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We will go through a simple and more complex example on how to use NGSadmix with visualization of the data.
We will go through a simple and more complex example on how to use NGSadmix with visualization of the data.


==Example of NGSadmix - Simple==
User need to to add -printInfo 1 in order to get information about sites retained for analysis.
 
==Example of NGSadmix - very small data set==


In our first example, we will infer admixture proportions for low depth NGS data using a small dataset from 30 human samples.
In our first example, we will infer admixture proportions for low depth NGS data using a small dataset from 30 human samples.


:1. Every time you open a new terminal window, set directories to all required programs and the data you will use depending on where you installed them
===Set paths to software===
Every time you open a new terminal window, set directories to all required programs and the data you will use depending on where you installed them
 
Set the path to NGSadmix, for example:
 
<code>NGSADMIX=~/Software/NGSadmix</code>


:: Set the path to NGSadmix, for example:
Test the link
::<code>NGSADMIX=~/Software/NGSadmix</code>


:: Test the link
<code>ls $NGSADMIX</code>
::<code>ls $NGSADMIX</code>


:2. Create the directories that will be used for working:
===Create directories===
::<code>mkdir Demo</code>
Create the directories that will be used for working:
::<code>cd Demo</code>
::<code>mkdir Data</code>
::<code>mkdir Results</code>


:3. Set the paths to your local directories, for example:
<code>mkdir Demo</code>
::<code>IN_DIR=~/Demo/Data</code>
::<code>OUT_DIR=~/Demo/Results</code>


::Test the links
<code>cd Demo</code>
::<code>ls $IN_DIR</code>
::<code>ls $OUT_DIR</code>


:4. The Input file
<code>mkdir Data</code>


::NGSadmix uses Genotype Likelihoods (GLs) in .beagle format as input. The input file has been created for you.
<code>mkdir Results</code>


::We will use a very reduced data set:
<code>cd ..</code>
::-10 individuals from each population: 10 from Nigeria (YRI), 10 from Japan (JPT) and 10 with European Ancestry (CEU).  
::-a very reduced genome 30 x 100k random regions across the autosomes
::-each individual is sequenced at 2-6X


::<table class="muse-table" border="2" cellpadding="5">
===Set the paths to your local directories===
 
<code>IN_DIR=Demo/Data</code>
 
<code>OUT_DIR=Demo/Results</code>
 
Test the links
 
<code>ls $IN_DIR</code>
 
<code>ls $OUT_DIR</code>
 
===The test data===
 
 
We will use a very reduced data set.
 
*10 individuals from each population: 10 from Nigeria (YRI), 10 from Japan (JPT) and 10 with European Ancestry (CEU).
*a very reduced genome 30 x 100k random regions across the autosomes
*each individual is sequenced at 2-6X
 
<table class="muse-table" border="2" cellpadding="5">
     <tr>
     <tr>
       <td>CEU</td>
       <td>CEU</td>
Line 49: Line 65:
       <td>West African - Nigerian Yoruba individuals</td>
       <td>West African - Nigerian Yoruba individuals</td>
     </tr>
     </tr>
::</table>
</table>
 
 
You can either download the beagle input files or create them yourself from bam files. Therefore you should choose either 'Download the beagle genotype likelihood input file' or 'Create the the beagle genotype likelihood input file using ANGSD'.
====Download the beagle genotype likelihood input file====
NGSadmix uses Genotype Likelihoods (GLs) in .beagle format as input. The input file has been created for you.
A file with the information about the population is also provided.
Download the files and move them to your input folder (for example, $IN_DIR):
 
<code>wget popgen.dk/software/download/NGSadmix/data/Demo1input.gz</code>
 
<code>wget popgen.dk/software/download/NGSadmix/data/Demo1pop.info</code>
 
<code>mv Demo1input.gz $IN_DIR</code>
 
<code>mv Demo1pop.info $IN_DIR</code>
 
====Create the the beagle genotype likelihood input file using ANGSD====
first set the path to ANGSD  (change ~/github/angsd/ to the path on your system)
 
<code> ANGSD=~/github/angsd/angsd </code>
 
test that you have the rigth path and that ANGSD is installed
 
<code> $ANGSD</code>
 
Download small BAM files and extract files
 
<code> wget http://popgen.dk/software/download/NGSadmix/data/smallerbams.tar </code>
 
<code> tar xf smallerbams.tar </code>
 
Make a list with the bam file names


<code>find smallerbams/ |  grep bam$ > all.files</code>


:5. Population information file.
calculate genotype likelihoods for polymorphic sites using ANGSD (see ANGSD website for further information)
::A file with labels that indicate which population the individuals are sampled from is also provided as the population information.


::To create the data files, please go the the following link [https://github.com/mfumagalli/ngsTools/blob/master/Scripts/data.sh]
<code>$ANGSD -bam all.files -GL 2 -doMajorMinor 1 -doMaf 1 -SNP_pval 2e-6 -minMapQ 30 -minQ 20 -minInd 25 -minMaf 0.05 -doGlf 2 -out $IN_DIR/Demo1input.gz -P 5 </code>


:6. Download the files to your input folder (for example, $IN_DIR):
create population information file
::<code>wget popgen.dk/software/download/NGSadmix/data/Demo1input.gz $IN_DIR</code>
::<code>wget popgen.dk/software/download/NGSadmix/data/Demo1pop.info $OUT_DIR</code>


:7. To view a summary of the population information file, cut the first column, sort and count:
<code> paste -d " " <( cut -f 5 -d"." all.files ) <(cut -f 1 -d"." all.files | xargs -n1 basename) > $IN_DIR/Demo1pop.info </code>
::<code>cut -f 1 -d " " $IN_DIR/Demo1pop.info | sort | uniq -c</code>


:8. Now let’s analyze the input file:
==== View population information file ====


::*In general, the first three columns of a beagle file contain marker name and the two alleles, allele1 and allele2, present in the locus (in beagle A=0, C=1, G=2, T=3). All following columns contain genotype likelihoods (three columns for each individual: first GL for homozygote for allele1, then GL for heterozygote and then GL for homozygote for allele2). Note that the GL values sum to one per site for each individual. This is just a normalization of the genotype likelihoods in order to avoid underflow problems in the beagle software, but it does not mean that they are genotype probabilities.
To view a summary of the population information file, cut the first column, sort and count:


::*In order to see the first 10 columns and 10 lines of the input file, type:
<code>cut -f 1 -d " " $IN_DIR/Demo1pop.info | sort | uniq -c</code>
:::<code>gunzip -c $IN_DIR/Demo1input.gz | head -n 10 | cut -fl-10 | column -t</code>


::*Use this command to count the number of lines of the input file. The number of lines, indicates the number of loci for which there are GLs plus one (as the command includes the count of the header line):
Lets make a population label file and place it in the output directory
:::<code>gunzip -c $IN_DIR/Demo1input.gz | wc -l</code>


:9. To run an analysis of the GLs with NGSadmix, assuming the number of ancestral populations is K=3, type the following command:
<code> cut -f1 -d" " $IN_DIR/Demo1pop.info  > $OUT_DIR/poplabel </code>


::<code>$NGSADMIX-likes $IN_DIR/Demo1input.gz -K 3 -minMaf 0.05 -seed 1 -o $OUT_DIR/Demo1NGSadmix</code>
==== View the genotype likelihood beagle file ====


:10. The output:
*In general, the first three columns of a beagle file contain marker name and the two alleles, allele1 and allele2, present in the locus (in beagle A=0, C=1, G=2, T=3). All following columns contain genotype likelihoods (three columns for each individual: first GL for homozygote for allele1, then GL for heterozygote and then GL for homozygote for allele2). Note that the GL values sum to one per site for each individual. This is just a normalization of the genotype likelihoods in order to avoid underflow problems in the beagle software, but it does not mean that they are genotype probabilities.  


::The analysis performed by NGSadmix produces 4 files:
*In order to see the first 10 columns and 10 lines of the input file, type:


::*'''Log likelihood of the estimates'''
:<code>gunzip -c $IN_DIR/Demo1input.gz | head -n 10 | cut -f 1-10 | column -t</code>
:::A .log file that summarizes the run.
:::Let’s take a look at the log file to determine the log likelihood of the estimates achieved by NGSadmix which is called the “best like” in the file:
:::<code>cat Demo1NGSadmix.log</code>


::*'''Estimated allele frequency'''
*Use this command to count the number of lines of the input file. The number of lines, indicates the number of loci for which there are GLs plus one (as the command includes the count of the header line):
:::A zipped .fopt file, that contains an estimate of the allele frequency in each of the 3 assumed ancestral populations (there is a line for each locus).
:::We can use this file to obtain the estimated allele frequency of the first 5 SNPs (one per line) of the three assumed ancestral populations, by typing the following command:
:::<code>zcat Demo1NGSadmix.fopt.gz | head -n 5</code>


::*'''Estimated admixture proportions'''
:<code>gunzip -c $IN_DIR/Demo1input.gz | wc -l</code>
:::A .qopt file, that contains an estimate of the individual's ancestry proportion from each of the three assumed ancestral populations (there is a line for each individual).
:::To obtain the estimated admixture proportions for the first 5 individuals, type the following command:
:::<code>head -n 5 Demo1NGSadmix.qopt</code>


::*'''DemoNGSadmix.filter''' if the filter was used, it will show the sites that were left out.
=== Let’s analyze the input file ===
:::To see the header file, type:
To run an analysis of the GLs with NGSadmix, assuming the number of ancestral populations is K=3, type the following command:
:::<code>head -n 5 Demo1NGSadmix.filter</code>


:11. Follow these instructions to make a simple plot of the estimated admixture proportions for all individuals in R:
<code>$NGSADMIX -likes $IN_DIR/Demo1input.gz -K 3 -minMaf 0.05 -seed 1 -o $OUT_DIR/Demo1NGSadmix</code>


::Make sure you stand on the output directory
For a reference on the parameters that can be used to run NGSadmix, please go to [http://www.popgen.dk/software/index.php/NgsAdmixv2#Parameters]
:::<code>cd $OUT_DIR</code>


::Type “R” in the terminal and press enter and paste the following code into R:
=== The output ===
 
The analysis performed by NGSadmix produces 4 files:
 
*'''Log likelihood of the estimates'''
A .log file that summarizes the run.
 
Let’s take a look at the log file to determine the log likelihood of the estimates achieved by NGSadmix which is called the “best like” in the file:
 
<code>cat $OUT_DIR/Demo1NGSadmix.log</code>
 
*'''Estimated allele frequency'''
 
::A zipped .fopt file, that contains an estimate of the allele frequency in each of the 3 assumed ancestral populations (there is a line for each locus).
 
::We can use this file to obtain the estimated allele frequency of the first 5 SNPs (one per line) of the three assumed ancestral populations, by typing the following command:
 
::<code>zcat $OUT_DIR/Demo1NGSadmix.fopt.gz | head -n 5</code>
 
*'''Estimated admixture proportions'''
::A .qopt file, that contains an estimate of the individual's ancestry proportion from each of the three assumed ancestral populations (there is a line for each individual).
 
::To obtain the estimated admixture proportions for the first 5 individuals, type the following command:
 
::<code>head -n 5 Demo1NGSadmix.qopt</code>
 
=== Plot the results in R ===
 
Follow these instructions to make a simple plot of the estimated admixture proportions for all individuals in R:
 
Make sure you stand on the output directory
 
<code>cd $OUT_DIR</code>
 
Type “R” in the terminal and press enter and paste the following code into R:


<pre>
<pre>
# Fill up a table with the IDs of the population information for each individual
# Get ID and pop info for each individual
# Get ID and pop info for each individual
s<-strsplit(basename(scan("all.files",what="theFuck")),"\\.")
pop<-scan("poplabel",what="theFuck")
pop<-sapply(s,function(x){paste(x[5],x[1],sep="_")})


# Read inferred admixture proportions file
# Read inferred admixture proportions file
Line 124: Line 188:
</pre>
</pre>


::The y-axis of the plot show the admixture proportions and the individuals in the samples are plotted in the x-axis.  
The y-axis of the plot show the admixture proportions and the individuals in the samples are plotted in the x-axis.  
::Each color represents a different ancestral population.
 
::The proportion of each color shows the different admixture of the individuals for each ancestral population.  
Each color represents a different ancestral population.
::The plot is sorted by the population of origin of each individual in the sample, and therefore, it shows blocks with prevalence of a certain color, which represents the population to which each individual belongs.
 
The proportion of each color shows the different admixture of the individuals for each ancestral population.  
 
The plot is sorted by the population of origin of each individual in the sample, and therefore, it shows blocks with prevalence of a certain color, which represents the population to which each individual belongs.


::NB As you could tell from the number of loci included in the analysis, the above analysis is based on data from very few loci (actually we on purpose only analyzed data from a small part of the genome to make sure the analysis ran fast). Results from an analysis of data from the entire genome can be seen here '''''[LINK ANDERS]'''''
NB As you could tell from the number of loci included in the analysis, the above analysis is based on data from very few loci (actually we on purpose only analyzed data from a small part of the genome to make sure the analysis ran fast).


==Example of NGSadmix - Complex==
==Example of NGSadmix with admixed populations==


Now that you know how to make input data to NGSadmix, how to run NGSadmix and what the output looks like, let's try to look at a more realistic size dataset. More specifically let's try to run NGSadmix on data from the 1000 genomes project from the following populations:
Now that you know how to make input data to NGSadmix, how to run NGSadmix and what the output looks like, let's try to look at a more realistic size dataset. More specifically let's try to run NGSadmix on 50000 sites from the 1000 genomes project from the following populations:


:<table class="muse-table" border="2" cellpadding="5">
:<table class="muse-table" border="2" cellpadding="5">
     <tr>
     <tr>
       <td>ASW</td>
       <td>ASW</td>
       <td>HapMap African ancestry individuals from SW US</td>
       <td>HapMap African Americans from SW US</td>
     </tr>
     </tr>
     <tr>
     <tr>
Line 166: Line 233:
''Note: please make sure you have created and set up the working directories as indicated in the previous tutorial.''
''Note: please make sure you have created and set up the working directories as indicated in the previous tutorial.''


:1. Download and copy the files to your input folder (for example, $IN_DIR):
===Download Files===
::<code>wget popgen.dk/software/download/NGSadmix/data/Demo2input.gz $IN_DIR</code>
Download and copy the files to your input folder (for example, $IN_DIR)
::<code>wget popgen.dk/software/download/NGSadmix/data/Demo2pop.info $OUT_DIR</code>
<pre>
wget popgen.dk/software/download/NGSadmix/data/Demo2input.gz
wget popgen.dk/software/download/NGSadmix/data/Demo2pop.info
mv Demo2input.gz $IN_DIR
mv Demo2pop.info $OUT_DIR</pre>


make sure you are back in your original folder (not the $OUT_DIR folder)


:2. Take a quick look at the population data by making a summary using the following:
===Take a quick look at the population data===
::cut first column | sort | count
make a summary by cutting the first column, sorting and counting
::<code>cut -f 1 -d " " $IN_DIR/Demo2pop.info | sort | uniq -c</code>
<code>cut -f 1 -d " " $OUT_DIR/Demo2pop.info | sort | uniq -c</code>


===Run NGSadmix===
Run an analysis of the data with NGSadmix with K=3 (-K 3), using 1 cpu (-P 1), using only SNPs with minor allele frequency above 0.05 (-minMaf 0.05), set the seed set to 21 (-seed 21), and set the prefix of the output files to Demo2NGSadmixK3. For a reference on the parameters that can be used to run NGSadmix, please go to [http://www.popgen.dk/software/index.php/NgsAdmixv2#Parameters]


:3. Run an analysis of the data with NGSadmix with K=3 (-K 3), using 1 cpu (-P 1), using only SNPs with minor allele frequency above 0.05 (-minMaf 0.05), set the seed set to 21 (-seed 21), and set the prefix of the output files to Demo2NGSadmixK3.
<code>$NGSADMIX -likes $IN_DIR/Demo2input.gz -K 3 -P 1 -minMaf 0.05 -seed 21 -o $OUT_DIR/Demo2NGSadmixK3</code>


::<code>NGSADMIX -likes $IN_DIR/Demo2input.gz -K 3 -P 1 -minMaf 0.05 -seed 21 -o $OUT_DIR/Demo2NGSadmixK3</code>
===Plot===
Plot the estimated admixture proportions by running the following code in R:
:4. Plot the estimated admixture proportions by running the following code in R:


::Make sure you stand on the output directory
Make sure you stand on the output directory
:::<code>cd $OUT_DIR</code>
<code>cd $OUT_DIR</code>


::Type “R” in the terminal and press enter and paste the following code into R:
Type “R” in the terminal and press enter and paste the following code into R:


<pre>
<pre>
Line 199: Line 272:
</pre>
</pre>


:Note that like in the previous example, the order of the individuals in the plot is not the same as in the .qopt file. Instead, to provide a better overview, the individuals have been ordered according to their population labels.
Note that like in the previous example, the order of the individuals in the plot is not the same as in the .qopt file. Instead, to provide a better overview, the individuals have been ordered according to their population labels.


:5. Try to run NGSadmix with K=4 and compare the plots.
===Choose a differnt K===
Try to run NGSadmix with K=4 and compare the plots.


::<code>$NGSADMIX -likes $IN_DIR/Demo2input.gz -K 4 -P 1 -minMaf 0.05 -seed 21 -o $OUT_DIR/Demo2NGSadmixK4</code>
<code>$NGSADMIX -likes $IN_DIR/Demo2input.gz -K 4 -P 1 -minMaf 0.05 -seed 21 -o $OUT_DIR/Demo2NGSadmixK4</code>


::Type “R” in the terminal and press enter and paste the following code into R:
Type “R” in the terminal and press enter and paste the following code into R:


<pre>
<pre>

Latest revision as of 23:59, 6 June 2022

We will go through a simple and more complex example on how to use NGSadmix with visualization of the data.

User need to to add -printInfo 1 in order to get information about sites retained for analysis.

Example of NGSadmix - very small data set

In our first example, we will infer admixture proportions for low depth NGS data using a small dataset from 30 human samples.

Set paths to software

Every time you open a new terminal window, set directories to all required programs and the data you will use depending on where you installed them

Set the path to NGSadmix, for example:

NGSADMIX=~/Software/NGSadmix

Test the link

ls $NGSADMIX

Create directories

Create the directories that will be used for working:

mkdir Demo

cd Demo

mkdir Data

mkdir Results

cd ..

Set the paths to your local directories

IN_DIR=Demo/Data

OUT_DIR=Demo/Results

Test the links

ls $IN_DIR

ls $OUT_DIR

The test data

We will use a very reduced data set.

  • 10 individuals from each population: 10 from Nigeria (YRI), 10 from Japan (JPT) and 10 with European Ancestry (CEU).
  • a very reduced genome 30 x 100k random regions across the autosomes
  • each individual is sequenced at 2-6X
CEU Europeans (mostly of British ancestry)
JPT East Asian - Japanese individuals
YRI West African - Nigerian Yoruba individuals


You can either download the beagle input files or create them yourself from bam files. Therefore you should choose either 'Download the beagle genotype likelihood input file' or 'Create the the beagle genotype likelihood input file using ANGSD'.

Download the beagle genotype likelihood input file

NGSadmix uses Genotype Likelihoods (GLs) in .beagle format as input. The input file has been created for you. A file with the information about the population is also provided.

Download the files and move them to your input folder (for example, $IN_DIR):

wget popgen.dk/software/download/NGSadmix/data/Demo1input.gz

wget popgen.dk/software/download/NGSadmix/data/Demo1pop.info

mv Demo1input.gz $IN_DIR

mv Demo1pop.info $IN_DIR

Create the the beagle genotype likelihood input file using ANGSD

first set the path to ANGSD (change ~/github/angsd/ to the path on your system)

ANGSD=~/github/angsd/angsd

test that you have the rigth path and that ANGSD is installed

$ANGSD

Download small BAM files and extract files

wget http://popgen.dk/software/download/NGSadmix/data/smallerbams.tar

tar xf smallerbams.tar

Make a list with the bam file names

find smallerbams/ | grep bam$ > all.files

calculate genotype likelihoods for polymorphic sites using ANGSD (see ANGSD website for further information)

$ANGSD -bam all.files -GL 2 -doMajorMinor 1 -doMaf 1 -SNP_pval 2e-6 -minMapQ 30 -minQ 20 -minInd 25 -minMaf 0.05 -doGlf 2 -out $IN_DIR/Demo1input.gz -P 5

create population information file

paste -d " " <( cut -f 5 -d"." all.files ) <(cut -f 1 -d"." all.files | xargs -n1 basename) > $IN_DIR/Demo1pop.info

View population information file

To view a summary of the population information file, cut the first column, sort and count:

cut -f 1 -d " " $IN_DIR/Demo1pop.info | sort | uniq -c

Lets make a population label file and place it in the output directory

cut -f1 -d" " $IN_DIR/Demo1pop.info > $OUT_DIR/poplabel

View the genotype likelihood beagle file

  • In general, the first three columns of a beagle file contain marker name and the two alleles, allele1 and allele2, present in the locus (in beagle A=0, C=1, G=2, T=3). All following columns contain genotype likelihoods (three columns for each individual: first GL for homozygote for allele1, then GL for heterozygote and then GL for homozygote for allele2). Note that the GL values sum to one per site for each individual. This is just a normalization of the genotype likelihoods in order to avoid underflow problems in the beagle software, but it does not mean that they are genotype probabilities.
  • In order to see the first 10 columns and 10 lines of the input file, type:
gunzip -c $IN_DIR/Demo1input.gz | head -n 10 | cut -f 1-10 | column -t
  • Use this command to count the number of lines of the input file. The number of lines, indicates the number of loci for which there are GLs plus one (as the command includes the count of the header line):
gunzip -c $IN_DIR/Demo1input.gz | wc -l

Let’s analyze the input file

To run an analysis of the GLs with NGSadmix, assuming the number of ancestral populations is K=3, type the following command:

$NGSADMIX -likes $IN_DIR/Demo1input.gz -K 3 -minMaf 0.05 -seed 1 -o $OUT_DIR/Demo1NGSadmix

For a reference on the parameters that can be used to run NGSadmix, please go to [1]

The output

The analysis performed by NGSadmix produces 4 files:

  • Log likelihood of the estimates

A .log file that summarizes the run.

Let’s take a look at the log file to determine the log likelihood of the estimates achieved by NGSadmix which is called the “best like” in the file:

cat $OUT_DIR/Demo1NGSadmix.log

  • Estimated allele frequency
A zipped .fopt file, that contains an estimate of the allele frequency in each of the 3 assumed ancestral populations (there is a line for each locus).
We can use this file to obtain the estimated allele frequency of the first 5 SNPs (one per line) of the three assumed ancestral populations, by typing the following command:
zcat $OUT_DIR/Demo1NGSadmix.fopt.gz | head -n 5
  • Estimated admixture proportions
A .qopt file, that contains an estimate of the individual's ancestry proportion from each of the three assumed ancestral populations (there is a line for each individual).
To obtain the estimated admixture proportions for the first 5 individuals, type the following command:
head -n 5 Demo1NGSadmix.qopt

Plot the results in R

Follow these instructions to make a simple plot of the estimated admixture proportions for all individuals in R:

Make sure you stand on the output directory

cd $OUT_DIR

Type “R” in the terminal and press enter and paste the following code into R:

# Get ID and pop info for each individual
pop<-scan("poplabel",what="theFuck")

# Read inferred admixture proportions file
q<-read.table("Demo1NGSadmix.qopt")

# Plot them (ordered by population)
ord = order(pop)
par(mar=c(7,4,1,1))
barplot(t(q)[,ord],col=c(2,1,3),names=pop[ord],las=2,ylab="Demo1 Admixture proportions",cex.names=0.75)

The y-axis of the plot show the admixture proportions and the individuals in the samples are plotted in the x-axis.

Each color represents a different ancestral population.

The proportion of each color shows the different admixture of the individuals for each ancestral population.

The plot is sorted by the population of origin of each individual in the sample, and therefore, it shows blocks with prevalence of a certain color, which represents the population to which each individual belongs.

NB As you could tell from the number of loci included in the analysis, the above analysis is based on data from very few loci (actually we on purpose only analyzed data from a small part of the genome to make sure the analysis ran fast).

Example of NGSadmix with admixed populations

Now that you know how to make input data to NGSadmix, how to run NGSadmix and what the output looks like, let's try to look at a more realistic size dataset. More specifically let's try to run NGSadmix on 50000 sites from the 1000 genomes project from the following populations:

ASW HapMap African Americans from SW US
CEU European individuals
CHB Han Chinese in Beijing
JPT Japanese individuals
YRI Yoruba individuals from Nigeria
MXL Mexican individuals from LA California

The input file Demo2input.gz with genotype likelihoods from 100 individuals in .beagle format, and a file with population info are given. Note: please make sure you have created and set up the working directories as indicated in the previous tutorial.

Download Files

Download and copy the files to your input folder (for example, $IN_DIR)

wget popgen.dk/software/download/NGSadmix/data/Demo2input.gz
wget popgen.dk/software/download/NGSadmix/data/Demo2pop.info
mv Demo2input.gz $IN_DIR
mv Demo2pop.info $OUT_DIR

make sure you are back in your original folder (not the $OUT_DIR folder)

Take a quick look at the population data

make a summary by cutting the first column, sorting and counting cut -f 1 -d " " $OUT_DIR/Demo2pop.info | sort | uniq -c

Run NGSadmix

Run an analysis of the data with NGSadmix with K=3 (-K 3), using 1 cpu (-P 1), using only SNPs with minor allele frequency above 0.05 (-minMaf 0.05), set the seed set to 21 (-seed 21), and set the prefix of the output files to Demo2NGSadmixK3. For a reference on the parameters that can be used to run NGSadmix, please go to [2]

$NGSADMIX -likes $IN_DIR/Demo2input.gz -K 3 -P 1 -minMaf 0.05 -seed 21 -o $OUT_DIR/Demo2NGSadmixK3

Plot

Plot the estimated admixture proportions by running the following code in R:

Make sure you stand on the output directory cd $OUT_DIR

Type “R” in the terminal and press enter and paste the following code into R:

# read population labels and estimated admixture proportions
pop<-read.table("Demo2pop.info",as.is=T)
q<-read.table("Demo2NGSadmixK3.qopt")

# order according to population
ord<-order(pop[,1])
barplot(t(q)[,ord],col=2:10,space=0,border=NA,xlab="Individuals",ylab="Demo2 Admixture proportions for K=3")
text(tapply(1:nrow(pop),pop[ord,1],mean),-0.05,unique(pop[ord,1]),xpd=T)
abline(v=cumsum(sapply(unique(pop[ord,1]),function(x){sum(pop[ord,1]==x)})),col=1,lwd=1.2)

Note that like in the previous example, the order of the individuals in the plot is not the same as in the .qopt file. Instead, to provide a better overview, the individuals have been ordered according to their population labels.

Choose a differnt K

Try to run NGSadmix with K=4 and compare the plots.

$NGSADMIX -likes $IN_DIR/Demo2input.gz -K 4 -P 1 -minMaf 0.05 -seed 21 -o $OUT_DIR/Demo2NGSadmixK4

Type “R” in the terminal and press enter and paste the following code into R:

# read population labels and estimated admixture proportions
pop<-read.table("Demo2pop.info",as.is=T)
q<-read.table("Demo2NGSadmixK4.qopt")

# order according to population
ord<-order(pop[,1])
barplot(t(q)[,ord],col=2:10,space=0,border=NA,xlab="Individuals",ylab="Demo2 Admixture proportions for K=4")
text(tapply(1:nrow(pop),pop[ord,1],mean),-0.05,unique(pop[ord,1]),xpd=T)
abline(v=cumsum(sapply(unique(pop[ord,1]),function(x){sum(pop[ord,1]==x)})),col=1,lwd=1.2)