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170120 giab stanford genetics seminar
1. Genome in a Bottle:
So you’ve sequenced a genome – how well did you do?
Justin Zook and Marc Salit
NIST Genome-Scale Measurements Group
Joint Initiative for Metrology in Biology (JIMB)
January 20, 2017
2. Genome in a Bottle Consortium
Authoritative Characterization of Human Genomes
Sample
gDNA isolation
Library Prep
Sequencing
Alignment/Mapping
Variant Calling
Confidence Estimates
Downstream Analysis
• gDNA reference materials to
evaluate performance
– materials characterized for their
variants against a reference
sequence, with confidence
estimates
• established consortium to
develop reference materials,
data, methods, performance
metrics
genericmeasurementprocess
www.slideshare.net/genomeinabottle
3. In September, we released 4 new
GIAB RM Genomes.
• PGP Human Genomes
– AJ son
– AJ trio
– Asian son
• Parents also characterized
National I nstituteof S tandards & Technology
Report of I nvestigation
Reference Material 8391
Human DNA for Whole-Genome Variant Assessment
(Son of Eastern European Ashkenazim Jewish Ancestry)
This Reference Material (RM) is intended for validation, optimization, and process evaluation purposes. It consists
of a male whole human genome sample of Eastern European Ashkenazim Jewish ancestry, and it can be used to assess
performance of variant calling from genome sequencing. A unit of RM 8391 consists of a vial containing human
genomic DNA extracted from a single large growth of human lymphoblastoid cell line GM24385 from the Coriell
Institute for Medical Research (Camden, NJ). The vial contains approximately 10 µg of genomic DNA, with the peak
of the nominal length distribution longer than 48.5 kb, as referenced by Lambda DNA, and the DNA is in TE buffer
(10 mM TRIS, 1 mM EDTA, pH 8.0).
This material is intended for assessing performance of human genome sequencing variant calling by obtaining
estimates of true positives, false positives, true negatives, and false negatives. Sequencing applications could include
whole genome sequencing, whole exome sequencing, and more targeted sequencing such as gene panels. This
genomic DNA is intended to be analyzed in the same way as any other sample a lab would process and analyze
extracted DNA. Because the RM is extracted DNA, it is not useful for assessing pre-analytical steps such as DNA
extraction, but it does challenge sequencing library preparation, sequencing machines, and the bioinformatics steps of
mapping, alignment, and variant calling. This RM is not intended to assess subsequent bioinformatics steps such as
functional or clinical interpretation.
Information Values: Information values are provided for single nucleotide polymorphisms (SNPs), small insertions
and deletions (indels), and homozygous reference genotypes for approximately 88 % of the genome, using methods
similar to described in reference 1. An information value is considered to be a value that will be of interest and use to
the RM user, but insufficient information is available to assess the uncertainty associated with the value. We describe
and disseminate our best, most confident, estimate of the genotypes using the data and methods currently available.
These data and genomic characterizations will be maintained over time as new data accrue and measurement and
informatics methods become available. The information values are given as a variant call file (vcf) that contains the
high-confidence SNPs and small indels, as well as a tab-delimited “bed” file that describes the regions that are called
high-confidence. Information values cannot be used to establish metrological traceability. The files referenced in this
report are available at the Genome in a Bottle ftp site hosted by the National Center for Biotechnology Information
(NCBI). The Genome in a Bottle ftp site for the high-confidence vcf and high confidence regions is:
4. We also released a
Microbial Genome RM
National I nstituteof S tandards & Technology
Report of I nvestigation
Reference Material 8375
Microbial Genomic DNA Standards for Sequencing Performance Assessment
(MG-001, MG-002, MG-003, MG-004)
This Reference Material (RM) is intended for validation, optimization, process evaluation, and performance
assessment of whole genome sequencing. A unit of RM 8375 consists of four vials. Each vial contains a different
microbial genomic DNA sample (MG-001 Salmonella Typhimurium LT2, MG-002 Staphylococcus aureus, MG-003
Pseudomonas aeruginosa, and MG-004 Clostridium sporogenes). Each vial contains approximately 2 µg of microbial
genomic DNA; with the peak of the nominal length distribution longer than 48.5 kb, as referenced by Lambda DNA;
in TE buffer (10 mM TRIS, 0.1 mM EDTA, pH 8.0).
This material is intended to help assess performance of high-throughput DNA sequencing methods. This genomic
DNA is intended to be analyzed in the same way as any other sample a laboratory would analyze extracted DNA, such
as through the use of a genome assembly or variant calling bioinformatics pipelines. Because the RM is extracted
DNA, it does not assess pre-analytical steps such as DNA extraction. It does, however, challenge sequencing library
preparation, sequencing machines, base calling algorithms, and the subsequent bioinformatics analyses such as variant
calling. This RM is not intended to assess other bioinformatics steps such as genome assembly, strain identification,
phylogenetic analysis, or genome annotation.
Information Values: Information values are currently provided for the whole genome sequence to enable
performance assessment of variant calling and assembly methods. An information value is considered to be a value
that will be of interest and use to the RM user, but insufficient information is available to assess the uncertainty
associated with the value. We describe and disseminate our best, most confident, estimate of the assembly using the
data and methods available at present [1]. Information values cannot be used to establish metrological traceability.
The genome sequence files referenced in this Report of Investigation are available at:
MG-001 Salmonella Typhimurium LT2
https://github.com/usnistgov/NIST_Micro_Genomic_RM_Data/MG001/ref_genome/MG001_v1.00.fasta
MG-002 Staphylococcus aureus
This Reference Material (RM) is
intended for validation,
optimization, process
evaluation, and performance
assessment of whole genome
sequencing.
• Salmonella Typhimurium
• Pseudomonas aeruginosa
• Staphylococcus aureus
• Clostridium sporogenes
5. Bringing Principles of Metrology
to the Genome
• Reference materials
– DNA in a tube you can buy from
NIST
– NA12878 pilot sample, now 2 PGP-
sourced trios
• Extensive state-of-the-art
characterization
– arbitrated “gold standard” calls for
SNPs, small indels
• “Upgradable” as technology
develops
• PGP genomes suitable for
commercial derived products
• Developing benchmarking tools
and software
– with GA4GH
• Samples being used to develop
and demonstrate new technology
6. NIST Reference Materials
Genome PGP ID Coriell ID NIST ID NIST RM #
CEPH
Mother/Daughter
N/A GM12878 HG001 RM8398
AJ Son huAA53E0 GM24385 HG002 RM8391
(son)/RM8392
(trio)
AJ Father hu6E4515 GM24149 HG003 RM8392 (trio)
AJ Mother hu8E87A9 GM24143 HG004 RM8392 (trio)
Asian Son hu91BD69 GM24631 HG005 RM8393
Asian Father huCA017E GM24694 N/A N/A
Asian Mother hu38168C GM24695 N/A N/A
7. Data for GIAB PGP Trios
Dataset Characteristics Coverage Availability Most useful for…
Illumina Paired-end WGS 150x150bp
250x250bp
~300x/individual
~50x/individual
on SRA/FTP SNPs/indels/some SVs
Complete Genomics 100x/individual on SRA/ftp SNPs/indels/some SVs
SOLiD 5500W WGS 50bp single end 70x/son on FTP SNPs
Illumina Paired-end WES 100x100bp ~300x/individual on SRA/FTP SNPs/indels in exome
Ion Proton Exome 1000x/individual on SRA/FTP SNPs/indels in exome
Illumina Mate pair ~6000 bp insert ~30x/individual on FTP SVs
Illumina “moleculo” Custom library ~30x by long fragments on FTP SVs/phasing/assembly
Complete Genomics LFR 100x/individual on SRA/FTP SNPs/indels/phasing
10X Linked reads 30-45x/individual on FTP SNPs/SVs/phasing/assembly
PacBio ~10kb reads ~70x on AJ son, ~30x on
each AJ parent
on SRA/FTP SVs/phasing/assembly/STRs
Oxford Nanopore 5.8kb 2D reads 0.05x on AJ son on FTP SVs/assembly
Nabsys 2.0 ~100kbp N50 nanopore
maps
70x on AJ son SVs/assembly
BioNano Genomics 200-250kbp optical map
reads
~100x/AJ individual; 57x on
Asian son
on FTP SVs/assembly
9. Principles of Integration Process
• Form sensitive variant calls from
each dataset
• Define “callable regions” for each
callset
• Filter calls from each method
with annotations unlike
concordant calls
• Compare high-confidence calls to
other callsets and manually
inspect subset of differences
– vs. pedigree-based calls
– vs. common pipelines
– Trio analysis
• When benchmarking a new
callset against ours, most
putative FPs/FNs should actually
be FPs/FNs
10. Integration Methods to Establish Benchmark Variant
Calls
Candidate variants
Concordant variants
Find characteristics of bias
Arbitrate using evidence of bias
Confidence Level Zook et al., Nature Biotechnology, 2014.
11. Integration Methods to Establish Benchmark Variant
Calls
Candidate variants
Concordant variants
Find characteristics of bias
Arbitrate using evidence of bias
Confidence Level Zook et al., Nature Biotechnology, 2014.
NEW: Reproducible
integration pipeline with
new calls for NA12878 and
PGP Trios on GRCh37 and
GRCh38!
12. Evolution of high-confidence calls
Calls
HC
Regions HC Calls
HC
indels
Concordant
with PG
NIST-
only in
beds
PG-only
in beds PG-only
Variants
Phased
v2.19 2.22 Gb 3153247 352937 3030703 87 404 1018795 0.3%
v3.2.2 2.53 Gb 3512990 335594 3391783 57 52 657715 3.9%
v3.3 2.57 Gb 3566076 358753 3441361 40 60 608137 8.8%
v3.3.2 2.58 Gb 3691156 487841 3529641 47 61 469202 99.6%
5-7
errors
in NIST
1-7
errors
in NIST
~2 FPs and ~2 FNs per million NIST variants in PG and NIST bed files
13. Global Alliance for Genomics and Health Benchmarking Task
Team
• Developed standardized
definitions for performance
metrics like TP, FP, and FN.
• Developing sophisticated
benchmarking tools
• Integrated into a single framework
with standardized inputs and
outputs
• Standardized bed files with
difficult genome contexts for
stratification
https://github.com/ga4gh/benchmarking-tools
Variant types can change when decomposing
or recomposing variants:
Complex variant:
chr1 201586350 CTCTCTCTCT CA
DEL + SNP:
chr1 201586350 CTCTCTCTCT C
chr1 201586359 T A
Credit: Peter Krusche, Illumina
GA4GH Benchmarking Team
16. FN rates high in some tandem repeats
1x0.3x 10x3x 30x
11to50bp51to200bp
2bp unit repeat
3bp unit repeat
4bp unit repeat
2bp unit repeat
3bp unit repeat
4bp unit repeat
FN rate vs. average
17. GA4GH benchmarking on Github
In-progress benchmarking standards document: doc/standards
Description of intermediate formats: doc/ref-impl
Truthset descriptions and download links: resources/high-confidence-sets
Stratification bed files and descriptions: resources/stratification-bed-files
Python-code for HTML reporting and running benchmarks: reporting/basic
Please contribute / join the discussion!
https://github.com/ga4gh/benchmarking-tools
Credit: Peter Krusche, Illumina
GA4GH Benchmarking Team
18. Benchmarking stats can be difficult to interpret
Example: decoy-like regions
“Decoy” sequence for GRCh37
• Created to capture reads that are from
sequences that are not in the GRCh37
reference assembly, which otherwise
can cause FPs
• We only include calls in decoy-
homologous regions if they have clear
support in both 10X haplotypes
• We look at error rates for bwa-GATK
without using the decoy
SNP benchmarking stats vs. different callsets
BWA/GATK-
no decoy
vs. 2.18 vs. 3.3.2 vs. PG
Precision 91% 67% 93%
Recall 99.8% 99.4% 93%
Outside bed 91% 92% 78%
• v3.3.2 best at identifying FP SNPs
– 43% of FPs in decoy (only 0.5% of TPs)
• PG best at identifying FN SNPs
– Mostly clustered, unclear variants in
difficult-to-map regions
19. Benchmarking stats can be difficult to interpret
Example: FP compound heterozygous indels
Compound heterozygous variants
• 2 different variants on different copies
of the chromosome within 10bp
• Many in repeats
• Many of the differences between
v3.3.2 and PG are due to errors and
partial calls in PG at these sites
• We look at FP rates for bwa-GATK using
the decoy
Indel benchmarking stats vs. PG and 3.3.2
• 93% precision vs. PG
– Only ~40% of FPs are errors in GATK
• 95% precision vs. NISTv3.3.2
– ~90% of FPs are errors in GATK
• As always, true precision in whole
genome is unknown
20. Benchmarking stats can be difficult to interpret
Example: FN SNPs in coding regions
RefSeq Coding Regions
• Studies often focus on variants in
coding regions
• We look at FN SNP rates for bwa-GATK
using the decoy
SNP benchmarking stats vs. PG and 3.3.2
• 97.98% sensitivity vs. PG
– FNs predominately in low MQ and/or
segmental duplication regions
– ~80% of FNs supported by long or linked
reads
• 99.96% sensitivity vs. NISTv3.3.2
– 62x lower FN rate than vs PG
• As always, true sensitivity is unknown
21. Approaches to Benchmarking Variant Calling
• Well-characterized whole genome Reference Materials
• Many samples characterized in clinically relevant regions
• Synthetic DNA spike-ins
• Cell lines with engineered mutations
• Simulated reads
• Modified real reads
• Modified reference genomes
• Confirming results found in real samples over time
22. Challenges in Benchmarking Variant Calling
• It is difficult to do robust benchmarking of tests designed to detect
many analytes (e.g., many variants)
• Easiest to benchmark only within high-confidence bed file, but…
• Benchmark calls/regions tend to be biased towards easier variants
and regions
– Some clinical tests are enriched for difficult sites
• Always manually inspect a subset of FPs/FNs
• Stratification by variant type and region is important
• Always calculate confidence intervals on performance metrics
23. How can we extend this approach to structural
variants?
Similarities to small variants
• Collect callsets from multiple
technologies
• Compare callsets to find calls
supported by multiple technologies
Differences from small variants
• Callsets have limited sensitivity
• Variants are often imprecisely
characterized
– breakpoints, size, type, etc.
• Representation of variants is poorly
standardized, especially when complex
• Comparison tools in infancy
24. Preliminary process for integrated deletions
Merge
deletions
within 1kb
Rank calls by
closeness of
predicted size
to median size
and select call
in each region
from best
callset
Find calls
supported by
2+
technologies
with size
within 20%
Filter calls
overlapping
seg dups,
reference N’s,
or with call
with predicted
size 2x larger
ftp://ftp-trace.ncbi.nlm.nih.gov/giab/ftp/data/AshkenazimTrio/analysis/NIST_DraftIntegratedDeletionsgt19bp_v0.1.8
<50bp 50-100bp 100-1000bp 1kb-3kb >3kbp
Pre-filtered calls 2627 1600 2306 385 389
Post-filtered calls 2548 1448 1996 297 262
25. Proposed SV integration process
Calls with
REF and ALT
sequence
SV
Discovery
Imprecise SV
calls
Sequence-
based
comparison
SV
corroboration
methods (e.g.,
svviz, nabsys,
bionano,
Illumina
population,
lumpy?)
Heuristics to
form tiers of
benchmark SVs
Machine
learning to
form
benchmark SVs
Comparison
of all
candidate
calls
(SURVIVOR/s
vcompare)
SV
Comparison
SV
Corroboration
Form SV
benchmark calls
SV sequence
refinement
(Parliament,
Spiral Genetics,
PBRefine,
graphs?)
Paper about calls
and
comparisons?
SV
Refinement
Manually
curate
alignments
around a
subset of calls;
ask community
for feedback
Evaluate/optimize
benchmark calls
26. Draft de novo assemblies for AJ Son
Data Method
Contig
N50
Scaffold
N50
Number
Scaffolds
Total
Size
PacBio Falcon 5.3 Mb 5.3 Mb 13231 3.04 Gb
PacBio PBcR 4.5 Mb 4.5 Mb 12523 2.99 Gb
PacBio+
BioNano
Falcon+
BioNano 6.1 Mb 59.4 Mb 10591 3.27 Gb
PacBio+
Dovetail
Falcon+
HiRise 5.3 Mb 12.9 Mb 12459 3.04 Gb
PacBio+
Dovetail
PBcR+
HiRise 4.1 Mb 20.6 Mb 10491 2.99 Gb
Illumina DISCOVAR 81 kb 149 kb 1.06M 3.13 Gb
Illumina+
Dovetail
DISCOVAR+
HiRise 85 kb 12.9 Mb 1.03M 3.15 Gb
10X Supernova 106 kb 15.2 Mb 1360 2.73 Gb
Credits for assemblies:
Ali Bashir, Mt. Sinai
Jason Chin, PacBio
Alex Hastie, BioNano
Serge Koren, NHGRI
Adam Phillippy, NHGRI
Kareina Dill, Dovetail
Noushin Ghaffari, TAMU
10X Genomics
Assembly-based SV calls:
MSPAC
Assemblytics
PBRefineIMPORTANT NOTE: These are draft assemblies and statistics should not be used to
compare quality of assembly methods.
27. New Samples
Additional ancestries
• Shorter term
– Use existing PGP individual samples
– Use existing integration pipeline
• Data-based selection
– Proportion of potential genomes from
different ancestries
• 3 to 8 new samples
• Longer term
– Recruit large family
– Recruit trios from other ancestry groups
Cancer samples
• Longer term
• Make PGP-consented tumor and
normal cell lines from same individual
• Select tumor with diversity of mutation
types
28.
29. Acknowledgements
• NIST/JIMB
– Marc Salit
– Jenny McDaniel
– Lindsay Vang
– David Catoe
– Lesley Chapman
• Genome in a Bottle Consortium
• GA4GH Benchmarking Team
• FDA
– Liz Mansfield
– Zivana Tevak
– David Litwack
30. For More Information
www.genomeinabottle.org - sign up for general GIAB and Analysis Team google group
emails
github.com/genome-in-a-bottle – Guide to GIAB data & ftp
www.slideshare.net/genomeinabottle
www.ncbi.nlm.nih.gov/variation/tools/get-rm/ - Get-RM Browser
Data: http://www.nature.com/articles/sdata201625
Global Alliance Benchmarking Team
– https://github.com/ga4gh/benchmarking-tools
Public workshops
– Possible SV integration mini-workshop in 2017
– Next large workshop early 2018
NIST/JIMB postdoc opportunities available!
Justin Zook: jzook@nist.gov
Marc Salit: salit@nist.gov