High-throughput data used in bioinformatics

Slides:



Advertisements
Similar presentations
Gene Regulation in Eukaryotic Cells. Gene regulation is complex Regulation, and therefore, expression of a gene is complex. Regulation of these genes.
Advertisements

Gregor Mendel ( ) DNA (gene) mRNA Protein Transcription RNA processing (splicing etc) Translation Folding Post translational modifications Peptides/amino.
Transcriptional-level control (10) Researchers use the following techniques to find DNA sequences involved in regulation: – Deletion mapping – DNA footprinting.
Lecture 4: DNA transcription
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.
Molecular Genetics DNA RNA Protein Phenotype Genome Gene
D. Cell Specialization: Regulation of Transcription Cell specialization in multicellular organisms results from differential gene expression.
Chapter 19: Eukaryotic Genomes Most gene expression regulated through transcription/chromatin structure Most gene expression regulated through transcription/chromatin.
Control of Gene Expression Eukaryotes. Eukaryotic Gene Expression Some genes are expressed in all cells all the time. These so-called housekeeping genes.
Introns and Exons DNA is interrupted by short sequences that are not in the final mRNA Called introns Exons = RNA kept in the final sequence.
Biology 1060 Chapter 17 From Gene to Protein. Genetic Information Important: Fig Describe how genes control phenotype –E.g., explain dwarfism in.
Regulation of Gene Expression
Eukaryotic Gene Control. Developmental pathways of multicellular organisms: All cells of a multicellular organism start with the same complement of DNA.
Regulation of Gene Expression Eukaryotes
Regulation of Gene Expression Chapter 18. Warm Up Explain the difference between a missense and a nonsense mutation. What is a silent mutation? QUIZ TOMORROW:
AP Biology Control of Eukaryotic Genes.
Regulating Eukaryotic Gene Expression. Why change gene expression? Different cells need different components Responding to the environment Replacement.
Copyright © 2009 Pearson Education, Inc. Regulation of Gene Expression in Eukaryotes Chapter 17 Lecture Concepts of Genetics Tenth Edition.
Eukaryotic Genomes  The Organization and Control of Eukaryotic Genomes.
REVIEW SESSION 5:30 PM Wednesday, September 15 5:30 PM SHANTZ 242 E.
Chapter 19 The Organization & Control of Eukaryotic Genomes.
Outline Molecular Cell Biology Assessment Review from last lecture Role of nucleoporins in transcription Activators and Repressors Epigenetic mechanisms.
Molecules and mechanisms of epigenetics. Adult stem cells know their fate! For example: myoblasts can form muscle cells only. Hematopoetic cells only.
Different microarray applications Rita Holdhus Introduction to microarrays September 2010 microarray.no Aim of lecture: To get some basic knowledge about.
TRANSCRIPTION (DNA → mRNA). Fig. 17-7a-2 Promoter Transcription unit DNA Start point RNA polymerase Initiation RNA transcript 5 5 Unwound.
The Code of Life: Topic 4 Regulation of gene expression.
Regulation of gene expression Fall, Gene Expression Regulation in Prokaryotes it includes : Control of transcription, little on translation How.
Gene Regulation, Part 2 Lecture 15 (cont.) Fall 2008.
Gene Expression: Prokaryotes and Eukaryotes AP Biology Ch 18.
(3) Gene Expression Gene Expression (A) What is Gene Expression?
Control of Gene Expression
Regulation of Gene Expression
Gene Expression.
Gene Expression 3B – Gene regulation results in differential gene expression, leading to cell specialization.
Transcription and Gene Regulation
Chapter 15 Controls over Genes.
Control of Gene Expression
Regulation of Gene Expression by Eukaryotes
GENE REGULATION Key control mechanism for dictating cell phenotype
Gene Regulation Ability of an organisms to control which genes are present in response to the environment.
Topic 7: The Organization and Control of Eukaryotic Genomes
SGN22 Regulation of Eukaryotic Genomes (CH 15.2, 15.3)
Molecular Mechanisms of Gene Regulation
Concept 18.2: Eukaryotic gene expression can be regulated at any stage
Gene Regulation.
Daily Warm-Up Thursday, January 9th
Genome organization and Bioinformatics
Chapter 18: Regulation of Gene Expression
Relationship between Genotype and Phenotype
Relationship between Genotype and Phenotype
Regulation of Gene Expression
Agenda 3/16 Eukaryotic Control Introduction and Reading
Control of Eukaryotic Genes
Review Warm-Up What is the Central Dogma?
7.2 Transcription & Gene Expression
Review Warm-Up What is the Central Dogma?
Review Warm-Up What is the Central Dogma?
Unit III Information Essential to Life Processes
T--A--C--A--A--G--T--A--C-- T--T--G--T--T--T--C--T--T--A--A—A
Using the genome Studying expression of all genes simultaneously
Mechanisms and Consequences of Alternative Polyadenylation
The Structure of the Genome
Epigenetics modification
Proteins Kinases: Chromatin-Associated Enzymes?
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:
Role of histone modification in transcription. Development imprinting.
Eukaryotic Gene Regulation
7.2 Transcription and gene expression
Relationship between Genotype and Phenotype
Epigenetic mechanisms and the development of asthma
Presentation transcript:

High-throughput data used in bioinformatics physical distance between enhancers and their target gene promoters (which could be upto 1 Mb apart) genome compartmentization location specific effect on expression DNA methylation histone modification mutations gene duplication genome rearrangement essential biological processes gene regulation networks phylogenomic relationships High-throughput data used in bioinformatics Epigenetic Genomic Whole exome sequencing Transcripto-mic Ribosome profiling Proteomic Protein and RNA Structure Cistromic Genome architecture somatic mutations in coding regions alternatively spliced isoforms Fig. ? Major types of high-throughput data and their key information relevant to drug discovery. genome-wise binding sites of proteins (e.g., transcription factors) differential gene regulation somatic mutation alternative splicing different transcription start and termination sites binding and docking properties location of charged residues for electrostatic interactions enzyme-substrate and ligand-protein interactions translation regulation translation mechanisms (e.g., cap-dependent or internal ribosomal entry) differential translation initiation, elongation and termination translation rate of individual proteins differential protein abundance posttranslational modification signal peptide and cellular localization

Applications of data Molecular biology Molecular evolution Molecular phylogenetics Molecular ecology Developmental biology Biomedical sciences Biopharmaceutical sciences Genetics/epigenetics ……

Recruiting methyl-CpG binding proteins Negatively charged DNA backbone wrapping tightly around histone CpG DNA methylation LM: bisulfite sequencing BQ: what is the methylation signal? Why some CpG methylated and some not? Flanking signal or trans-acting factors or both? Gene on/off Recruiting deacetylase to restore positive charge to histone (hypothetical) negatively charged epigenetic writer, reader or eraser DNA/protein binding mediated by DNA methylation, methy-CpG binding proteins, acetylation/deacetylation, and electrostatic interaction LM: ChIP-on-chip, ChIP-Seq BQ: What are the signals on protein binding sites at sequence and structural level? What is the spatial (tissue- or cell-specific) and temporal (developmental) pattern of protein/DNA binding? What is the effect of changed electric charge of histone through acetylation/deacetylation affect electrostatic interaction with other DNA-binding proteins Fig. ? A general framework of epigenetic effects on gene expression, through 1) DNA methylation and histone acetylation/deacetylation, 2) alteration of DNA-binding proteins and consequent protein-DNA and protein-protein interactions, and 3) alteration of long-distance interactions such as enhancer-promotor interactions. LM – laboratory method, BQ: sample bioinformatic questions. - + Histone deacetylated DNA Alteration of long-distance interaction patterns changes genome architecture (e.g., enhancers and promoters far apart along the genome are brought together) LM: Hi-C BQ: How much variation in gene expression can be explained by its physical location? What genes tend to be spatially associated? What genes tend to change its physical location in response to intra- and extracellular environment? DNA enhancer Protein complex bringing the two together promoter