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Computational Biology

Computational Biology. June 24, 2004 MUPGRET Workshop. Overview. Math Statistics Computer Models Bioinformatics. Math and Science. Mathematics are an integral part of science. Used everyday by bench scientists to perform experiments, interpret data, and make predictions. Math Examples.

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Computational Biology

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  1. Computational Biology June 24, 2004 MUPGRET Workshop

  2. Overview • Math • Statistics • Computer Models • Bioinformatics

  3. Math and Science • Mathematics are an integral part of science. • Used everyday by bench scientists to perform experiments, interpret data, and make predictions.

  4. Math Examples • Making solutions • Plotting graphs • Calculating area

  5. Area calculations • NIH Image Software • http://rsb.info.nih.gov/nih-image/Default.html • Allows you to measure length, width, area, density on objects in a picture. • Free

  6. Statistics and Science • Necessity for analyzing datasets. • Experiment must be well designed to be meaningful. • Ex. replications and controls • Should know how you’ll analyze data before you start the experiment. • Means, standard deviations, and linear regression are often used.

  7. Probability • Tests the likelihood that something will or will not occur. • Used extensively in everyday life. • Las Vegas type gaming • Lotto • Insurance amortization • Decisions regarding medical treatment

  8. Everyday examples • Rolling the dice • 1 in 6 chance that you will roll a one with a single die. • (1/6)2 = 1/36 chance you will roll snake eyes. • Playing cards • 4 in 52 chance (1/13) of drawing an ace at random from a deck. • What’s the chance of a full house?

  9. Biology examples • Punnett square • Nucleotide frequencies along a gene are used to examine evolutionary forces. • Mutation rates • Testing limits and sample sizes for transgenics. • DNA forensics

  10. Computers • Data quality • Data storage • Data analysis • Data validation • Data manipulation

  11. Barcode systems

  12. The “ics” • Genomics • Proteomics • Metabolomics • Bioinformatics

  13. Bioinformatics • Revolutionized our ability to do biology in much the same way as PCR and robotics changed the bench science. • “the computational branch of molecular biology” (Bioinformatics for Dummies). • a merger of computer science and biology (Introduction to Bioinformatics)

  14. Before bioinformatics • In vivo experiments • In the living organism • In vitro experiments • In a test tube

  15. Manhattan Project • Space Program • Human Genome Project

  16. Progress towards the HGP • 1953-DNA structure • 1975-Maxim and Gilbert DNA sequencing • 1977- First genome sequenced (x174) • 1981-Human mitochondrial genome sequenced • 1984-Epstein Barr virus sequenced

  17. Progress towards the HGP • 1990- Human genome project launched • 1992-TIGR formed • 1996-High resolution map of the human genome • 1998-C. elegans genome sequenced • 1999-Drosophila genome sequenced • 2000-Draft sequence of human genome completed.

  18. Bioinformatics • Integration of computer science and biology • Applied field • Inference • Connection • Prediction

  19. The basics • DNA sequence  protein sequence • protein sequence  protein structure • protein structure  protein function

  20. Bioinformatics • Computer simulation • Data management and retrieval • Pattern recognition • Artificial intelligence

  21. Data management/retrieval • Database design and implementation • Data entry tools • Distributed computing • Querying tools www.mgdb.org

  22. Pattern Recognition • DNA sequence analysis • www.ncbi.nlm.nih • Geneology • Disease diagnosis

  23. Artificial intelligence • Software learns from the data it is given and modifies its programs to be more efficient or to be more accurate. • Proteomics software • Disease diagnostic imaging

  24. Computer Science • Algorithm-program that specifies how to solve a problem • Data structure and information retrieval • Software engineering

  25. The human side • Curation • Annotation • Quality control design

  26. Examples of utility • Determining phylogenetic relationships • Sequence similarities • Protein structure prediction • Disease diagnosis • Pharmacogenomics

  27. Detailed structure information • Requires crystallization of the protein. • Large amount of protein required. • Often time consuming. • Limiting step to high throughput. • Followed by X-ray crystallography or NMR. • Determines position of each atom in the molecule.

  28. A Rational Approach • Christendat et al. 2000. Nat. Struct. Biol. 7:903-908. • Determine structure of all proteins in Methanobacterium thermoautotrophicum. • 1871 ORFs

  29. The dilemma • Cell membrane is “semipermeable” and comprised of phospholipids. • Only hydrophobic molecules can pass through cell membranes. • Conversely, no charged (polar) molecules. • Water can pass through membranes. • Water is a polar molecule.

  30. Aquaporin-1 • First water channel protein cloned. • Water travels through aquaporin rather than phospholipid bilayer. • Water can pass through but protons can’t. • Membrane potential • Hydrogen gradients

  31. Aquaporin • But protons can move along a column of water so how does aquaporin prevent this? • Monomer has 269 aa with 6 membrane spanning domains. • Heterotetramer is the functional molecule.

  32. Aquaporin • Protein has a hourglass shape. • The narrowest place is 3.0 A wide (water is 2.8 A). • Passage is lined with hydrophobic aa that help exclude other small charged molecules. • Predicts one water molecule passes through at a time. • Hydrogen bond between molecules is transferred to two asparagine molecules. Fig. 6.11

  33. Prions • Proteins that can change shape. • And make other proteins change their shape! • As number of changed proteins increases a phenotype is observed. • Causal agent of mad cow disease, scrapie in sheep and Creutzfeldt-Jakob disease in humans.

  34. Prions II • Previously thought only nucleic acid encoded changes caused disease. • Stanley Prusiner discovered prion’s ability to change other protein’s structure and won the Nobel Prize. • Sup35 is a prion-like protein in yeast.

  35. Sup35 • Translation termination factor • Carboxyl end binds to the ribosomal complex to terminate translation. • If Sup35 is converted to an alternate conformation (infectious prion conformation) the shape change spreads throughout the cell and is passed to daughter cells.

  36. Sup35 • In prion conformation causes ribosomes to read through stop codons altering shape and function of proteins. • Fig. 6.13 • Not adaptively advantageous so why is it maintained?

  37. Why? • True et al. 2000. Nature 407: 477-483. • Reduced translation fidelity, extends proteins. • Some of these are antibiotic resistant. • Could lead to stabilization of new phenotype under correct environment.

  38. Introduction to Bioinformatics • www.oup.com/uk/lesk/bioinf

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