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Course Sequence Analysis for Bioinformatics Master’s Bart van Houte, Radek Szklarczyk, Victor Simossis, Jens Kleinjung, Jaap Heringa

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Presentation on theme: "Course Sequence Analysis for Bioinformatics Master’s Bart van Houte, Radek Szklarczyk, Victor Simossis, Jens Kleinjung, Jaap Heringa"— Presentation transcript:

1 Course Sequence Analysis for Bioinformatics Master’s Bart van Houte, Radek Szklarczyk, Victor Simossis, Jens Kleinjung, Jaap Heringa heringa@cs.vu.nl, http://ibivu.cs.vu.nl, Tel. 47649, Rm R4.41

2 Sequence Analysis course schedule Lectures [wk 45] 01/11/04 IntroductionLecture 1 [wk 45] 04/11/04 Sequence Alignment 1Lecture 2 [wk 46] 08/11/04 Sequence Alignment 2Lecture 3 [wk 46] 11/11/04 Sequence Alignment 3Lecture 4 [wk 47] 15/11/04 Multiple Sequence Alignment 1Lecture 5 [wk 47] 18/11/04 Multiple Sequence Alignment 2Lecture 6 [wk 48] 22/11/04 Multiple Sequence Alignment 3Lecture 7 [wk 48] 25/11/04 Sequence Databank Searching 1Lecture 8 [wk 49] 29/11/04 Sequence Databank Searching 2Lecture 9 [wk 49] 02/12/04 Pattern Matching 1Lecture 10 [wk 50] 06/12/04 Pattern Matching 2Lecture 11 [wk 50] 09/12/04 Genome AnalysisLecture 12 [wk 51] 13/12/04 (lecture rm TBA) Phylogenetics/OverviewLecture 13

3 Sequence Analysis course schedule Practical assignments There will be four practical assignments you will have to carry out. Each assignment will be introduced and placed on the IBIVU website: 1.Pairwise alignment (DNA and protein) (Victor/Radek) 2.Multiple sequence alignment (insulin family) (Victor) 3.Pattern recognition (Jens) 4.Database searching (Jens) Optionally, you can further do an assignment on programming your own sequence analysis method (assignment ‘Dynamic programming’ supervised by Bart). This assignment will give you bonus points for your final mark but is not required.

4 Sequence Analysis course final mark TaskFraction 1.Oral exam 1/2 2.Assignment Pairwise alignment1/8 3.Assignment Multiple sequence alignment 1/8 4.Assignment Pattern recognition1/8 5.Assignment Database searching1/8 6.Optional assignment 1/8 (bonus) Dynamic programming

5 Bioinformatics staff for this course Jens Kleinjung – UD (1/11/02) Victor Simossis – PhD (1/12/02) Radek Szklarczyk - PhD (1/03/03) Bart van Houte – PhD (1/09/04) Jaap Heringa – Grpldr (1/10/02)

6 Gathering knowledge Anatomy, architecture Dynamics, mechanics Informatics (Cybernetics – Wiener, 1948) (Cybernetics has been defined as the science of control in machines and animals, and hence it applies to technological, animal and environmental systems) Genomics, bioinformatics Rembrandt, 1632 Newton, 1726

7 Mathematics Statistics Computer Science Informatics Biology Molecular biology Medicine Chemistry Physics Bioinformatics

8 “Studying informational processes in biological systems” (Hogeweg, early 1970s) No computers necessary Back of envelope OK Applying algorithms with mathematical formalisms in biology (genomics) -- USA “Information technology applied to the management and analysis of biological data” (Attwood and Parry-Smith)

9 Bioinformatics in the olden days Close to Molecular Biology: –(Statistical) analysis of protein and nucleotide structure –Protein folding problem –Protein-protein and protein-nucleotide interaction Many essential methods were created early on (BG era) –Protein sequence analysis (pairwise and multiple alignment) –Protein structure prediction (secondary, tertiary structure)

10 Bioinformatics in the olden days (Cont.) Evolution was studied and methods created –Phylogenetic reconstruction (clustering – NJ method

11 But then the big bang….

12 The Human Genome -- 26 June 2000 Dr. Craig Venter Celera Genomics -- Shotgun method Sir John Sulston Human Genome Project

13 Human DNA There are about 3bn (3  10 9 ) nucleotides in the nucleus of almost all of the trillions (3.5  10 12 ) of cells of a human body (an exception is, for example, red blood cells which have no nucleus and therefore no DNA) – a total of ~10 22 nucleotides! Many DNA regions code for proteins, and are called genes (1 gene codes for 1 protein in principle) Human DNA contains ~30,000 expressed genes Deoxyribonucleic acid (DNA) comprises 4 different types of nucleotides: adenine (A), thiamine (T), cytosine (C) and guanine (G). These nucleotides are sometimes also called bases

14 Human DNA (Cont.) All people are different, but the DNA of different people only varies for 0.2% or less. So, only 2 letters in 1000 are expected to be different. Over the whole genome, this means that about 3 million letters would differ between individuals. The structure of DNA is the so-called double helix, discovered by Watson and Crick in 1953, where the two helices are cross-linked by A-T and C-G base-pairs (nucleotide pairs – so-called Watson-Crick base pairing). The Human Genome has recently been announced as complete (in 2004).

15 Genome size OrganismNumber of base pairs  X-174 virus5,386 Epstein Bar Virus172,282 Mycoplasma genitalium580,000 Hemophilus Influenza1.8  10 6 Yeast (S. Cerevisiae)12.1  10 6 Human 3.2  10 9 Wheat16  10 9 Lilium longiflorum 90  10 9 Salamander100  10 9 Amoeba dubia670  10 9

16 Humans have spliced genes…

17 Protein mRNA DNA transcription translation CCTGAGCCAACTATTGATGAA PEPTIDEPEPTIDE CCUGAGCCAACUAUUGAUGAA A gene codes for a protein

18 Genome information has changed bioinformatics More high-throughput (HTP) applications (cluster computing, GRID, etc.) More automatic pipeline applications More user-friendly interfaces Greater emphasis on biostatistics Greater influence of computer science (machine learning, software engineering, etc.) More integration of disciplines, databases and techniques

19 Protein Sequence-Structure-Function Sequence Structure Function Threading Homology searching (BLAST) Ab initio prediction and folding Function prediction from structure

20 Luckily for bioinformatics… There are many annotated databases (i.e. DBs with experimentally verified information) We can relate biological macromolecules using evolution and then “steal” annotation of “neighbouring” proteins or DNA in the DB This works for sequence as well as structural information Problem we discuss in this course: how do we score the evolutionary relationships; i.e. we need to develop a measure to decide which molecules are (probably) neighbours and which are not

21 Modern bioinformatics is closely associated with genomics The aim is to solve the genomics information problem Ultimately, this should lead to biological understanding how all the parts fit (DNA, RNA, proteins, metabolites) and how they interact (gene regulation, gene expression, protein interaction, metabolic pathways, protein signalling, etc.)

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