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-rw-r--r--gnu/packages/bioconductor.scm221
1 files changed, 209 insertions, 12 deletions
diff --git a/gnu/packages/bioconductor.scm b/gnu/packages/bioconductor.scm
index 3810749f83..e87907fac5 100644
--- a/gnu/packages/bioconductor.scm
+++ b/gnu/packages/bioconductor.scm
@@ -590,6 +590,35 @@ data. It is derived from the UCSC hg19 genome and based on the \"knownGene\"
track. The database is exposed as a @code{TxDb} object.")
(license license:artistic2.0)))
+(define-public r-txdb-hsapiens-ucsc-hg38-knowngene
+ (package
+ (name "r-txdb-hsapiens-ucsc-hg38-knowngene")
+ (version "3.4.6")
+ (source (origin
+ (method url-fetch)
+ ;; We cannot use bioconductor-uri here because this tarball is
+ ;; located under "data/annotation/" instead of "bioc/".
+ (uri (string-append "https://bioconductor.org/packages/"
+ "release/data/annotation/src/contrib"
+ "/TxDb.Hsapiens.UCSC.hg38.knownGene_"
+ version ".tar.gz"))
+ (sha256
+ (base32
+ "12j7rri9r129v9w1yiqadg952dx462dh092sxif3r5kk8l7bxkn9"))))
+ (properties
+ `((upstream-name . "TxDb.Hsapiens.UCSC.hg38.knownGene")))
+ (build-system r-build-system)
+ (propagated-inputs
+ `(("r-genomicfeatures" ,r-genomicfeatures)))
+ (home-page
+ "https://bioconductor.org/packages/TxDb.Hsapiens.UCSC.hg38.knownGene/")
+ (synopsis "Annotation package for human genome in TxDb format")
+ (description
+ "This package provides an annotation database of Homo sapiens genome
+data. It is derived from the UCSC hg38 genome and based on the \"knownGene\"
+track. The database is exposed as a @code{TxDb} object.")
+ (license license:artistic2.0)))
+
(define-public r-txdb-mmusculus-ucsc-mm9-knowngene
(package
(name "r-txdb-mmusculus-ucsc-mm9-knowngene")
@@ -1153,14 +1182,14 @@ determining dependencies between variables, code improvement suggestions.")
(define-public r-chippeakanno
(package
(name "r-chippeakanno")
- (version "3.18.0")
+ (version "3.18.1")
(source
(origin
(method url-fetch)
(uri (bioconductor-uri "ChIPpeakAnno" version))
(sha256
(base32
- "089v16mm5m0rlyyyd0d6rz8gwb852zf3bcdrrw70wanlfjn258q7"))))
+ "1mwi5s600c3jxy8f1azfrndc3g06qvhbmrp9wqac9nwjbfx1kfji"))))
(properties `((upstream-name . "ChIPpeakAnno")))
(build-system r-build-system)
(propagated-inputs
@@ -2086,14 +2115,14 @@ independent of the p-value under the null hypothesis.")
(define-public r-icobra
(package
(name "r-icobra")
- (version "1.12.0")
+ (version "1.12.1")
(source
(origin
(method url-fetch)
(uri (bioconductor-uri "iCOBRA" version))
(sha256
(base32
- "1w9frnczgypzc2czbwrvlizqcqhbp6cdpyws7vkmnn9k0ggzxvfc"))))
+ "1wj0vqyb6h4rddmn4va3182yap9bv4m1r1jlzyjfyrqxhl2sqb1q"))))
(properties `((upstream-name . "iCOBRA")))
(build-system r-build-system)
(propagated-inputs
@@ -2886,14 +2915,14 @@ to multiple hypothesis correction.")
(define-public r-dose
(package
(name "r-dose")
- (version "3.10.0")
+ (version "3.10.1")
(source
(origin
(method url-fetch)
(uri (bioconductor-uri "DOSE" version))
(sha256
(base32
- "0dvhnfhzhhzcxm8zhdwrkif7sak4p888sjqfd3a0p77h0hs6g8pv"))))
+ "0ab7mgj42fg6608qkciyqivr1n8s8r5ibvp0z3jfclrnyx6cl0w1"))))
(properties `((upstream-name . "DOSE")))
(build-system r-build-system)
(propagated-inputs
@@ -3408,14 +3437,14 @@ position-specific scores within R and Bioconductor.")
(define-public r-atacseqqc
(package
(name "r-atacseqqc")
- (version "1.8.0")
+ (version "1.8.1")
(source
(origin
(method url-fetch)
(uri (bioconductor-uri "ATACseqQC" version))
(sha256
(base32
- "03f130vcd6hd3fv2pg60id0ddd6qkwsyx73gm907xaayf42ar2pj"))))
+ "0h5j3724hnd86w22vy3whqx6gkf0nf2dxd2clgzdvjzblbcd5s69"))))
(properties `((upstream-name . "ATACseqQC")))
(build-system r-build-system)
(propagated-inputs
@@ -3621,14 +3650,14 @@ investigation using RNA-seq data.")
(define-public r-aucell
(package
(name "r-aucell")
- (version "1.6.0")
+ (version "1.6.1")
(source
(origin
(method url-fetch)
(uri (bioconductor-uri "AUCell" version))
(sha256
(base32
- "025q1as9pifbxa7hidlz634q6d7l73zx8mqy4rjbfrk7d5615xvm"))))
+ "1vd8w6dygn1b5bwlha09mm6fbwyj07pmawpv53agcg1y7jlxs31b"))))
(properties `((upstream-name . "AUCell")))
(build-system r-build-system)
(propagated-inputs
@@ -4438,14 +4467,14 @@ interpretation.")
(define-public r-rhisat2
(package
(name "r-rhisat2")
- (version "1.0.1")
+ (version "1.0.2")
(source
(origin
(method url-fetch)
(uri (bioconductor-uri "Rhisat2" version))
(sha256
(base32
- "01jhj5vvfl4n2d0nl3nd1iw9nii85mgw2adnrmxb8wwlxgy240vr"))))
+ "1y3zqvk1vbcb10r1myh6f5yzjvf7bhwhpiq78bs1k6spli4bzj0q"))))
(properties `((upstream-name . "Rhisat2")))
(build-system r-build-system)
(native-inputs
@@ -4548,3 +4577,171 @@ high-throughput sequencing data. It performs parallel processing of entire
files and produces a report which contains a set of high-resolution
graphics.")
(license license:gpl2+)))
+
+(define-public r-birewire
+ (package
+ (name "r-birewire")
+ (version "3.16.0")
+ (source
+ (origin
+ (method url-fetch)
+ (uri (bioconductor-uri "BiRewire" version))
+ (sha256
+ (base32
+ "1gjb18l3gq3w8zl6r5d49hw0r1kfh9f7ghv9hz6y86aniprvb518"))))
+ (properties `((upstream-name . "BiRewire")))
+ (build-system r-build-system)
+ (propagated-inputs
+ `(("r-igraph" ,r-igraph)
+ ("r-matrix" ,r-matrix)
+ ("r-slam" ,r-slam)
+ ("r-tsne" ,r-tsne)))
+ (home-page "https://bioconductor.org/packages/release/bioc/html/BiRewire.html")
+ (synopsis "Tools for randomization of bipartite graphs")
+ (description
+ "This package provides functions for bipartite network rewiring through N
+consecutive switching steps and for the computation of the minimal number of
+switching steps to be performed in order to maximise the dissimilarity with
+respect to the original network. It includes functions for the analysis of
+the introduced randomness across the switching steps and several other
+routines to analyse the resulting networks and their natural projections.")
+ (license license:gpl3)))
+
+(define-public r-birta
+ (package
+ (name "r-birta")
+ (version "1.28.0")
+ (source
+ (origin
+ (method url-fetch)
+ (uri (bioconductor-uri "birta" version))
+ (sha256
+ (base32
+ "12xjyvgmh4h0b7hi4qg50kcpb9003gnh2xyfgncb8l9mzvsbkxc2"))))
+ (build-system r-build-system)
+ (propagated-inputs
+ `(("r-biobase" ,r-biobase)
+ ("r-limma" ,r-limma)
+ ("r-mass" ,r-mass)))
+ (home-page "https://bioconductor.org/packages/birta")
+ (synopsis "Bayesian inference of regulation of transcriptional activity")
+ (description
+ "Expression levels of mRNA molecules are regulated by different
+processes, comprising inhibition or activation by transcription factors and
+post-transcriptional degradation by microRNAs. @dfn{birta} (Bayesian
+Inference of Regulation of Transcriptional Activity) uses the regulatory
+networks of transcription factors and miRNAs together with mRNA and miRNA
+expression data to predict switches in regulatory activity between two
+conditions. A Bayesian network is used to model the regulatory structure and
+Markov-Chain-Monte-Carlo is applied to sample the activity states.")
+ (license license:gpl2+)))
+
+(define-public r-ropls
+ (package
+ (name "r-ropls")
+ (version "1.16.0")
+ (source
+ (origin
+ (method url-fetch)
+ (uri (bioconductor-uri "ropls" version))
+ (sha256
+ (base32
+ "099nv9dgmw3avkxv7cd27r16yj56svjlp5q4i389yp1n0r5zhyl2"))))
+ (build-system r-build-system)
+ (propagated-inputs `(("r-biobase" ,r-biobase)))
+ (native-inputs
+ `(("r-knitr" ,r-knitr))) ; for vignettes
+ (home-page "https://dx.doi.org/10.1021/acs.jproteome.5b00354")
+ (synopsis "Multivariate analysis and feature selection of omics data")
+ (description
+ "Latent variable modeling with @dfn{Principal Component Analysis} (PCA)
+and @dfn{Partial Least Squares} (PLS) are powerful methods for visualization,
+regression, classification, and feature selection of omics data where the
+number of variables exceeds the number of samples and with multicollinearity
+among variables. @dfn{Orthogonal Partial Least Squares} (OPLS) enables to
+separately model the variation correlated (predictive) to the factor of
+interest and the uncorrelated (orthogonal) variation. While performing
+similarly to PLS, OPLS facilitates interpretation.
+
+This package provides imlementations of PCA, PLS, and OPLS for multivariate
+analysis and feature selection of omics data. In addition to scores, loadings
+and weights plots, the package provides metrics and graphics to determine the
+optimal number of components (e.g. with the R2 and Q2 coefficients), check the
+validity of the model by permutation testing, detect outliers, and perform
+feature selection (e.g. with Variable Importance in Projection or regression
+coefficients).")
+ (license license:cecill)))
+
+(define-public r-biosigner
+ (package
+ (name "r-biosigner")
+ (version "1.12.0")
+ (source
+ (origin
+ (method url-fetch)
+ (uri (bioconductor-uri "biosigner" version))
+ (sha256
+ (base32
+ "1643iya40v6whb7lw7y34w5sanbasvj4yhvcygbip667yhphyv5b"))))
+ (build-system r-build-system)
+ (propagated-inputs
+ `(("r-biobase" ,r-biobase)
+ ("r-e1071" ,r-e1071)
+ ("r-randomforest" ,r-randomforest)
+ ("r-ropls" ,r-ropls)))
+ (native-inputs
+ `(("r-knitr" ,r-knitr)
+ ("r-rmarkdown" ,r-rmarkdown)
+ ("pandoc" ,ghc-pandoc)
+ ("pandoc-citeproc" ,ghc-pandoc-citeproc))) ; all for vignettes
+ (home-page "https://bioconductor.org/packages/biosigner/")
+ (synopsis "Signature discovery from omics data")
+ (description
+ "Feature selection is critical in omics data analysis to extract
+restricted and meaningful molecular signatures from complex and high-dimension
+data, and to build robust classifiers. This package implements a method to
+assess the relevance of the variables for the prediction performances of the
+classifier. The approach can be run in parallel with the PLS-DA, Random
+Forest, and SVM binary classifiers. The signatures and the corresponding
+'restricted' models are returned, enabling future predictions on new
+datasets.")
+ (license license:cecill)))
+
+(define-public r-annotatr
+ (package
+ (name "r-annotatr")
+ (version "1.10.0")
+ (source
+ (origin
+ (method url-fetch)
+ (uri (bioconductor-uri "annotatr" version))
+ (sha256
+ (base32
+ "1zlhy6swfgqjhhcqn8c6akxd4c4z8p85swfh095imji7hxnlhh1f"))))
+ (build-system r-build-system)
+ (propagated-inputs
+ `(("r-annotationdbi" ,r-annotationdbi)
+ ("r-annotationhub" ,r-annotationhub)
+ ("r-dplyr" ,r-dplyr)
+ ("r-genomeinfodb" ,r-genomeinfodb)
+ ("r-genomicfeatures" ,r-genomicfeatures)
+ ("r-genomicranges" ,r-genomicranges)
+ ("r-ggplot2" ,r-ggplot2)
+ ("r-iranges" ,r-iranges)
+ ("r-readr" ,r-readr)
+ ("r-regioner" ,r-regioner)
+ ("r-reshape2" ,r-reshape2)
+ ("r-rtracklayer" ,r-rtracklayer)
+ ("r-s4vectors" ,r-s4vectors)))
+ (home-page "https://bioconductor.org/packages/annotatr/")
+ (synopsis "Annotation of genomic regions to genomic annotations")
+ (description
+ "Given a set of genomic sites/regions (e.g. ChIP-seq peaks, CpGs,
+differentially methylated CpGs or regions, SNPs, etc.) it is often of interest
+to investigate the intersecting genomic annotations. Such annotations include
+those relating to gene models (promoters, 5'UTRs, exons, introns, and 3'UTRs),
+CpGs (CpG islands, CpG shores, CpG shelves), or regulatory sequences such as
+enhancers. The annotatr package provides an easy way to summarize and
+visualize the intersection of genomic sites/regions with genomic
+annotations.")
+ (license license:gpl3)))