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多组学联合分析-Matrix eQTL

2018-09-26  本文已影响1908人  子鹿学生信

找到Matrix eQTL这个包,看下文章Matrix eQTL: ultra fast eQTL analysis via large matrix operations(https://doi.org/10.1093/bioinformatics/bts163

eQTL(表达数量性状位点)计算transcript-SNP 的关系,即分析SNP与基因的表达是否相关。由于计算数量巨大,很多人都用较小的数据来做。因此该作者开发了Matrix eQTL,用于处理大数据,支持additive linear and ANOVA models with covariates,并且可以将cis- and trans-eQTLs分开计算。
Matrix eQTL相较于其他软件如FastMap — 18.4 min, Merlin — 12.3 min, Plink — 9.0 min, Matrix eQTL — 5.7 min and snpMatrix — 3.3 min要快,它设置一个阈值,只有超过这个阈值的p值才会被计算。
采用的是线型回归模型,g为基因表达情况,s为SNP分型结果。

说明文档http://www.bios.unc.edu/research/genomic_software/Matrix_eQTL/runit.html
示例数据:http://www.bios.unc.edu/research/genomic_software/Matrix_eQTL/R.html
分析过程很简单,首先设置好要分析文件的路径和名称:

install.packages("MatrixEQTL")

# 设置数据目录,示例数据放在包的安装目录下了。
base.dir = find.package("MatrixEQTL")

#设置分析的模型
useModel = modelLINEAR; # modelANOVA or modelLINEAR or modelLINEAR_CROSS 
#设置SNP文件的名称
SNP_file_name = paste(base.dir, "/data/SNP.txt", sep="");
# 设置表达数据文件的名称
expression_file_name = paste(base.dir, "/data/GE.txt", sep="");
# 设置协变量文件的名称
# 无协变量设置为character()
covariates_file_name = paste(base.dir, "/data/Covariates.txt", sep="");

output_file_name = tempfile();
Model: useModel = modelLINEAR
Equation: expression = α + ∑k βk⋅covariatek + γ⋅genotype_additive
Testing for significance of: γ
Test statistic: t-statistic

(2) modelANOVA

Model: useModel = modelANOVA
Equation: expression = α + ∑k βk⋅covariatek + γ1⋅genotype_additive + γ2⋅genotype_dominant
Testing for significance of: (γ1,γ2) pair
Test statistic: F-statistic

(3) modelLINEAR_CROSS

Model: useModel = modelLINEAR_CROSS
Equation:
    expression = α + ∑k βk⋅covariatek + γ⋅genotype_additive + δ⋅genotype_additive⋅covariateK
Testing for significance of: δ
Test statistic: t-statistic
pvOutputThreshold = 1e-2
# 设置协变量矩阵为 numeric(),很少用,默认
errorCovariance = numeric()
# 这里建立了一个SlicedData的新对象,用于存放martix的数据,并设置存放数据的格式
snps = SlicedData$new();
# 设置数据分隔符为tab
snps$fileDelimiter = "\t";      # the TAB character
# 设置缺失值为NA
snps$fileOmitCharacters = "NA"; # denote missing values;

snps$fileSkipRows = 1;          # one row of column labels
snps$fileSkipColumns = 1;       # one column of row labels
snps$fileSliceSize = 2000;      # read file in pieces of 2,000 rows
snps$LoadFile( SNP_file_name );

## Load gene expression data

gene = SlicedData$new();
gene$fileDelimiter = "\t";      # the TAB character
gene$fileOmitCharacters = "NA"; # denote missing values;
gene$fileSkipRows = 1;          # one row of column labels
gene$fileSkipColumns = 1;       # one column of row labels
gene$fileSliceSize = 2000;      # read file in slices of 2,000 rows
gene$LoadFile(expression_file_name);

## Load covariates

cvrt = SlicedData$new();
cvrt$fileDelimiter = "\t";      # the TAB character
cvrt$fileOmitCharacters = "NA"; # denote missing values;
cvrt$fileSkipRows = 1;          # one row of column labels
cvrt$fileSkipColumns = 1;       # one column of row labels

看下文件格式,snp文件用0,1,2表示,基因文件是表达量,cvrt是covariates:


image.png
image.png
image.png

设置好文件后可以用 Matrix_eQTL_engine主函数进行eQTL分析了,参数snps设置SNP文件,gene设置表达量文件,cvrt设置协变量。然后将每行的SNP和gene放到一块进行线性回归的分析。

me = Matrix_eQTL_engine(
    snps = snps,
    gene = gene,
    cvrt = cvrt,
    output_file_name = output_file_name,
    pvOutputThreshold = pvOutputThreshold,
    useModel = useModel, 
    errorCovariance = errorCovariance, 
    verbose = TRUE,
    pvalue.hist = TRUE,
    min.pv.by.genesnp = FALSE,
    noFDRsaveMemory = FALSE);

运行完后得到的me对象是一个list:


image.png

输出文件的每行eqtl为:SNP name, a transcript name, estimate of the effect size, t- or F-statistic, p-value, and FDR。

Matrix eQTL可以区分顺式(cis,local)和反式(trans,distant)eQTL,主要用Matrix_eQTL_main函数来分析。其包括以下几个参数:

*   `pvOutputThreshold.cis` – p-value threshold for cis-eQTLs.
*   `output_file_name.cis` – detected cis-eQTLs are saved in this file.
*   `cisDist` – maximum distance at which gene-SNP pair is considered local.
*   `snpspos` – data frame with information about SNP locations, must have 3 columns - SNP name, chromosome, and position. See [sample SNP location file](http://www.bios.unc.edu/research/genomic_software/Matrix_eQTL/Sample_Data/snpsloc.txt).
*   `genepos` – data frame with information about gene locations, must have 4 columns - the name, chromosome, and positions of the left and right ends. See [sample gene location file](http://www.bios.unc.edu/research/genomic_software/Matrix_eQTL/Sample_Data/geneloc.txt).

下面来看具体代码:

# source("Matrix_eQTL_R/Matrix_eQTL_engine.r");
library(MatrixEQTL)

## Location of the package with the data files.
base.dir = find.package('MatrixEQTL');
# base.dir = '.';

## Settings

# Linear model to use, modelANOVA, modelLINEAR, or modelLINEAR_CROSS
useModel = modelLINEAR; # modelANOVA, modelLINEAR, or modelLINEAR_CROSS

# Genotype file name
SNP_file_name = paste(base.dir, "/data/SNP.txt", sep="");
snps_location_file_name = paste(base.dir, "/data/snpsloc.txt", sep="");

# Gene expression file name
expression_file_name = paste(base.dir, "/data/GE.txt", sep="");
gene_location_file_name = paste(base.dir, "/data/geneloc.txt", sep="");

# Covariates file name
# Set to character() for no covariates
covariates_file_name = paste(base.dir, "/data/Covariates.txt", sep="");

# Output file name
output_file_name_cis = tempfile();
output_file_name_tra = tempfile();

# Only associations significant at this level will be saved
pvOutputThreshold_cis = 2e-2;
pvOutputThreshold_tra = 1e-2;

# Error covariance matrix
# Set to numeric() for identity.
errorCovariance = numeric();
# errorCovariance = read.table("Sample_Data/errorCovariance.txt");

# Distance for local gene-SNP pairs
cisDist = 1e6;

## Load genotype data

snps = SlicedData$new();
snps$fileDelimiter = "\t";      # the TAB character
snps$fileOmitCharacters = "NA"; # denote missing values;
snps$fileSkipRows = 1;          # one row of column labels
snps$fileSkipColumns = 1;       # one column of row labels
snps$fileSliceSize = 2000;      # read file in slices of 2,000 rows
snps$LoadFile(SNP_file_name);

## Load gene expression data

gene = SlicedData$new();
gene$fileDelimiter = "\t";      # the TAB character
gene$fileOmitCharacters = "NA"; # denote missing values;
gene$fileSkipRows = 1;          # one row of column labels
gene$fileSkipColumns = 1;       # one column of row labels
gene$fileSliceSize = 2000;      # read file in slices of 2,000 rows
gene$LoadFile(expression_file_name);

## Load covariates

cvrt = SlicedData$new();
cvrt$fileDelimiter = "\t";      # the TAB character
cvrt$fileOmitCharacters = "NA"; # denote missing values;
cvrt$fileSkipRows = 1;          # one row of column labels
cvrt$fileSkipColumns = 1;       # one column of row labels
if(length(covariates_file_name)>0) {
cvrt$LoadFile(covariates_file_name);
}

## Run the analysis
snpspos = read.table(snps_location_file_name, header = TRUE, stringsAsFactors = FALSE);
genepos = read.table(gene_location_file_name, header = TRUE, stringsAsFactors = FALSE);

me = Matrix_eQTL_main(
snps = snps, 
gene = gene, 
cvrt = cvrt,
output_file_name     = output_file_name_tra,
pvOutputThreshold     = pvOutputThreshold_tra,
useModel = useModel, 
errorCovariance = errorCovariance, 
verbose = TRUE, 
output_file_name.cis = output_file_name_cis,
pvOutputThreshold.cis = pvOutputThreshold_cis,
snpspos = snpspos, 
genepos = genepos,
cisDist = cisDist,
pvalue.hist = "qqplot",
min.pv.by.genesnp = FALSE,
noFDRsaveMemory = FALSE);

unlink(output_file_name_tra);
unlink(output_file_name_cis);

## Results:

cat('Analysis done in: ', me$time.in.sec, ' seconds', '\n');
cat('Detected local eQTLs:', '\n');
show(me$cis$eqtls)
cat('Detected distant eQTLs:', '\n');
show(me$trans$eqtls)

## Plot the Q-Q plot of local and distant p-values

plot(me)

因此,分析自己的数据需要准备
genotype
expression
covariates
gene location
SNP location
这五个文件,前三个需要每列的样本名对应且顺序一致。
作者也提供了生成模拟数据的代码:

# Create an artificial dataset and plot the histogram and Q-Q plot of all p-values
library('MatrixEQTL')

# Number of samples
n = 100;

# Number of variables
ngs = 2000;

# Common signal in all variables (population stratification)
pop = 0.2 * rnorm(n);

# data matrices
snps.mat = matrix(rnorm(n*ngs), ncol = ngs) + pop;
gene.mat = matrix(rnorm(n*ngs), ncol = ngs) + pop + snps.mat*((1:ngs)/ngs)^9/2;

# data objects for Matrix eQTL engine
snps1 = SlicedData$new( t( snps.mat ) );
gene1 = SlicedData$new( t( gene.mat ) );
cvrt1 = SlicedData$new( );
rm(snps.mat, gene.mat)

# Slice data in blocks of 500 variables
snps1$ResliceCombined(500);
gene1$ResliceCombined(500);

# name of temporary output file
filename = tempfile();

# Perform analysis recording information for 
# a histogram
meh = Matrix_eQTL_engine(
  snps = snps1,
  gene = gene1,
  cvrt = cvrt1,
  output_file_name = filename, 
  pvOutputThreshold = 1e-100, 
  useModel = modelLINEAR, 
  errorCovariance = numeric(), 
  verbose = TRUE,
  pvalue.hist = 100);
unlink( filename );
# png(filename = "histogram.png", width = 650, height = 650)
plot(meh, col="grey")
# dev.off();

# Perform the same analysis recording information for 
# a Q-Q plot
meq = Matrix_eQTL_engine(
  snps = snps1, 
  gene = gene1, 
  cvrt = cvrt1, 
  output_file_name = filename,
  pvOutputThreshold = 1e-6, 
  useModel = modelLINEAR, 
  errorCovariance = numeric(), 
  verbose = TRUE,
  pvalue.hist = "qqplot");
unlink( filename );
# png(filename = "QQplot.png", width = 650, height = 650)
plot(meq, pch = 16, cex = 0.7)
# dev.off();

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