ATAC-seq on Mus musculus C57BL/6 frontal cortex adult
Report generated at 2018-12-06 11:16:12
Pipeline type: ATAC-Seq
Peak caller: MACS2
Alignment
Flagstat (raw BAM)
rep1
rep2
Total
141785320
120504492
Total(QC-failed)
0
0
Dupes
0
0
Dupes(QC-failed)
0
0
Mapped
129935211
119273855
Mapped(QC-failed)
0
0
% Mapped
91.6400
98.9800
Paired
0
0
Paired(QC-failed)
0
0
Read1
0
0
Read1(QC-failed)
0
0
Read2
0
0
Read2(QC-failed)
0
0
Properly Paired
0
0
Properly Paired(QC-failed)
0
0
% Properly Paired
0.0000
0.0000
With itself
0
0
With itself(QC-failed)
0
0
Singletons
0
0
Singletons(QC-failed)
0
0
% Singleton
0.0000
0.0000
Diff. Chroms
0
0
Diff. Chroms (QC-failed)
0
0
Marking duplicates (filtered BAM)
Filtered out (samtools view -F 1804):
read unmapped (0x4)
not primary alignment (0x100)
read fails platform/vendor quality checks (0x200)
read is PCR or optical duplicate (0x400)
rep1
rep2
Unpaired Reads
55527625
53570813
Paired Reads
0
0
Unmapped Reads
0
0
Unpaired Dupes
25590151
15110687
Paired Dupes
0
0
Paired Opt. Dupes
0
0
% Dupes/100
0.4609
0.2821
Library complexity (filtered non-mito BAM)
rep1
rep2
Total Reads
38074482
47500660
Distinct Reads
32217704
40037045
One Read
30277193
35874186
Two Reads
1547993
3134862
NRF = Distinct/Total
0.8462
0.8429
PBC1 = OneRead/Distinct
0.9398
0.8960
PBC2 = OneRead/TwoReads
19.5590
11.4436
Mitochondrial reads are filtered out.
NRF (non redundant fraction)
PBC1 (PCR Bottleneck coefficient 1)
PBC2 (PCR Bottleneck coefficient 2)
PBC1 is the primary measure. Provisionally
0-0.5 is severe bottlenecking
0.5-0.8 is moderate bottlenecking
0.8-0.9 is mild bottlenecking
0.9-1.0 is no bottlenecking
Flagstat (filtered/deduped BAM)
Filtered and duplicates removed
rep1
rep2
Total
29937474
38460126
Total(QC-failed)
0
0
Dupes
0
0
Dupes(QC-failed)
0
0
Mapped
29937474
38460126
Mapped(QC-failed)
0
0
% Mapped
100.0000
100.0000
Paired
0
0
Paired(QC-failed)
0
0
Read1
0
0
Read1(QC-failed)
0
0
Read2
0
0
Read2(QC-failed)
0
0
Properly Paired
0
0
Properly Paired(QC-failed)
0
0
% Properly Paired
0.0000
0.0000
With itself
0
0
With itself(QC-failed)
0
0
Singletons
0
0
Singletons(QC-failed)
0
0
% Singleton
0.0000
0.0000
Diff. Chroms
0
0
Diff. Chroms (QC-failed)
0
0
Peak calling
IDR (Irreproducible Discovery Rate) plots
rep1-rep2rep1-prrep2-prppr
Reproducibility QC and peak detection statistics
The number of peaks is capped at 300K for peak-caller MACS2
overlap
IDR
Nt
248249
122878
N1
213469
100429
N2
231341
101843
Np
254200
135019
N optimal
254200
135019
N conservative
248249
122878
Optimal Set
ppr
ppr
Conservative Set
rep1-rep2
rep1-rep2
Rescue Ratio
1.0240
1.0988
Self Consistency Ratio
1.0837
1.0141
Reproducibility
pass
pass
Overlapping peaks
N1: Replicate 1 self-consistent overlapping peaks (comparing two pseudoreplicates generated by subsampling Rep1 reads)
N2: Replicate 2 self-consistent overlapping peaks (comparing two pseudoreplicates generated by subsampling Rep2 reads)
Nt: True Replicate consisten overlapping peaks (comparing true replicates Rep1 vs Rep2 )
Np: Pooled-pseudoreplicate consistent overlapping peaks (comparing two pseudoreplicates generated by subsampling pooled reads from Rep1 and Rep2 )
Self-consistency Ratio: max(N1,N2) / min (N1,N2)
Rescue Ratio: max(Np,Nt) / min (Np,Nt)
Reproducibility Test: If Self-consistency Ratio >2 AND Rescue Ratio > 2, then 'Fail' else 'Pass'
IDR (Irreproducible Discovery Rate) peaks
N1: Replicate 1 self-consistent IDR 0.05 peaks (comparing two pseudoreplicates generated by subsampling Rep1 reads)
N2: Replicate 2 self-consistent IDR 0.05 peaks (comparing two pseudoreplicates generated by subsampling Rep2 reads)
Nt: True Replicate consistent IDR 0.05 peaks (comparing true replicates Rep1 vs Rep2 )
Np: Pooled-pseudoreplicate consistent IDR 0.05 peaks (comparing two pseudoreplicates generated by subsampling pooled reads from Rep1 and Rep2 )
Self-consistency Ratio: max(N1,N2) / min (N1,N2)
Rescue Ratio: max(Np,Nt) / min (Np,Nt)
Reproducibility Test: If Self-consistency Ratio >2 AND Rescue Ratio > 2, then 'Fail' else 'Pass'
Enrichment
Strand cross-correlation measures
Performed on subsampled reads (25M)
rep1
rep2
Reads
25000000
25000000
Est. Fragment Len.
0
0
Corr. Est. Fragment Len.
0.3773
0.3807
Phantom Peak
45
45
Corr. Phantom Peak
0.3481
0.3506
Argmin. Corr.
1500
1500
Min. Corr.
0.2805
0.2865
NSC
1.3450
1.3288
RSC
1.4306
1.4711
NOTE1: For SE datasets, reads from replicates are randomly subsampled.
NOTE2: For PE datasets, the first end of each read-pair is selected and the reads are then randomly subsampled.
Normalized strand cross-correlation coefficient (NSC) = col9 in outFile
Relative strand cross-correlation coefficient (RSC) = col10 in outFile
Estimated fragment length = col3 in outFile, take the top value
rep1rep2
Fraction of reads in overlapping peaks
rep1-rep2
rep1-pr
rep2-pr
ppr
Fraction of Reads in Peak
0.2599
0.2400
0.2470
0.2638
ppr: Overlapping peaks comparing pooled pseudo replicates
rep1-pr: Overlapping peaks comparing pseudoreplicates from replicate 1
rep2-pr: Overlapping peaks comparing pseudoreplicates from replicate 2
repi-repj: Overlapping peaks comparing true replicates (rep i vs. rep j)
Fraction of reads in IDR peaks
rep1-rep2
rep1-pr
rep2-pr
ppr
Fraction of Reads in Peak
0.1692
0.1529
0.1475
0.1800
ppr: IDR peaks comparing pooled pseudo replicates
rep1-pr: IDR peaks comparing pseudoreplicates from replicate 1
rep2-pr: IDR peaks comparing pseudoreplicates from replicate 2
repi-repj: IDR peaks comparing true replicates (rep i vs. rep j)
ATAQC
Summary table
rep1
rep2
Genome
mm10_no_alt_analysis_set_ENCODE.fasta.gz
mm10_no_alt_analysis_set_ENCODE.fasta.gz
Paired/single-ended
Single-ended
Single-ended
Read length
50
50
Read count from sequencer
141785320
120504492
Read count successfully aligned
129935211
119273855
Read count after filtering for mapping quality
86224763
88974415
Read count after removing duplicate reads
60634612
73863728
Read count after removing mitochondrial reads (final read count)
29937474
38460126
Bowtie stats
79937574
67703560
Mapping quality > q30 (out of total)
86224763, 0.608136039754
88974415, 0.738349363773
Duplicates (after filtering)
25590151, 0.460854
15110687, 0.282069
Mitochondrial reads (out of total)
23426656, 0.180294900972
8174188, 0.0685329404336
Duplicates that are mitochondrial (out of all dups)
17422149, 0.680814622782
6041008, 0.399783808638
Final reads (after all filters)
29937474, 0.211146499511
38460126, 0.319159272502
NRF = Distinct/Total
0.846176, OK
0.842873, OK
PBC1 = OneRead/Distinct
0.939769, OK
0.896025, OK
PBC2 = OneRead/TwoReads
19.558999, OK
11.443625, OK
Picard est library size
0
0
Raw peaks
100429, OK
101843, OK
Naive overlap peaks
254200, OK
254200, OK
Idr peaks
135019, OK
135019, OK
Min size
73.0000
73.0000
25 percentile
431.0000
431.0000
50 percentile (median)
633.0000
633.0000
75 percentile
896.0000
896.0000
Max size
2215.0000
2215.0000
Mean
689.4522
689.4522
Tss enrichment
13.4140
10.6782
Fraction of reads in universal dhs regions
16522326, 0.552466421993
21943761, 0.570991435269
Fraction of reads in blacklist regions
10652, 0.000356176989067
12261, 0.000319039474949
Fraction of reads in promoter regions
3230332, 0.10801445038
4713232, 0.122641469912
Fraction of reads in enhancer regions
13300481, 0.444735756264
17254753, 0.448980290147
Fraction of reads in called peak regions
4573525, 0.152927559512
5668071, 0.147487023555
Replicate 1
Sample Information
Sample
Genome
mm10_no_alt_analysis_set_ENCODE.fasta.gz
Paired/Single-ended
Single-ended
Read length
50
Summary
Read count from sequencer
141,785,320
Read count successfully aligned
129,935,211
Read count after filtering for mapping quality
86,224,763
Read count after removing duplicate reads
60,634,612
Read count after removing mitochondrial reads (final read count)
29,937,474
Note that all these read counts are determined using 'samtools view' - as such,
these are all reads found in the file, whether one end of a pair or a single
end read. In other words, if your file is paired end, then you should divide
these counts by two. Each step follows the previous step; for example, the
duplicate reads were removed after reads were removed for low mapping quality.
This bar chart also shows the filtering process and where the reads were lost
over the process. Note that each step is sequential - as such, there may
have been more mitochondrial reads which were already filtered because of
high duplication or low mapping quality. Note that all these read counts are
determined using 'samtools view' - as such, these are all reads found in
the file, whether one end of a pair or a single end read. In other words,
if your file is paired end, then you should divide these counts by two.
Alignment statistics
Bowtie alignment log
79937574 reads; of these:
79937574 (100.00%) were unpaired; of these:
11850109 (14.82%) aligned 0 times
36903789 (46.17%) aligned exactly 1 time
31183676 (39.01%) aligned >1 times
85.18% overall alignment rate
Samtools flagstat
141785320 + 0 in total (QC-passed reads + QC-failed reads)
61847746 + 0 secondary
0 + 0 supplementary
0 + 0 duplicates
129935211 + 0 mapped (91.64%:-nan%)
0 + 0 paired in sequencing
0 + 0 read1
0 + 0 read2
0 + 0 properly paired (-nan%:-nan%)
0 + 0 with itself and mate mapped
0 + 0 singletons (-nan%:-nan%)
0 + 0 with mate mapped to a different chr
0 + 0 with mate mapped to a different chr (mapQ>=5)
Filtering statistics
Mapping quality > q30 (out of total)
86,224,763
0.608
Duplicates (after filtering)
25,590,151
0.461
Mitochondrial reads (out of total)
23,426,656
0.180
Duplicates that are mitochondrial (out of all dups)
17,422,149
0.681
Final reads (after all filters)
29,937,474
0.211
Mapping quality refers to the quality of the read being aligned to that
particular location in the genome. A standard quality score is > 30.
Duplications are often due to PCR duplication rather than two unique reads
mapping to the same location. High duplication is an indication of poor
libraries. Mitochondrial reads are often high in chromatin accessibility
assays because the mitochondrial genome is very open. A high mitochondrial
fraction is an indication of poor libraries. Based on prior experience, a
final read fraction above 0.70 is a good library.
Library complexity statistics
ENCODE library complexity metrics
Metric
Result
NRF
0.846176 - OK
PBC1
0.939769 - OK
PBC2
19.558999 - OK
The non-redundant fraction (NRF) is the fraction of non-redundant mapped reads
in a dataset; it is the ratio between the number of positions in the genome
that uniquely mapped reads map to and the total number of uniquely mappable
reads. The NRF should be > 0.8. The PBC1 is the ratio of genomic locations
with EXACTLY one read pair over the genomic locations with AT LEAST one read
pair. PBC1 is the primary measure, and the PBC1 should be close to 1.
Provisionally 0-0.5 is severe bottlenecking, 0.5-0.8 is moderate bottlenecking,
0.8-0.9 is mild bottlenecking, and 0.9-1.0 is no bottlenecking. The PBC2 is
the ratio of genomic locations with EXACTLY one read pair over the genomic
locations with EXACTLY two read pairs. The PBC2 should be significantly
greater than 1.
Picard EstimateLibraryComplexity
0
Yield prediction
Preseq performs a yield prediction by subsampling the reads, calculating the
number of distinct reads, and then extrapolating out to see where the
expected number of distinct reads no longer increases. The confidence interval
gives a gauge as to the validity of the yield predictions.
Fragment length statistics
Metric failed.
Metric
Result
Open chromatin assays show distinct fragment length enrichments, as the cut
sites are only in open chromatin and not in nucleosomes. As such, peaks
representing different n-nucleosomal (ex mono-nucleosomal, di-nucleosomal)
fragment lengths will arise. Good libraries will show these peaks in a
fragment length distribution and will show specific peak ratios.
Peak statistics
Metric
Result
Raw peaks
100429 - OK
Naive overlap peaks
254200 - OK
IDR peaks
135019 - OK
Raw peak file statistics
Min size
73.0
25 percentile
353.0
50 percentile (median)
507.0
75 percentile
716.0
Max size
2175.0
Mean
557.836949487
Naive overlap peak file statistics
Min size
73.0
25 percentile
277.0
50 percentile (median)
448.0
75 percentile
703.0
Max size
2215.0
Mean
530.36763572
IDR peak file statistics
Min size
73.0
25 percentile
431.0
50 percentile (median)
633.0
75 percentile
896.0
Max size
2215.0
Mean
689.452203023
For a good ATAC-seq experiment in human, you expect to get 100k-200k peaks
for a specific cell type.
Sequence quality metrics
GC bias
Open chromatin assays are known to have significant GC bias. Please take this
into consideration as necessary.
Annotation-based quality metrics
Enrichment plots (TSS)
Open chromatin assays should show enrichment in open chromatin sites, such as
TSS's. An average TSS enrichment is above 6-7. A strong TSS enrichment is
above 10.
Annotated genomic region enrichments
Fraction of reads in universal DHS regions
16,522,326
0.552
Fraction of reads in blacklist regions
10,652
0.000
Fraction of reads in promoter regions
3,230,332
0.108
Fraction of reads in enhancer regions
13,300,481
0.445
Fraction of reads in called peak regions
4,573,525
0.153
Signal to noise can be assessed by considering whether reads are falling into
known open regions (such as DHS regions) or not. A high fraction of reads
should fall into the universal (across cell type) DHS set. A small fraction
should fall into the blacklist regions. A high set (though not all) should
fall into the promoter regions. A high set (though not all) should fall into
the enhancer regions. The promoter regions should not take up all reads, as
it is known that there is a bias for promoters in open chromatin assays.
Comparison to Roadmap DNase
This bar chart shows the correlation between the Roadmap DNase samples to
your sample, when the signal in the universal DNase peak region sets are
compared. The closer the sample is in signal distribution in the regions
to your sample, the higher the correlation.
Replicate 2
Sample Information
Sample
Genome
mm10_no_alt_analysis_set_ENCODE.fasta.gz
Paired/Single-ended
Single-ended
Read length
50
Summary
Read count from sequencer
120,504,492
Read count successfully aligned
119,273,855
Read count after filtering for mapping quality
88,974,415
Read count after removing duplicate reads
73,863,728
Read count after removing mitochondrial reads (final read count)
38,460,126
Note that all these read counts are determined using 'samtools view' - as such,
these are all reads found in the file, whether one end of a pair or a single
end read. In other words, if your file is paired end, then you should divide
these counts by two. Each step follows the previous step; for example, the
duplicate reads were removed after reads were removed for low mapping quality.
This bar chart also shows the filtering process and where the reads were lost
over the process. Note that each step is sequential - as such, there may
have been more mitochondrial reads which were already filtered because of
high duplication or low mapping quality. Note that all these read counts are
determined using 'samtools view' - as such, these are all reads found in
the file, whether one end of a pair or a single end read. In other words,
if your file is paired end, then you should divide these counts by two.
Alignment statistics
Bowtie alignment log
67703560 reads; of these:
67703560 (100.00%) were unpaired; of these:
1230637 (1.82%) aligned 0 times
42326108 (62.52%) aligned exactly 1 time
24146815 (35.67%) aligned >1 times
98.18% overall alignment rate
Samtools flagstat
120504492 + 0 in total (QC-passed reads + QC-failed reads)
52800932 + 0 secondary
0 + 0 supplementary
0 + 0 duplicates
119273855 + 0 mapped (98.98%:-nan%)
0 + 0 paired in sequencing
0 + 0 read1
0 + 0 read2
0 + 0 properly paired (-nan%:-nan%)
0 + 0 with itself and mate mapped
0 + 0 singletons (-nan%:-nan%)
0 + 0 with mate mapped to a different chr
0 + 0 with mate mapped to a different chr (mapQ>=5)
Filtering statistics
Mapping quality > q30 (out of total)
88,974,415
0.738
Duplicates (after filtering)
15,110,687
0.282
Mitochondrial reads (out of total)
8,174,188
0.069
Duplicates that are mitochondrial (out of all dups)
6,041,008
0.400
Final reads (after all filters)
38,460,126
0.319
Mapping quality refers to the quality of the read being aligned to that
particular location in the genome. A standard quality score is > 30.
Duplications are often due to PCR duplication rather than two unique reads
mapping to the same location. High duplication is an indication of poor
libraries. Mitochondrial reads are often high in chromatin accessibility
assays because the mitochondrial genome is very open. A high mitochondrial
fraction is an indication of poor libraries. Based on prior experience, a
final read fraction above 0.70 is a good library.
Library complexity statistics
ENCODE library complexity metrics
Metric
Result
NRF
0.842873 - OK
PBC1
0.896025 - OK
PBC2
11.443625 - OK
The non-redundant fraction (NRF) is the fraction of non-redundant mapped reads
in a dataset; it is the ratio between the number of positions in the genome
that uniquely mapped reads map to and the total number of uniquely mappable
reads. The NRF should be > 0.8. The PBC1 is the ratio of genomic locations
with EXACTLY one read pair over the genomic locations with AT LEAST one read
pair. PBC1 is the primary measure, and the PBC1 should be close to 1.
Provisionally 0-0.5 is severe bottlenecking, 0.5-0.8 is moderate bottlenecking,
0.8-0.9 is mild bottlenecking, and 0.9-1.0 is no bottlenecking. The PBC2 is
the ratio of genomic locations with EXACTLY one read pair over the genomic
locations with EXACTLY two read pairs. The PBC2 should be significantly
greater than 1.
Picard EstimateLibraryComplexity
0
Yield prediction
Preseq performs a yield prediction by subsampling the reads, calculating the
number of distinct reads, and then extrapolating out to see where the
expected number of distinct reads no longer increases. The confidence interval
gives a gauge as to the validity of the yield predictions.
Fragment length statistics
Metric failed.
Metric
Result
Open chromatin assays show distinct fragment length enrichments, as the cut
sites are only in open chromatin and not in nucleosomes. As such, peaks
representing different n-nucleosomal (ex mono-nucleosomal, di-nucleosomal)
fragment lengths will arise. Good libraries will show these peaks in a
fragment length distribution and will show specific peak ratios.
Peak statistics
Metric
Result
Raw peaks
101843 - OK
Naive overlap peaks
254200 - OK
IDR peaks
135019 - OK
Raw peak file statistics
Min size
73.0
25 percentile
374.0
50 percentile (median)
548.0
75 percentile
775.0
Max size
2147.0
Mean
597.558447807
Naive overlap peak file statistics
Min size
73.0
25 percentile
277.0
50 percentile (median)
448.0
75 percentile
703.0
Max size
2215.0
Mean
530.36763572
IDR peak file statistics
Min size
73.0
25 percentile
431.0
50 percentile (median)
633.0
75 percentile
896.0
Max size
2215.0
Mean
689.452203023
For a good ATAC-seq experiment in human, you expect to get 100k-200k peaks
for a specific cell type.
Sequence quality metrics
GC bias
Open chromatin assays are known to have significant GC bias. Please take this
into consideration as necessary.
Annotation-based quality metrics
Enrichment plots (TSS)
Open chromatin assays should show enrichment in open chromatin sites, such as
TSS's. An average TSS enrichment is above 6-7. A strong TSS enrichment is
above 10.
Annotated genomic region enrichments
Fraction of reads in universal DHS regions
21,943,761
0.571
Fraction of reads in blacklist regions
12,261
0.000
Fraction of reads in promoter regions
4,713,232
0.123
Fraction of reads in enhancer regions
17,254,753
0.449
Fraction of reads in called peak regions
5,668,071
0.147
Signal to noise can be assessed by considering whether reads are falling into
known open regions (such as DHS regions) or not. A high fraction of reads
should fall into the universal (across cell type) DHS set. A small fraction
should fall into the blacklist regions. A high set (though not all) should
fall into the promoter regions. A high set (though not all) should fall into
the enhancer regions. The promoter regions should not take up all reads, as
it is known that there is a bias for promoters in open chromatin assays.
Comparison to Roadmap DNase
This bar chart shows the correlation between the Roadmap DNase samples to
your sample, when the signal in the universal DNase peak region sets are
compared. The closer the sample is in signal distribution in the regions
to your sample, the higher the correlation.
