Bioinformatics Databases:Getting Knowledge from
Information
Kristen AntonDirector of BioInformaticsDartmouth Medical School
BioInformatics @ Dartmouth Medical School
What is Bioinformatics?
Bioinformatics provides the backbone computational tools, databases and domain
expertise that facilitates modern biomedical, biological and genomic research.
BioInformatics @ Dartmouth Medical School
BioInformatics @ Dartmouth Medical School
What is Bioinformatics?
• ‘Wet-lab’ science• Sequence analysis• Modeling & structural work• Algorithm development• Clinical and Translational research• Hardware & software infrastructure
The expertise is multidisciplinary,and the skills fall on a continuum from
‘pure’ science to ‘pure’ computing:
With a field this extensive and skill sets so varied, where do we begin?
BioInformatics @ Dartmouth Medical School
BioInformatics @ Dartmouth Medical School
From Information Design, Nathan Shedroff
Moving from Information to Knowledge to Understanding:
Genetic testing
• BRCA1 and BRCA2 gene mutations: what is the real risk to women carriers? 25% - 80%
• Huntington’s Disease: mechanism defined, but what does that mean for the individual in terms of age of onset, severity of disease, or how disease will progress?
BioInformatics @ Dartmouth Medical School
How can Bioinformatics facilitate the extraction of
information?• Development of tools that support laboratory
experiments• Design, implementation and integration of
biological databases• Development of various analytical tools, algorithms
and models• Development of systems to collect, validate,
manage and integrate clinical and research data to facilitate translational research
BioInformatics @ Dartmouth Medical School
Bioinformatics will not replace experiments, but can greatly
streamline and enable the discovery process.
BioInformatics @ Dartmouth Medical School
One of the fundamental toolsof bioinformatics: Database
• A database is a body of information stored in two dimensions (rows and columns)
• The power of the database lies in the relationships that you construct between the pieces of information (tables)
• SQL (Structured Query Language) - interactive and embedded
• Good design and application ensure data integrity• Interoperability
BioInformatics @ Dartmouth Medical School
Industry Challenge #1:Genome annotation
The Human Genome is sequenced. It is estimated that 2% of the human genome codes for genes.
The function of the remaining 98% (non-coding regions) is largely unknown but likely include providing chromosomal structural integrity and regulating where, when, and in what quantity proteins are made.
BioInformatics @ Dartmouth Medical School
What does the genome data look like? 1 gcggagggtg cgtgcgggcc gcggcagccg aacaaaggag caggggcgcc gccgcaggga 61 cccgccaccc acctcccggg gccgcgcagc ggcctctcgt ctactgccac catgaccgcc 121 aacggcacag ccgaggcggt gcagatccag ttcggcctca tcaactgcgg caacaagtac 181 ctgacggccg aggcgttcgg gttcaaggtg aacgcgtccg ccagcagcct gaagaagaag 241 cagatctgga cgctggagca gccccctgac gaggcgggca gcgcggccgt gtgcctgcgc 301 agccacctgg gccgctacct ggcggcggac aaggacggca acgtgacctg cgagcgcgag 361 gtgcccggtc ccgactgccg tttcctcatc gtggcgcacg acgacggtcg ctggtcgctg 421 cagtccgagg cgcaccggcg ctacttcggc ggcaccgagg accgcctgtc ctgcttcgcg 481 cagacggtgt cccccgccga gaagtggagc gtgcacatcg ccatgcaccc tcaggtcaac 541 atctacagtg tcacccgtaa gcgctacgcg cacctgagcg cgcggccggc cgacgagatc 601 gccgtggacc gcgacgtgcc ctggggcgtc gactcgctca tcaccctcgc cttccaggac 661 cagcgctaca gcgtgcagac cgccgaccac cgcttcctgc gccacgacgg gcgcctggtg 721 gcgcgccccg agccggccac tggctacacg ctggagttcc gctccggcaa ggtggccttc 781 cgcgactgcg agggccgtta cctggcgccg tcggggccca gcggcacgct caaggcgggc 841 aaggccacca aggtgggcaa ggacgagctc tttgctctgg agcagagctg cgcccaggtc 901 gtgctgcagg cggccaacga gaggaacgtg tccacgcgcc agggtatgga cctgtctgcc 961 aatcaggacg aggagaccga ccaggagacc ttccagctgg agatcgaccg cgacaccaaa ...
Multiply times eighteen million
BioInformatics @ Dartmouth Medical School
What does the genome annotation look like today?
BioInformatics @ Dartmouth Medical School
BioInformatics @ Dartmouth Medical School
The value of a genome is onlyas good as its annotation
• Two steps: annotation & curation• Each genome is annotated individually• Manual curation is standard practice• New tools, ie. NCBI Mapviewer,
ESTAnnotator, NCBI Annotation Pipeline• Many databases available …
BioInformatics @ Dartmouth Medical School
Nucleic Acids Research article lists1078 public databases (up from 719 in
2005):
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Nucleic Acids Research, 2008, Vol. 36, Database issuehttp://nar.oxfordjournals.org/cgi/reprint/36/suppl_1/D2
BioInformatics @ Dartmouth Medical School
Growth in Available Bioinformatics Databases
Industry Challenge #2:Too much unintegrated data
• Data sources incompatible
• No (or few) standard naming convention
• No common interface (varying tools for browsing, querying and visualizing data)
BioInformatics @ Dartmouth Medical School
Public Data Resources• “Mandatory” sequence submissions• Cover enormously wide range of informational
topics• Broad (sequence) to very specific (proteins
associated with tooth decay) issues• No standard database format: poor
interoperability, difficulty with integration• Ongoing efforts to address annotation problem
BioInformatics @ Dartmouth Medical School
NCBI Database Resources
BioInformatics @ Dartmouth Medical School
http://www.ncbi.nlm.nih.gov/gquery/gquery.fcgi?term=uniprot
Major Sequence Repositories
• GenBank All known nucleotide and protein sequences; International Nucleotide Sequence Database Collaboration
• EMBL Nucleotide Sequence Database All known nucleotide and protein sequences; International Nucleotide Sequence Database Collaboration
• DNA Data Bank of Japan (DDBJ) All known nucleotide and protein sequences; International Nucleotide Sequence Database Collaboration
• TIGR/J. Craig Venter Institute Non-redundant, gene-oriented clusters (and many curated microbial genome databases)
• UniGene Non-redundant, gene-oriented clusters
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Entrez Gene: a unified queryenvironment for genes defined by
sequence
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• Summary/descriptive information• Pubmed entries/bibliography• Interactions• NCBI Reference Sequences (Refseq)• Related sequences• Pathways• Ontologies• Additional likes (e.g. UniGene reference)
GenBank
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GenBank Growth
BioInformatics @ Dartmouth Medical School
GenBank Growth
• 1982 Database contains 606 sequences• Feb 2008 release notes: Database contains
more than 82 million sequences - 82853685 (the number of bases approximately doubles every 18 months)
• 240,000 different species represented, with new species added at rate of 2900/month
• 16% of sequences are of human origin, 13% are human ESTs
BioInformatics @ Dartmouth Medical School
Potential Errors in GenBank
• Sequence errors estimated at between 0.37 and 35 (!) errors per 1000 bases
• Recombination• Contamination• Annotation errors - propagated misannotations
– Transfer by similarity is problematic– Errors not always corrected in a timely way– Genes with varying unrelated functions depending on
context– Functional annotation is often unsystematic
• Name-function disconnect
BioInformatics @ Dartmouth Medical School
Potential Errors in GenBank
• Naming conflicts– One gene, many acronyms– Many genes, shared acronym– Spelling errors– Cultural differences (US, UK)– Representation of non-ASCII characters
BioInformatics @ Dartmouth Medical School
BioInformatics @ Dartmouth Medical School
BioInformatics @ Dartmouth Medical School
BioInformatics @ Dartmouth Medical School
BioInformatics @ Dartmouth Medical School
BioInformatics @ Dartmouth Medical School
Also known as ACTR; AIB1; RAC3; SRC3; pCIP; AIB-1; CTG26; SRC-1; CAGH16; KAT13B; TNRC14; TNRC16; TRAM-1; MGC141848
Many Databases available:• Comparative Genomics• Gene Expression• Gene Identification & structure• Genetic Maps• Genomic Databases• Intermolecular Interactions• Metabolic Pathways and Cellular Regulation• Mutation Databases• Pathology• Protein Databases• Protein Sequence Motifs• Proteome Resources• Retrieval Systems & Database Structure• RNA Sequences• Structure• Transgenics• Varied Biomedical Content
BioInformatics @ Dartmouth Medical School
The principal requirementson the public data services
• Data quality - data quality has to be of the highest priority. However, because the data services in most cases lack access to supporting data, the quality of the data must remain the primary responsibility of the submitter. Gene Expression
• Supporting data - database users will need to examine the primary experimental data, either in the database itself, or by following cross-references back to network-accessible laboratory databases. Genetic Maps
• Deep annotation - deep, consistent annotation comprising supporting and ancillary information should be attached to each basic datat object in the database. Intermolecular Interactions
• Timeliness - the basic data should be available on an Internet-accessible server within days (or hours) of publication or submission.
• Integration - each data object in the database should be cross-referenced to representation of the same or related biological entities in other databases. Data services should provide capabilities for following these links from one database or data service to another.
BioInformatics @ Dartmouth Medical School
Comparative Genomics: COG
• Clusters of Orthologous Groups of proteins (COGs) were delineated by comparing protein sequencesencoded in 66 complete genomes, representing 38 major phylogenetic lineages.
• Each cluster corresponds to an ancient conserved domain.
BioInformatics @ Dartmouth Medical School
Gene Expression
BioInformatics @ Dartmouth Medical School
Genetic Maps
BioInformatics @ Dartmouth Medical School
Genomic Databases
BioInformatics @ Dartmouth Medical School
Intermolecular Interactions
BioInformatics @ Dartmouth Medical School
Metabolic Pathways and Celluar Regulation
BioInformatics @ Dartmouth Medical School
Mutation Databases
BioInformatics @ Dartmouth Medical School
Pathology
BioInformatics @ Dartmouth Medical School
Protein Databases
BioInformatics @ Dartmouth Medical School
Protein Databases: Swiss-Prot• Extremely well curated
protein database
• Link to BLAST
• Powerful cross-references
• Est. 1986
• Maintained by the Department of Medical Biochemistry of the University of Geneva and the EMBL Data Library
BioInformatics @ Dartmouth Medical School
Proteome Resources: Proteome BKL
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RNA Sequences
BioInformatics @ Dartmouth Medical School
Structure
BioInformatics @ Dartmouth Medical School
Varied Biomedical Content
BioInformatics @ Dartmouth Medical School
Extinct: Gene Identification & Structure
BioInformatics @ Dartmouth Medical School
National Center for Biotechnology Information (NCBI):
A network of linked resources• Database access: Genbank,
structure, function, SNP, taxonomy...
• Literature (PubMed)• Whole genomes• Tools• Contacts & research
information• FTP
BioInformatics @ Dartmouth Medical School
NCBI resources
• Nucleotide databases• Protein databases• Structure databases• Taxonomy databases• Genome databases• Expression databases
BioInformatics @ Dartmouth Medical School
BioInformatics @ Dartmouth Medical School
A word about caBIG:Cancer Biomedical Informatics Grid
• NCI (National Cancer Institute) effort to align NCI-funded Cancer Centers
• Definition: a voluntary network or grid connecting individuals and institutions to enable the sharing of data and tools, creating a www of cancer research
• Goal: to speed up the delivery of innovative approaches for the prevention and treatment of cancer
• Leadership: NCI Center for Bioinformatics
BioInformatics @ Dartmouth Medical School
The real fun:Clinical and Translational Research
• Clinical Trials, Prevention studies, Molecular Epidemiology studies
• Integrating epidemiological, clinical, outcome and molecular data
• Cross-disciplinary: requires expert technical skill (process engineering, system design, software development, data mgt & integration), scientific expertise (genetics, genomics, proteomics)
BioInformatics @ Dartmouth Medical School
BioInformatics @ Dartmouth Medical School
Chemoprevention study: Prevention of skin cancer by antioxidants
• Subjects (5000) with clinical evidence of chronic arsenic exposure will be recruited from two ongoing cohort studies
• Two study sites in Araihazar and Matlab; Coordinating center at Dhaka and University of Chicago; Data center at Dartmouth
• Goal: to test effectiveness of vitamin E and selenium in preventing development of skin cancer
BioInformatics @ Dartmouth Medical School
Data issues
• Design processes, forms and systems• Collect: Family history, Risk factors, Health &
outcomes, bio-specimens/related data• Screening, recruitment, pill distribution, data
collection, bio-specimen tracking, data management, data integration and analysis
• Challenges: intermittent power, low bandwidth internet access, low-tech facilities (no land-line phone, no fax, no cooling, no computers at sites), translation of information into and back from Bengali – etc.
BioInformatics @ Dartmouth Medical School
BioInformatics @ Dartmouth Medical School
BioInformatics @ Dartmouth Medical School
BioInformatics @ Dartmouth Medical School
BioInformatics @ Dartmouth Medical School
BioInformatics @ Dartmouth Medical School
BioInformatics @ Dartmouth Medical School
BioInformatics @ Dartmouth Medical School
BioInformatics @ Dartmouth Medical School
Mars, Palm trees & Cancer Biomarkers?
BioInformatics @ Dartmouth Medical School
Dartmouth – NASA JPL collaborationLife Sciences Data
BioInformatics @ Dartmouth Medical School
Early Detection Research Network: Biomarker Atlas Project
• EDRN is an NCI initiative to discover and validate individual or panels of biomarkers for the early detection of cancers
• Organ-based research groups, international team• Informatics center at JPL – novel and
sophisticated infrastructure• First step: EDRN Resource Network Exchange
(ERNE) – Dartmouth collaboration - 2002
eCASScience Warehouse
CDE Repository
ERNE
VSIMS
Participant DB
Protocol DB
Public Portal
Distributed SpecimenDatabases
EDRN science data results (local, distributed and varying
degrees of validation)
Descriptions of biomarkersand their use (protocol_id)
Descriptions of EDRN studies-Participants-Specimen tracking, etc
Protocols and theirdescriptions
Data elements and their descriptions
BIOINFORMATICSTOOLS
EDRN science data results
(protocol_id,participant_id)
(protocol_id,participant_id)
(protocol_id,participant_id)
Biomarker_DB
(protocol_id)
Participants and their
characteristics
EDRN Knowledge Environment
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EDRN Biomarker Atlas Project:Lung Prototype
BioInformatics @ Dartmouth Medical School
EDRN Biomarker Atlas ProjectColon Models
BioInformatics @ Dartmouth Medical School
BioInformatics @ Dartmouth Medical School
BioInformatics @ Dartmouth Medical School
BioInformatics @ Dartmouth Medical School
Barro Colorado – Smithsonian Tropical Research Institute
BioInformatics @ Dartmouth Medical School
BioInformatics @ Dartmouth Medical School
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