A Suite of Packages for Analysis of Big Genomic Data.
BGData: A Suite of Packages for Analysis of Big Genomic Data
BGData (Grueneberg & de los Campos, 2019) is an R package that provides scalable and efficient computational methods for large genomic datasets, e.g., genome-wide association studies (GWAS) or genomic relationship matrices (G matrices). It also contains a container class called BGData
that holds genotypes, sample information, and variant information.
Modern genomic datasets are big (large n), high-dimensional (large p), and multi-layered. The challenges that need to be addressed are memory requirements and computational demands. Our goal is to develop software that will enable researchers to carry out analyses with big genomic data within the R environment.
We have identified several approaches to tackle those challenges within R:
- File-backed matrices: The data is stored in on the hard drive and users can read in smaller chunks when they are needed.
- Linked arrays: For very large datasets a single file-backed array may not be enough or convenient. A linked array is an array whose content is distributed over multiple file-backed nodes.
- Multiple dispatch: Methods are presented to users so that they can treat these arrays pretty much as if they were RAM arrays.
- Multi-level parallelism: Exploit multi-core and multi-node computing.
- Inputs: Users can create these arrays from standard formats (e.g., PLINK .bed).
The BGData package is an umbrella package that comprises several packages: BEDMatrix, LinkedMatrix, and symDMatrix.
Examples
Loading the package
Load the BGData package:
library(BGData)
Inspecting the example dataset
The inst/extdata
folder contains example files that were generated from the 250k SNP and phenotype data in Atwell et al. (2010). Only the first 300 SNPs of chromosome 1, 2, and 3 were included to keep the size of the example dataset small enough for CRAN. PLINK was used to convert the data to .bed and .raw files. FT10
has been chosen as a phenotype and is provided as an alternate phenotype file. The file is intentionally shuffled to demonstrate that the additional phenotypes are put in the same order as the rest of the phenotypes.
path <- system.file("extdata", package = "BGData")
list.files(path)
#> [1] "chr1.bed" "chr1.bim" "chr1.fam" "chr1.raw" "chr2.bed" "chr2.bim"
#> [7] "chr2.fam" "chr2.raw" "chr3.bed" "chr3.bim" "chr3.fam" "chr3.raw"
#> [13] "pheno.txt"
Loading example dataset
Loading individual PLINK .bed files
Load the .bed file for chromosome 1 (chr1.bed) using the BEDMatrix package:
chr1 <- BEDMatrix(paste0(path, "/chr1.bed"))
#> Extracting number of individuals and rownames from .fam file...
#> Extracting number of markers and colnames from .bim file...
BEDMatrix
objects behave similarly to regular matrices:
dim(chr1)
#> [1] 199 300
rownames(chr1)[1:10]
#> [1] "5837_5837" "6008_6008" "6009_6009" "6016_6016" "6040_6040" "6042_6042"
#> [7] "6043_6043" "6046_6046" "6064_6064" "6074_6074"
colnames(chr1)[1:10]
#> [1] "snp1_T" "snp2_G" "snp3_A" "snp4_T" "snp5_G" "snp6_T" "snp7_C"
#> [8] "snp8_C" "snp9_C" "snp10_G"
chr1["6008_6008", "snp5_G"]
#> [1] 0
Linking multiple BEDMatrix objects together
Load the other two .bed files:
chr2 <- BEDMatrix(paste0(path, "/chr2.bed"))
#> Extracting number of individuals and rownames from .fam file...
#> Extracting number of markers and colnames from .bim file...
chr3 <- BEDMatrix(paste0(path, "/chr3.bed"))
#> Extracting number of individuals and rownames from .fam file...
#> Extracting number of markers and colnames from .bim file...
Combine the BEDMatrix objects by columns using the LinkedMatrix to avoid the inconvenience of having three separate matrices:
wg <- ColumnLinkedMatrix(chr1, chr2, chr3)
Just like BEDMatrix
objects, LinkedMatrix
objects also behave similarly to regular matrices:
dim(wg)
#> [1] 199 900
rownames(wg)[1:10]
#> [1] "5837_5837" "6008_6008" "6009_6009" "6016_6016" "6040_6040" "6042_6042"
#> [7] "6043_6043" "6046_6046" "6064_6064" "6074_6074"
colnames(wg)[1:10]
#> [1] "snp1_T" "snp2_G" "snp3_A" "snp4_T" "snp5_G" "snp6_T" "snp7_C"
#> [8] "snp8_C" "snp9_C" "snp10_G"
wg["6008_6008", "snp5_G"]
#> [1] 0
Creating a BGData object
BGData
objects can be created from individual BEDMatrix
objects or a collection of BEDMatrix
objects as a LinkedMatrix
object using the as.BGData()
function. This will read the .fam and .bim file that comes with the .bed files. The alternatePhenotypeFile
parameter points to the file that contains the FT10
phenotype:
bg <- as.BGData(wg, alternatePhenotypeFile = paste0(path, "/pheno.txt"))
#> Extracting phenotypes from .fam file, assuming that the .fam file of the first BEDMatrix instance is representative of all the other nodes...
#> Extracting map from .bim files...
#> Merging alternate phenotype file...
The bg
object will use the LinkedMatrix
object as genotypes, the .fam file augmented by the FT10
phenotype as sample information, and the .bim file as variant information.
str(bg)
#> Formal class 'BGData' [package "BGData"] with 3 slots
#> ..@ geno :Formal class 'ColumnLinkedMatrix' [package "LinkedMatrix"] with 1 slot
#> .. .. ..@ .Data:List of 3
#> .. .. .. ..$ :BEDMatrix: 199 x 300 [/home/agrueneberg/.pkgs/R/BGData/extdata/chr1.bed]
#> .. .. .. ..$ :BEDMatrix: 199 x 300 [/home/agrueneberg/.pkgs/R/BGData/extdata/chr2.bed]
#> .. .. .. ..$ :BEDMatrix: 199 x 300 [/home/agrueneberg/.pkgs/R/BGData/extdata/chr3.bed]
#> ..@ pheno:'data.frame': 199 obs. of 7 variables:
#> .. ..$ FID : int [1:199] 5837 6008 6009 6016 6040 6042 6043 6046 6064 6074 ...
#> .. ..$ IID : int [1:199] 5837 6008 6009 6016 6040 6042 6043 6046 6064 6074 ...
#> .. ..$ PAT : int [1:199] 0 0 0 0 0 0 0 0 0 0 ...
#> .. ..$ MAT : int [1:199] 0 0 0 0 0 0 0 0 0 0 ...
#> .. ..$ SEX : int [1:199] 0 0 0 0 0 0 0 0 0 0 ...
#> .. ..$ PHENOTYPE: int [1:199] -9 -9 -9 -9 -9 -9 -9 -9 -9 -9 ...
#> .. ..$ FT10 : num [1:199] 57 60 98 75 71 56 90 93 96 91 ...
#> ..@ map :'data.frame': 900 obs. of 6 variables:
#> .. ..$ chromosome : int [1:900] 1 1 1 1 1 1 1 1 1 1 ...
#> .. ..$ snp_id : chr [1:900] "snp1" "snp2" "snp3" "snp4" ...
#> .. ..$ genetic_distance : int [1:900] 0 0 0 0 0 0 0 0 0 0 ...
#> .. ..$ base_pair_position: int [1:900] 657 3102 4648 4880 5975 6063 6449 6514 6603 6768 ...
#> .. ..$ allele_1 : chr [1:900] "T" "G" "A" "T" ...
#> .. ..$ allele_2 : chr [1:900] "C" "A" "C" "C" ...
Saving a BGData object
A BGData object can be saved like any other R object using the save
function:
save(bg, file = "BGData.RData")
Loading a BGData object
The genotypes in a BGData
object can be of various types, some of which need to be initialized in a particular way. The load.BGData
takes care of reloading a saved BGData object properly:
load.BGData("BGData.RData")
#> Loaded objects: bg
Summarizing data
Use chunkedApply
to count missing values (among others):
countNAs <- chunkedApply(X = geno(bg), MARGIN = 2, FUN = function(x) sum(is.na(x)))
Use the summarize
function to calculate minor allele frequencies and frequency of missing values:
summarize(geno(bg))
Running GWASes with different regression methods
A data structure for genomic data is useful when defining methods that act on both phenotype and genotype information. We have implemented a GWAS
function that supports various regression methods. The formula takes phenotypes from the sample information of the BGData
object and inserts one marker at a time.
gwas <- GWAS(formula = FT10 ~ 1, data = bg)
Generating the G Matrix
G <- getG(geno(bg))
Installation
Install the stable version from CRAN:
install.packages("BGData")
Alternatively, install the development version from GitHub:
# install.packages("remotes")
remotes::install_github("QuantGen/BGData")
Documentation
Further documentation can be found on RDocumentation.
Contributing
- Issue Tracker: https://github.com/QuantGen/BGData/issues
- Source Code: https://github.com/QuantGen/BGData.