GIS DNA PET Track Settings
 
ENCODE Genome Institute of Singapore DNA Paired-End Ditags   (All Variation tracks)

Display mode:       Reset to defaults   

Display read names
Attempt to join paired end reads by name
Minimum alignment quality:

Color track by bases: Help on base coloring

Alignment Gap/Insertion Display Options Help on display options
Draw double horizontal lines when both genome and query have an insertion
Draw a vertical purple line for an insertion at the beginning or end of the
query, orange for insertion in the middle of the query
Draw a vertical green line where query has a polyA tail insertion

Additional coloring modes:
Color by strand (blue for +, red for -)
Use gray for
No additional coloring

Display data as a density graph:

BAM configuration help

Select subtracks by cell line and frag size: (help)
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 GM12878  1k  ENCODE GIS DNA PET Alignments (1k frags in GM12878 cells)    Data format   2010-01-03 
 
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 GM12878  5k  ENCODE GIS DNA PET Alignments (5k frags in GM12878 cells)    Data format   2010-01-03 
 
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 GM12878  10k  ENCODE GIS DNA PET Alignments (10k frags in GM12878 cells)    Data format   2009-12-11 
 
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 K562  1k  ENCODE GIS DNA PET Alignments (1k frags in K562 cells)    Data format   2009-12-11 
 
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 K562  10k  ENCODE GIS DNA PET Alignments (10k frags in K562 cells)    Data format   2009-12-11 
 
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 K562  20k  ENCODE GIS DNA PET Alignments (20k frags in K562 cells)    Data format   2011-01-05 
     Restriction Policy
Assembly: Human Feb. 2009 (GRCh37/hg19)

Description

This track is produced as part of the ENCODE Transcriptome Project. It shows the starts and ends of DNA fragments from different cell lines determined by paired-end ditag (PET) sequencing using different DNA fragment sizes for analysis of genome structural variation.

Display Conventions and Configuration

In the graphical display, the ends are represented by blocks connected by a horizontal line. In full and packed display modes, the arrowheads on the horizontal line represent the strand, and an ID of the format XXXXX-N-M is shown to the left of each PET, where X is the unique ID for each PET, N indicates the number of mapping locations in the genome (1 for a single mapping location, 2 for two mapping locations, and so forth), and M is the number of PET sequences at this location. PETs that mapped to multiple locations may represent low complexity or repetitive sequences.

To show only selected subtracks, uncheck the boxes next to the tracks that you wish to hide.

The query sequences in the SAM/BAM alignment representation are normalized to the + strand of the reference genome (see the SAM Format Specification for more information on the SAM/BAM file format). If a query sequence was originally the reverse of what has been stored and aligned, it will have the following flag:

(0x10) Read is on '-' strand.

BAM/SAM alignment representations also have tags. The following tags are associated with this track: RG, CQ, CS, and MD.

Mapping quality is not available for this track and so, in accordance with the SAM Format Specification, a score of 255 is used.

Methods

Sample genomic DNA was isolated, hydrosheared at a given size-range, then ligated with specific DNA linker sequence at both ends, followed by gel-selection of the desired size, e.g., 1 kb, 10 kb, etc. respectively. The DNA fragments modified with linker at both ends (e.g., 10 kb) were then circularized by ligation, followed by restriction digest with enzyme EcoP15I to generate DNA PETs (25 bp tag from each end). The PETs were ligated with SOLiD sequencing adaptors at both ends, then amplified by PCR and purified as complex templates for high throughput DNA sequencing. The current DNA PET data sets submitted are mostly generated by SOLiD platform. Cells were grown according to the approved ENCODE cell culture protocols.

Data: Reads of DNA PETs were mapped onto reference genome, GRCh37, hg19, excluding mitochondrion, haplotypes, randoms and chromosome Y. Majority of the PETs mapped on the same chromosome in correct orientations and within expected distance span (e.g., a 10 kb DNA PET was expected mapping on ~10 kb span distance). A small portion of misaligned PETs, called discordant PETs, mapped either too far from each other, had wrong orientations, or in different chromosomes indicating various genome structure or variations observed between the sample and the reference genome. The variations could be due to deletion, inversion, tandem repeats, trans-location, fusion etc.

Mapping parameters: Mapping was done using Applied Biosystems' SOLiD alignment and pairing pipeline. The ungapped alignment is done in color space. Seed and extend strategy is adopted where initial seed length of 25 is mapped with maximum of 2 mismatches and then extended to read length, each color space match is awarded a score of +1 and each mismatch is awarded a penalty of -2. Read Score = read length - # of mismatches - 2 * # of mismatches After extension each read is trimmed to its maximum score, shortest length. The color space sequences are then converted into base space and checked to ensure that each sequence has a maximum of 2 base pair mismatches. If any sequence has more than 2 mismatches, then that pair is discarded. The final output is converted into SAM/BAM format.

Verification

Representative structural variations identified by DNA PET data have been verified by targeted PCR and sequencing analysis to confirm the predicted rearrangement sites. Some of them have also been validated by FISH.

Credits

The GIS DNA PET libraries and sequence data for genome structural variation analysis were produced at the Genome Institute of Singapore. The data were mapped and analyzed by scientists Xiaoan Ruan, Atif Shahab, Chialin Wei, and Yijun Ruan at the Genome Institute of Singapore.

Contact: Yijun Ruan (now at The Jackson Laboratory)

Data Release Policy

Data users may freely use ENCODE data, but may not, without prior consent, submit publications that use an unpublished ENCODE dataset until nine months following the release of the dataset. This date is listed in the Restricted Until column, above. The full data release policy for ENCODE is available here.