Bridging Bioinformatics and Chemoinformatics

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Bridging Bioinformatics and Chemoinformatics

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Title: Bridging Bioinformatics and Chemoinformatics

1
Bridging Bioinformatics and Chem(o)informatics

Gary Wiggins
School of Informatics
Indiana University
wiggins_at_indiana.edu
Yan He (SLIS MLS Student)
Meredith Saba (SLIS MLS Student)

2
Provocative Thought

While much bioscience is published with the
knowledge that machines will be expected to
understand at least part of it, almost all
chemistry is published purely for humans to
read.
Murray-Rust et al. Org. Biomol. Chem. 2004, 2,
3201.

3
Overview of the Talk

Review of ACS CINF 2004 Papers
Review of Relevant Articles
Public Chemistry Databases and Data Repositories
with Bioinformatics Info/Links
Overview of Web Services
NIH-funded Projects Underway or Planned at
Indiana University

4
The Bigger Picture Linking Bioinformatics to
Cheminformatics

American Chemical Society Division of Chemical
Information (CINF) Symposium, Anaheim, Spring
2004
All-day session with 16 papers
http//www.acscinf.org/new/docs/meetings/227nm/227
cinfabstracts.htm

5
Problems from ACS CINF 2004

Both technical and people factors hinder
knowledge exchange between biology and chemistry.
(Lipinski)
People Problems per Chris Lipinski
Meta data capture is complicated by people
issues, particularly those between chemists and
biologists.
Discipline-based disconnects occur distressingly
often and are frequently overlooked as a cause of
lost productivity.

6
Interdisciplinary Collaborations Biology and
Chemistry

Whats ... important for these collaborations
is, not only do you have to accept the other
guys paradigm or at least live with it you have
to be willing to accept the other guys foibles
or your perception of the other guys foibles
(and recognize the opposite of this). We each
have our own approaches to how we do science, and
its just different cultures.
--Thom Kauffman interview in ACS LiveWire, March
2005, 7.3. http//pubs.acs.org/4librarians/livewir
e/2006/7.3/profile.html

7
Some Questions from the ACS CINF 2004 Symposium

"Find all proteins related to protein A (i.e.
within a given path length of A) in a protein
interaction graph, and retrieve related assay
results and compound structures.
Find all pathways where compound X inhibits or
slows a reaction, and retrieve Gene Ontology
classifications for all proteins involved in the
reaction.

8
Problems from ACS CINF 2004

Commercial vs. public data
Batch mode data processing possible in biology,
but primitive in chemistry
Primary HTS data has a very high noise factor
Data format standardization problem
Chemoinformatics and bioinformatics use
completely different data formats and analysis
tools
Chemical and protein sequence information has
been largely analyzed separately

9
Solutions from ACS CINF 2004

Linking biological and chemical information in
computational approaches to predict biological
activity, ADME profiles, and adverse drug
reactions (ADR)
Energetics of binding for more accurate and
sensitive chemical representation of DNA-protein
interactions
A discovery informatics platform that facilitates
archival, sharing, integration, and exploration
of synthetic methods and biological activity data

10
Solutions from ACS CINF 2004

Data pipelining approach makes it possible to
apply bioinformatics and chemoinformatics data
and analyses together.
Visualizations are the best way for people to
understand data.

11
Solutions from ACS CINF 2004

Cabinet (Chemical And Biological Information
NETwork, formerly Fedora) servers include
Metabolic pathway network chart (Empath)
Protein-Ligand Association Network (Planet)
Enzyme Commission Codebook (EC Book)
Traditional Chinese Medicines (TCM)
World Drug Index (WDI), and others.
Built on the Daylight HTTP toolkit
http//www.metaphorics.com/products/cabinet.html

12
Overview of the Talk

Review of ACS CINF 2004 Papers
Review of Relevant Articles
Public Chemistry Databases and Data Repositories
with Bioinformatics Info/Links
Overview of Web Services
NIH-funded Projects Underway or Planned at
Indiana University

13
What is Chemoinformatics? (Brown)

the essence of chemoinformatics is integration
and focus rather than its components, which are
independent disciplines.
Supporting disciplines
Chemical information
Computational chemistry
Chemometrics

14
Chemoinformatics and Disease
15
Toolkits as Integrators (Brown)

Companies such as Daylight, Advanced Visual
Systems, OpenEye, and SciTegic provide
integration systems for
Statistical methods
Text mining
Computational chemistry
Visualization

16
Genegos MetaDrug Product

Toxicogenomics platform for the prediction of
human drug metabolism and toxicity of novel
compounds
Enables the visualization of pre-clinical and
clinical high-throughput data in the context of
the complete biological system
Integrates chemical, biological, and protein
function data
http//www.genego.com/

17
BioWisdom

Examination of vast amounts of available
information using its Sofia KnowledgeScan
methodology
SRS data integration platform
http//www.biowisdom.com/

18
Lessons from Hip Hop (Salamone)

Mashup technique
Bring together disparate informatics, biological,
chemical, and imaging information when conducting
research
Example of an integration tool iSpecies.org
A search for a species returns a page with NCBI
genomics information, Yahoo images of the
species, and articles culled from Google Scholar

19
iSpecies.org Search

For mus musculus

20
Chemogenomics and Chemoproteomics (Gagna)

Chemogenomics (def.)The description of all
potential drugs that can be used against all
possible target sites, OR the actions of
target-specific chemical ligands and how they are
used to globally examine genes
Chemoproteomics (def.)Uses chemistry to
characterize protein structure and functions
They are . . . a form of chemical biology
brought up to date in the area of genome and
proteome analysis.

21
New Interdisciplinary Journals

ACS Chemical Biology (ACS)
ChemBioChem A European Journal of Chemical
Biology (Wiley/VCH)
Chemical Biology and Drug Design (Blackwell)
JBIC Journal of Biological and Inorganic
Chemistry (Springer)
Journal of Biochemical and Molecular Toxicology
(Wiley)
Molecular Biosystems (RSC)
Nature Chemical Biology (Nature Publishing)
Organic Biomolecular Chemistry (RSC)

22
Open Source Software (Geldenhuys)

Log P calculator from Interactive Analysis
http//www.logp.com
University of Utahs Computational Science and
Engineering Online
Can submit jobs for molecular mechanics, quantum
chemical calculations, and biomolecular
interfaces for viewing PDB files
http//www.cse-online.net
Virtual Computational Chemistry Laboratory
http//www.vcclab.org

23
The Blue Obelisk (Guha)

Several open chemistry and chemoinformatics
projects that have pooled forces to enhance
interoperability
Maintain
Chemoinformatics Algorithms Dictionary
Data Repository for standardized data for
chemical properties and other facts (e.g., mass)
http//www.blueobelisk.org/

24
BlueObelisk.org

Working collaboratively on projects such as
Chemistry Development Kit (CDK)
JChemPaint
Jmol
JUMBO
NMRShiftDB
Octet
Open Babel
QSAR
World Wide Molecular Matrix (WWMM)

25
Barriers to the Use of Open Source Software

Unix command line
Problem Lack of known standards and datasets of
compounds for validation, e.g., in docking
programs

26
Lessons from the Human Genome Project (Austin)

Keys to success in the HGP were
Comprehensiveness
Commitment to open access to the sequence as a
research tool without encumbrance
Proposed tools for a genome functionation
toolbox
Whole-genome transcriptome and proteome
characterization
Development of small inhibitory RNAs (siRNAs) and
knockout mice for every gene
Small molecules and the druggable genome

27
ChemDB http//cdb.ics.uci.edu/CHEM/Web/
28
ChEBI, Chemical Entities of Biological Interest

Dictionary of molecular entities focused on small
chemical compounds
Features an ontological classification, showing
the relationships between molecular entities or
classes of entities and their parents and/or
children

29
Vioxx Entry in ChEBI
30
The IUPAC International Chemical Identifier
(InChI)

Open source, non-proprietary, public-domain
identifier for chemicals
String of characters that uniquely represent a
molecular substance
Independent of the way the chemical structure is
drawn
Enables reliable structure recognition and easy
linking of diverse data compilations
Accepts as input MOLfiles (or SDfiles) and CML
files
Download the program to your computer at
http//www.iupac.org/inchi/license.html

31
Generation of InChI for Vioxx with wInChI
32
Vioxx Entry in PubChem Compounds Found with InChI
33
Vioxx Bioassay Data in PubChem
34
Vioxx PubChem Link to External Sources of
Information
35
The Elsevier MDL/NIH Link via PubChem and
DiscoveryGate

Cross-indexes PubChem to the Compound Index
hosted on Elsevier MDLs DiscoveryGate platform
MDL added 5 million structures from PubChem to
their index, resulting in over 14 million unique
chemical structures
Links go both ways
Can move from biological data in PubChem to
bioactivity, chemical sourcing, synthetic
methodology, and EHS data in DiscoveryGate
sources

36
Elsevier MDLs xPharm

Comprehensive set of records linking
Agents (compounds) (2300)
Targets (600)
Disorders (450)
Principles that govern their interactions (180)
Answers questions such as
What targets are associated with control of blood
pressure?
What adverse effects are associated with
monoamine oxidase inhibitors?

37
Text Datamining (Banville)

In the pharmaceutical field, it is ideally the
marriage of biological and chemical information
that needs to be the ultimate focus of text data
mining applications.
Problems
Lack of universal publication standards for
identifying each unique chemical entity
Selective indexing policies of AI services
Need to understand how chemical structures link
to biological processes

38
Chemical Datamining Software

SureChem
http//surechem.reeltwo.com/
CLiDE
Recognizes structures, reactions, and text
http//www.simbiosys.ca/clide/
OSCAR
OSCAR1 to check experimental data
http//www.ch.cam.ac.uk/magnus/checker.html
http//www.rsc.org/Publishing/ReSourCe/AuthorGuide
lines/AuthoringTools/ExperimentalDataChecker/
CSR (Chemical Structure Reconstruction)
http//www.scai.fraunhofer.de/uploads/media/MZ-ERC
IM05_04.pdf
MDL DocSearchcombines MDLs Isentris platform
and EMCs Documentum

39
Overview of the Talk

Review of ACS CINF 2004 Papers
Review of Relevant Articles
Public Chemistry Databases and Data Repositories
with Bioinformatics Info/Links
Overview of Web Services
NIH-funded Projects Underway or Planned at
Indiana University

40
Themes from SwissProts 20th Anniversary
Conference, In silico Analysis of Proteins

Knowledgebases, databases and other information
resources for proteins
Sequence searches and alignments
Protein sequence analysis
Protein structure prediction, analysis and
visualization
Proteomics data analysis

41
Chemoinformatics Databases (Jónsdóttir)

Lists databases relevant to drug discovery and
development, including
General databases
DBs for screening compounds
DBs for medicinal agents
DBs with ADMET properties
DBs with physico-chemical properties
Curiously does not mention Chemical Abstracts

42
Databases with Protein and Ligand Information
(Jónsdóttir)

Protein Data Bank
Target Registration Database
Relibaseuses structural info to analyze
protein-ligand interactions Relibase for
protein-protein interaction searching
Cambridge Structural Database
KEGG LIGAND DB for enzyme reactions
http//www.genome.ad.jp/ligand

43
Other Databases with Protein and Ligand
Information

SitesBase--a database of known ligand binding
sites within the PDB
http//www.bioinformatics.leeds.ac.uk/sb/main.html
Binding MOAD
http//www.bindingmoad.org/
sc-PDB (Kellenberger)
http//bioinfo-pharma.u-strasbg.fr8080/scPDB/inde
x.jsp

44
sc-PDB http//bioinfo-pharma.u-strasbg.fr8080/sc
PDB/index.jsp
45
Isatin Search on sc-PDB
46
Other Databases with Protein-Protein Interaction
Data (Jónsdóttir)

YPD, Yeast Proteome Database (for proteins from
S. cerevisiae)
http//www.biobase.de/pages/index.php?id139
Human Protein Reference Database
http//www.hprd.org/
BIND, Biomolecular Interaction Network Database
(ceased as of 11/16/2005?)
http//www.bind.ca/Action

47
International Molecular Exchange (IMEx)
Consortiumhttp//imex.sourceforge.net/

BIND (http//www.blueprint.org) The Blueprint
Initiative AsiaPte. Ltd, Singapore and The
Blueprint Initiative North America,Toronto Canada
DIP (http//dip.doe-mbi.ucla.edu) UCLA-DOE
Institute for Genomics Proteomics
IntAct (http//www.ebi.ac.uk/intact),
EMBLEuropean Bioinformatics Institute, Hinxton,
UK
MINT (http//mint.bio.uniroma2.it/mint/)
University of Rome Tor Vergata, Rome Italy
MPact (http//mips.gsf.de/genre/proj/mpact), MIPS
/ Institute for Bioinformatics, Munich, Germany.

48
Protein Sites from IU I533 Students and others

LigandDepotintegrated source for small molecules
http//ligand-depot.rutgers.edu/index.html
PSIPRED Protein Structure Prediction Server
http//bioinf.cs.ucl.ac.uk/psipred/
DSSP--a database of secondary structure
assignments (and much more) for all protein
entries in the PDB
http//swift.cmbi.ru.nl/gv/dssp/
Dr. Predrag Radivojacs I690 class on Structural
Bioinformatics
http//www.informatics.indiana.edu/predrag/2006spr
ingi690/2006springi690.htm

49
Protein Secondary Structure Prediction

Methods
Neural Network
Rule Based
Other Machine Learning
Homology Based

50
Protein Secondary Structure Prediction Software

PredictProtein
http//www.predictprotein.org/
Chou-Fasman http//fasta.bioch.virginia.edu/fasta_
www/chofas.htm
NN Predict
http//www.cmpharm.ucsf.edu/nomi/nnpredict.html

51
Structure-Based Docking Methods

Method
Scans many small molecules and docks them to a
site of interest on a protein structure
Predicts free energy of binding
Filters thousands of compounds relatively quickly
Top hits can be used for more rigorous
computational/experimental characterization and
optimization

52
Structure-Based Docking Methods

DOCK
http//dock.compbio.ucsf.edu/
Accelryss Insight (built on DOCK)
http//www.accelrys.com/products/insight/
FlexX
http//www.biosolveit.de/FlexX/
Glide
http//www.schrodinger.com/ProductDescription.php?
mID6sID6
GOLD
http//www.ccdc.cam.ac.uk/products/life_sciences/g
old/

53
Useful Structure Databases

ModBase
http//modbase.compbio.ucsf.edu/modbase-cgi-new/se
arch_form.cgi
Dali Database (Fold classification based on PDB)
http//ekhidna.biocenter.helsinki.fi/dali/start
Protein Structure Analysis, Comparison, /or
Classification Guide
http//www.bio.vu.nl/nvtb/Structures.html

54
SCOP, Structural Classification of Proteins

Curated database of structural and evolutionary
relationships
All known protein folds (v. 1.69, July 2005)
70,859 domains organized into 2,845 families,
1,539 superfamilies, and 945 folds
Detailed information about close relatives
Links to coordinates, images of structures,
interactive viewers, and literature references
http//scop.mrc-lmb.cam.ac.uk/scop/

55
SCOP Search Options

Homology search yields a list of structures with
significant levels of sequence similarity
Keyword search matches words in SCOP and PDB

56
CATH Protein Structure Classification

Like SCOP, structured hierarchically by
Class (determined by secondary structure)
Architecture (overall shape, e.g., barrel,
sandwich, roll, etc.) no equivalent in SCOP
Topology (grouped into fold families based on
overall shape and connectivity of secondary
structures)
Homologous Superfamily (domains thought to share
a common ancestor)
As of January 2005, had 43,229 domains classified
into 1,467 superfamilies and 5,107 sequence
families A protein family database (CATH-PFDB)
contained a total of 616,470 domain sequences
classified into 23,876 sequence families
http//cathwww.biochem.ucl.ac.uk/latest/index.html

57
CATH Search Options

Can browse or search the classification by CATH
code
CATH codes can be used to search other databases,
e.g., DHS, Gene3D, and Impala

58
Gasteigers Biochemical Pathways Database

Database of biochemical pathways that represents
chemical structures and reactions on the atomic
level
Gives access to each atom and bond of the
substrates of enzyme reactions
Allows the study of transition state hypotheses
of enzyme reactions
Analysis of the physicochemical effects operating
at the reaction site allows a classification of
enzyme reactions that goes beyond the traditional
EC code for enzymes.
1533 biochemical molecules and 2175 reactions
http//www2.chemie.uni-erlangen.de/services/biopat
h/index.html

59
A Gene Expression Database for NCI60 (Scherf)

Published in Nature Genetics, 2000
First study to integrate gene expression with
molecular pharmacology databases
Gene expression profiles for NCI60 assessed
using microarray technology
Gene-drug relationships investigated by how the
gene transcription levels vary with respect to
drug activities

60
Correlation Matrix Between Drug Activity and Gene
Expression
61
Other Relevant Databases/Servers

Each year Nucleic Acids Research publishes a
Database Issue in January and a Web Server Issue
in July (See refs in Bibliography section).
Examples from the most recent issues

62
Overview of the Talk

Review of ACS CINF 2004 Papers
Review of Relevant Articles
Public Chemistry Databases and Data Repositories
with Bioinformatics Info/Links
Overview of Web Services
NIH-funded Projects Underway or Planned at
Indiana University

63
Web Services Overview

What are Web Services?
A distributed invocation system built on Grid
computing
Independent of platform and programming language
Built on existing Web standards
A service oriented architecture with
Interfaces based on Internet protocols
Messages in XML (except for binary data
attachments)

64
Service-Oriented Architecture

From Curcin et al. DDT, 2005, 10(12),867

65
Web Services for Chemistry Problems

Performance and scalability
Proprietary data
Competition from high-performance desktop
applications
-- Geoff Hutchison, its a puzzle blog,
2005-01-05
ALSO
Lack of a substantial body of trustworthy Open
Access databases
Non-standard chemical data formats (over 40 in
regular use and requiring normalization to one
another)

66
Overview of the Talk

Review of ACS CINF 2004 Papers
Review of Relevant Articles
Public Chemistry Databases and Data Repositories
with Bioinformatics Info/Links
Overview of Web Services
NIH-funded Projects Underway or Planned at
Indiana University

67
Indiana University Planned Projectshttp//www.ch
embiogrid.org

Design of a Grid-based distributed data
architecture
Development of tools for HTS data analysis and
virtual screening
Database for quantum mechanical simulation data
Chemical prototype projects
Novel routes to enzymatic reaction mechanisms
Mechanism-based drug design
Data-inquiry-based development of new methods in
natural product synthesis

68
Web Services for Chemistry at IU
69
NCI Developmental Therapeutics Program (DTP)

Downloadable data
In vitro 60 cell line results
in vitro anti-HIV results
Yeast assay
200,000 chemical structures
molecular targets
microarray data
Or search the database at
http//dtp.nci.nih.gov/docs/dtp_search.html

70
IU Database of NIH DTP Data

Contains over 200,000 chemical structures tested
in 60 cellular assays from different human tumor
cell lines
Also includes microarray assay profiles for the
untreated cell lines (14,000 datapoints)
A local PostgreSQL database containing the data
that is exposed as a web service
Using workflows and complex SQL queries, we can
do advanced data mining that exploits the
chemical, biological and genomic information for
particular audiences (chemists, biologists, etc)

71
Mining the NIH DTP database
14,000 gene expression values
60 cell lines
Cell lines can be clustered based on gene
expression similarity
200,000 compounds
Compounds can be clustered based on similarity of
profile across cell lines, or by chemical
structure fingerprint similarity
72
Use of Taverna at IU

A protein implicated in tumor growth is supplied
to the docking program (in this case HSP90 taken
from the PDB 1Y4 complex)
The workflow employs our local NIH DTP database
service to search 200,000 compounds tested in
human tumor cellular assays for similar
structures to the ligand.
Client portlets are used to browse these
structures
Once docking is complete, the user visualizes the
high-scoring docked structures in a portlet using
the JMOL applet.
Similar structures are filtered for drugability,
and are automatically passed to the OpenEye FRED
docking program for docking into the target
protein.
A 2D structure is supplied for input into the
similarity search (in this case, the extracted
bound ligand from the PDB IY4 complex)
Correlation of docking results and biological
fingerprints across the human tumor cell lines
can help identify potential mechanisms of action
of DTP compounds

73
Taverna Workflow
Workflow definition
Available web services (WSDL)
Visual depiction of workflow
74
Taverna in Action
75
Overall Workflow
76
Pre-Closing Quote

There is not going to be a voila moment at the
computer terminal. Instead, there is systematic
use of wide-ranging computational tools to
facilitate and enhance the drug discovery
process.
Jorgensen. Science, March 19, 2004, 303, 1814.

77
Closing quote

The future of chemistry depends on the
automated analysis of chemical knowledge,
combining disparate data sources in a single
resource, such as the World-Wide Molecular
Matrix, which can be analysed using computational
techniques to assess and build on these data.
Townsend et al. Org. Biomol. Chem. 2004, 2, 3299.

78
Post-closing quote zzzzzCAS

In an industry first, Chemical Abstracts Service
(CAS) has unveiled a revolutionary new literature
searching tool which will permit scientists to
search and retrieve the worlds chemical
literatureincluding patents and obscure
technical reportsin their sleep.
--Author unknown

79
Acknowledgements

Randy Arnold
Xiao Dong
Sean Mooney
Peter Murray-Rust
David J. Wild
I533 Chemical Informatics Seminar Students
Elsevier Science

80
Bibliography Articles, Books, and Conference
Papers

The Bigger Picture Linking Bioinformatics to
Cheminformatics CINF Symposium Abstracts
1-16, 227th ACS National MeetingAnaheim, CA,
March 28-April 1, 2004 http//www.acscinf.org/new/
docs/meetings/227nm/227cinfabstracts.htm
Austin, C.P. The completed human genome
implications for chemical biology. Current
Opinion in Chemical Biology 2003, 7, 511-515.
Bajorath, Jürgen, ed. Chemoinformatics concepts,
methods, and tools for drug discovery. Totowa,
N.J. Humana Press, c2004. (Methods in molecular
biology v. 275)
Banville, Debra L. Mining chemical structural
informationo from the drug literature. Drug
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Brown F. Editorial opinion chemoinformatics - a
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Discovery and Development 2005 May 8(3)
298-302.

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Bibliography Articles (contd)

Coles, Simon J. Day, Nick E. Murray-Rust,
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Curcin, Vera Ghanem, Moustafa Guo, Yike. "Web
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Zimmermann, Marc Thi, Le Thuy Bui Hofmann,
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85
Bibliography Databases

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86
Bibliography Databases (contd)

Kanehisa, M. Goto, S. Hattori, M.
Aoki-Kinoshita, F. Itoh, M. Kawashima, S.
Katayama, T. Araki, M Hirakawa, M. From
genomics to chemical genomics new developments
in KEGG. Nucleic Acids Research 2006, 34,
Database issue D354-D357. doi
101093/nar/gkj102.
Kellenberger, Esther Muller, Pascal Schalon,
Clarire Bret, Guillaume Foata, Nicolas Rognan,
Didier. sc-PDB An annotated database of
druggable binding sites from the Protein Data
Bank. Journal of Chemical Information and
Modeling 2006, 46(2), 717-727.
Kirwin, J.J. Shoichet, B.K. ZINCA free
database of commercially available compounds for
virtual screening. Journal of Chemical
Information and Modeling 2005, 45, 177-182.
Kouranov, A. Xie, L. de la Cruz, J. Chen, L.
Westbrook, J. Bourne, P.E. Berman, H.M. The
RCSB PDB information protal for structural
genomics. Nucleic Acids Research 2006, 34,
Database issue D302-D305 doe 101093/nar/gkj120
Kumar, M.D.S. Gromiha, M.M. PINT
Protein-protein interactions thermodynamic
database. Nucleic Acids Research 2006, 34
Database issue D195-D198 doi 10.1093/nar/gkj017

87
Bibliography Databases (contd)

Lo Conte, L. Brenner, S.E. Hubbard, T.J.P.
Chothia, C. Murzin, A.G. SCOP database in 2002
refinements accommodate structural genomics.
Nucleic Acids Research 2002, 30(1) 264-267.
Murzin, A.G. Brenner, S.E. Hubbard, T.
Chothia, C. SCOP A structural classification of
proteins database for the investigation of
sequences and structures. Journal of Molecular
Biology 1995, 247, 536-540.
Okuno, Y. Yang, J. Taneishi, K. Yabuuchi, H.
Tsujimoto, G. GLIDA GPCR-ligand database for
chemical genomic drug discovery. Nucleic Acids
Research 2006, 34, Database issue D673-D677 doi
10.1093/nar/gkj028.
Pearl F, Todd A, Sillitoe I, Dibley M, Redfern O,
Lewis T, Bennett C, Marsden R, Grant A, Lee D,
Akpor A, Maibaum M, Harrison A, Dallman T, Reeves
G, Diboun I, Addou S, Lise S, Johnston C, Sillero
A, Thornton J, Orengo C. The CATH Domain
Structure Database and related resources Gene3D
and DHS provide comprehensive domain family
information for genome analysis. Nucleic Acids
Research. 2005, 33 Database Issue D247-D251.

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Bibliography Databases (contd)

Wheeler, D.L. et al. Database resources of the
National Center for Biotechnology Information.
Nucleic Acids Research 2006, 34 Database Issue
D173-D180 doi 10.1093/nar/gkj158
Wishart DS, Knox C, Guo AC, Shrivastava S,
Hassanali M, Stothard P, Chang Z, Woolsey,
Jennifer. DrugBank a comprehensive resource for
in silico drug discovery and exploration.Nucleic
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D668-72.

89
Biotech Validation Suite for Protein Structures

Send the server a PDB file
Server provides a comprehensive check of the
protein, including
Atomic volume analysis
Full geometric analysis
NMR restraint data
http//biotech.ebi.ac.uk8400/

90
Knowledge-Driven Bioinformatics Enhanced with
Chemistry
91
ToxTree

An in silico toxicology prediction suite
Based on the CDK toolkit
Built on CML
Released as OpenSource under the GPL
Standalone PC software
User Manual http//ecb.jrc.it/DOCUMENTS/QSAR/TOXT
REE/toxTree_user_manual.pdf

92
Tools for Genomic and Proteomic Scientists
vis-à-vis Cell Biology (Gagna et al.)

Tools to fully exploit the techniques in cellular
biology
Light microscopy for high resolution images
Fractionation of cells into basic components via
ultracentrifugation
Analysis of individual cells through flow
cytometry
LCM, normal and diseased TMAs (tissue
microarrays), quantitative computer image
analysis, cell micromanipulation, and
high-throughput microscopy

93
InChI Generation on the Web

The following websites provide the facility to
generate InChIs
www.acdlabs.com/download/chemsk.htmlACD/Labs'
freely available structure-drawing program
ChemSketch includes the facility to generate
InChIs from drawn structures.
pubchem.ncbi.nlm.nih.gov/edit/PubChem Server
Side Structure Editor v1.8 includes a facility
for generating InChIs as you draw the structure.

94
Advances in Macromolcular Crystallography by CCG

More protein structures available now
Use of 3D info in bioinformatics makes functional
inferences more dependable
CCG Structural Family Database distributed with
MOE
Includes fold detection methodology to ID
structurally similar proteins
Simultaneous sequence and structural alignment of
large collections of proteins
3D structural family analysis for insight into
conserved geometry, water molecules, salt
bridges, hydrogen bonds, hydrophobic contacts,
and disulfide bonds

95
CCGs Cheminformatics Offerings

MOE Molecular Database
Mo lecular Descriptors calculated and used for
classification, clustering, filtering, and
predictive model construction
QSAR/QSPR Predictive Modeling
Diversity and Similarity Searching
High Throughput Conformational Search
3D Pharmacophore Search

96
Components of the Semantic Web for Chemistry

XML eXtensible Markup Language
RDF Resource Description Framework
RSS Rich Site Summary
Dublin Core allows metadata-based newsfeeds
OWL for ontologies
BPEL4WS for workflow and web services
Murray-Rust et al. Org. Biomol. Chem. 2004, 2,
3192-3203.

97
Web Services Integration Projects Biosciences

myGrid
http//www.mygrid.org.uk/
BIOPIPE
http//biopipe.org/
BioMOBY
http//biomoby.org/

98
BIOT 2006

Major themes, areas and suggested topics include
- Bio-molecular and Phylogenetic Databases
- Molecular Evolution and Phylogenetic analysis
- Drug Delivery Systems
- Bio-Ontology and Data Mining
- Sequence Search and Alignment
- Microarray Analysis
- System Biology
- Pathway analysis
- Identification and Classification of Genes
- Protein Structure Prediction and Molecular
Simulation
- Functional Genomics
- Proteomics
- Tertiary structure prediction
- Drug Docking
- Gene Expression Analysis
- Biomedical Imaging

99
Proteomics What is it?

Proteomics is the study of protein expression,
regulation, modification, and function in living
systems for understanding how living systems use
proteins. Using a variety of techniques,
proteomics can be used to study how proteins
interact within a system, or how proteins change
due to applied stresses.
Requires advanced measurement techniques,
especially separations and mass spectrometry

100
Proteomics Needs Informatics for