Changes

1,518 bytes removed , 16:47, 16 June 2014

→‎Normalization

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##INFO=<ID=FIC,Number=1,Type=Float,Description="Genotype likelihood based Inbreeding Coefficient">

##INFO=<ID=AB,Number=1,Type=Float,Description="Genotype likelihood based Allele Balance">

−

##FILTER=<ID=~~TPASS~~,Description="Temporary pass">

+

##FILTER=<ID=PASS,Description="Temporary pass">

##FILTER=<ID=overlap,Description="Overlapping variant">

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The columns are CHROM, POS, ID, REF, ALT, QUAL, FILTER, INFO, FORMAT, Genotype fields denoted by the sample name.

−

22 ~~36990877~~ . GGT G ~~. TPASS~~ AC=32;AN=116;AF=0.275862;GC=32,20,6;GN=58;

+

22 36990878 . GGT G 455 PASS AC=32;AN=116;AF=0.275862;GC=32,20,6;GN=58;

GF=0.551724,0.344828,0.103448;NS=58;

HWEAF=0.275797;HWEGF=0.52447,0.399466,0.0760642;

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22 : chromosome

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~~36990877~~ : genome position

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36990878 : genome position

. : this is the ID field that is left blank.

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GGT : the reference sequence that is replaced by the alternative sequence below.

+

GGT : the reference sequence that is replaced by the alternative sequence below.

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G : so this is basically a deletion of GT

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G : so this is basically a deletion of GT

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. : QUAL field ~~which is left missing~~.

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455 : QUAL field denoting validity of this variant, higher the better.

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~~TPASS~~ : a ~~temporary~~ passed variant.

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PASS : a passed variant.

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INFO : fields containing information about the variant.

+

INFO : fields containing information about the variant.

FORMAT : format field labels for the genotype columns.

0/0:0,9,108:9:3,0,6:10 : genotype information.

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no. of observed variants : 720

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The variants have filter labels ~~TPASS~~ meaning a temporary pass and overlap, meaning that the variants are overlapping with another variant, implying multiallelicity.

+

The variants have filter labels PASS meaning a temporary pass and overlap, meaning that the variants are overlapping with another variant, implying multiallelicity.

We can count the number of variants with the following commands.

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vt peek all.genotypes.bcf -f "FILTER.~~TPASS~~"

+

vt peek all.genotypes.bcf -f "FILTER.PASS"

stats: no. of samples : 62

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no. of chromosomes : 1

no. Indels : 136

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2 alleles (ins/del) : 136 (1.89) [89/47] #notice the difference insertion deletion ratios ~~differences~~

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2 alleles (ins/del) : 136 (1.89) [89/47] #notice the difference in insertion deletion ratios

>=3 alleles (ins/del) : 0 (-nan) [0/0]

+

#passed singletons only

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vt peek all.genotypes.bcf -f "FILTER.PASS&&INFO.AC==1"

+

#passed indels of length 1 only

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vt peek all.genotypes.bcf -f "FILTER.PASS&&LEN==1"

+

#passed indels of length >4

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vt peek all.genotypes.bcf -f "FILTER.PASS&&LEN>1"

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#passed singletons of length 4 or insertions of length 3

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vt peek all.genotypes.bcf -f "FILTER.PASS&&(LEN==4||DLEN==3)"

== Comparison with other data sets ==

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It is usually useful to examine the call sets against known data sets.

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It is usually useful to examine the call sets against known data sets for the passed variants.

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vt profile_indels -g ~~/net/fantasia/home/atks/ref/vt/grch37/~~indel.reference.txt -r ~~/net/fantasia/home/atks/ref/vt/grch37/~~hs37d5.fa ~~run/final/~~all.genotypes.bcf -i 22:36000000-37000000

+

vt profile_indels -g indel.reference.txt -r hs37d5.fa all.genotypes.bcf -i 22:36000000-37000000 -f "PASS"

data set

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No Indels : ~~720~~ [0.84] #~~720 indels,~~ with ~~and~~ insertion deletion ratio of 0.84

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No Indels : 613 [0.72] #613 passed variants with an insertion deletion ratio of 0.72

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FS/NFS : 0.50 (2/2) #~~only 4 variants overlap with coding regions~~, ~~half~~ of ~~which are~~ frameshift ~~variants~~

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FS/NFS : 0.50 (2/2) #frame shift / non frameshift indels proportion, the bracket gives the counts of the frame shift and non frameshift indels

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Low complexity : 0.47 (~~335~~/~~720~~) #~~47%~~ of ~~the variants are~~ in low complexity ~~regions~~

+

Low complexity : 0.46 (283/613) #fraction of indels in low complexity region, the bracket gives the counts of the indels

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1000G

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1000G #1000 Genomes Phase 1 data set

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A-B ~~719~~ [0.83]

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A-B 371 [0.76] #variants found in call set only, square brackets contain insertion deletion ratio

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A&B 1 [~~inf~~] #~~only one variant overlaps with 1000 Genomes phase 1~~ data ~~set.~~

+

A&B 242 [0.66] #variants found in both data sets

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B-A ~~517~~ [0.77]

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B-A 276 [0.89] #variants found in 1000G phase 1 data set only

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Precision 0.1%

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Precision 39.5% #39.5% of the call set are previously known, so 60.5% are novel variants.

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Sensitivity 0.2%

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Sensitivity 46.7% #sensitivity of variant calling, 46,7% of known variants from 1000 Genomes were rediscovered

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mills

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mills #The gold standard Mills et al. indel set

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A-B ~~720~~ [0.84]

+

A-B 542 [0.68]

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A&B 0 [~~-nan~~] ~~#no variants overlaps with Mills et al. double hit variants.~~

+

A&B 71 [1.03]

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B-A ~~102~~ [1.04]

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B-A 31 [1.07]

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Precision 0.0%

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Precision 11.6%

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Sensitivity 0.0%

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Sensitivity 69.6%

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dbsnp

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dbsnp #Indels from dbSNP

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A-B ~~720~~ [0.84]

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A-B 405 [0.68]

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A&B 0 ~~[-nan~~] ~~#no variants overlaps with Mills et al. double hit variants.~~

+

A&B 208 [0.79]

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B-A ~~702~~ [1.52]

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B-A 494 [2.03]

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Precision 0.0%

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Precision 33.9%

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Sensitivity 0.0%

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Sensitivity 29.6%

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This discovery ~~set~~ appears to ~~have many novel variants! (or false positives)~~

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Ins/Del ratios: Reference alignment based methods tend to be biased towards the detection of deletions. This provides a useful measure for discovery Indel sets to show the varying degree of biasness. It also appears that as coverage increases, the ins/del ratio tends to 1.

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~~==Peek==~~

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Coding region analysis: Coding region Indels may be categorised as Frame shift Indels and Non frameshift Indels. A lower proportion of Frameshift Indels may indicate a better quality data set but this depends also on the individuals sequenced.

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~~You can see what you have~~ in the ~~file with:~~

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Complexity region analysis: Indels in regions marked by DUST - a low complexity region masker used in the NCBI pipeline.

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~~vt peek mills.genotypes~~.~~bcf~~

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~~You can also focus on a chromosome~~:

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Overlap analysis: overlap analysis with other data sets is an indicator of sensitivity.

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~~vt peek mills~~.~~genotypes~~.~~bcf -i 20~~

+

* 1000G: contains Indels from 1000 Genomes, represent a wide spectrum of variants from many different populations. Variants here have an allele frequency above 0.005.

+

* Mills: contains doublehit common indels from the Mills. et al paper and is a relatively good measure of sensitivity for common variants. Because not all Indels in this set is expected to be present in your sample, this actually gives you an underestimate of sensitivity.

+

* dbsnp: contains Indels submitted from everywhere, I am not sure what does this represent exactly. But assuming most are real, then precision is a useful estimated quantity from this reference data set.

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Or with ~~just passed variants:~~

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We perform the same analysis for the failed variants again, the relatively low overlap with known data sets imply a reasonable tradeoff in sensitivity and specificity.

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vt ~~peek mills~~.genotypes.bcf -i 20 -f PASS

+

vt profile_indels -g indel.reference.txt -r hs37d5.fa all.genotypes.bcf -i 22:36000000-37000000 -f "~PASS"

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~~Or with failed variants~~:

+

data set

+

No Indels : 107 [2.06]

+

FS/NFS : -nan (0/0)

+

Low complexity : 0.79 (85/107)

+

1000G

+

A-B 107 [2.06]

+

A&B 0 [-nan]

+

B-A 518 [0.77]

+

Precision 0.0%

+

Sensitivity 0.0%

+

mills

+

A-B 105 [2.09]

+

A&B 2 [1.00]

+

B-A 100 [1.04]

+

Precision 1.9%

+

Sensitivity 2.0%

+

dbsnp

+

A-B 102 [2.00]

+

A&B 5 [4.00]

+

B-A 697 [1.51]

+

Precision 4.7%

+

Sensitivity 0.7%

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~~vt peek mills.genotypes.bcf -i 20 -f ~PASS~~

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~~Or with just 1bp indels:~~

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This analysis supports filters too.

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~~vt peek mills.genotypes.bcf -i 20 -f "PASS&&DLEN~~==1"

+

==Normalization==

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~~Or with just 1bp deletions:~~

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~~vt peek mills.genotypes.bcf -i 20 -f "PASS&&LEN==-1"~~

+

A slight digression here, when analyzing indels, it is important to normalize it. While it is a simple concept,

−

+

it is hardly standardized. The call set here had already been normalized but we feel that this is an important

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~~Or with just biallelic 1bp~~ indels:

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concept so we discuss this a bit here.

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~~vt peek mills~~.~~genotypes.bcf -i 20 -f "PASS&&N_ALLELE==2&&LEN==1"~~

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~~Or with just biallelic 1bp indels that are somewhat rare:~~

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~~vt peek mills~~.~~sites.bcf -f "PASS&&N_ALLELE==2&&LEN==1&&INFO.AF<0.03"~~

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~~Or with just biallelic 1bp indels~~ that ~~are somewhat rare with sanity checking:~~

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~~vt peek mills.sites.bcf -f "PASS&&N_ALLELE==2&&LEN==1&&INFO.AC/INFO.AN<0.03"~~

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~~which you will observe discrepancies due to rounding off in AF~~. ~~So you should probably use INFO.AC/INFO.AN.~~

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~~==Normalization==~~

Indel representation is not unique, you should normalize them and remove duplicates.

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| 0

| 374

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|

+

| 0

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|

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| 0

|-

| Left aligned

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To normalize and remove duplicate variants:

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vt normalize mills.genotypes.bcf -r ~~~/ref/vt/grch37/~~hs37d5.fa | vt mergedups - -o mills.normalized.genotypes.bcf

+

vt normalize mills.genotypes.bcf -r hs37d5.fa | vt mergedups - -o mills.normalized.genotypes.bcf

and you will observe that 3994 variants had to be left aligned and 1092 variants were removed.

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no. right trimmed : 0

no. variants observed : 9996

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~~Time elapsed: 0.14s ~~

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stats: Total number of observed variants 9996

Total number of unique variants 8904

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~~Time elapsed: 0.13s~~

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~~The following will be slight faster: + denotes using of uncompressed bcf stream.~~

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~~vt normalize mills.genotypes.bcf -r ~/ref/vt/grch37/hs37d5.fa -o + | vt mergedups + -o mills.normalized.genotypes.bcf~~

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~~Also remember to index this file and extract the sites.~~

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~~==Insertion/Deletion ratios, Coding Regions and Overlap analysis==~~

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~~You can obtain measure of insertion deletion ratios, coding region indels and sensitivity analysis by using the profile_indels analysis.~~

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~~vt profile_indels -g indel.reference.txt -r ~/ref/vt/grch37/hs37d5.fa mills.normalized.sites.bcf~~

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~~The indel.reference.txt file contains the required reference to perform the overlap analysis.~~

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~~data set~~

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~~No Indels : 8904 [0.93] //#variants in your data set [ins/del ratio]~~

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~~FS/NFS : 0.66 (67/35) //Proportion of frameshift Indels. (#Frameshift Indels/#Nonframeshift Indels) ~~

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~~dbsnp //A represents the data set you input, B represents dbsnp~~

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~~A-B 2975 [1.06] //#variants in A only [ins/del ratio]~~

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~~A&B 5929 [0.86] //#variants in A and B~~

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~~B-A 2059845 [1.51]~~

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~~Precision 66.6% //A&B/A this represents how novel your data set is in the variants represented.~~

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~~Sensitivity 0.3% //A&B/B this represents sensitivity somewhat if dbsnp is considered a high quality Indel~~

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~~//set and the sample are the same in both data sets. (which they usually are not, this is still~~

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~~//nonetheless a useful indicator) ~~

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Ins/Del ratios: Reference alignment based methods tend to be biased towards the detection of deletions. This provides a useful measure for discovery Indel sets to show the varying degree of biasness. It also appears that as coverage increases, the ins/del ratio tends to 1.

−

Coding region analysis: Coding region Indels may be categorised as Frame shift Indels and Non frameshift Indels. A lower proportion of Frameshift Indels may indicate a better quality data set but this depends also on the individuals sequenced.

−

~~Overlap analysis: overlap analysis with other data sets is an indicator of sensitivity.~~

−

* dbsnp: contains Indels submitted from everywhere, I am not sure what does this represent exactly. But assuming most are real, then precision is a useful estimated quantity from this reference data set.

−

* Mills: contains doublehit common indels from the Mills. et al paper and is a relatively good measure of sensitivity for common variants. Because not all Indels in this set is expected to be present in your sample, this actually gives you an underestimate of sensitivity.

−

* Mills chip: This is a subset of the Mills data set. There are genotypes here that are useful for subsetting polymophic subsets of variants that are present in samples common with your data set, this can potentially provide a better estimate of sensitivity. In general not very useful unless you happen to be working on 1000 Genomes data or any data set who's individuals are commonly studied.

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* Affy Exome Chip: This contains somewhat rare variants in exonic regions and is useful for exome chip analysis. You should subset your exome data to exome region Indels before comparing against this data set.

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~~This analysis supports filters too.~~

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~~==to document==~~

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* Annotation of STRs is ~~really important~~. ~~Show example of a deceptive single base pair variant~~

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UMICH's algorithm for normalization has been adopted by Petr Danecek in bcftools and is also used in GKNO.

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* Mendelian analysis

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* AFS

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* Can check concordance of genotypes between callers - partitiion

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* Type of Indels - homopolymer types and STR types and isolated, Adjacent SNPs ,Adjacent MNPs,Clumping variants

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* genotype likelihood concordance

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* concordance stratified by indel length or tract length

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* mendelian concordance by tract length

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Changes

Sequencing Workshop Analysis of Indels (view source)

Revision as of 16:47, 16 June 2014

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