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microhaplot
generates visual summaries of
microhaplotypes found in short read alignments. All you need are
alignment SAM files and a variant call VCF file. (The latter tells
microhaplot
which SNPs to include into microhaplotypes). It
was designed for extracting and visualized haplotypes from high-quality
amplicon sequencing data. We have used it extensively to process
amplicon sequencing data (with 100 to 500 amplicons) from rockfish and
Chinook salmon, generated on an Illumina MiSeq sequencer. It should be
extensible to sequences from capture arrays, like RAPTURE data.
This software exists as an R package microhaplot
that
includes within it the code to set up and establish an Rstudio/Shiny
server to visualize and manipulate the data. There are two key steps in
the microhaplot
workflow:
The first step is to summarize alignment and variant (SNP) data
into a single data frame that is easily operated upon. This is done
using the function microhaplot::prepHaplotFiles
. You must
supply a VCF file that includes variants that you are interested in
extracting, and as many SAM files (one for each individual) that you
want to extract read information from at each of the variants. The
function microhaplot::prepHaplotFiles
makes a call to PERL
to parse the CIGAR strings in the SAM files to extract the variant
information at each read and store this information into a data frame
which gets saved with the installed Shiny app (see below) for later use.
Depending on the size of the data set, this can take a few
minutes.
The second step is to run the microhaplot Shiny app to visualize the sequence information, call genotypes using simple read-depth based filtering criteria, and curate the loci. microhaplot is suitable for quick assessment and quality control of haplotypes generated from library runs. Plot summaries include read depth, fraction of callable haplotypes, Hardy-Weinberg equilibrium plots, and more.
See the Example Data section to learn about how to run each of these steps on the example data that are provided with the package.
You need to have Perl (version >5.014) installed in your OS in
order to run Microhaplot.
For Window users, we recommend install it via
http://strawberryperl.com/.
For Mac and Linux users, Perl can be downloaded from
https://www.perl.org/get.html
You can either clone the repository and build the
microhaplot
package yourself, or, more easily, you can
install it using devtools. You can get
devtools
by install.packages("devtools")
.
To mac user: remember to install XQuartz, when upgrading your macOS to a new major version.
Once you have devtools
available in R, you can get
microhaplot
this way:
::install_github("ngthomas/microhaplot", build_vignettes = TRUE, build_opts = c("--no-resave-data", "--no-manual")) devtools
Once you have installed the microhaplot
R package with
devtools there you need to use the microhaplot::mvHaplotype
to establish the microhaplot Shiny App in a convenient location on your
system. The following line creates the directory Shiny
in
my home directory and then within that it creates the directory
microhaplot
and fills it with the Shiny app as well as the
example data that go along with that.
::mvShinyHaplot("~/Shiny") # provide a directory path to host the microhaplot app microhaplot
To start familiarizing yourself with microhaplot using the provided example data. We recommend going through our first vignette. Call it up with:
browseVignettes("microhaplot")
and check out microhaplot-walkthrough
.
Now, having done that, we can launch Shiny microhaplot on the example data:
library(microhaplot)
<- "~/Shiny/microhaplot"
app.path runShinyHaplot(app.path)
This microhaplot package comes with a small customized sample data drawn from an actual run of short read sequencing run on Rockfish species. The sample data contains sequences of eight genomic loci for four populations of five individuals each, with a total of twenty individuals.
First you need to create a tab-separate label file with 3 info columns: path to SAM file name, individual ID, and group label (in this particular order). If you do not want assign any group label for the individuals, you can just leave it as “NA”. It is recommended that you have all of the SAM files under one directory to make this labeling task easier.
The label
file looks like this:
s6.sam s6 copper
s11.sam s11 copper
s13.sam s13 gold
s14.sam s14 kelp s18.sam s18 gold
Once you have the label file in place, you can run
prepHaplotFiles
, a R function that generates tables of
microhaplotype, by providing the following: * a label to display in
haPLOType * path to the directory with all SAM files * path to the
label
file you just created * path to the VCF file
* optional number of threads (for non-Windows user); recommend 2 * # of
processors
library(microhaplot)
# to access package sample case study dataset of rockfish
<- "sebastes"
run.label
<- tempdir()
sam.path untar(system.file("extdata",
"sebastes_sam.tar.gz",
package="microhaplot"),
exdir = sam.path)
<- file.path(sam.path, "label.txt")
label.path <- file.path(sam.path, "sebastes.vcf")
vcf.path <- tempdir()
out.path <- "~/Shiny/microhaplot"
app.path
# for your dataset: customize the following paths
# sam.path <- "~/microhaplot/extdata/"
# label.path <- "~/microhaplot/extdata/label.txt"
# vcf.path <- "~/microhaplot/extdata/sebastes.vcf"
# app.path <- "~/Shiny/microhaplot"
<- prepHaplotFiles(run.label = run.label,
haplo.read.tbl sam.path = sam.path,
out.path = out.path,
label.path = label.path,
vcf.path = vcf.path,
app.path = app.path,
n.jobs = 4) # assume running on dual core
runShinyHaplot(app.path)
These binaries (installable software) and packages are in development.
They may not be fully stable and should be used with caution. We make no claims about them.
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