codes for a polypeptide to be made May have another useful function Non-coding sequences of DNA e.g. STRs Another example:

Chapter 18 Bacterial Regulation of Gene Expression

Prokaryotic (Bacterial) Gene Regulation

Prokaryotic cells turn genes on and off by controlling transcription.

Prokaryotic cells turn genes on and off by controlling transcription.

Gene Regulation A gene (DNA) is expressed when it is made into a functional product (protein/enzyme)

Prokaryotic cells turn genes on and off by controlling transcription.

In vivo interaction of SAF-1 transcription factor with VEGF promoter in MDA-MB-231 cells. In vivo interaction of SAF-1 transcription factor with VEGF promoter.

Relative abundance and expression of the 10 most abundant MAGs in the bioreactor at day 96. Relative abundance and expression of the 10 most abundant MAGs.

Presentation transcript:

Transcriptional regulatory code of a eukaryotic genome Harbison CT et al. Nature, 2004, Vol. 431, pp Milica Volar 3 March 2005.

Outline of talk Background Yeast’s transcriptional regulatory map Promoter structure Regulator binding behaviour Summary

Transcriptional regulators Proteins that bind to specific promoter sequences in genome Regulate genome expression and its maintenance Cell cycle, environment changes, replication, condensation, cohesion, etc.

Procedure

Genome wide location analysis Crosslink protein to DNA in vivo with formaldehyde Break open cells and shear DNA Immunoprecipitate Reverse-crosslinks, blunt DNA and ligate to unidirectional linkers LM-PCR Labeling Hybridize to array Ren B et al, 2004

Procedure They tested the binding by GWLA: 203 (84) DNA transcriptional regulators in rich media -> 11,000 unique interactions between regulators and promoter regions at high confidence (P<0.001)

Yeast transcriptional regulatory map

3,353 interactions within 1,296 promoter regions

Promoter architectures

Regulator binding behaviour

Summary Construction of the yeast transcriptional regulatory map Promoter architectures Patterns of regulator binding behaviour