- Research article
- Open Access
CANGS DB: a stand-alone web-based database tool for processing, managing and analyzing 454 data in biodiversity studies
© Pandey et al; licensee BioMed Central Ltd. 2011
- Received: 13 December 2010
- Accepted: 30 June 2011
- Published: 30 June 2011
Next generation sequencing (NGS) is widely used in metagenomic and transcriptomic analyses in biodiversity. The ease of data generation provided by NGS platforms has allowed researchers to perform these analyses on their particular study systems. In particular the 454 platform has become the preferred choice for PCR amplicon based biodiversity surveys because it generates the longest sequence reads. Nevertheless, the handling and organization of massive amounts of sequencing data poses a major problem for the research community, particularly when multiple researchers are involved in data acquisition and analysis. An integrated and user-friendly tool, which performs quality control, read trimming, PCR primer removal, and data organization is desperately needed, therefore, to make data interpretation fast and manageable.
We developed CANGS DB (C leaning and A nalyzing N ext G eneration S equences D ataB ase) a flexible, stand alone and user-friendly integrated database tool. CANGS DB is specifically designed to organize and manage the massive amount of sequencing data arising from various NGS projects. CANGS DB also provides an intuitive user interface for sequence trimming and quality control, taxonomy analysis and rarefaction analysis. Our database tool can be easily adapted to handle multiple sequencing projects in parallel with different sample information, amplicon sizes, primer sequences, and quality thresholds, which makes this software especially useful for non-bioinformaticians. Furthermore, CANGS DB is especially suited for projects where multiple users need to access the data. CANGS DB is available at http://code.google.com/p/cangsdb/.
CANGS DB provides a simple and user-friendly solution to process, store and analyze 454 sequencing data. Being a local database that is accessible through a user-friendly interface, CANGS DB provides the perfect tool for collaborative amplicon based biodiversity surveys without requiring prior bioinformatics skills.
- Chimeric Sequence
- Rarefaction Analysis
- Query Interface
- Biodiversity Survey
- Database Tool
Next generation sequencing technologies are delivering data at a hitherto unprecedented speed and dramatically reduced costs. In addition to genome sequencing and transcriptome profiling, ultra-deep sequencing of short amplicons offers an enormous potential in clinical studies  and in surveys of ecological diversity [2–4]. Typical biodiversity surveys include sequences from a diverse set of samples. An effective data analysis requires the ability to link additional data, such as time of collection and ecological variables, to the sequences. Furthermore, biodiversity surveys often require sequence information on different taxonomic levels. Hence, researchers need an analytical tool that provides the flexibility to handle different PCR primers.
Until now several tools have been developed, but none of them unite all of the requirements for a comprehensive tool. In the following we briefly introduce these tools, highlight their features, and discuss missing options.
1) RDP  is an online tool for sequence trimming and filtering. It provides an excellent taxonomic classifier, which is, however, limited to small ribosomal subunit gene sequences from bacteria and archea. Furthermore, it provides no option to store and manage data provided by the user. MOTHUR  combines read trimming and filtering capabilities along with rare-faction analyses. MOTHUR is a command line software and provides many useful utility commands for biodiversity studies but it does not offer a data storage option. CANGS  and CANGS DB rely on MOTHUR for rarefaction analyses. VAMPS  provides sequence trimming, filtering of low quality reads and taxonomic path assignment using the GAST pipeline. The user can upload data for visualization and analysis of microbial population structures. The limitation of VAMPS is a rigid sequence-processing pipeline that does not allow for user-defined options (e.g.: reads are only filtered allowing for ambiguities, it is not possible to define a size range for amplicon sizes, and quality scores of the sequence reads are not accounted for). Furthermore, it is not possible to store additional data about the sequences, such as ecological variables. Finally, the user cannot retrieve data according to user-defined criteria. PANGEA  allows for trimming of the barcodes and groups sequences according to the barcode. PANGEA has many useful features including clustering, classification, and comparison of microbial communities. While PANGEA uses a local database for classification, it is not designed to incorporate user-generated sequences into this database. Thus, data manipulation and organization of 454 data from multiple runs is not possible.
We developed CANGS DB (http://code.google.com/p/cangsdb/) as an integrated user-friendly database tool that can be easily installed on local computers and accessed through the internet by standard browsers. It offers a flexible, customizable sequence-processing pipeline where 454 sequences can be uploaded/downloaded and data can be manipulated via a user-friendly interface. A variety of tools are available in the CANGS DB web interface for the downstream analysis of stored 454 sequencing data. CANGS DB links external information, such as details about the collection site, time of the year and environmental variables, to the sequence information. This allows the user to extract sequences according to combinations of particular variables (e.g.: all sequences obtained from water samples with a given temperature). A demo of CANGS DB is running on http://i122mc100.vu-wien.ac.at/CANGSdb/
Database and web interface development
Required programs are Bioperl , BLAST  for the similarity search in the taxonomy analysis tool, MAFFT  for pairwise distance calculation (MAFFT is used for pairwise alignment) in the rarefaction analysis tool, MOTHUR  for estimating the number of species (OTUs), MySQL  for data storage, update_blastdb.pl  for downloading the BLAST database on a local computer, and R  to plot rarefaction curves from MOTHUR output.
Processing the raw sequence data
1. Removal of adapter B
based on the sequences of adapter B, as specified in the primer & barcodes input file, the 3'- end of each read is trimmed. It is possible to process only sequences with a perfect match to adapter B. Alternatively, a pattern search that allows for imperfection in adapter B can also be used, allowing more sequences to be recovered. CANGS DB also enables trimming multiple adapter B sequences of different lengths. Poly N tails at the 3' end of the 454 reads are removed before Adapter B trimming.
2. Filtering sequences with ambiguities
CANGS DB allows the removal of reads with one or more Ns (unknown bases).
3. Grouping of sequences according to bar codes
CANGS DB groups sequences based on the barcodes specified in the primer & barcodes input file. Sequences with the same barcode are grouped into one category. This step is skipped when only a single sample is processed. CANGS DB is designed to allow for barcodes of different length.
4. Removal of singletons
to ameliorate the problem of sequencing errors and chimeric sequences generated by jumping PCR, CANGS DB allows the user to remove low frequency variants from the data set. Sequences must be present in at least two different samples in the entire data set before trimming of the primers. This is more stringent than the former criterion implemented in CANGS , namely a sequence being present two or three times in the whole dataset. By conditioning on the presence in two independent data sets CANGS DB excludes chimeric sequences more efficiently, as a chimeric sequence could occur multiple times in a data set, in particular if the chimeric molecule has been generated during the early PCR steps. Note that several data sets could be combined to minimize the removal of true low frequency sequence variants.
5. Filtering sequences according to length threshold
CANGS DB removes sequence reads falling outside the size range specified in the primer & barcode input file.
6. Removal of PCR primers
forward and reverse PCR primers are specified in the primer & barcode input file and removed from the sequence. Only sequences with perfect identity to the specified PCR primers are processed. The 454 sequencing process preferentially generates length variants in homopolymers. As homopolymers can be as short as two bases and the target sequence is frequently not known, we developed a special procedure to recognize such sequencing errors at the end of the PCR primer as described in .
7. Quality filtering
CANGS DB averages the quality values for each base in a read. Quality values are taken from the .qual file after the values corresponding to adapter B, bar code and primer bases have been removed in step 1, step 3 and step 6, respectively. Sequence reads with a quality value lower than the threshold specified in the user interface page will be discarded. Note that the quality filtering may result in new singletons, which remain in the data set, as the quality filtering is the last step in the analysis.
After trimming the sequence reads, CANGS DB creates a non-redundant sequence data set in order to reduce the computational burden for further analysis. In the non-redundant sequence data set each sequence variant is only represented once. Note that in this step indels are considered to be informative. Hence, two sequences differing only by an indel will be listed independently in the non-redundant data set. The frequency of each sequence in the non-redundant data set is included in the FASTA header. The output file contains non-redundant reads that are ranked by copy number in descending order.
Taxonomic classification assignment
CANGS DB uses the CANGS  taxonomy analysis pipeline to assign a taxonomic path to the newly sequenced 454 reads. CANGS taxonomy analysis pipeline does not rely on a pre-curated database for either 16S or 18S sequence like RDP classifier , thus it can handle sequences from any genomic region.
One of the unique features of CANGS DB is its powerful query interface. The query interface was designed with the diversity of 454 data (ecological or clinical) in mind that need to be stored and queried. In case of ecological survey sequencing data, users can retrieve subsets of the sequences in the data base according to user defined variables, such as time of the year, temperature, pH, sampling location etc. In case of clinical data, the user can retrieve sequences according to tissue type, experiment date, sampling date, time, and other related information.
According to data sets: it is possible to select any combination of data sets loaded in the database.
According to PCR primer ID
According to sample ID: the use of barcodes permits the sequencing of multiple samples in one experiment. This option permits the user to restrict the search to specific sample IDs.
According to external sample information: A drop down menu displays all external data categories (e.g.: temperature, pH, depth, conductivity etc). The user can then specify the desired range for each of the external data categories (e.g.: temperature range: 10-20° C)
According to taxonomic group
According to sample size: The user can select a sample size and obtain random samples from all selected data sets for downstream analysis. This is particularly helpful for analyses that are sensitive to different sample sizes.
The query interface is also integrated with the Blast and rarefaction interfaces so that these analyses can be performed on the subsequent query output.
Sequence Analysis Tools
Blast analysis tool (Figure 4): it performs a BLAST search of any user provided query sequences against data stored in the CANGS DB MySQL database. This analysis provides the user with an estimate about the abundance of the queried sequences in the databank. Most important, by specifying the queried dataset this tool allows the user to ask specific questions (e.g.: does this sequence occur in samples collected in May?). Additionally, the user can retrieve the abundance of each hit sequence by clicking on it (Figure 5)
Taxonomy analysis : this tool classifies the query 454 reads by assessing their similarity to taxonomic entries in the NCBI database (Figure 6). This analysis requires the nucleotide preformatted BLAST database from ftp://ftp.ncbi.nih.gov/blast/db/ be installed, which is done using the perl program "update_blastdb.pl" .
Editing of sequence information
CANGS DB provides a user-friendly interface to update existing information, add new information or delete information. CANGS DB also allows users to edit the taxonomic path for any stored sequences. CANGS DB does not overwrite the edited taxonomic path; rather it keeps the edited taxonomic path in an additional column. This option is particularly helpful if multiple users work on the same data set, as it permits experts to correct the automated species assignation by CANGS DB and these changes are traceable for all users.
Re-processing stored 454 sequences
CANGS DB provides option to delete any uploaded data set.
Evaluation of the database
Number of reads eliminated at different steps of the CANGS DB sequence processing pipeline
Order of steps
Total no. of sequences
No. of sequences considered
No. of sequences discarded
Removal of Adapter B
Filtering sequences with ambiguities
Removal of singletons
Grouping of sequences according to bar codes
Filtering sequences according to length threshold
Removal of PCR primers
In order to increase transparency and reproducibility of the results, CANGS DB prints a log file for all processed raw data. This includes the parameter and summary statistics used for each step taken in sequence processing along with discarded sequence identities. Furthermore, stored sequences can be downloaded from CANGS DB according to the user-defined criteria.
The current version of CANGS DB is only compatible for Unix operating systems; however, we plan to make it PC compatible. Additionally we will integrate more downstream analysis tools in the CANGS DB web interface.
CANGS DB is a user-friendly and stand-alone database tool for processing, analyzing and managing the high throughput sequencing data from 454 amplicon resequencing projects. CANGSDB is very easy to use; it could be installed and used on any local UNIX based computer to handle individual as well as multiple sequencing projects in collaboration. It provides full-fledged flexibility with various options in raw sequence processing and analysis. CANGS DB provides a very powerful data retrieval interface, which enables researchers to retrieve information on samples, primers and barcodes from any individual data set or from a combination of data sets. It also provides an interface to update sample information and taxonomic classifications assigned by CANGS taxonomy analysis pipeline as well as delete any data set. The tool can be downloaded at http://code.google.com/p/cangsdb/.
Project name: CANGS DB --Cleaning, Analyzing and Managing 454 sequences.
Operating System: Mac OS X, Linux and any other UNIX like system
Programming language: Perl 5.10.0
Other requirements: BioPerl, R, BLAST, MAFFT, MOTHUR, MySQL 5.1, Apache, CGI, DBI.pm, DBD::mysql.pm
License: GNU General Public License.
Any restrictions to use by non-academics: license needed.
We are thankful to members of the Institut für Populationsgenetik for helpful discussion and special thanks to Pablo Orozco-terWengel and Raymond Tobler for helpful discussion and comments. This work was supported by FWF grants (No. P19467-B11) to CS.
- Thomas RK, Nickerson E, Simons JF, Jänne PA, Tengs T, Yuza Y, Garraway LA, LaFramboise T, Lee JC, Shah K, et al: Sensitive mutation detection in heterogeneous cancer specimens by massively parallel picoliter reactor sequencing. Nature medicine. 2006, 12 (7): 852-855. 10.1038/nm1437.PubMedView ArticleGoogle Scholar
- Huber JA, Mark Welch DB, Morrison HG, Huse SM, Neal PR, Butterfield DA, Sogin ML: Microbial population structures in the deep marine biosphere. Science. 2007, 318 (5847): 97-100. 10.1126/science.1146689.PubMedView ArticleGoogle Scholar
- Nolte V, Pandey RV, Jost S, Medinger R, Ottenwälder B, Boenigk J, Schlötterer C: Contrasting seasonal niche separation between rare and abundant taxa conceals the extent of protist diversity. Mol Ecol. 2010, 19 (14): 2908-2915. 10.1111/j.1365-294X.2010.04669.x.PubMedPubMed CentralView ArticleGoogle Scholar
- Medinger R, Nolte V, Pandey RV, Jost S, Ottenwälder B, Schlötterer C, Boenigk J: Diversity in a hidden world: potential and limitation of next-generation sequencing for surveys of molecular diversity of eukaryotic microorganisms. Mol Ecol. 2010, 19 (Suppl. 1): 32-40.PubMedPubMed CentralView ArticleGoogle Scholar
- RDP (Ribosonmal Database Project). [http://pyro.cme.msu.edu/]
- Schloss PD, Handelsman J: Introducing DOTUR, a computer program for defining operational taxonomic units and estimating species richness. Applied and Environmental Microbiology. 2005, 71 (3): 1501-1506. 10.1128/AEM.71.3.1501-1506.2005.PubMedPubMed CentralView ArticleGoogle Scholar
- Pandey RV, Nolte V, Schlötterer C: CANGS: a user-friendly utility for processing and analyzing 454 GS-FLX data in biodiversity studies. BMC Res Notes. 2010, 11;3: 3-View ArticleGoogle Scholar
- VAMPS: Visualization and Analysis of Microbial Population Structures. [http://vamps.mbl.edu/index.php]
- Giongo A, Crabb DB, Davis-Richardson AG, Chauliac D, Mobberley JM, Gano KA, Mukherjee N, Casella G, Roesch LF, Walts B, Riva A, King G, Triplett EW: PANGEA: pipeline for analysis of next generation amplicons. ISME J. 2010, 4 (7): 852-861. 10.1038/ismej.2010.16.PubMedPubMed CentralView ArticleGoogle Scholar
- Stajich JE, Block D, Boulez K, Brenner SE, Chervitz SA, Dagdigian C, Fuellen G, Gilbert JG, Korf I, Lapp H, et al: The Bioperl toolkit: Perl modules for the life sciences. Genome Research. 2002, 12 (10): 1611-1618. 10.1101/gr.361602.PubMedPubMed CentralView ArticleGoogle Scholar
- Altschul SF, Gish W, Miller W, Myers EW, Lipman DJ: Basic local alignment search tool. Journal of Molecular Biology. 1990, 215 (3): 403-410.PubMedView ArticleGoogle Scholar
- Katoh K, Kuma K, Toh H, Miyata T: MAFFT version 5: improvement in accuracy of multiple sequence alignment. Nucleic Acids Research. 2005, 33 (2): 511-518. 10.1093/nar/gki198.PubMedPubMed CentralView ArticleGoogle Scholar
- MySQL. [http://www.mysql.com]
- Update_blastdb.pl. [http://0-www.ncbi.nlm.nih.gov.brum.beds.ac.uk/BLAST/docs/update_blastdb.pl]
- R. [http://cran.r-project.org/]
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