FastNgsAdmixOld: Difference between revisions
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Where the marker should be chr_pos, instead of rs ID. | |||
A provided SNP.sites file has been included. | A provided SNP.sites file has been included. | ||
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If the reference panel has more than K populations, the program will just use the K first populations. | If the reference panel has more than K populations, the program will just use the K first populations. | ||
You can pick which populations should be analyzed via the "-whichPops" option, where you write the names of the population comma seperated, K has to be same number as selected populations. | You can pick which populations should be analyzed via the "-whichPops" option, where you write the names of the population comma seperated, K has to be same number as selected populations. | ||
It should also be noted that the program quits if there are duplicate sites (based on chrosomoe and position) in the input or the reference panel. | |||
It then produces two files indi_genotypelikelihood.beagle.qopt with the admixture proportions and indi_genotypelikelihood.beagle.log. | It then produces two files indi_genotypelikelihood.beagle.qopt with the admixture proportions and indi_genotypelikelihood.beagle.log. | ||
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Another option is "-boot" which specifies the number of bootstrap runs, where random sites are sampled for each run. This is useful for generating a confidence interval of your estimate. The program will execute a maximum of 100 times. | Another option is "-boot" which specifies the number of bootstrap runs, where random sites are sampled for each run. This is useful for generating a confidence interval of your estimate. The program will execute a maximum of 100 times. | ||
For faster inference of admixture proportions the "-Qconv" option can be set to 1, this bases the converge criteria on change in the admixture proportions values. The threshold of this can be set with "-Qtol". | For faster inference of admixture proportions the "-Qconv" option can be set to 1, this bases the converge criteria on change in the admixture proportions values. The threshold of this can be set with "-Qtol". | ||
By default the "-Qtol" threshold is 0.0000001, it should not be put lower than this and generally this is only for when wanting a fast overview of the data, as it is less precise than the likelihood based convergence. | |||
By default the method adjusting the frequencies is used, to use the unadjusted approach set "-doAdjust 0". The accelerated EM algorithm is used by default, to use regular EM algorithm set "-method 0". | By default the method adjusting the frequencies is used, to use the unadjusted approach set "-doAdjust 0". The accelerated EM algorithm is used by default, to use regular EM algorithm set "-method 0". | ||
Revision as of 16:18, 5 January 2017
This page contains information about the program called FastNGSadmixPCA, which is a very fast tool for finding admixture proportions from NGS data of a single individual to incorporate into PCA of NGS data. It is based on genotype likelihoods. The program is written in R.
Installation
wget http://popgen.dk/albrecht/kristian/tool_download.zip unzip tool_download.zip OR simply use SHINY: http://popgen.dk:443/kristian/admixpca_human/
Run example
tool.zip contains all files needed to execute FASTNGSAdmixPCA. The sample is from the HAPMAP project. In need of more samples, one can find a couple more samples in http://popgen.dk/albrecht/kristian/ The Rscript below executes the tool. all output is directed to a output_folder that is created in the process. To see the preset: Rscript FastNGSAdmixPCA.r
Rscript FastNGSAdmixPCA.r infile=NA12763.mapped.ILLUMINA.bwa.CEU.low_coverage.20130502.bam.beagle.gz
All arguments can be altered. To alter the reference populations, one need to write comma separated populations to the refpops argument as shown below
Rscript FastNGSAdmixPCA.r infile=NA12763.mapped.ILLUMINA.bwa.CEU.low_coverage.20130502.bam.beagle.gz refpops=YRI,JPT,CHB,CEU
To get an overview of available reference populations, one can make a dry run
Rscript FastNGSAdmixPCA.r infile=TRUE dryrun=TRUE
Input Files
Input files are contains genotype likelihoods in genotype likelihood beagle input file format [1]. We recommend [ANGSD] for easy transformation of Next-generation sequencing data to beagle format.
The example below show how to make a beagle file of genotype likelihood using ANGSD.
HOME$ ./angsd0.594/angsd -i 'pathtoindi.bam' -GL 2 -sites 'SNP.sites' -doGlf 2 -doMajorMinor 3 -minMapQ 30 -minQ 20 -doDepth 1 -doCounts 1 -out indi_genotypelikelihood
Example of a beagle genotype likelihood input file for 3 individuals.
marker allele1 allele2 Ind0 Ind0 Ind0 1_14000023 1 0 0.941 0.058 0.000 1_14000072 2 3 0.709 0.177 0.112 1_14000113 0 2 0.855 0.106 0.037 1_14000202 2 0 0.835 0.104 0.060 ...
version 2
Input files are genotype likelihoods in the genotype likelihood beagle input file format [2]. Or called genotypes in the binary plink files (*.bed) format [3] We recommend [ANGSD] for easy transformation of Next-generation sequencing data to beagle format and plink2 for handling plink files.
The example below show how to make a beagle file of genotype likelihood using ANGSD.
HOME$ ./angsd0.594/angsd -i 'pathtoindi.bam' -GL 2 -sites 'SNP.sites' -doGlf 2 -doMajorMinor 3 -minMapQ 30 -minQ 20 -doDepth 1 -doCounts 1 -out indi_genotypelikelihood
Example of a beagle genotype likelihood input file for 1 individual.
marker allele1 allele2 Ind0 Ind0 Ind0 1_14000023 1 0 0.941 0.058 0.000 1_14000072 2 3 0.709 0.177 0.112 1_14000113 0 2 0.855 0.106 0.037 1_14000202 2 0 0.835 0.104 0.060 ...
Where the marker should be chr_pos, instead of rs ID.
A provided SNP.sites file has been included.
The program also needs frequencies of a reference panel with the populations for which admixture proportions should be estimated,
for instance from 1000 G or HGDP, or another custom made reference panel. The program also needs a file telling the size of each reference panel population.
There is an R script called plinkToRefV2.R, that can convert a plink file to a reference panel and size of reference panel populations.
Example:
Rscript plinkToRefV2.R plinkFile
This generates 3 files, a reference panel named refPanel_plinkFile.txt, a number of individuals file called nInd_plinkFile.txt and a plinkFile.sites file with chr pos and minor major alleles.
fastNGSadmix already comes with a premade reference panel, made from Lazaridis et al. (2014) where the curated dataset was selected.
I lifted the dataset hg19 using the program liftOver, I then translated snpNames to rs names, using 1000G data, generating a unique name for each site via "chr-pos-A1-A2" (where A1 and A2 are alphabetically sorted).
Furthermore I removed sites with more than 5 % missing and a MAF below 5 %, and only autosomal sites. I selected 5 populations French, Han, Karitiana, Papuan and Yoruba to have representation for most of the world. Furthermore I made sure that I only used unadmixed individuals within each population.
An example of a command running fastNGSadmix with a beagle file and a chosen K of 3:
./fastNGSadmix -likes indi_genotypelikelihood.beagle -fname refPanel.txt -Nname nInd.txt -outfiles indi_genotypelikelihood.beagle -K 3
If the reference panel has more than K populations, the program will just use the K first populations. You can pick which populations should be analyzed via the "-whichPops" option, where you write the names of the population comma seperated, K has to be same number as selected populations. It should also be noted that the program quits if there are duplicate sites (based on chrosomoe and position) in the input or the reference panel.
It then produces two files indi_genotypelikelihood.beagle.qopt with the admixture proportions and indi_genotypelikelihood.beagle.log.
Or with a plink file:
./fastNGSadmix -plink plinkFile -fname refPanel.txt -Nname nInd.txt -outfiles plinkFile -K 3
A whole list of options can be explored by running fastNGSadmix without any input:
./fastNGSadmix
The option "-conv" specifies the number of convergence runs, with a new random starting point for each run. This is useful to test for convergence. The program will execute a maximum of 10 times. Another option is "-boot" which specifies the number of bootstrap runs, where random sites are sampled for each run. This is useful for generating a confidence interval of your estimate. The program will execute a maximum of 100 times. For faster inference of admixture proportions the "-Qconv" option can be set to 1, this bases the converge criteria on change in the admixture proportions values. The threshold of this can be set with "-Qtol". By default the "-Qtol" threshold is 0.0000001, it should not be put lower than this and generally this is only for when wanting a fast overview of the data, as it is less precise than the likelihood based convergence. By default the method adjusting the frequencies is used, to use the unadjusted approach set "-doAdjust 0". The accelerated EM algorithm is used by default, to use regular EM algorithm set "-method 0".
OPTIONS OPTIONS OPTIONS!??
Custom refpanel can be supplied, has to look like this, where the 5 first columns have to be, then populations frequencies:
chr,pos,name,A0,A1
The frequencies have to be of the A0 allele.
Basically the files have to look like this: bgl rs1 A B GL(AA) GL(AB) GL(BB) Then ref 1 1 rs1 B A f(B)
Then solution is this: bgl rs1 A B GL(AA) GL(AB) GL(BB) Then ref 1 1 rs1 B A 1-f(B)
Then prepFreqs.R will take care of preparing the files properly.
Example of running prepFreqs.R:
Rscript prepFreqs.R indi_genotypelikelihood.bgl
Can also specify other populations than the default 5 ones in the reference panel. Also a custom made reference panel can be supplied (has to be .Rdata file).
Rscript prepFreqs.R indi_genotypelikelihood.bgl Pop1,Pop2,Pop3,Pop4 customRefPanel
indi_genotypelikelihood
Then run prepFreqs.R to get the proper beagle, refpanel and nInd files for the analysis.
Then run fastNGSadmix.
All the awesome options with the program.
So bgl
rs1 A B GL(AA) GL(AB) GL(BB)
Then ref
1 1 rs1 A B f(A)
(So if the 3 columns with genotype likelihoods in the beagle file is coded like this AA AB BB, then the frequencies should be of the A allele.)
Furthermore a file with the number of individuals in each reference population should be supplied.
Then a lot of different options and filters can be specified:
(TO BE CONTINUED...)