biological databases.pptx

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Biological Databases
Introduction to Database
A database is a computerized archive used to store and organize data in such a way that information can be retrieved easily via a variety of
search criteria.
Databases are composed of computer hardware and software for data management.
The chief objective of the development of a database is to organize data in a set of structured records to enable easy retrieval of information.
Each record, also called an entry,should contain a number of fields that hold the actual data items, for example, fields for names, phone
numbers, addresses, dates.
To retrieve a particular record from the database, a user can specify a particular piece of information, called value, to be found in a particular
field and expect the computer to retrieve the whole data record.
This process is called making a query.
Although data retrieval is the main purpose of all databases, biological databases often have a higher level of requirement, known as
knowledge discovery, which refers to the identification of connections between pieces of information that were not known when the
information was first entered.
For example, databases containing rawsequence information can perform extra computational tasks to identify sequence homology or
conserved motifs. These features facilitate the discovery of new biological insights from raw data
Structure of Databases
Biological databases are organized in a structured manner to facilitate efficient storage and retrieval of information.
The most common structure is a relational database, where data is stored in tables with rows and columns. Each row
represents a record, and each column represents an attribute.
Databases employ a schema that defines the relationships between different tables and ensures data consistency.
Classification of Biological Database
(Based on type of data)

Biological Database

Structure Sequence Other

Nucleotide Protein
Protein Data Bank Gene
(PDB) Expression
SCOP Omnibus
GenBank Swiss-
CATH (GEO)
DDBJ PROT PubMed
EMBL PIR ArrayExpress
TrEMBL BioCyc
ProSite BRENDA
PFam PubChem
Primary Databases
There are three major public sequence databases that store raw nucleic acid
sequence data produced and submitted by researchers worldwide:
GenBank, the European Molecular Biology Laboratory (EMBL)
database and the DNA Data Bank of Japan (DDBJ), which are all freely
available on the Internet.
These three public databases closely collaborate and exchange new data
daily. They together constitute the International Nucleotide Sequence
Database Collaboration (INSDC). This means that by connecting to any
one of the three databases, one should have access to the same nucleotide
sequence data.
Although the three databases all contain the same sets of raw data, each of
the individual databases has a slightly different kind of format to represent
the data.
Fortunately, for the three-dimensional structures of biological
macromolecules, there is only one centralized database, the Protein Data
Bank (PDB).
The International Nucleotide Sequence Database Collaboration (INSDC) is a global collaboration of
independent governmental or non-profit organisations that manage nucleotide sequence databases capturing
and preserving nucleotide sequence information and annotations to create a comprehensive collection that
preserves the scientific record and enables broad sharing of such data. INSDC Members provide data
resources that include raw sequence reads and alignments, structured metadata describing investigated
samples such as taxonomic information, experimental, and project design, assembled nucleotide sequence
data with functional annotation, and sequence-derived analyses. INSDC Members exchange data and make
exchanged data freely accessible without restrictive licensing as part of the scientific record, including all
corrections and updates.
 GenBank Data Storage Public Access
https://www.ncbi.nlm.nih.gov/genbank/
GenBank stores information on GenBank data is freely
GenBank is a comprehensive database of publicly DNA and RNA sequences, accessible to researchers
available nucleotide sequences. It is maintained by the including their annotations, such as worldwide, enabling scientists to
National Center for Biotechnology Information gene names, protein products, and collaborate and share their
(NCBI) in the United States.The database started in other relevant details. findings.
1982 by Walter Goad and Los Alamos National
Laboratory. GenBank has become an important
database for research in biological fields and has Regular Updates
grown in recent years at an exponential rate by GenBank is regularly updated with new sequences and annotations, ensuring
doubling roughly every 18 months. that the database remains current and comprehensive.
 EMBL
EMBL is a nucleotide sequence database maintained by the European Molecular
Biology Laboratory (EMBL-EBI) in the United Kingdom. EMBL was created in 1974
and is funded by public research money from its member states. The Laboratory
operates from six sites: the main laboratory in Heidelberg (Germany), and sites in
Barcelona (Spain), Grenoble (France), Hamburg (Germany), Hinxton (the European
Bioinformatics Institute (EBI), in England), and Rome (Italy).

https://www.ebi.ac.uk/
1 Global Collaboration 2 Data Variety
EMBL collaborates with other EMBL stores a wide range of
international databases, such as GenBank sequence data, including
and DDBJ, to ensure data consistency genomic DNA, mRNA, and
and facilitate data exchange. protein sequences.

3 Specialized Resources 4 Data Sharing
EMBL offers specialized resources and EMBL is committed to open data sharing
tools for sequence analysis, including and provides access to its data through its
BLAST and ClustalW. website and various data exchange
platforms.
DDBJ https://www.ddbj.nig.ac.jp/index-e.html

DDBJ is a nucleotide sequence database maintained by the DNA Data Bank of Japan (DDBJ) in Japan.
It is located at the National Institute of Genetics (NIG) in the Shizuoka prefecture of Japan. DDBJ began data bank
activities in 1987 at NIG and remains the only nucleotide sequence data bank in Asia.

Japanese Focus International Collaboration Specialized Resources
DDBJ has a strong focus on DDBJ collaborates closely with DDBJ offers specialized
sequencing data from Japanese GenBank and EMBL, ensuring resources for analyzing sequence
researchers, particularly in the that the three databases maintain data, such as the DDBJ
fields of genomics and a high level of consistency. Sequence Read Archive (DRA).
transcriptomics.
 Similarities and Differen
between the Databases
GenBank, EMBL, and DDBJ share the common goal of storin
disseminating nucleotide sequence data.

GenBank EMBL
Feature

United States United
Location
Kingdom

Nucleotide Nucleotide
Data Type
sequences sequences

Data Size Largest Medium

Collaboration Yes Yes
Data Formats and File Types
Nucleotide sequence databases utilize specific data formats and file types to store and exchange sequence data and associated metadata.

FASTA Format XML Format
A flexible format that allows for the representation of
A simple text-based format that represents a sequence with a
complex data structures and relationships using tags and
header line providing information about the sequence,
hierarchical organization. XML is used by some
followed by the sequence string itself. This format is widely
databases to encode sequence data and associated
used for exchanging and storing sequence data due to its
metadata in a machine-readable format that facilitates
simplicity and ease of use.
data exchange and integration.

GenBank Flat File
A more structured format used by the GenBank database that
includes extensive annotations and metadata related to the sequence,
such as source organism, gene features, references, and other
contextual information. This format provides a rich representation of
the sequence data.

These data formats and file types play a crucial role in the efficient storage, exchange, and analysis of nucleotide sequence data within and across the major
sequence databases.
Sample GenBank Record
FASTA format

A sequence in FASTA format begins with a single-line description, followed by lines of
sequence data.
The description line (defline) is distinguished from the sequence data by a greater-than (“>”)
symbol at the beginning.
Blank lines are not allowed in the middle of FASTA input.
It is recommended that all lines of text be shorter than 80 characters in length.
An example sequence in FASTA format is:
>P01013GENEXPROTEIN(OVALBUMINRELATED)
QIKDLLVSSSTDLDTTLVLVNAIYFKGMWKTAFNAEDTREMPFHVTKQESKPVQMMCMNNSFNVATLPAEK
MKILELPFASGDLSMLVLLPDEVSDLERIEKTINFEKLTEWTNPNTMEKRRVKVYLPQMKIEEKYNLTSVLMA
LGMTDLFIPSANLTGISSAESLKISQAVHGAFMELSEDGIEMAGSTGVIEDIKHSPESEQFRADHPFLFLIKHNPT
NTIVYFGRYWSP
https://www.uniprot.org/
The Universal Protein Resource KnowledgeBase (UniProtKB) is the central hub for the collection of functional information
on proteins.

Swiss-Prot Tr-EMBL
TrEMBL
Founder: Rolf Apweiler
Secondary database
TrEMBL is a computer annotated protein sequence database
UniProtKB/TrEMBL contains the translations of all coding sequences (CDS) present in the
INSDC.
Protein sequences extracted from literature or submitted to UniProtKB/ Swiss-Prot
Enriched with automated classification and annotation.
 UniProtKB
REM-TrEMBL
contains sequences which
will not be incorporated in
Swiss-Prot
EX- synthetic sequences,
Swiss-Prot Tr-EMBL fragment of less than 8
amini acids and CDS where
Reviewed Unreviewed there is strong experimental
Manually annotated Computationally evidence that sequence does
Records with annotated not code for a real protein
information extracted Records that await
from literature and full manual
curator-evaluated annotation
computational Sp-TrEMBL
analysis contains sequences
which will eventually be
added into Swiss-Prot
 https://www.expasy.org/resources/uniprotkb-swiss-prot

Swiss-Prot
UniProtKB/Swiss-Prot is the expertly curated component of UniProtKB (produced by the UniProt consortium).
It contains hundreds of thousands of protein descriptions, including function, domain structure, subcellular location, post-translational
modifications and functionally characterized variants.
Developed by the Swiss-Prot group and UniProt partners at EMBL-EBI and PIR, and supported by the SIB Swiss Institute of
Bioinformatics.
https://www.rcsb.org/

3D structural data of large
biological molrcules, such as WHY?
proteins and nucleic acids Growing crystallographic data
Data-X-ray crystallography, development of BRAD in 1968
NMR spectroscopy or cryo-
electron microscopy
Overseen by wwPDB

How did it start?
The PDB was established in 1971 at Brookhaven National Laboratory under the
leadership of Walter Hamilton and originally contained 7 structures.
After Hamilton's untimely death, Tom Koetzle began to lead the PDB in 1973,
and then Joel Sussman in 1994.
In 2003, the Worldwide Protein Data Bank (wwPDB) was formed to maintain a
single PDB archive of macromolecular structural data that is freely and publicly
available to the global community.
PDB file format
Protein Data Bank (PDB) format is a standard for files containing atomic coordinates
Protein Data Bank format consists of lines of information in a text file. Each line of
information in
the file is called a record.
https://www.yeastgenome.org/

SGD project provides the highest-quality manually curated information from peer-reviewed literature.
The completion of the S.cerevisiae genomic DNA sequence in 1996 provided the sequence of each of its genes
The acquisition, integration and retrieval of these data allow SGD to facilitate experimental design and analysis by
providing an encyclopedia of the yeast genome, its chromosomal features, their functions and interactions.
SGD has information about the DNA sequence and its individual components, RNAs, encoded proteins and the
structures and biological functions of any known gene products.
SGD has been to create tools which allow the user to easily retrieve and display these types of information.
https://ensemblgenomes.org/
 Ensembl
Ensembl provides a genome browser that acts as a single point of access to annotated genomes for mainly vertebrate
species
Information about genes, transcripts and further annotation can be retrieved at the genome, gene and protein level.
This includes information on protein domains, genetic variation, homology, syntenic regions and regulatory elements.
The project began in 1999 as a joint project between the EMBL European Bioinformatics Institute and the Wellcome
Trust Sanger Institute
As of Ensembl release 109 (February 2023), over 300 species are supported, along with 15 mouse strains, 5 dog
breeds and 13 pig breeds.
https://www.brenda-enzymes.org/
BRENDA (BRaunschweig ENzyme DAtabase) was created in 1987 at the German National Research Center for Biotechnology in Braunschweig
(GBF) and is now continued at the University of Cologne, Institute of Biochemistry.