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Introduction to Algorithms in Computational Biology Lecture 1

Introduction to Algorithms in Computational Biology Lecture 1. Background Readings : The first three chapters (pages 1-31) in Genetics in Medicine, Nussbaum et al., 2001.

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Introduction to Algorithms in Computational Biology Lecture 1

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  1. Introduction to Algorithms in Computational Biology Lecture 1 Background Readings: The first three chapters (pages 1-31) in Genetics in Medicine, Nussbaum et al., 2001. This class has been edited from Nir Friedman’s lecture which is available at www.cs.huji.ac.il/~nir. Changes made by Dan Geiger. .

  2. Course Information Meetings: • Lecture, by Dan Geiger: Mondays 16:30 –18:30, Taub 4. • Tutorial, by Ydo Wexler: Tuesdays 10:30 – 11:30, Taub 2. Grade: • 20% in five question sets. These questions sets are obligatory. Each contains 4-6 theoretical problems. Submit in pairs in two weeks time • 80% test. Must pass beyond 55 for the homework’s grade to count Information and handouts: • www.cs.technion.ac.il/~cs236522 • A brochure with zeroxed material at Taub library

  3. Course Prerequisites Computer Science and Probability Background • Data structure 1 (cs234218) • Algorithms 1 (cs234247) • Probability (any course) Some Biology Background • Formally: None, to allow CS students to take this course. • Recommended: Biology 1 (especially for those in the Bioinformatics track), or a similar Biology course, and/or a serious desire to complement your knowledge in Biology by reading the appropriate material (see the course web site). Studying the algorithms in this course while acquiring enough biology background is far more rewarding than ignoring the biological context.

  4. Relations to Some Other Courses Intro to Bioinformatics (cs236523). This course covers practical aspects and hands on experience with web-based bioinformatics Software. Albeit not a formal requirement, it is recommended that you look on the web site http://webcourse.technion.ac.il/234523/ and examine the relevant software. Algorithms in Computational Biology (cs236522). This is the current course which focuses on modeling some bioinformatics problems and presents algorithmsfor their solution. Bioinformatics project (cs5236524).Developing bioinformatics tools under close guidance.

  5. First Homework Assignment Read carefully the first three chapters (pages 1-31) in Genetics in Medicine, Nussbaum et al., 2001. Solve two of the questions for Chapter 2 and two of the questions for Chapter 3. Due time: During the third tutorial class, or earlier in the teaching assistant’s mail slot. Recall to submit in pairs.

  6. Computational Biology Computational biology is the application of computational tools and techniques to (primarily) molecular biology.  It enables new ways of study in life sciences, allowing analytic and predictive methodologies that support and enhance laboratory work. It is a multidisciplinary area of study that combines Biology, Computer Science, and Statistics. Computational biology is also called Bioinformatics, although many practitioners define Bioinformatics somewhat narrower by restricting the field to molecular Biology only.

  7. Examples of Areas of Interest • Building evolutionary trees from molecular (and other) data • Efficiently assembling genomes of various organisms • Understanding the structure of genomes (SNP, SSR, Genes) • Understanding function of genes in the cell cycle and disease • Deciphering structure and function of proteins

  8. Exponential growth of biological information: growth of sequences, structures, and literature.

  9. Four Aspects Biological • What is the task? Algorithmic • How to perform the task at hand efficiently? Learning • How to adapt/estimate/learn parameters and models describing the task from examples Statistics • How to differentiate true phenomena from artifacts

  10. Example: Sequence Comparison Biological • Evolution preserves sequences, thus similar genes might have similar function Algorithmic • Consider all ways to “align” one sequence against another Learning • How do we define “similar” sequences? Use examples to define similarity Statistics • When we compare to ~106 sequences, what is a random match and what is true one

  11. Course Goals • Learning about computational tools for (primarily) molecular biology. • We will cover computational tasks that are posed by modern molecular biology • We will discuss the biological motivation and setup for these tasks • We will understand the kinds of solutions that exist and what principles justify them

  12. Topics I Dealing with DNA/Protein sequences: • Finding similar sequences • Models of sequences: Hidden Markov Models • Gene finding • Genome projects and how sequences are found

  13. Topics II Models of genetic change: • Long term: evolutionary changes among species • Reconstructing evolutionary trees from sequences • Short term: genetic variations in a population • Finding genes by linkage and association

  14. Topics III (One class, if time allows) Protein World: • How proteins fold - secondary & tertiary structure • How to predict protein folds from sequences data • How to analyze proteins changes from raw experimental measurements (MassSpec)

  15. Human Genome Most human cells contain 46 chromosomes: • 2 sex chromosomes (X,Y): XY – in males. XX – in females. • 22 pairs of chromosomes named autosomes.

  16. DNA Organization Source: Alberts et al

  17. The Double Helix Source: Alberts et al

  18. DNA Components Four nucleotide types: • Adenine • Guanine • Cytosine • Thymine Hydrogen bonds (electrostatic connection): • A-T • C-G

  19. Genome Sizes • E.Coli (bacteria) 4.6 x 106 bases • Yeast (simple fungi) 15 x 106 bases • Smallest human chromosome 50 x 106 bases • Entire human genome 3 x 109 bases

  20. Genetic Information • Gene – basic unit of genetic information. They determine the inherited characters. • Genome – the collection of genetic information. • Chromosomes – storage units of genes.

  21. Genes The DNA strings include: • Coding regions (“genes”) • E. coli has ~4,000 genes • Yeast has ~6,000 genes • C. Elegans has ~13,000 genes • Humans have ~32,000 genes • Control regions • These typically are adjacent to the genes • They determine when a gene should be expressed • “Junk” DNA (unknown function)

  22. The Cell All cells of an organism contain the same DNA content (and the same genes) yet there is a variety of cell types.

  23. Example: Tissues in Stomach How is this variety encoded and expressed ?

  24. Transcription Translation mRNA Protein Gene Central Dogma שעתוק תרגום cells express different subset of the genes In different tissues and under different conditions

  25. Transcription • Coding sequences can be transcribed to RNA • RNA nucleotides: • Similar to DNA, slightly different backbone • Uracil (U) instead of Thymine (T) Source: Mathews & van Holde

  26. Transcription: RNA Editing • Transcribe to RNA • Eliminate introns • Splice (connect) exons • * Alternative splicing exists Exons hold information, they are more stable during evolution. This process takes place in the nucleus. The mRNA molecules diffuse through the nucleus membrane to the outer cell plasma.

  27. RNA roles • Messenger RNA (mRNA) • Encodes protein sequences. Each three nucleotide acids translate to an amino acid (the protein building block). • Transfer RNA (tRNA) • Decodes the mRNA molecules to amino-acids. It connects to the mRNA with one side and holds the appropriate amino acid on its other side. • Ribosomal RNA (rRNA) • Part of the ribosome, a machine for translating mRNA to proteins. It catalyzes (like enzymes) the reaction that attaches the hanging amino acid from the tRNA to the amino acid chain being created. • ...

  28. Translation (Outside the nucleolus) • Translation is mediated by the ribosome • Ribosome is a complex of protein & rRNA molecules • The ribosome attaches to the mRNA at a translation initiation site • Then ribosome moves along the mRNA sequence and in the process constructs a sequence of amino acids (polypeptide) which is released and folds into a protein.

  29. Genetic Code There are 20 amino acids from which proteins are build.

  30. Protein Structure • Proteins are poly-peptides of 70-3000 amino-acids • This structure is (mostly) determined by the sequence of amino-acids that make up the protein

  31. Protein Structure

  32. Evolution • Related organisms have similar DNA • Similarity in sequences of proteins • Similarity in organization of genes along the chromosomes • Evolution plays a major role in biology • Many mechanisms are shared across a wide range of organisms • During the course of evolution existing components are adapted for new functions

  33. Evolution Evolution of new organisms is driven by • Diversity • Different individuals carry different variants of the same basic blue print • Mutations • The DNA sequence can be changed due to single base changes, deletion/insertion of DNA segments, etc. • Selection bias

  34. The Tree of Life Source: Alberts et al

  35. One Answer (the parsimony principle): Pick a tree that has a minimum total number of substitutions of symbols between species and their originator in the evolutionary tree (Also called phylogenetictree). AAA AAA AAA 2 1 1 GGA AGA AAG AAA Total #substitutions = 4 Example for Phylogenetic Analysis Input: four nucleotide sequences: AAG, AAA, GGA, AGA taken from four species. Question: Which evolutionary tree best explains these sequences ?

  36. AAA AAA 1 AAA AAA AGA AAA 1 2 1 1 1 AAA AGA AGA GGA AAG GGA AAG AAA Total #substitutions = 3 Total #substitutions = 4 Example Continued There are many trees possible. For example: The left tree is “better” than the right tree. Questions: Is this principle yielding realistic phylogenetic trees ? (Evolution) How can we compute the best tree efficiently ? (Computer Science) What is the probability of substitutions given the data ? (Learning) Is the best tree found significantly better than others ? (Statistics)

  37. Werner’s Syndrome A successful application of genetic linkage analysis

  38. The Disease • First references in 1960s • Causes premature ageing • Linkage studies from 1992 • WRN gene cloned in 1996 • Subsequent discovery of mechanisms involved in wild-type and mutant proteins

  39. D A2/A2 H A1/A1 1 2 H A2/A2 H A1/A2 3 4 H | D A2 | A2 H D A1 A2 D D A2 A2 D D A1 A2 Recombinant D A1/A2 5 A sample Input Phase inferred The study used 13 Markers; here we see only one. The study used 14 families; here we see only one.

  40. Marker’s name D8S131 D8S339 D8S259 Genehunter Output position LOD_score information 0.00 -1.254417 0.224384 1.52 2.836135 0.226379 ...[data skipped]... 18.58 13.688599 0.384088 19.92 14.238474 0.401992 21.26 14.718037 0.426818 22.60 15.159389 0.462284 22.9215.056713 0.462510 23.24 14.928614 0.463208 23.56 14.754848 0.464387 ...[data skipped]... 81.84 1.939215 0.059748 90.60 -11.930449 0.087869 Log likelihood of placing disease gene at distance, relative to it being unlinked. distance between markers in centi-morgans Most ‘likely’ position Maximum log likelihood score

  41. Final Location Marker D8S259 location of marker D8S339 Marker D8S131 WRN Gene final location Error in location by genetic linkage of about 1.25M base pairs.

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