Warning: file_get_contents(/data/phpspider/zhask/data//catemap/4/r/76.json): failed to open stream: No such file or directory in /data/phpspider/zhask/libs/function.php on line 167

Warning: Invalid argument supplied for foreach() in /data/phpspider/zhask/libs/tag.function.php on line 1116

Notice: Undefined index: in /data/phpspider/zhask/libs/function.php on line 180

Warning: array_chunk() expects parameter 1 to be array, null given in /data/phpspider/zhask/libs/function.php on line 181
R 基因排序微阵列_R_Bioinformatics_Bioconductor - Fatal编程技术网
Fatal编程技术网
  • r/
  • R 基因排序微阵列

R 基因排序微阵列

r

R 基因排序微阵列,r,bioinformatics,bioconductor,R,Bioinformatics,Bioconductor,我想知道是否有人熟悉Bioconductor RankProduct软件包,用于排名和获得差异表达基因。有关该软件的一些信息如下 我在使用程序时遇到了一些问题,可能是因为我对R语言知之甚少。我试图用自己的数据复制上面pdf文件中的步骤。虽然我自己的数据集不像示例中那样位于afffy.cel文件中,但仅作为制表符分隔文件中的行和列。我有两个条件(1和2,每个复制=4) 这是我的密码: library(RankProd) library(preprocessCore) #Read expressi

我想知道是否有人熟悉Bioconductor RankProduct软件包,用于排名和获得差异表达基因。有关该软件的一些信息如下

我在使用程序时遇到了一些问题,可能是因为我对R语言知之甚少。我试图用自己的数据复制上面pdf文件中的步骤。虽然我自己的数据集不像示例中那样位于afffy.cel文件中,但仅作为制表符分隔文件中的行和列。我有两个条件(1和2,每个复制=4)

这是我的密码:

library(RankProd)
library(preprocessCore)

#Read expression data
#gdata <- read.table(file="data2.txt", sep="\t", header=T) #9000 rows of genes X 8 columns of chips
gdata <- read.table(file="data2.txt", sep="\t", header=T, row.names=1) #9000 rows of genes X 8 columns of chips

#colnames(gdata)

# This vector contains the microarray sample names
SampleNames= names(data.frame(gdata[,-1]))
#names(datExpr)=gdata[,1]

# This vector contains the gene names
datExpr.gnames= gdata$GeneName

# Since the first column contains the gene names, exclude it.
# dataExp is then the matix required
datExpr=data.frame(gdata[,-1])

#convert data into matrix form
datExpr <- as.matrix(datExpr)

#data normalization - quantile normalization
#datExpr.log.norm <- normalize.quantiles((log2(datExpr)),copy=TRUE) #with logged data
datExpr <- datExpr.log.norm
#datExpr.norm <- normalize.quantiles(datExpr,copy=TRUE) #without logged data
#datExpr <- datExpr.norm


# Identify two class data - control/treatment (or condition 1/condition2)
nl <- 4
n2 <- 4
cl <- rep(c(0,1), c(nl, n2))

datExpr.cl <- cl

# data were generated under identical or very similar conditions except the
# factor of interest (e.g., control and treatment),
origin <- rep(1, nl + n2)

datExpr.origin <- origin

# Data anslysis
datExpr.sub <- datExpr[,which(datExpr.origin == 1)]
datExpr.cl.sub <- datExpr.cl[which(datExpr.origin == 1)]
datExpr.origin.sub <- datExpr.origin[which(datExpr.origin == 1)]

#Rank product analysis and output
#RP.out <- RP(datExpr.sub, datExpr.cl.sub, num.perm = 100, logged = TRUE,na.rm = FALSE,    plot = FALSE, rand = 123)

RP.out <- RPadvance(datExpr.sub, datExpr.cl.sub, datExpr.origin.sub, num.perm = 100,logged = TRUE,
                na.rm = FALSE, gene.names = datExpr.gnames, plot = FALSE,rand = 123)



# Output a table of the identified genes based on user-specified selection criteria
topGene(RP.out, cutoff = 0.05, method = "pfp", logged = TRUE,logbase = 2, gene.names = datExpr.gnames)

库(RankProd)
图书馆(核心)
#读取表达式数据

#gdata乍一看,我注意到的是


#datExpr.log.norm <- normalize.quantiles((log2(datExpr)),copy=TRUE) #with logged data
datExpr <- datExpr.log.norm



#datExpr.log.norm谢谢Csgillespie。我决定改用RankProdIt(交互式程序),这对我的需要很有用。