1. Biological Information and Biological Databases Meena K Sakharkar Bioinformatics Centre National University of Singapore

2. Biological Information

3. Nature of Life Science Information Descriptive Classification and Nomenclatural Observational and Phenomenological Experimental Deduced/Computed Simulated? Theoretical?

4. Descriptive

5. Classify and Give Names Classification and Nomenclature Linnaeus - binomial nomenclature Group into kingdoms, phyla, classes, orders, families, genera, species, subspecies, strains, etc Associate descriptions to these classification schema, and classify according to description etc

6. Observational/Phenomenological Like descriptive, yet more active Observe a lot of biological phenomenon Charles Darwin Gregor Mendel to McClintock Start to do some experiments

7. Experimental From dissections to complex genetic engineering experiments

8. BioInformatics Deduced/Computed Simulated? Theoretical?

9. What is BioInformatics? Many related terms and buzzwords A multiplicity of names: – bioinformatics – biocomputing – biological computing – computational biology – computational genomics – biological data mining

10. Overview of the challenges of Molecular Biology Computing The huge dataset problem –automated DNA sequencers –the Human Genome Project –bulk sequencing of cDNAs (ESTs)

11. Human Genome Project What is the Human Genome Project? –15-year effort formally begun in October 1990. coordinated by the U.S. Department of Energy and the National Institutes of Health. –identify all the estimated 80,000 genes in human DNA, –determine the sequences of the 3 billion chemical bases that make up human DNA, – store this information in databases, –develop tools for data analysis, and –address the ethical, legal, and social issues (ELSI) that may arise from the project.

12. Who is head of the U.S. Human Genome Project? –The DOE Human Genome Program is directed by Ari Patrinos, and Francis Collins directs the NIH Human Genome Program. –Ari Patrinos also heads the Department of Energy Office of Biological and Environmental Research.

13. What are the comparative genome sizes of humans and other organisms being studied? If compiled in books, the data would fill an estimated 200 volumes the size of a Manhattan telephone book (at 1000 pages each), and reading it would require 26 years working around the clock

15. Informatics: Data Collection and Interpretation HUMAN GENETIC DIVERSITY The Ultimate Human Genetic Database Any two individuals differ in about 3 x 106 bases (0.1%). The population is now about 5 x 109. A catalog of all sequence differences would require 15 x 1015 entries. This catalog may be needed to find the rarest or most complex disease genes.

16. Databases

17. Basic Terminology What is a nucleotide/protein sequence database and databank? Database is a collection of Nucleotide/protein sequence and their Associated annotations. Databanks Groups which collect, compile, maintain and distribute the database.

18. Fundamental Dogma

19. Work from the Code of Life

21. Deduced and Computed Information in the Era of Computational Biology

23. Databases What are the different kinds of databases and their formats? Nucleic Acid Sequence EMBL at EBI. GENBANK at NCBI. DDBJ at Japan. Protein Sequence SWISS PROT NBRF(PIR)

24. Database Protein structure databases PDB Information on the structural data for the proteins/nucleic acids. whose 3-D structure solved by X-ray crystallography/NMR PDB database NRL 3D Database NRL_3D is a sequence-structure database. Can be used in conjunction with PIR. PDB with PIR.

25. GenBank Entry

26. EMBL Entry

27. SwissProt Entry

28. Other databases Genome Databases –GDB :Genome Data Bank –OMIM Pattern Databases –Prosite –TFD

29. Usage of databases Annotation Searches - KW, Authors, Features. –What is the protein sequence for human insulin? –How does the 3D structure of calmodulin look like? –What is the genetic location of cystic fibrosis gene? –List all introns in rat? Homology Searches –Is there any protein sequence that is similar to mine? –Is this gene known in any other species? –Has someone already cloned this sequence?

30. Usage of databases Pattern searches –Does my sequence contain any known motif (that can give me a clue about the function)? –Which known sequences contain this motif? –Is any part of my sequence recoganised by a transcription factor? –List all known start, splice and stop signals in my genomic sequence Prediction - Use the database as knowledge database –What may the structure of my protein be? Secondary structure prediction Modeling by homology –What is the gene structure of my genomic sequence? –Which parts of my protein have a high antigenicity?

31. Usage of Databases Comparisons: –Gene Families –Phylogenetic Trees

32. GenBank Growth Chart Year Bases

33. Evolutionary basis of Alignment Enable the researcher to determine if two sequences display sufficient similarity to justify the inference of homology. Similarity is an observable quantity that may be expressed as say %identity or some other measure. Homology is a conclusion drawn from this data that the two genes share a common evolutionary history.

34. Sequence Formats

35. Fasta Format >SANJAY REFORMAT of: SANJAY.seq check: 8826 from: 1 to: 573 March 12, 1998 MASSSVPPMITEEEARFEAEVSAVESWWRTDRFRLTRRPYSARDVVSLRGTLHHSYASDQ MAKKLWRTLKSHQSAGTASRTFGALDPVQVTMMAKHLDTIYVSGWQCSSTHTATNEPGPD LADYPYNTVPNKVEHLFFAQLYHDRKQHEARVSMTREQRAKTPYVDYLRPIIADGDTGFG GATATVKLCKLFVERGAAGVHIEDQSSVTKKCGHMAGKVLVAVSEHINRLVAARLQFDVM GVETVLVARTDAVAATLIQSNVDLRDHQFILGATNPDFKRRSLAAVLSAAMAAGKTGAVL QAIEDDWLSRAGLMTFSDAVINGINRQLPEYEKQRRLNEWAAATEYSKCVSNEQGREIAE RLGAGEIFWDWDIARTREGFYRFRGSVEAAVVRGRAFAPHADLIWMETSSPDLVECGKFA QGMKASHPEIMLAYNLSPSFNWDAAGMTDEEMRDFIPRIAKMGFCWQFITLGGFHADALV TDTFAREFAKQGMLAYVERIQREERNNGVDTLAHQKWSGANYYDRYLKTVQGGISSTAAM GKGVTEEQFKEESRTGTRGLDRGGITVNAKSRL

36. GCG Format ckl.seq Length: 473 September 15, 1999 12:25 Type: P Check: 8103.. 1 MSTKYSASAE SASSYRRTFG SGLGSSIFAG HGSSGSSGSS RLTSRVYEVT 51 KSSASPHFSS HRASGSFGGG SVVRSYAGLG EKLDFNLADA INQDFLNTRT 101 NEKAELQHLN DRFASYIEKV RFLEQQNSAL TVEIERLRGR EPTRIAELYE 151 EEMRELRGQV EALTNQRSRV EIERDNLVDD LQKLKLRLQE EIHQKEEAEN 201 NLSAFRADVD AATLARLDLE RRIEGLHEEI AFLRKIHEEE IRELQNQMQE 251 SQVQIQMDMS KPDLTAALRD IRLQYEAIAA KNISEAEDWY KSKVSDLNQA 301 VNKNNEALRE AKQETMQFRH QLQSYTCEID SLKGTNESLR RQMSEDGGAA 351 GREAGGYQDT IARLEAEIAK MKDEMARHLR EYQDLLNVKM ALDVEIATYR 401 KLLEGEESRI SLPVQSFSSL SFRESSPEQH HHQQQQPQRS SEVHSKKTVL 451 IKTIETRDGE VVSESTQHQQ DVM

37. Taxonomy Database

53. Blast Results

54. Examples of the New Biology 1.Full genome-genome comparisons 2.Rapid assessment of polymorphic genetic variations 3.Complete construction of orthologous or paralogous groups of genes 4.Structure determination of large macromolecular assemblies/complexes 5.Dynamically simulation of realistic oligomeric systems 6.Rapid structural/topological clustering of proteins 7.Prediction of unknown molecular structures; Protein folding 8.Computer simulation of membrane structure and dynamic function 9.Simulation of genetic networks and the sensitivity of these pathways to component stoichiometry and kinetics 10.Integration of observations across scales of vastly different dimensions and organization to yield realistic environmental models for basic biology and societal needs

55. Theoretical? The day will dawn when we will have sufficient information to understand how basic life functions are integrated into a living cell, and how such cells intercommunicate and interoperate to function as a living whole. Then maybe, we can start talking about theoretical biology

56. Categories of BioDbs - by domain of information DNA RNA Protein Genomic Mapping Pathways Structure Bibliographic Biochemical/Molecular/Miscellaneous

57. Other categories By category of species By families or superfamilies of molecules etc Demo http://www.infobiogen.fr/services/dbcat/

58. Demonstration of BioDatabases Majority of Life Science databases are online, accessible with Web via Internet Catalogs of databases available Need for a Registry to keep track and offer quality control