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This page contains information about the program PCAngsd, which estimates the covariance matrix for low depth NGS data in an iterative procedure based on genotype likelihoods. Based on the population structure inference PCAngsd is able to estimate individual allele frequencies. By incorporating these allele frequencies in Empirical Bayes approaches, PCAngsd can perform PCA (estimate covariance matrix), call genotypes, estimate inbreeding coefficients (per-individual and per-site) and perform a genome selection scan using principal components in structured populations. The entire program is written in Python 2.7.


[[File:Pcangsd_plot.png|thumb]]


=Download=


The program can be downloaded from Github:
PCAngsd is a program that estimates the covariance matrix and individual allele frequencies for low-depth next-generation sequencing (NGS) data in structured/heterogeneous populations using principal component analysis (PCA) to perform multiple population genetic analyses using genotype likelihoods. Since version 0.98, PCAngsd was re-written to be based on Cython for computational bottlenecks and parallelization.
https://github.com/Rosemeis/pcangsd


The main method was published in 2018 and can be found here: [https://www.genetics.org/content/210/2/719]
The HWE test was published in 2019 and can be found here: [https://onlinelibrary.wiley.com/doi/abs/10.1111/1755-0998.13019]
[[File:Pcangsd_admix3.gif|frame]]
[[File:Pcangsd_pca.png|thumb|400px|Simulated low depth NGS data of 3 populations]]
=Overview=
Framework for analyzing low-depth next-generation sequencing (NGS) data in heterogeneous/structured populations using principal component analysis (PCA). Population structure is inferred by estimating individual allele frequencies in an iterative approach using a truncated SVD model. The covariance matrix is estimated using the estimated individual allele frequencies as prior information for the unobserved genotypes in low-depth NGS data.
The estimated individual allele frequencies can further be used to account for population structure in other probabilistic methods. PCAngsd can perform the following analyses:
*Covariance matrix
*Admixture estimations
*Inbreeding coefficients (both per-individual and per-site)
*HWE test
*Genome-wide selection scan
*Genotype calling
*Estimate NJ tree of samples
Older versions of PCAngsd can be found here [https://github.com/Rosemeis/pcangsd/releases/].
=Download and Installation=
PCAngsd should work on all platforms meeting the requirements but server-side usage is highly recommended. Installation has only been tested on Linux systems.
Get PCAngsd and build
<pre>
<pre>
git clone https://github.com/Rosemeis/pcangsd.git;
git clone https://github.com/Rosemeis/pcangsd.git
cd pcangsd/
cd pcangsd/
python setup.py build_ext --inplace
</pre>
</pre>
Install dependencies:


The following Python packages are needed to run PCAngsd (found in all popular distributions):
The required set of Python packages are easily installed using the pip command and the 'requirements.txt file' included in the 'pcangsd' folder.
'''numpy''' and '''pandas'''.


PCAngsd should work on all platforms meeting the requirements but server-side usage is recommended.
<pre>
pip install --user -r requirements.txt
</pre>


=Quick start=


==Quick start==
PCAngsd is used by running the main caller file pcangsd.py. To see all available options use the following command:
<pre>
<pre>
# See all options in PCAngsd
python pcangsd.py -h
python pcangsd.py -h


# Only estimate covariance matrix
# Genotype likelihoods using 64 threads
python pcangsd.py -beagle test.beagle.gz -o test
python pcangsd.py -beagle input.beagle.gz -out output -threads 64


# Estimate covariance matrix and inbreeding coefficients
# PLINK files (using file-prefix, *.bed, *.bim, *.fam)
python pcangsd.py -beagle test.beagle.gz -inbreed 1 -o test
python pcangsd.py -beagle input.plink -out output -threads 64
</pre>
 
PCAngsd accepts either genotype likelihoods in Beagle format or PLINK genotype files. Beagle files can be generated from BAM files using [http://popgen.dk/angsd ANGSD]. For inference of population structure in genotype data with non-random missigness, we recommend our [http://www.popgen.dk/software/index.php/EMU EMU] software that performs accelerated EM-PCA, however with fewer functionalities than PCAngsd (#soon).
 
PCAngsd will mostly output files in binary Numpy format (.npy) with a few exceptions. In order to read files in python:
<pre>
import numpy as np
C = np.genfromtxt("output.cov") # Reads in estimated covariance matrix (text)
D = np.load("output.selection.npy") # Reads PC based selection statistics
</pre>


# Estimate covariance matrix and perform selection scan
R can also read Numpy matrices using the "RcppCNPy" R library:
python pcangsd.py -beagle test.beagle.gz -selection 1 -o test
<pre>
library(RcppCNPy)
C <- as.matrix(read.table("output.cov")) # Reads in estimated covariance matrix
D <- npyLoad("output.selection.npy") # Reads PC based selection statistics
</pre>
</pre>


=Input=
An example of generating genotype likelihoods in [http://popgen.dk/angsd ANGSD] and output them in the required Beagle text format.
The only input PCAngsd needs and accepts are genotype likelihoods in [http://faculty.washington.edu/browning/beagle/beagle.html Beagle] format. [http://popgen.dk/angsd ANGSD] can be easily be used to compute genotype likelihoods and output them in the required Beagle format.


<pre>
<pre>
./angsd -GL 1 -out genoLikes -nThreads 10 -doGlf 2 -doMajorMinor 1 -doMaf 2 -SNP_pval 1e-6 -bam bam.filelist
./angsd -GL 2 -out input -nThreads 4 -doGlf 2 -doMajorMinor 1 -doMaf 2 -SNP_pval 1e-6 -bam bam.filelist
</pre>
</pre>


See [http://popgen.dk/angsd ANGSD] for more info on how to compute the genotype likelihoods and call SNPs.
=Tutorial=


=Using PCAngsd=
Please refer to the tutorial's page [http://www.popgen.dk/software/index.php/PCAngsdTutorial]
 
=Options=
<pre>
# See all options in PCAngsd
python pcangsd.py -h
</pre>


All the different options in PCAngsd are listed here. '''All desired analyses must be run in the same command!''' (''For now...'')
==General usage==
; -beagle [Beagle file]
Input file of genotype likelihoods in Beagle format (.beagle.gz).
; -filter [Text file]
Input file of 1's or 0's whether to keep individuals or not.
; -plink [Prefix for binary PLINK files]
Path to PLINK files using their ONLY prefix (.bed, .bim, .fam).
; -plink_error [float]
Incorporate errors into genotypes by specifying rate as argument.
; -minMaf [float]
Minimum minor allele frequency threshold. (Default: 0.05)
; -maf_iter [int]
Maximum number of EM iterations for computing the population allele frequencies (Default: 200).
; -maf_tole [float]
Tolerance value in EM algorithm for population allele frequencies estimation (Default: 1e-4).
; -iter [int]
Maximum number of iterations for estimation of individual allele frequencies (Default: 100).
; -tole [float]
Tolerance value for update in estimation of individual allele frequencies (Default: 1e-5).
; -hwe [.lrt.npy file]
Input file of LRT binary file from previous PCAngsd run to filter based on HWE.
; -hwe_tole [float]
Threshold for HWE filtering of sites.
; -e [int]
Manually select the number of eigenvalues to use in the modelling of individual allele frequencies (Default: Automatically tested using MAP test).
; -pi [.pi.npy file]
Load previous estimation of individual allele frequencies to skip covariance estimation.
; -maf_save
Choose to save estimated population allele frequencies (Binary). Numpy format (.npy).
; -pi_save
Choose to save estimated individual allele frequencies (Binary). Numpy format (.npy). Can be used with the '-pi' command.
; -dosage_save
Choose to save estimated genotype dosages (Binary). Numpy format (.npy).
; -post_save
Choose to save the posterior genotype probabilities. Beagle format (.beagle).
; -sites_save
Choose to save the kept sites after filtering which is useful for downstream analysis. Outputs a file of 1's and 0's for keeping a site or not, respectively.
; -threads [int]
Specify the number of thread(s) to use (Default: 1).
; -out [output prefix]
Fileprefix for all output files created by PCAngsd (Default: "pcangsd").


PCAngsd will always compute the covariance matrix. It uses the computed principal components to estimate the individual allele frequencies in an iterative procedure. This procedure is performed until the individual allele frequencies have converged.
==Selection==
Perform PC-based genome-wide selection scans using posterior expectations of the genotypes (genotype dosages):


; -beagle [Beagle filename]
; -selection
Path to file of the genotype likelihoods in Beagle format.
Using an extended model of [http://www.cell.com/ajhg/abstract/S0002-9297(16)00003-3 FastPCA]. Performs a genome-wide selection scan along all significant PCs. Outputs the selection statistics and must be converted to p-values by user. Each column reflect the selection statistics along a tested PC and they are χ²-distributed with 1 degree of freedom.
; -beaglelist [filelist]
Parse a file with a list of multiple Beagle files, e.g. if the genotype likelihoods have been computed separately for each chromosome.
; -M [int]
Maximum number of iterations for covariance estimation. Only needed in rare cases. (Default: 100)
; -M_tole [float]
Tolerance value for the iterative covariance matrix estimation. (Default: 1e-4)
; -EM [int]
Maximum number of EM iterations for computing the population allele frequencies. (Default: 200)
; -EM_tole [float]
Tolerance value in EM algorithm for population allele frequencies estimation. (Default: 1e-4)
; -e [int]
Manually select the number of eigenvalues to use in modelling of individual allele frequencies. (Default: Automatically tested)
; -reg
(Not fully tested!) Toogle to use Tikhonov regularization in modelling of individual allele frequencies to penalize lesser important PCs. May also help on convergence.
; -o [prefix]
Set the prefix for all output files created by PCAngsd (Default: "pcangsd").


==Call genotypes==
; -pcadapt
Genotypes can be called from posterior genotype probabilities incorporating the individual allele frequencies in prior.
Using an extended model of [https://onlinelibrary.wiley.com/doi/abs/10.1111/1755-0998.12592 pcadapt]. Performs a genome-wide selection scan across all significant PCs. Outputs the z-scores and must be converted to test statistics with the provided script 'pcangsd/scripts/pcadapt.R', and the test statistics are χ²-distributed with K degree of freedom.


; -geno [float]
; -snp_weights
Call genotypes with defined threshold.
Output the SNP weights of the significant K eigenvectors.
; -genoInbreed [float]
Call genotypes with defined threshold also taking inbreeding into account. ''-inbreed'' is required.


==Inbreeding==
==Inbreeding==
Per-individual inbreeding coefficients incorporating population structure can be computed using three different methods:
; -inbreedSites
Estimate per-site inbreeding coefficients accounting for population structure and perform likehood ratio test for detecting sites deviating from HWE [https://onlinelibrary.wiley.com/doi/abs/10.1111/1755-0998.13019].
 
; -inbreedSamples
Estimate per-individual inbreeding coefficients accounting for population structure which is based on an extension of [http://genome.cshlp.org/content/23/11/1852.full ngsF] for structured populations.


; -inbreed 1
A maximum likelihood estimator computed by an EM algorithm. Only allows for F-values between 0 and 1. Based on [https://www.cambridge.org/core/journals/genetics-research/article/maximum-likelihood-estimation-of-individual-inbreeding-coefficients-and-null-allele-frequencies/2DEBA0C0C2B92DF0EE89BD27DFCAD3FB].
; -inbreed 2
Simple estimator also computed by an EM algorithm. Based on [http://genome.cshlp.org/content/23/11/1852.full ngsF].
; -inbreed 3
(Not recommended for low depth NGS data!) Estimator using the kinship matrix. Based on [http://www.cell.com/ajhg/abstract/S0002-9297(15)00493-0 PC-Relate].
; -inbreed_iter [int]
; -inbreed_iter [int]
Maximum number of iterations for the EM algorithm methods. (Default: 200)
Maximum number of iterations for inbreeding EM algorithm. (Default: 200)
 
; -inbreed_tole [float]
; -inbreed_tole [float]
Tolerance value for the EM algorithms for inbreeding coefficients estimation. (Default: 1e-4)
Tolerance value for inbreeding EM algorithm in estimating inbreeding coefficients. (Default: 1e-4)


==Call genotypes==
Genotypes can be called from posterior genotype probabilities by incorporating the individual allele frequencies as prior information.


Per-site inbreeding coefficients incorporating population structure alongside likehood ratio tests for HWE can be computed as follows:
; -geno [float]
 
Call genotypes with defined threshold.
; -inbreedSites
; -genoInbreed [float]
Call genotypes with defined threshold also taking inbreeding into account. '-inbreedSamples' must also be called for using this option.


==Selection==
==Admixture==
A genome selection scan can be computed using two different methods:
Individual admixture proportions and ancestral allele frequencies can be estimated assuming K ancestral populations using an accelerated mini-batch NMF method.


; -selection 1
; -admix
Using an extended model of [http://www.cell.com/ajhg/abstract/S0002-9297(16)00003-3 FastPCA]. Performs a genome selection scan along all significant PCs.
Toggles admixture estimations. Estimates admixture proportions and ancestral allele frequencies.
; -selection 2
; -admix_K [int]
(Not fully tested!) Using an extended model of [http://onlinelibrary.wiley.com/doi/10.1111/1755-0998.12592/abstract PCAdapt].  
Not recommended. Override the number of ancestry components (K) to use, instead of using K=e-1.
; -admix_iter [int]
Maximum number of iterations for admixture estimations using NMF. (Default: 200)
; -admix_tole [float]
Tolerance value for update in admixture estimations using NMF. (Default: 1e-5)
; -admix_alpha [float
Specify alpha (sparseness regularization parameter). (Default: 0)
; -admix_auto [float]
Enable automatic search for optimal alpha using likelihood measure, by giving soft upper search bound of alpha.
; -admix_seed [int]
Specify seed for random initializations of factor matrices in admixture estimations.


==Tree==
; -tree
Construct neighbour-joining tree of samples from estimated covariance matrix estimated based on indivdual allele frequencies.
; -tree_samples
Provide a list of sample names of all individuals to construct a beautiful tree.


LD can also be taken into account when performing selection scans. LD regression has been implemented in PCAngsd but the functionality is not fully tested.
=Citation=
; -LD [int]
Our methods for inferring population structure have been published in GENETICS:
Select the window (in bases) of preceding sites to use in regression.


==Relatedness==
[http://www.genetics.org/content/early/2018/08/21/genetics.118.301336 Inferring Population Structure and Admixture Proportions in Low Depth NGS Data]
'''Work in progress...'''


Estimate kinship matrix:


; -kinship
Our method for testing for HWE in structured populations has been published in Molecular Ecology Resources:
Automatically estimated if ''-inbreed 3'' has been selected.


==Example==
[https://onlinelibrary.wiley.com/doi/abs/10.1111/1755-0998.13019 Testing for Hardy‐Weinberg Equilibrium in Structured Populations using Genotype or Low‐Depth NGS Data]
<pre>
# Estimate covariance matrix, inbreeding coefficients, kinship matrix and perform genome selection scan including various filters.
python pcangsd.py -beagle test.beagle.gz -inbreed 2 -kinship -selection 1 -o test -M_tole 1e-3 -inbreed_tole 1e-3
</pre>
 
 
=Citation=

Latest revision as of 12:26, 24 October 2023


PCAngsd is a program that estimates the covariance matrix and individual allele frequencies for low-depth next-generation sequencing (NGS) data in structured/heterogeneous populations using principal component analysis (PCA) to perform multiple population genetic analyses using genotype likelihoods. Since version 0.98, PCAngsd was re-written to be based on Cython for computational bottlenecks and parallelization.

The main method was published in 2018 and can be found here: [1]

The HWE test was published in 2019 and can be found here: [2]

Simulated low depth NGS data of 3 populations


Overview

Framework for analyzing low-depth next-generation sequencing (NGS) data in heterogeneous/structured populations using principal component analysis (PCA). Population structure is inferred by estimating individual allele frequencies in an iterative approach using a truncated SVD model. The covariance matrix is estimated using the estimated individual allele frequencies as prior information for the unobserved genotypes in low-depth NGS data.

The estimated individual allele frequencies can further be used to account for population structure in other probabilistic methods. PCAngsd can perform the following analyses:

  • Covariance matrix
  • Admixture estimations
  • Inbreeding coefficients (both per-individual and per-site)
  • HWE test
  • Genome-wide selection scan
  • Genotype calling
  • Estimate NJ tree of samples

Older versions of PCAngsd can be found here [3].

Download and Installation

PCAngsd should work on all platforms meeting the requirements but server-side usage is highly recommended. Installation has only been tested on Linux systems.

Get PCAngsd and build

git clone https://github.com/Rosemeis/pcangsd.git
cd pcangsd/
python setup.py build_ext --inplace

Install dependencies:

The required set of Python packages are easily installed using the pip command and the 'requirements.txt file' included in the 'pcangsd' folder.

pip install --user -r requirements.txt

Quick start

PCAngsd is used by running the main caller file pcangsd.py. To see all available options use the following command:

python pcangsd.py -h

# Genotype likelihoods using 64 threads
python pcangsd.py -beagle input.beagle.gz -out output -threads 64

# PLINK files (using file-prefix, *.bed, *.bim, *.fam)
python pcangsd.py -beagle input.plink -out output -threads 64

PCAngsd accepts either genotype likelihoods in Beagle format or PLINK genotype files. Beagle files can be generated from BAM files using ANGSD. For inference of population structure in genotype data with non-random missigness, we recommend our EMU software that performs accelerated EM-PCA, however with fewer functionalities than PCAngsd (#soon).

PCAngsd will mostly output files in binary Numpy format (.npy) with a few exceptions. In order to read files in python:

import numpy as np
C = np.genfromtxt("output.cov") # Reads in estimated covariance matrix (text)
D = np.load("output.selection.npy") # Reads PC based selection statistics

R can also read Numpy matrices using the "RcppCNPy" R library:

library(RcppCNPy)
C <- as.matrix(read.table("output.cov")) # Reads in estimated covariance matrix
D <- npyLoad("output.selection.npy") # Reads PC based selection statistics

An example of generating genotype likelihoods in ANGSD and output them in the required Beagle text format.

./angsd -GL 2 -out input -nThreads 4 -doGlf 2 -doMajorMinor 1 -doMaf 2 -SNP_pval 1e-6 -bam bam.filelist

Tutorial

Please refer to the tutorial's page [4]

Options

# See all options in PCAngsd
python pcangsd.py -h

General usage

-beagle [Beagle file]

Input file of genotype likelihoods in Beagle format (.beagle.gz).

-filter [Text file]

Input file of 1's or 0's whether to keep individuals or not.

-plink [Prefix for binary PLINK files]

Path to PLINK files using their ONLY prefix (.bed, .bim, .fam).

-plink_error [float]

Incorporate errors into genotypes by specifying rate as argument.

-minMaf [float]

Minimum minor allele frequency threshold. (Default: 0.05)

-maf_iter [int]

Maximum number of EM iterations for computing the population allele frequencies (Default: 200).

-maf_tole [float]

Tolerance value in EM algorithm for population allele frequencies estimation (Default: 1e-4).

-iter [int]

Maximum number of iterations for estimation of individual allele frequencies (Default: 100).

-tole [float]

Tolerance value for update in estimation of individual allele frequencies (Default: 1e-5).

-hwe [.lrt.npy file]

Input file of LRT binary file from previous PCAngsd run to filter based on HWE.

-hwe_tole [float]

Threshold for HWE filtering of sites.

-e [int]

Manually select the number of eigenvalues to use in the modelling of individual allele frequencies (Default: Automatically tested using MAP test).

-pi [.pi.npy file]

Load previous estimation of individual allele frequencies to skip covariance estimation.

-maf_save

Choose to save estimated population allele frequencies (Binary). Numpy format (.npy).

-pi_save

Choose to save estimated individual allele frequencies (Binary). Numpy format (.npy). Can be used with the '-pi' command.

-dosage_save

Choose to save estimated genotype dosages (Binary). Numpy format (.npy).

-post_save

Choose to save the posterior genotype probabilities. Beagle format (.beagle).

-sites_save

Choose to save the kept sites after filtering which is useful for downstream analysis. Outputs a file of 1's and 0's for keeping a site or not, respectively.

-threads [int]

Specify the number of thread(s) to use (Default: 1).

-out [output prefix]

Fileprefix for all output files created by PCAngsd (Default: "pcangsd").

Selection

Perform PC-based genome-wide selection scans using posterior expectations of the genotypes (genotype dosages):

-selection

Using an extended model of FastPCA. Performs a genome-wide selection scan along all significant PCs. Outputs the selection statistics and must be converted to p-values by user. Each column reflect the selection statistics along a tested PC and they are χ²-distributed with 1 degree of freedom.

-pcadapt

Using an extended model of pcadapt. Performs a genome-wide selection scan across all significant PCs. Outputs the z-scores and must be converted to test statistics with the provided script 'pcangsd/scripts/pcadapt.R', and the test statistics are χ²-distributed with K degree of freedom.

-snp_weights

Output the SNP weights of the significant K eigenvectors.

Inbreeding

-inbreedSites

Estimate per-site inbreeding coefficients accounting for population structure and perform likehood ratio test for detecting sites deviating from HWE [5].

-inbreedSamples

Estimate per-individual inbreeding coefficients accounting for population structure which is based on an extension of ngsF for structured populations.

-inbreed_iter [int]

Maximum number of iterations for inbreeding EM algorithm. (Default: 200)

-inbreed_tole [float]

Tolerance value for inbreeding EM algorithm in estimating inbreeding coefficients. (Default: 1e-4)

Call genotypes

Genotypes can be called from posterior genotype probabilities by incorporating the individual allele frequencies as prior information.

-geno [float]

Call genotypes with defined threshold.

-genoInbreed [float]

Call genotypes with defined threshold also taking inbreeding into account. '-inbreedSamples' must also be called for using this option.

Admixture

Individual admixture proportions and ancestral allele frequencies can be estimated assuming K ancestral populations using an accelerated mini-batch NMF method.

-admix

Toggles admixture estimations. Estimates admixture proportions and ancestral allele frequencies.

-admix_K [int]

Not recommended. Override the number of ancestry components (K) to use, instead of using K=e-1.

-admix_iter [int]

Maximum number of iterations for admixture estimations using NMF. (Default: 200)

-admix_tole [float]

Tolerance value for update in admixture estimations using NMF. (Default: 1e-5)

-admix_alpha [float

Specify alpha (sparseness regularization parameter). (Default: 0)

-admix_auto [float]

Enable automatic search for optimal alpha using likelihood measure, by giving soft upper search bound of alpha.

-admix_seed [int]

Specify seed for random initializations of factor matrices in admixture estimations.

Tree

-tree

Construct neighbour-joining tree of samples from estimated covariance matrix estimated based on indivdual allele frequencies.

-tree_samples

Provide a list of sample names of all individuals to construct a beautiful tree.

Citation

Our methods for inferring population structure have been published in GENETICS:

Inferring Population Structure and Admixture Proportions in Low Depth NGS Data


Our method for testing for HWE in structured populations has been published in Molecular Ecology Resources:

Testing for Hardy‐Weinberg Equilibrium in Structured Populations using Genotype or Low‐Depth NGS Data