BIOINFORMATICS APPLICATIONS NOTE
Vol. 25 no. 12 2009, pages 1568–1569
Databases and ontologies
ProtVirDB: a database of protozoan virulent proteins
Jayashree Ramana and Dinesh Gupta∗
Structural and Computational Biology Group, International Centre for Genetic Engineering and Biotechnology
(ICGEB), Aruna Asaf Ali Marg, New Delhi 110067, India
Received on February 13, 2009; revised on March 23, 2009; accepted on April 8, 2009
Advance Access publication April 15, 2009
Associate Editor: Burkhard Rost
Summary: ProtVirDB is a comprehensive and user-friendly web-
based knowledgebase of virulent proteins belonging to protozoan
species. The database will facilitate research and provide an
integrated platform for comparative studies of virulent proteins in
different parasitic protozoans and organize them under a unifying
classification schema with functional categories. Remarkably,
one-third of the protein sequences in the database showed
presence of either mono- or hetero-repeats, or both concomitantly—
hence reiterating the importance of repeats in parasite virulence
mechanisms. A number of useful bioinformatics tools including
BLAST and tools for phylogenetic analysis are integrated with the
database. With the rapidly burgeoning interest in the pathogenesis
mechanisms of protozoans and ongoing genome sequencing
projects, we anticipate that the database will be a useful tool for
the research community.
Supplementary information: Supplementary data are available at
Virulent proteins are an important class of proteins enabling
pathogens to evade host immune mechanisms to cause disease
in the host. There is an ever-growing interest to identify novel
virulent proteins in variety of pathogens in order to counter growing
drug resistance and to develop novel vaccines. Well-defined classes
for bacterial virulent proteins (Prescott et al., 1999) have been
described; however, no such classification is available for protozoan
virulent proteins. There are databases of bacterial virulent proteins
like VFDB, PRINTS and MVirDB (Zhou et al., 2006); however,
there is no report of any such database for protozoans.
In this work, our main objective was to develop a unified
other parasites. We have attempted a function-based classification
for these proteins. However, the delineation amongst different
categories is rather vague, for example adhesion and invasion
(e.g. CSP protein from Plasmodium falciparum), and is for the
purpose of a broad outline.
∗To whom correspondence should be addressed.
ProtVirDB is a non-redundant database currently holding a
cumulative collection of 345 unique virulent proteins (however,
number of total entries is 1775, as the database contains several
polymorphic proteins) from 12 important parasitic protozoans
(Supplementary Material 1). The database entries were manually
curated from bibliographic (PubMed) and sequence (GenBank,
RefSeq and SwissProt) databases (Fig. 1). Based on the currently
available literature, each protein was allotted to one of the following
functional categories: Adhesin, Invasion, Establishment (within the
host, i.e. proteins involved in nutrient acquisition or evasion of
host immunity), Proteases, Cysteine proteases, Heat shock proteins
and Others. Cysteine proteases serve a multitude of roles like
cytoadherence, invasion, etc., so an exclusive category has been
devoted to these.
3 DATABASE ARCHITECTURE AND DATA
ProtVirDB is implemented as a MySQL database (Supplementary
Material 2), PHP is used to connect the database and dynamically
generate user-friendly HTML front-end queries, using Apache web
server. The web interface query form allows users to selectively
retrieve a table enlisting details (functional category and a brief
Fig. 1. ProtVirDB database schema. The protein sequences were collected
by keyword search from different databases and then filtered by retrieving
related articles from PubMed. Value addition included classification of
filtered pool sequences into different categories and additional analysis
(like Pfam domains, pI/Mw, PDB code, vaccine potential and presence of
amino acid repeats). The web-based user interface integrated with powerful
bioinformatics tools facilitates database query and analysis.
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ProtVirDB Download full-text
description) of virulent proteins from one or more organisms within
a single or multiple functional categories. Users can selectively
download the proteins of interest as an excel table or FASTA file.
Each protein is linked to additional information comprising its
molecular weight, pI, PDB code, Pfam domains (Finn et al., 2008),
amino acid repeats and PubMed links. Additional PubMed links
for verified or predicted vaccine or immunotherapeutic targets are
included. Links have been provided for TDR drug target database
entries (Aguero et al., 2008). Alternatively, the database can be
queried with user-defined keywords, with accession number or
molecular weight combined with the filter based on organism name.
and epitope prediction are provided.
ProtVirDB is integrated with several useful tools to facilitate
sequence retrieval and analysis. The ViroBlast (Deng et al.,
2007) tool allows users to search for entries in ProtVirDB
that have sequence similarity to query protein sequences. This
provides the advantage of parsing the results according to an
E-value or score cut-off chosen by the user. The integrated
ClustalW (Thomson et al., 1994) and Muscle (Edgar, 2004) tools,
supplemented with the colorful display generated by Jalview
(Clamp et al., 2004), perform multiple sequence alignment of
selected sequences. The Java-based ATV program (Clamp et al.,
2004) allows the viewing of phylogenetic trees obtained from
the QuickTree program (Howe et al., 2002). The antigenic
program from the EMBOSS package (Rice et al., 2000) predicts
potentially antigenic regions of a protein sequence. The detection
of conserved motifs in protein sequences is critical for annotation
of proteins. The available tools for this purpose like PPsearch
(http://www.ebi.ac.uk/Tools/ppsearch/index.html) allow the user to
scrutinize only the already recognized and conserved motifs in
databases like Prosite. Herein, a simple and versatile tool called
ProbeMotiF facilitates search of user-defined motifs within the
ProtVirDB database or any other user-defined set of sequences. This
is a PERL-based tool that allows the users to search for motifs
using regular expressions including wildcards. This serves as a
supplementary tool, especially in cases where a newly discovered
motif can be quickly searched in the database.
INTEGRATED WEB-BASED TOOLS
well as protozoans (Fankhauser et al., 2007). We scanned the entire
ProtVirDB database for the presence of repeats using the DIREP
program developed by us earlier (Kalita et al., 2006). Interestingly,
both homo- and heterorepeats were detected in 32% of the total
sequences (101 unique proteins out of 315). See Supplementary
Materials 3 and 4 for the list of sequences. In the database, the P.
falciparum sequences alone accounted for 33 proteins with repeats
(out of 45), followed by Entamoeba histolytica 11 (out of 29) (see
Supplementary Material 1 for details). These figures are strikingly
high when compared with the percentages of repeat containing
proteins in the entire proteomes [33.49% and 2.79%, respectively,
Depledge et al. (2007)]. This may well be an underestimation
of the proportions since the set of ProtVirDB virulent proteins
represents only the currently annotated virulent proteins in the
AMINO ACID REPEATS ANALYSIS
parasite genomes. Yet, the presence of repeats in almost one-third
of the proteins within a small collection is certainly intriguing
and reinforces that repeat-containing proteins play an indispensable
role in the parasite’s virulence. It is noteworthy that we did not
observe any bias of repeat-containing proteins within any specific
functional category. Cysteine proteases, proteases and heat shock
protein categories were scantily represented in this set, but this bias
could be due to their under-representation in the database.
Diseases caused by parasitic protozoans are often studied in
isolation; however, comparative studies may provide a key to
hitherto undiscovered but common mechanisms of virulence. The
ProtVirDB database can assist in research efforts aimed at such
comparative studies. It also provides ground for further studies
related to the significance of repeat-containing proteins in the
virulence of the protozoan parasites. The database will be updated
regularly and additional tools incorporated. Given the mounting
interest in protozoan parasitic diseases, we expect ProtVirDB to
serve as a valuable resource to the scientific community.
Computational resources were provided by the Bioinformatics
International Center for Genetic Engineering and Biotechnology,
New Delhi, India.
Funding: Council of Scientific and Industrial Research (CSIR)
fellowship (to J.R.).
Conflict of Interest: none declared.
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