LD-Based Genotype and Haplotype Inference from Low-Coverage Short Sequencing Reads Ion Mandoiu Computer Science and Engineering Department University of.

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Presentation transcript:

LD-Based Genotype and Haplotype Inference from Low-Coverage Short Sequencing Reads Ion Mandoiu Computer Science and Engineering Department University of Connecticut Joint work with S. Dinakar, J. Duitama, Y. Hernández, J. Kennedy, and Y. Wu

Outline Introduction Single SNP Genotype Calling Multilocus Genotyping Problem HMM-Posterior Algorithm Experimental Results Conclusion

Illumina Genome Analyzer II 35-50bp reads 1.5Gb/2.5 day run Roche/454 FLX Titanium 400bp reads 400Mb/10h run ABI SOLiD bp reads 3-4Gb/6 day run Recent massively parallel sequencing technologies deliver orders of magnitude higher throughput compared to classic Sanger sequencing Ultra-high throughput sequencing Helicos HeliScope 25-55bp reads >1Gb/day

UHTS is a transformative technology Numerous applications besides de novo genome sequencing: RNA-Seq Non-coding RNAs ChIP-Seq Epigenetics Structural variation Metagenomics Paleogenomics … UHTS applications

Personal genomics C.Venter J. Watson NA18507

Sequencing provides single-base resolution of genetic variation (SNPs, CNVs, genome rearrangements) However, interpretation requires determination of both alleles at variable loci This is limited by coverage depth due to random nature of shotgun sequencing For the Venter and Watson genomes (both sequenced at ~7.5x average coverage), comparison with SNP genotyping chips has shown only ~75% accuracy for sequencing based calls of heterozygous SNPs [Levy et al 07, Wheeler et al 08] Challenges for medical applications of sequencing

Allele coverage for heterozygous SNPs (Watson 5.85x avg. coverage)

Allele coverage for heterozygous SNPs (Watson 2.93x avg. coverage)

Allele coverage for heterozygous SNPs (Watson 1.46x avg. coverage)

Allele coverage for heterozygous SNPs (Watson 0.73x avg. coverage)

Allele coverage for heterozygous SNPs (Watson 0.37x avg. coverage)

Most work devoted to de novo variation discovery from sequencing data, e.g., SNPs, CNVs Unlike genotying known variation, de novo discovery requires very stringent detection criteria Prior genotyping methods are based on allele coverage [Levy et al 07] and [Wheeler et al 08] require that each allele be covered by at least 2 reads in order to be called Combined with hypothesis testing based on the binomial distribution when calling hets Binomial probability for the observed number of 0 and 1 alleles must be at least 0.01 [Wendl&Wilson 08] generalize coverage methods to allow an arbitrary minimum allele coverage k Prior work

[Wendl&Wilson 08] estimate that 21x coverage will be required for sequencing of normal tissue samples based on idealized theory that “neglects any heuristic inputs” What coverage is required?

We propose methods incorporating additional sources of information: Quality scores reflecting uncertainty in sequencing data Allele/genotype frequency and linkage disequilibrium (LD) info extracted from a reference panel such as Hapmap Experimental results show significantly improved genotyping accuracy Do heuristic inputs help?

Outline Introduction Single SNP Genotype Calling Multilocus Genotyping Problem HMM-Posterior Algorithm Experimental Results Conclusion

Biallelic SNPs: 0 = major allele, 1 = minor allele SNP genotypes: 0/2 = homozygous major/minor, 1=heterozygous Inferred genotypes Mapped reads with allele 0 Mapped reads with allele Sequencing errors Basic notations

Let r i denote the set of mapped reads covering SNP locus i and c i =| r i | For a read r in r i, r(i) denotes the allele observed at locus i If q r(i) is the phred quality score of r(i), the probability that r(i) is incorrect is given by Incorporating base call uncertainty Probability of observing read set r i conditional on G i :

Applying Bayes’ formula: Where are genotype frequencies inferred from a representative panel Single SNP genotype calling

Outline Introduction Single SNP Genotype Calling Multilocus Genotyping Problem HMM-Posterior Algorithm Experimental Results Conclusion

Haplotype structure in human populations

F i = founder haplotype at locus i, H i = observed allele at locus i P(F i ), P(F i | F i-1 ) and P(H i | F i ) estimated from reference genotype or haplotype data For given haplotype h, P(H=h|M) can be computed in O(nK 2 ) using forward algorithm Similar models proposed in [Schwartz 04, Rastas et al. 05, Kennedy et al. 07, Kimmel&Shamir 05, Scheet&Stephens 06] HMM model of haplotype frequencies F1F1 F2F2 FnFn … H1H1 H2H2 HnHn

F1F1 F2F2 FnFn … H1H1 H2H2 HnHn G1G1 G2G2 GnGn …R 1,1 R 2,1 F' 1 F' 2 F' n … H' 1 H' 2 H' n R 1,c …R 2,c …R n,1 R n,c 1 2 n HF-HMM for multilocus genotype inference

P(f 1 ), P(f’ 1 ), P(f i+1 |f i ), P(f’ i+1 |f’ i ), P(h i |f i ), P(h’ i |f’ i ) trained using Baum-Welch algorithm on haplotypes inferred from the populations of origin for mother/father P(g i |h i,h’ i ) set to 1 if h+h’ i =g i and to 0 otherwise Model training This gives

GIVEN: Shotgun read sets r=(r 1, r 2, …, r n ) Quality scores Trained HMM models representing LD in populations of origin for mother/father FIND: Multilocus genotype g*=(g* 1,g* 2,…,g* n ) with maximum posterior probability, i.e., g*=argmax g P(g | r ) Multilocus genotyping problem

Theorem: max g P(g | r) cannot be approximated within unless ZPP=NP Computational complexity of MGP Idea: reduction from the clique problem

Outline Introduction Single SNP Genotype Calling Multilocus Genotyping Problem HMM-Posterior Algorithm Experimental Results Conclusion

Posterior decoding algorithm 1. For each i = 1..n, compute 2. Return

fifi … hihi gigi … r 1,1 r i,1 f’ i … h’ i r 1,c … r i,c …R n,1 R n,c 1 i n … … Forward-backward computation of posterior probabilities

fifi … hihi gigi … r 1,1 r i,1 f’ i … h’ i r 1,c … r i,c …R n,1 R n,c 1 i n … … Forward-backward computation of posterior probabilities

fifi … hihi gigi … r 1,1 r i,1 f’ i … h’ i r 1,c … r i,c …R n,1 R n,c 1 i n … … Forward-backward computation of posterior probabilities

fifi … hihi gigi … r 1,1 r i,1 f’ i … h’ i r 1,c … r i,c …R n,1 R n,c 1 i n … … Forward-backward computation of posterior probabilities

fifi … hihi gigi … r 1,1 r i,1 f’ i … h’ i r 1,c … r i,c …R n,1 R n,c 1 i n … … Forward-backward computation of posterior probabilities

Runtime Direct recurrences for computing forward probabilities: Runtime reduced to O(m+nK 3 ) by reusing common terms: where

Outline Introduction Single SNP Genotype Calling Multilocus Genotyping Problem HMM-Posterior Algorithm Experimental Results Conclusion

>gi| |ref|NT_ |Hs1_ Homo sapiens chromosome 1 genomic contig, reference assembly GAATTCTGTGAAAGCCTGTAGCTATAAAAAAATGTTGAGCCATAAATACCATCAGAAATAACAAAGGGAG CTTTGAAGTATTCTGAGACTTGTAGGAAGGTGAAGTAAATATCTAATATAATTGTAACAAGTAGTGCTTG GATTGTATGTTTTTGATTATTTTTTGTTAGGCTGTGATGGGCTCAAGTAATTGAAATTCCTGATGCAAGT AATACAGATGGATTCAGGAGAGGTACTTCCAGGGGGTCAAGGGGAGAAATACCTGTTGGGGGTCAATGCC CTCCTAATTCTGGAGTAGGGGCTAGGCTAGAATGGTAGAATGCTCAAAAGAATCCAGCGAAGAGGAATAT TTCTGAGATAATAAATAGGACTGTCCCATATTGGAGGCCTTTTTGAACAGTTGTTGTATGGTGACCCTGA AATGTACTTTCTCAGATACAGAACACCCTTGGTCAATTGAATACAGATCAATCACTTTAAGTAAGCTAAG TCCTTACTAAATTGATGAGACTTAAACCCATGAAAACTTAACAGCTAAACTCCCTAGTCAACTGGTTTGA ATCTACTTCTCCAGCAGCTGGGGGAAAAAAGGTGAGAGAAGCAGGATTGAAGCTGCTTCTTTGAATTTAC >gi| |ref|NT_ |Hs1_ Homo sapiens chromosome 1 genomic contig, reference assembly GAATTCTGTGAAAGCCTGTAGCTATAAAAAAATGTTGAGCCATAAATACCATCAGAAATAACAAAGGGAG CTTTGAAGTATTCTGAGACTTGTAGGAAGGTGAAGTAAATATCTAATATAATTGTAACAAGTAGTGCTTG GATTGTATGTTTTTGATTATTTTTTGTTAGGCTGTGATGGGCTCAAGTAATTGAAATTCCTGATGCAAGT AATACAGATGGATTCAGGAGAGGTACTTCCAGGGGGTCAAGGGGAGAAATACCTGTTGGGGGTCAATGCC CTCCTAATTCTGGAGTAGGGGCTAGGCTAGAATGGTAGAATGCTCAAAAGAATCCAGCGAAGAGGAATAT TTCTGAGATAATAAATAGGACTGTCCCATATTGGAGGCCTTTTTGAACAGTTGTTGTATGGTGACCCTGA AATGTACTTTCTCAGATACAGAACACCCTTGGTCAATTGAATACAGATCAATCACTTTAAGTAAGCTAAG TCCTTACTAAATTGATGAGACTTAAACCCATGAAAACTTAACAGCTAAACTCCCTAGTCAACTGGTTTGA ATCTACTTCTCCAGCAGCTGGGGGAAAAAAGGTGAGAGAAGCAGGATTGAAGCTGCTTCTTTGAATTTAC >gnl|ti| name:EI1W3PE02ILQXT >gnl|ti| name:EI1W3PE02ILQXT >gnl|ti| name:EI1W3PE02ILQXT TCAGTGAGGGTTTTTGTTTTGTTTTGTTTTGTTTTGTTTTGTTTTGTTTTTGAGACAGAATTTTGCTCTT GTCGCCCAGGCTGGTGTGCAGTGGTGCAACCTCAGCTCACTGCAACCTCTGCCTCCAGGTTCAAGCAATT CTCTGCCTCAGCCTCCCAAGTAGCTGGGATTACAGGCGGGCGCCACCACGCCCAGCTAATTTTGTATTGT TAGTAAAGATGGGGTTTCACTACGTTGGCTGAGCTGTTCTCGAACTCCTGACCTCAAATGAC >gnl|ti| name:EI1W3PE02GTXK0 TCAGAATACCTGTTGCCCATTTTTATATGTTCCTTGGAGAAATGTCAATTCAGAGCTTTTGCTCAGCTTT TAATATGTTTATTTGTTTTGCTGCTGTTGAGTTGTACAATGTTGGGGAAAACAGTCGCACAACACCCGGC AGGTACTTTGAGTCTGGGGGAGACAAAGGAGTTAGAAAGAGAGAGAATAAGCACTTAAAAGGCGGGTCCA GGGGGCCCGAGCATCGGAGGGTTGCTCATGGCCCACAGTTGTCAGGCTCCACCTAATTAAATGGTTTACA >gnl|ti| name:EI1W3PE02ILQXT TCAGTGAGGGTTTTTGTTTTGTTTTGTTTTGTTTTGTTTTGTTTTGTTTTTGAGACAGAATTTTGCTCTT GTCGCCCAGGCTGGTGTGCAGTGGTGCAACCTCAGCTCACTGCAACCTCTGCCTCCAGGTTCAAGCAATT CTCTGCCTCAGCCTCCCAAGTAGCTGGGATTACAGGCGGGCGCCACCACGCCCAGCTAATTTTGTATTGT TAGTAAAGATGGGGTTTCACTACGTTGGCTGAGCTGTTCTCGAACTCCTGACCTCAAATGAC >gnl|ti| name:EI1W3PE02GTXK0 TCAGAATACCTGTTGCCCATTTTTATATGTTCCTTGGAGAAATGTCAATTCAGAGCTTTTGCTCAGCTTT TAATATGTTTATTTGTTTTGCTGCTGTTGAGTTGTACAATGTTGGGGAAAACAGTCGCACAACACCCGGC AGGTACTTTGAGTCTGGGGGAGACAAAGGAGTTAGAAAGAGAGAGAATAAGCACTTAAAAGGCGGGTCCA GGGGGCCCGAGCATCGGAGGGTTGCTCATGGCCCACAGTTGTCAGGCTCCACCTAATTAAATGGTTTACA Mapped reads Hapmap genotypes or haplotypes F ? ? F ?100201? ? M M ? F ? F M ?001? ? M F ? ? F ?100201? ? M M ? F ? F M ?001? ? M F ? ? F ?100201? ? M M ? F ? F M ?001? ? M Reference genome sequence >gi| |ref|NT_ |Hs1_ Homo sapiens chromosome 1 genomic contig, reference assembly GAATTCTGTGAAAGCCTGTAGCTATAAAAAAATGTTGAGCCATAAATACCATCAGAAATAACAAAGGGAG CTTTGAAGTATTCTGAGACTTGTAGGAAGGTGAAGTAAATATCTAATATAATTGTAACAAGTAGTGCTTG GATTGTATGTTTTTGATTATTTTTTGTTAGGCTGTGATGGGCTCAAGTAATTGAAATTCCTGATGCAAGT AATACAGATGGATTCAGGAGAGGTACTTCCAGGGGGTCAAGGGGAGAAATACCTGTTGGGGGTCAATGCC CTCCTAATTCTGGAGTAGGGGCTAGGCTAGAATGGTAGAATGCTCAAAAGAATCCAGCGAAGAGGAATAT TTCTGAGATAATAAATAGGACTGTCCCATATTGGAGGCCTTTTTGAACAGTTGTTGTATGGTGACCCTGA AATGTACTTTCTCAGATACAGAACACCCTTGGTCAATTGAATACAGATCAATCACTTTAAGTAAGCTAAG TCCTTACTAAATTGATGAGACTTAAACCCATGAAAACTTAACAGCTAAACTCCCTAGTCAACTGGTTTGA ATCTACTTCTCCAGCAGCTGGGGGAAAAAAGGTGAGAGAAGCAGGATTGAAGCTGCTTCTTTGAATTTAC … … … …… … … >gnl|ti| name:EI1W3PE02ILQXT TCAGTGAGGGTTTTTGTTTTGTTTTGTTTTGTTTTGTTTTGTTTTGTTTTTGAGACAGAATTTTGCTCTT GTCGCCCAGGCTGGTGTGCAGTGGTGCAACCTCAGCTCACTGCAACCTCTGCCTCCAGGTTCAAGCAATT CTCTGCCTCAGCCTCCCAAGTAGCTGGGATTACAGGCGGGCGCCACCACGCCCAGCTAATTTTGTATTGT TAGTAAAGATGGGGTTTCACTACGTTGGCTGAGCTGTTCTCGAACTCCTGACCTCAAATGAC >gnl|ti| name:EI1W3PE02GTXK0 TCAGAATACCTGTTGCCCATTTTTATATGTTCCTTGGAGAAATGTCAATTCAGAGCTTTTGCTCAGCTTT TAATATGTTTATTTGTTTTGCTGCTGTTGAGTTGTACAATGTTGGGGAAAACAGTCGCACAACACCCGGC AGGTACTTTGAGTCTGGGGGAGACAAAGGAGTTAGAAAGAGAGAGAATAAGCACTTAAAAGGCGGGTCCA GGGGGCCCGAGCATCGGAGGGTTGCTCATGGCCCACAGTTGTCAGGCTCCACCTAATTAAATGGTTTACA >gnl|ti| name:EI1W3PE02ILQXT Read sequences Quality scores SNP genotype calls rs T T e-01 rs C T e-01 rs G G e-01 rs G G e-01 rs G G e-01 rs C C e-01 rs A G e-01 rs C C e-01 rs C C e-01 rs G G e-01 rs G G e-01 rs G G e-01 rs A C e-01 rs G G e-01 rs A A e-01 rs A A e-01 rs A A e-01 rs T T e-01 rs G G e-01 rs C G e-01 rs G T e-01 rs G G e-01 rs C C e-01 rs A C e-01 rs G G e-01 rs C C e-01 rs C C e-01 rs C C e-01 Pipeline for LD-Based Genotype Calling

Datasets Watson Sequencing data: 74.4 million 454 reads (average length 265bp) Reference panel: CEU genotypes from Hapmap r23a phased using the ENT algorithm [Gusev et al. 08] Ground truth: duplicate Affymetrix 500k SNP genotypes Excluded discordant genotypes and SNPs for which Hapmap and Affymetrix annotations have more than 5% difference in same-strand CEU allele frequency NA18507 (Illumina & SOLiD) Sequencing data: 525 million Illumina reads (36bp, paired) and 764 million SOLiD reads ( bp, unpaired) Reference panel: YRI haplotypes from Hapmap r22 excluding NA18507 haplotypes Ground truth: Hapmap r22 genotypes for NA18507

Mapping Procedure 454 reads mapped on human genome build 36.3 using the NUCMER tool of the MUMmer package [Kurtz et al 04] with default parameters Additional filtering: at least 90% of the read length matched to the genome, no more than 10 errors (mismatches or indels) Reads meeting above conditions at multiple genome positions (likely coming from genomic repeats) were discarded Illumina and SOLiD reads mapped using MAQ [Li et al 08] with default parameters For reads mapped at multiple positions MAQ returns best position (breaking ties arbitrarily) together with mapping confidence We filtered bad alignments and discarded paired end reads that are not mapped in pairs using the “submap -p” command

Mapping statistics Dataset Raw reads Raw sequence Mapped reads Test SNPs Avg. mapped SNP cov. Watson74.2M19.7Gb 49.8M (67%) 443K5.85x NA18507 Illumina 525M18.9Gb 397M (78%) 2.85M6.10x NA18507 SOLiD 764M21.15Gb 324M (42%) 2.85M3.21x

Concordance vs. avg. coverage (Watson 454 reads)

Tradeoff with call rate (5.85x Watson 454 reads, homo SNPs)

Tradeoff with call rate (5.85x Watson 454 reads, het SNPs)

Concordance vs. avg. coverage for NA18507 (Illumina & SOLiD reads)

Recombination rate effects (NA18507 Illumina)

Coverage effects (NA18507 Illumina)

Exploiting LD information yields significant improvements in genotyping calling accuracy and/or cost reductions Improvement depends on the coverage depth (higher at lower coverage), e.g., accuracy achieved by previously proposed binomial test at 5-6x average coverage is achieved by HMM-based posterior decoding algorithm using less than 1/4 of the reads Ongoing work Extension to population sequencing data (removing need for reference panels) Mapping repetitive reads & haplotype inferrence Conclusions & ongoing work

Acknowledgments Work supported in part by NSF awards IIS and DBI to IM and IIS to YW. SD and YH performed this research as part of the Summer REU program “Bio-Grid Initiatives for Interdisciplinary Research and Education" funded by NSF award CCF