1 / 33

Opportunities in Bioinformatics Presented By Dr G. P. S. Raghava

Opportunities in Bioinformatics Presented By Dr G. P. S. Raghava Co-ordinator, Bioinformatic Centre IMTECH, Chandigarh Email: raghava@imtech.res.in Web: http://imtech.res.in/raghava/.

kadeem
Télécharger la présentation

Opportunities in Bioinformatics Presented By Dr G. P. S. Raghava

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Opportunities in Bioinformatics Presented By Dr G. P. S. Raghava Co-ordinator, Bioinformatic Centre IMTECH, Chandigarh Email: raghava@imtech.res.in Web: http://imtech.res.in/raghava/

  2. What is Bioinformatics (BI) ?More About Bioinformatics Historical Background Media Hype & ConfusionImportant Applications of BIBioinformatics in India Demand of BI ProfessionalsHow to Enter in BI (Course & Degrees)

  3. What is Bioinformatics • Biocomputing: Application of Computer in Biosciences • Biocomputing started in 1960’s • Explosion of Genomic Data • Access and Management of Data • Biocomputing+Information Science • Role of Internet in BI

  4. Core of Bioinformatics • Relationships between • sequence 3D structure protein functions • Properties and evolution of genes, genomes, proteins, metabolic pathways in cells • Use of this knowledge for prediction, modelling, and design TDQAAFDTNIVTLTRFVMEQGRKARGTGEMTQLLNSLCTAVKAISTAVRKAGIAHLYGIAGSTNVTGDQVKKLDVLSNDLVINVLKSSFATCVLVTEEDKNAIIVEPEKRGKYVVCFDPLDGSSNIDCLVSIGTIFGIYRKNSTDEPSEKDALQPGRNLVAAGYALYGSATMLV

  5. The challenge (Boguski, 1999) In 1995, the number of genes in the database started to exceed the number of papers on molecular biology and genetics in the literature!

  6. More About Bioinformatics GenomeMapping ProteinAnalysisProteomics MultipleSequenceAlignment DatabaseHomologySearching 3DModeling BioInformatics HomologyModelingDocking SequenceAnalysis SampleRegistration &Tracking IntellectualPropertyAuditing IntegratedDataRepositories CommonVisualInterfaces

  7. Computational Biology in the High-Throughput Era The Genome and Beyond • Scientific Challenges • Algorithmic Challenges • Computational Challenges

  8. Historical Background • Life Science - young compared to physics and chemistry • 1953 Structure of DNA • 1960s Understanding of “code of life” • 1970s Genetic manipulation technology • 1980s Widespread innovation -biotechnology/genetic revolution • 1990s Human Genome Project • 2000s Structural Genomics ?

  9. Media Hype and Confusion • Anybody can do BI • BI can do anything • Colleges/Courses/Training • No Quality Check • Limited Knowledge of Subject • More user than developer

  10. Why Bioinformatcs is Required • Data growth is exponential • Difficult to understand life without BI • Detection of new diseases • BI tools allow to save expr. Expend. • Rational Drug design • Computer-aided vaccine design

  11. Application of Bioinformatics • Genome Annotation • Protein Structure Prediction • Proteomics • DNA Chip technology • Disease Diagnostics • Fingerprinting Technique • Drug/Vaccine Design

  12. Genome Annotation The Process of Adding Biology Information and Predictions to a Sequenced Genome Framework

  13. Protein Structures

  14. Protein Structure Prediction • Experimental Techniques • X-ray Crystallography • NMR • Limitations of Current Experimental Techniques • Protein DataBank (PDB) -> 17000 protein structures • SwissProt -> 90,000 proteins • Non-Redudant (NR) -> 800,000 proteins • Importance of Structure Prediction • Fill gap between known sequence and structures • Protein Engg. To alter function of a protein • Rational Drug Design

  15. Traditional Proteomics • 1D gel electrophoresis (SDS-PAGE) • 2D gel electrophoresis • Protein Chips • Chips coated with proteins/Antibodies • large scale version of ELISA • Mass Spectrometry • MALDI: Mass fingerprinting • Electrospray and tandem mass spectrometry • Sequencing of Peptides (N->C) • Matching in Genome/Proteome Databases

  16. Overview of 2D Gel • SDS-PAGE + Isoelectric focusing (IEF) • Gene Expression Studies • Medical Applications • Sample Experiments • Capturing and Analyzing Data • Image Acquistion • Image Sizing & Orientation • Spot Identification • Matching and Analysis

  17. Comparision/Matcing of Gel Images • Compare 2 gel images • Set X and y axis • Overlap matching spots • Compare intensity of spots • Scan against database • Compare query gel with all gels • Calculate similarity score • Sort based on score

  18. Mass Fingerprinting • Add protease (e.g. trypsin) • Get fragment size of peptides • Scan against peptides of a protein obtained theortically by that protease • Scan against all proteomes

  19. Normal Cells Disease Cells Differential Proteomics: Fingerprints of Disease • Phenotypic • Changes • Differential protein expression • Protein nitration patterns • Altered phosporylation • Altered glycosylation profiles • Utility • Target discovery • Disease pathways • Disease biomarkers

  20. Fingerprinting Technique • What is fingerprinting • It is technique to create specific pattern for a given organism/person • To compare pattern of query and target object • To create Phylogenetic tree/classification based on pattern • Type of Fingerprinting • DNA Fingerprinting • Mass/peptide fingerprinting • Properties based (Toxicity, classification) • Domain/conserved pattern fingerprinting • Common Applications • Paternity and Maternity • Criminal Identification and Forensics • Personal Identification • Classification/Identification of organisms • Classification of cells

  21. Drug Design based on Bioinformatics Tools • Detect the Molecular Bases for Disease • Detection of drug binding site • Tailor drug to bind at that site • Protein modeling techniques • Traditional Method (brute force testing) • Rational drug design techniques • Screen likely compounds built • Modeling large number of compounds (automated) • Application of Artificial intelligence • Limitation of known structures • Search of Target protein • Search of Lead compound

  22. History of Bioinformatics in India • Biocomputing started in 1950’s • IISc Banglore (Prof G Ramachandran) • Mostly analysis of protein structure • Distributed information center (DIC) • DBT initiate 9 DICs during 1986-7 • National Facilities (IMT,IISc,IARI,JNU,MKU) • Sub-DICs started (around 50) • Mirror sites in 1999 (IMT,Pune,JNU,IISc)

  23. Education in Bioinformatics • Role of BIC’s in education • Workshops, training, course etc started • Facilities/Infrastructure in BI • Advanced diploma in BI (Pune,JNU,MKU) • M.Sc. In bioinformatics • Private Sector • Number of courses initiated • Dedicated training centers • Universities • R&D Institutes • Ph.D in Bioinformatics (IMT)

  24. Company Revenues IT Budget Pct Chase-Manhattan 16,431,000,000 1,800,000,000 10.95 % AMR Corporation 17,753,000,000 1,368,000,000 7.71 % Nation’s Bank 17,509,000,000 1,130,000,000 6.45 % Sprint 14,235,000,000 873,000,000 6.13 % IBM 75,947,000,000 4,400,000,000 5.79 % MCI 18,500,000,000 1,000,000,000 5.41 % Microsoft 11,360,000,000 510,000,000 4.49 % United Parcel 22,400,000,000 1,000,000,000 4.46 % Bristol-Myers Squibb 15,065,000,000 440,000,000 2.92 % Pfizer 11,306,000,000 300,000,000 2.65 % Pacific Gas & Electric 10,000,000,000 250,000,000 2.50 % Wal-Mart 104,859,000,000 550,000,000 0.52 % K-Mart 31,437,000,000 130,000,000 0.41 % Business Comparisons

  25. Typical BioinformaticsMulti-Disciplinary Training • Scientists • Biology, Molecular Genetics, Clinical Biochemistry, Protein Structure Chemistry • Mathematicians • Statistics, Algorithms, Image processing • Computer Scientists • Database, User Interface/Visualizations, Networking (Internets/Intranets), Instrument Control

  26. Typical BioinformaticsMulti-Disciplinary Functions • Scientists • Experimental Design & Interpretation • Laboratory Protocols & Standards/Controls • Mathematicians • Analysis & Correlation of Data • Validation methodologies • Computer Scientists • Information Storage / Control Vocabulary • Data Mining

  27. External Public Databases External Proprietary Databases Bioinformatics Architecture Java & Desktop Programs Web Browser Users Workstation MS Access SharedAccessDatabases Web Server NT servers ActiveServer Livewire CGI Unix servers & Specialized Hardware Proprietary Internal Databases

  28. Business Opportunities in BI • Software development • Web servers development • Train manpower in Field of BI • Database management • Rational Drug design • Develop Diagnostic kits • Assist user in Vaccine development • Consultant to Biotech Companies

  29. Bioinformatics at IMT, Chandigarhhttp://imtech.res.in/bic/ http://imtech.res.in/ • Mirror Sites (http://www.imtech.res.in/mirror_sites/) • Public Domain Resources in Biology (www.imtech.res.in/) • IMTECH Library on Internet (/lib/) • Concept of vaccine design • Protein Structure Prediction (Olympic-2000) • Gene Prediction • Software for general use • GNU software • SUN Freeware • PostgreSQL • Site: http//:imtech.res.in/raghava/www.html

  30. THANK YOU!

More Related