The hardware and bandwidth for this mirror is donated by dogado GmbH, the Webhosting and Full Service-Cloud Provider. Check out our Wordpress Tutorial.
If you wish to report a bug, or if you are interested in having us mirror your free-software or open-source project, please feel free to contact us at mirror[@]dogado.de.
July 8th, 2023
This update fixes a bug in the DistCalc() function.
June 30th, 2023
This update fixes a bug in the DistCalc() function and introduces a few minor edits in the reference manual.
March 22nd, 2023
This update fixes a bug in the ReplMatch() and PapaDiv() functions, which caused an error when matching the occurrence of sequences between samples. Sequences are now named using index numbers of the sequences with zeroes padded in front, e.g. “Sequence_001” to “Sequence_999”. This prevents RegEx pattern matching between e.g. “Sequence_1” and “Sequence_1X”. This naming concept has been implemented throughout MHCtools, for the sake of consistency. The updated functions are: CreateFas(), CreateSamplesFas(), DistCalc(), HpltFind(), ReplMatch(), and PapaDiv().
In addition, a bug was fixed in the HpltMatch() function, which caused an error when running the function with the setting threshold=NULL.
October 19th, 2022
New functions
This update introduces three new functions to MHCtools, which are all
related to haplotype inference:
The CreateHpltOccTable() function creates a haplotype-sequence occurrence matrix from the output of HpltFind(), for easy overview of which sequences are present in which haplotypes.
The HpltMatch() function compares haplotypes to help identify overlapping and potentially identical types.
The NestTablesXL() function translates the output from HpltFind() to an Excel workbook, that provides a convenient overview for evaluation and curation of the inferred putative haplotypes.
More details on these new functions are provided in the reference manual.
Adjustment to DistCalc()
The DistCalc() function has been updated so that it can handle data sets
where some samples have 0 or 1 sequence(s) in a sequence occurrence
table. DistCalc() will assign NA to the mean distance value for such
samples in the output table.
Adjustment to ReplMatch()
The ReplMatch() function has been updated to throw a warning if all
samples in a replicate set have 0 sequences. ReplMatch() will report
which replicate set is problematic and suggest to remove it from the
replicates table.
Miscellaneous
Finally, a few minor adjustments have been made to improve the
efficiency of the code in most functions, with no change in
functionality.
August 15th, 2022
This update fixes a bug in the HpltFind function, which caused an error when no alleles are shared between a chick and one of its parents (this may e.g. occur in nests with extra-pair fertilization).
Furthermore, the updated version of HpltFind introduces the alpha-parameter, which may be used to fine-tune the haplotype analysis (details provided in the reference manual).
May 23rd, 2022
This version provides the following citation details following
presentation of MHCtools in Molecular Ecology Resources:
Roved, J., Hansson, B., Stervander, M., Hasselquist, D., &
Westerdahl, H. (2022). MHCtools - an R package for MHC high-throughput
sequencing data: genotyping, haplotype and supertype inference, and
downstream genetic analyses in non-model organisms. Molecular Ecology
Resources. https://doi.org/10.1111/1755-0998.13645
October 11th, 2021
This update fixes a bug in the DistCalc() function, which caused an error when attempting to calculate p-distances from a fasta file of amino acid sequences.
September 13th, 2021
The BootKmeans() and ClusterMatch() functions
In this update, two new functions BootKmeans() and ClusterMatch() have
been added. In MHC data analysis, it is often desirable to group alleles
by their physico-chemical properties, as MHC receptors with similar
properties share the repertoire of peptides they can bind. From a
functional immunological perspective, alleles with similar properties
may therefore be regarded as belonging to the same supertypes, which in
many cases can simplify statistical analyses by reducing the number of
independent variables and increase statistical power as more samples
will share supertypes compared to alleles. Inference of MHC supertypes
has traditionally been carried out by k-means clustering analysis on a
set of z-descriptors of the physico-chemical properties of the amino
acid sequences. However, the inference of relevant clusters is not
always straightforward, since MHC data sets do not always produce clear
inflection points (e.g. the elbow in an elbow plot). The BootKmeans()
function is a wrapper for the kmeans() function of the stats package,
which allows for bootstrapping of a k-means clustering analysis.
BootKmeans() performs multiple runs of kmeans() and estimates optimal
k-values based on a user-defined threshold of BIC reduction. The method
may be seen as an automated and bootstrapped version of visually
inspecting elbow plots of BIC- vs. k-values. To evaluate which of the
bootstrapped k-means models is most accurate and/or informative, the
ClusterMatch() function offers a tool for evaluating whether different
k-means clustering models identify similar clusters, and summarize
bootstrap model stats as means for different estimated values of k.
ClusterMatch() is designed to take files produced by the BootKmeans()
function as input, but other data can be analysed if the descriptions of
the required data formats are observed carefully.
September 15th, 2020
The DistCalc() function
In this update, the new function DistCalc() replaces CalcPdist(). The
DistCalc() function calculates Grantham, Sandberg, or p-distances and
produces a matrix with distances from pairwise comparisons of all
sequences in an input file. Input files may be either a fasta file (in
the format rendered by the read.fasta() function from the package
seqinr) or a dada2-style sequence table. If a dada2-style sequence table
is used as input, the function produces a table with mean distances for
each sample in the data set in addition to the distance matrix. Amino
acid distances may be calculated from input files with nucleotide
sequences by automatic translation using the standard genetic code. The
function furthermore includes an option for the user to specify which
codons to compare, which is useful e.g. if conducting the analysis only
on codon positions involved in specific functions such as the
peptide-binding of an MHC molecule.
Z-descriptors
If calculation of Sandberg distances is specified when using DistCalc(),
the function additionally outputs five tables with physico-chemical
z-descriptor values for each amino acid position in all sequences in the
input file. These tables may be useful for further downstream analyses,
such as estimation of MHC supertypes. The z-descriptor values are
derived from Sandberg et al. 1998, JMed Chem. 41(14):2481-2491.
Miscellaneous
This update furthermore removes the dependency on the package rlist.
August 8th, 2019
This update provides a minor modification of the CalcPdist() function, so that when a dada2 sequence table is used as input, sequences are now named by an index number (corresponding to their column number in the input table) in the p-distance matrix.
August 8th, 2019
This update replaces the MeanPdist() function with the new function CalcPdist(), which has more universal applications. The CalcPdist function produces a matrix with p-distances from pairwise comparisons of all sequences in an input file. If a dada2 sequence table is used as input, the function furthermore produces a table with mean p-distances for each sample in the data set. Optionally, amino acid p-distances may be calculated, based on the standard genetic code. The function furthermore includes an option for the user to specify which codons to compare, which is useful e.g. if conducting the analysis only on codon positions involved in specific functions such as the peptide-binding of an MHC molecule. Input files may be either a fasta file (fasta files are accepted in the format rendered by e.g. the read.fasta() function from the package seqinr) or a dada2 sequence table.
February 4th, 2019
This update fixes bugs in the HpltFind and PapaDiv functions. Furthermore, a minor modification of the functions GetHpltTable and GetReplTable ensures that results are presented according to nest or replicate number, respectively (previous versions presented them in alphanumeric order).
October 23rd, 2017
This update adds the new function MeanPdist() to the R package MHCtools. The MeanPdist() function calculates the mean p-distance from pairwise comparisons of the sequences in each sample in a data set. The function includes an option for the user to specify which codons to compare, which is useful e.g. if conducting the analysis only on codon positions involved in specific functions such as the peptide-binding of an MHC molecule.
September 29th, 2017
This new R package contains nine useful functions for analysis of
major histocompatibility complex (MHC) data in non-model species. The
functions are tailored for amplicon data sets that have been filtered
using the dada2 pipeline (for more information visit https://benjjneb.github.io/dada2/), but even other data
sets can be analyzed, if the data tables are formatted according to the
description in each function.
The ReplMatch() function matches replicates in data sets in order to
evaluate genotyping success.
The GetReplTable() and GetReplStats() functions perform such an
evaluation.
The HpltFind() function infers putative haplotypes from families in the
data set.
The GetHpltTable() and GetHpltStats() functions evaluate the accuracy of
the haplotype inference.
The PapaDiv() function compares parent pairs in the data set and
calculate their joint MHC diversity, taking into account sequence
variants that occur in both parents.
The CreateFas() function creates a fasta file with all the sequences in
the data set.
The CreateSamplesFas() function creates a fasta file for each sample in
the data set.
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.
Health stats visible at Monitor.