MoM2010: Bioinformatics

MOM 2010 Bioinformatics: Reality Check & ChallengesDr. SouhamMeshoulInformation Technology Dept. CCIS, KSUsmeshoul@ksu.edu.saDr. NikhatSiddiqiBiochemistry Dept.CS, KSUnikkat@ksu.edu.sa&MOM 2010 , May 31 st

Central Dogma of Molecular Biology

Biological Data representation

How Computers can be useful in Biology

ConclusionIntroductionThe human body is made up of an estimated 1012 cells, each of which contains 23 pairs of chromosomes that are composed of approximately 30,000 genes which in turn contain some 3 billion pairs of DNA bases.Biological data explosionhttp://bip.weizmann.ac.il/education/course/introbioinfo/04/lect1/introbioinfo04/index.htm

IntroductionWhat is Bioinformatics?Bioinformatics is the field of science in which biology, computer science, and information technology merge into a single disciplineBioinformatics is the electronic infrastructure of BiologyScience that encompasses the methods that are used to collect, store, retrieve, analyze, and correlate the mountain of complex biological information.Source: http://ccb.wustl.edu/

IntroductionBioinformatics Vs Computational biologySource: http://ccb.wustl.edu/

IntroductionThe problem: basic understanding of how gene sequences code specific proteins l Lack of the information necessary to completely understand role of DNA in specific diseases or the functions of the thousands of proteins that are produced.The goals:provide scientists with a means to explain:Biological processes. Malfunctions in these processes which lead to diseases. Drug discovery and their mode of action.

Central Dogma of Molecular BiologyDNA is responsible for all the hereditary information in an organism.

Deoxyribonucleic Acid (DNA)DNA is found inside a special area of the cell called the nucleus. Because the cell is very small, and because organisms have many DNA molecules per cell, each DNA molecule must be tightly packaged. This packaged form of the DNA is called a chromosome.

Deoxyribonucleic Acid (DNA)CompositionDNA is made of chemical building blocks called nucleotides. What is DNA made of?The four types of nitrogen bases found in nucleotides are: adenine (A), , thymine (T), guanine (G) and cytosine (C). The order, or sequence, of these bases determines what biological instructions are contained in a strand of DNA. For example, the sequence ATCGTT might instruct for blue eyes, while ATCGCT might instruct for brown.

Deoxyribonucleic Acid (DNA)GenesGenesThese unique coding sections of DNA that ultimately are transcribed into unique mRNA which are translated into unique proteins are called genes.

Deoxyribonucleic Acid (DNA)FunctionWhat does DNA do?DNA contains the instructions needed for an organism to develop, survive and reproduce. To carry out these functions, DNA sequences must be converted into messages that can be used to produce proteins, which are the complex molecules that do most of the work in our bodies.To form a strand of DNA, nucleotides are linked into chains, with the phosphate and sugar groups alternating.

Deoxyribonucleic Acid (DNA)ReplicationReplicationChromosomes are located in the nucleus of a cell. DNA must be duplicated in a process called replication before a cell divides. The replication of DNA allows each daughter cell to contain a full complement of chromosomes.

Deoxyribonucleic Acid (DNA)TranscriptionTranscription: The actual information in the DNA of chromosomes is decoded in a process called transcription through the formation of another nucleic acid, ribonucleic acid or RNA.

Deoxyribonucleic Acid (DNA)TranslationTranslation:The information from the DNA, now in the form of a linear RNA sequence, is decoded in a process called translation, to form a protein, another biological polymer.

Biological Data Representation

Biological Data RepresentationStrings: to represent DNA, RNA and sequences of amino-acids DNA: {A,C,G,T}, RNA: {A,C,G,U},Protein: {A,C,D,E,F,G,H,I,K,L,M,N,P,Q,R,S,T,V,W,Y}e.g5’GTAAAGTCCCGTTAGC 3’Image source; www.ebi.ac.uk/microarray/ biology_intro.htm

Biological Data RepresentationTrees: to represent the evolution of various organisms

Biological Data RepresentationSets of 3D points: to represent the protein structure

Biological Data RepresentationGraphs: to represent metabolic and signaling pathways.

How can computers be useful for biology?

How can computers be useful to biology?First, Computing technology for storing DNA sequences and constructing these latter from fragments. Data storage and access requirements – Study of the organization and evolution of genomes through comparative genome analysis. Visualisation tools and techniques requirements, sequence analysis requirements .

How can computers be useful to biology?Structuring and organizing large databases using a common ontology . Access data from different databases using the same query language. (Gene Ontology Consortium )Many areas of biology use images to communicate their results. Tools and techniques for searching, describing, manipulating and analyzing features within these images.

How can computers be useful to biology?Databases maintenance: Need to check consistency of databases for a valid and error free content. Storing protein sequences, their structure as well as their function. Tools and techniques for manipulating protein sequences, protein secondary and tertiary structure prediction…

How can computers be useful for biology?Several databases: genome databases, protein sequence databases, metabolic databases, Microarray databasesEMBL-EBI (Europe), GenBank-NCBI (USA), DDBJ (Japan)Basic Local Alignment Search Tool (BLAST) program for quick DB searches.

How can computers be useful for biology?Several algorithms: Sequence Comparison Algorithms: Needleman-Wunch (global alignment 1970),Smith-Waterman algorithm: Local sequence alignment (1981).BLAST, FASTA, CLUSTALW, MEME...etchttp://en.wikipedia.org/wiki/Category:Bioinformatics_algorithms

Intelligent Bioinformatics Data generation in biology/bioinformatics is outpacing methods of data analysis.

Data interpretation and generation of hypotheses requires intelligence.

AI offers established methods for knowledge representation and “intelligent” data interpretation.

Predict utilization of AI in bioinformatics to increase.Intelligent BioinformaticsSearch problems: Sequence alignmentLearning problems: Gene regulatory networksClustering problems: Gene expression data processing.Prediction problems: tertiary and secondary structure.Data mining: Inferring knowledge from large biological databases.

Intelligent BioinformaticsAI and computational intelligence techniques and models:Basic search techniques A*, Branch and Bound, Genetic Algorithms Simulated Annealing Particle Swarm Optimization Neural networks, Support Vector Machines,K nearest neighbors,Hidden Markov Models,….

Intelligent Bioinformatics:An example: Sequence AlignmentA-TGGGG--TTA-TACCC-G-AG-GTTGTGT-A--ACCA-GCPossible alignmentPossible alignmentS1=AGGTCS2=GTTCGS3=TGAACFor lengthy sequences the problem is very hard to solve:Optimization problem.

Scoring functionIntelligent Bioinformatics:An example: Sequence Alignmentsi: string defined over an alphabet AAligning sequences in S is obtaining S’ /such that:Each sequence si’ is an extension of si defined over the alphabet 2. For all i,jlength(S)=length(S’

Intelligent BioinformaticsAn example: the robot scientistSource: BBC NewsUniversity of Wales

Designed for the study of functional genomics

Tested on yeast metabolic pathways

Uses knowledge representation schemes

Utilizes a Prolog database to store background biological information.

MoM2010: Bioinformatics

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