inst/extended_tests/extended_tests.R
In YTLogos/ensembldb: Utilities to create and use Ensembl-based annotation databases
## This script comprises extended tests.
##*****************************************************************
## Gviz stuff
notrun_test_genetrack_df <- function(){
do.plot <- FALSE
if(do.plot){
##library(Gviz)
options(ucscChromosomeNames=FALSE)
data(geneModels)
geneModels$chromosome <- 7
chr <- 7
start <- min(geneModels$start)
end <- max(geneModels$end)
myGeneModels <- getGeneRegionTrackForGviz(edb, chromosome=chr,
start=start,
end=end)
## chromosome has to be the same....
gtrack <- GenomeAxisTrack()
gvizTrack <- GeneRegionTrack(geneModels, name="Gviz")
ensdbTrack <- GeneRegionTrack(myGeneModels, name="ensdb")
plotTracks(list(gtrack, gvizTrack, ensdbTrack))
plotTracks(list(gtrack, gvizTrack, ensdbTrack), from=26700000,
to=26780000)
## Looks very nice...
}
## Put the stuff below into the vignette:
## Next we get all lincRNAs on chromosome Y
Lncs <- getGeneRegionTrackForGviz(edb,
filter=list(SeqNameFilter("Y"),
GeneBiotypeFilter("lincRNA")))
Prots <- getGeneRegionTrackForGviz(edb,
filter=list(SeqNameFilter("Y"),
GeneBiotypeFilter("protein_coding")))
if(do.plot){
plotTracks(list(gtrack, GeneRegionTrack(Lncs, name="lincRNAs"),
GeneRegionTrack(Prots, name="proteins")))
plotTracks(list(gtrack, GeneRegionTrack(Lncs, name="lincRNAs"),
GeneRegionTrack(Prots, name="proteins")),
from=5000000, to=7000000, transcriptAnnotation="symbol")
}
## is that the same than:
TestL <- getGeneRegionTrackForGviz(edb,
filter=list(GeneBiotypeFilter("lincRNA")),
chromosome="Y", start=5000000, end=7000000)
TestP <- getGeneRegionTrackForGviz(edb,
filter=list(GeneBiotypeFilter("protein_coding")),
chromosome="Y", start=5000000, end=7000000)
if(do.plot){
plotTracks(list(gtrack, GeneRegionTrack(Lncs, name="lincRNAs"),
GeneRegionTrack(Prots, name="proteins"),
GeneRegionTrack(TestL, name="compareL"),
GeneRegionTrack(TestP, name="compareP")),
from=5000000, to=7000000, transcriptAnnotation="symbol")
}
expect_true(all(TestL$exon %in% Lncs$exon))
expect_true(all(TestP$exon %in% Prots$exon))
## Crazy amazing stuff
## system.time(
## All <- getGeneRegionTrackForGviz(edb)
## )
}
notrun_test_getSeqlengthsFromMysqlFolder <- function() {
## Test this for some more seqlengths.
library(EnsDb.Rnorvegicus.v79)
db <- EnsDb.Rnorvegicus.v79
seq_info <- seqinfo(db)
seq_lengths <- ensembldb:::.getSeqlengthsFromMysqlFolder(
organism = "Rattus norvegicus", ensembl = 79,
seqnames = seqlevels(seq_info))
sl <- seqlengths(seq_info)
sl_2 <- seq_lengths$length
names(sl_2) <- rownames(seq_lengths)
checkEquals(sl, sl_2)
## Mus musculus
}
notrun_test_ensDbFromGtf_Gff_AH <- function() {
gtf <- paste0("/Users/jo/Projects/EnsDbs/80/caenorhabditis_elegans/",
"Caenorhabditis_elegans.WBcel235.80.gtf.gz")
outf <- tempfile()
db <- ensDbFromGtf(gtf = gtf, outfile = outf)
## use Gff
gff <- paste0("/Users/jo/Projects/EnsDbs/84/canis_familiaris/gff3/",
"Canis_familiaris.CanFam3.1.84.gff3.gz")
outf <- tempfile()
db <- ensDbFromGff(gff, outfile = outf)
## Checking one from ensemblgenomes:
gtf <- paste0("/Users/jo/Projects/EnsDbs/ensemblgenomes/30/",
"solanum_lycopersicum/",
"Solanum_lycopersicum.GCA_000188115.2.30.chr.gtf.gz"
)
outf <- tempfile()
db <- ensDbFromGtf(gtf = gtf, outfile = outf)
gtf <- paste0("/Users/jo/Projects/EnsDbs/ensemblgenomes/30/",
"solanum_lycopersicum/",
"Solanum_lycopersicum.GCA_000188115.2.30.gtf.gz"
)
outf <- tempfile()
db <- ensDbFromGtf(gtf = gtf, outfile = outf)
## AH
library(AnnotationHub)
ah <- AnnotationHub()
query(ah, c("release-83", "gtf"))
ah_1 <- ah["AH50418"]
db <- ensDbFromAH(ah_1, outfile = outf)
ah_2 <- ah["AH50352"]
db <- ensDbFromAH(ah_2, outfile = outf)
}
notrun_test_builds <- function(){
input <- "/Users/jo/Projects/EnsDbs/83/Homo_sapiens.GRCh38.83.gtf.gz"
fromGtf <- ensDbFromGtf(input, outfile=tempfile())
## provide wrong ensembl version
fromGtf <- ensDbFromGtf(input, outfile=tempfile(), version="75")
## provide wrong genome version
fromGtf <- ensDbFromGtf(input, outfile=tempfile(), genomeVersion="75")
EnsDb(fromGtf)
## provide wrong organism
fromGtf <- ensDbFromGtf(input, outfile=tempfile(), organism="blalba")
EnsDb(fromGtf)
## GFF
input <- "/Users/jo/Projects/EnsDbs/83/Homo_sapiens.GRCh38.83.chr.gff3.gz"
fromGff <- ensDbFromGff(input, outfile=tempfile())
EnsDb(fromGff)
fromGff <- ensDbFromGff(input, outfile=tempfile(), version="75")
EnsDb(fromGff)
fromGff <- ensDbFromGff(input, outfile=tempfile(), genomeVersion="bla")
EnsDb(fromGff)
fromGff <- ensDbFromGff(input, outfile=tempfile(), organism="blabla")
EnsDb(fromGff)
## AH
library(AnnotationHub)
ah <- AnnotationHub()
fromAh <- ensDbFromAH(ah["AH47963"], outfile=tempfile())
EnsDb(fromAH)
fromAh <- ensDbFromAH(ah["AH47963"], outfile=tempfile(), version="75")
EnsDb(fromAH)
fromAh <- ensDbFromAH(ah["AH47963"], outfile=tempfile(), genomeVersion="bla")
EnsDb(fromAH)
fromAh <- ensDbFromAH(ah["AH47963"], outfile=tempfile(), organism="blabla")
EnsDb(fromAH)
}
notrun_test_ensdbFromGFF <- function(){
library(ensembldb)
##library(rtracklayer)
## VERSION 83
gtf <- "/Users/jo/Projects/EnsDbs/83/Homo_sapiens.GRCh38.83.gtf.gz"
fromGtf <- ensDbFromGtf(gtf, outfile=tempfile())
egtf <- EnsDb(fromGtf)
gff <- "/Users/jo/Projects/EnsDbs/83/Homo_sapiens.GRCh38.83.gff3.gz"
fromGff <- ensDbFromGff(gff, outfile=tempfile())
egff <- EnsDb(fromGff)
## Compare EnsDbs
ensembldb:::compareEnsDbs(egtf, egff)
## OK, only Entrezgene ID "problems"
## Compare with the one built with the Perl API
library(EnsDb.Hsapiens.v83)
db <- EnsDb.Hsapiens.v83
ensembldb:::compareEnsDbs(egtf, edb)
ensembldb:::compareEnsDbs(egff, edb)
## OK, I get different genes...
genes1 <- genes(egtf)
genes2 <- genes(edb)
only2 <- genes2[!(genes2$gene_id %in% genes1$gene_id)]
## That below was before the fix to include feature type start_codon and stop_codon
## to the CDS type.
## Identify which are the different transcripts:
txGtf <- transcripts(egtf)
txGff <- transcripts(egff)
commonIds <- intersect(names(txGtf), names(txGff))
haveCds <- commonIds[!is.na(txGtf[commonIds]$tx_cds_seq_start) & !is.na(txGff[commonIds]$tx_cds_seq_start)]
diffs <- haveCds[txGtf[haveCds]$tx_cds_seq_start != txGff[haveCds]$tx_cds_seq_start]
head(diffs)
## What could be reasons?
## 1) alternative CDS?
## Checking the GTF:
## tx ENST00000623834: start_codon: 195409 195411.
## first CDS: 195259 195411.
## last CDS: 185220 185350.
## stop_codon: 185217 185219.
## So, why the heck is the stop codon OUTSIDE the CDS???
## library(rtracklayer)
## theGtf <- import(gtf, format="gtf")
## ## Apparently, the GTF contains the additional elements start_codon/stop_codon.
## theGff <- import(gff, format="gff3")
## transcripts(egtf, filter=TxIdFilter(diffs[1]))
## transcripts(egff, filter=TxIdFilter(diffs[1]))
## VERSION 81
## Try to get the same via AnnotationHub
gff <- "/Users/jo/Projects/EnsDbs/81/homo_sapiens/Homo_sapiens.GRCh38.81.gff3.gz"
fromGff <- ensDbFromGff(gff, outfile=tempfile())
egff <- EnsDb(fromGff)
gtf <- "/Users/jo/Projects/EnsDbs/81/homo_sapiens/Homo_sapiens.GRCh38.81.gtf.gz"
fromGtf <- ensDbFromGtf(gtf, outfile=tempfile())
egtf <- EnsDb(fromGtf)
## Compare those two:
ensembldb:::compareEnsDbs(egff, egtf)
## Why are there some differences in the transcripts???
trans1 <- transcripts(egff)
trans2 <- transcripts(egtf)
onlyInGtf <- trans2[!(trans2$tx_id %in% trans1$tx_id)]
##gtfGRanges <- ah["AH47963"]
library(AnnotationHub)
ah <- AnnotationHub()
fromAh <- ensDbFromAH(ah["AH47963"], outfile=tempfile()) ## That's human...
eah <- EnsDb(fromAh)
## Compare it to gtf:
ensembldb:::compareEnsDbs(eah, egtf)
## OK. Same cds starts and cds ends.
## Compare it to gff:
ensembldb:::compareEnsDbs(eah, egff)
## hm.
## Compare to EnsDb
library(EnsDb.Hsapiens.v81)
edb <- EnsDb.Hsapiens.v81
ensembldb:::compareEnsDbs(edb, egtf)
## Problem with CDS
ensembldb:::compareEnsDbs(edb, egff)
## That's fine.
## Summary:
## GTF and AH are the same.
## GFF and Perl API are the same.
## OLD STUFF BELOW.
##fromAh <- EnsDbFromAH(ah["AH47963"], outfile=tempfile(), organism="Homo sapiens", version=81)
## Try with a fancy species:
gff <- "/Users/jo/Projects/EnsDbs/83/gadus_morhua/Gadus_morhua.gadMor1.83.gff3.gz"
fromGtf <- ensDbFromGff(gff, outfile=tempfile())
gff <- "/Users/jo/Projects/EnsDbs/83/rattus_norvegicus/Rattus_norvegicus.Rnor_6.0.83.gff3.gz"
fromGff <- ensDbFromGff(gff, outfile=tempfile())
## That works.
## Try with a file from AnnotationHub: Gorilla gorilla.
library(AnnotationHub)
ah <- AnnotationHub()
ah <- ah["AH47962"]
res <- ensDbFromAH(ah, outfile=tempfile())
edb <- EnsDb(res)
genes(edb)
## ensRel <- query(ah, c("GTF", "ensembl"))
## gtf <- "/Users/jo/Projects/EnsDbs/83/Homo_sapiens.GRCh38.83.gtf.gz"
## ## GTF
## dir.create("/tmp/fromGtf")
## fromGtf <- ensDbFromGtf(gtf, path="/tmp/fromGtf", verbose=TRUE)
## ## GFF
## dir.create("/tmp/fromGff")
## fromGff <- ensembldb:::ensDbFromGff(gff, path="/tmp/fromGff", verbose=TRUE)
## ## ZBTB16:
## ## exon: ENSE00003606532 is 3rd exon of tx: ENST00000335953
## ## exon: ENSE00003606532 is 3rd exon of tx: ENST00000392996
## ## the Ensembl GFF has 2 entries for this exon.
}
############################################################
## Can not perform these tests right away, as they require a
## working MySQL connection.
library(EnsDb.Hsapiens.v75)
edb <- EnsDb.Hsapiens.v75
dontrun_test_useMySQL <- function() {
edb_mysql <- useMySQL(edb, user = "anonuser", host = "localhost", pass = "")
}
dontrun_test_connect_EnsDb <- function() {
library(RMySQL)
con <- dbConnect(MySQL(), user = "anonuser", host = "localhost", pass = "")
ensembldb:::listEnsDbs(dbcon = con)
## just with user.
ensembldb:::listEnsDbs(user = "anonuser", host = "localhost", pass = "",
port = 3306)
## Connecting directly to a EnsDb MySQL database.
con <- dbConnect(MySQL(), user = "anonuser", host = "localhost", pass = "",
dbname = "ensdb_hsapiens_v75")
edb_mysql <- EnsDb(con)
}
notrun_compareEnsDbs <- function() {
res <- ensembldb:::compareEnsDbs(edb, edb)
}
############################################################
## Massive test validating the cds:
## compare the length of the CDS with the length of the encoded protein.
## Get the CDS sequence, translate that and compare to protein sequence.
notrun_massive_cds_test <- function() {
## Get all CDS:
tx_cds <- cdsBy(edb, by = "tx", filter = SeqNameFilter(c(1:22, "X", "Y")))
prots <- proteins(edb, filter = TxIdFilter(names(tx_cds)),
return.type = "AAStringSet")
checkTrue(all(names(tx_cds) %in% mcols(prots)$tx_id))
tx_cds <- tx_cds[mcols(prots)$tx_id]
## Check that the length of the protein sequence is length of CDS/3
diff_width <- sum(width(tx_cds)) != width(prots) * 3
## Why??? I've got some many differences here???
sum(diff_width)
## Check some of them manually in Ensembl
## 1st: - strand.
tx_1 <- tx_cds[diff_width][1]
## Protein: 245aa
prots[diff_width][1]
## OK.
## Tx 2206bp:
exns <- exonsBy(edb, filter = TxIdFilter(names(tx_1)))
sum(width(exns))
## OK.
## Now to the CDS:
cds_ex1 <- "ATGGCGTCCCCGTCTCGGAGACTGCAGACTAAACCAGTCATTACTTGTTTCAAGAGCGTTCTGCTAATCTACACTTTTATTTTCTGG"
cds_ex2 <- "ATCACTGGCGTTATCCTTCTTGCAGTTGGCATTTGGGGCAAGGTGAGCCTGGAGAATTACTTTTCTCTTTTAAATGAGAAGGCCACCAATGTCCCCTTCGTGCTCATTGCTACTGGTACCGTCATTATTCTTTTGGGCACCTTTGGTTGTTTTGCTACCTGCCGAGCTTCTGCATGGATGCTAAAACTG"
cds_ex3 <- "TATGCAATGTTTCTGACTCTCGTTTTTTTGGTCGAACTGGTCGCTGCCATCGTAGGATTTGTTTTCAGACATGAG"
cds_ex4 <- "ATTAAGAACAGCTTTAAGAATAATTATGAGAAGGCTTTGAAGCAGTATAACTCTACAGGAGATTATAGAAGCCATGCAGTAGACAAGATCCAAAATACG"
cds_ex5 <- "TTGCATTGTTGTGGTGTCACCGATTATAGAGATTGGACAGATACTAATTATTACTCAGAAAAAGGATTTCCTAAGAGTTGCTGTAAACTTGAAGATTGTACTCCACAGAGAGATGCAGACAAAGTAAACAATGAA"
cds_ex6 <- "GGTTGTTTTATAAAGGTGATGACCATTATAGAGTCAGAAATGGGAGTCGTTGCAGGAATTTCCTTTGGAGTTGCTTGCTTCCAA"
cds_ex7 <- "CTGATTGGAATCTTTCTCGCCTACTGCCTCTCTCGTGCCATAACAAATAACCAGTATGAGATAGTGTAA"
cds_seq <- c(cds_ex1, cds_ex2, cds_ex3, cds_ex4, cds_ex5, cds_ex6, cds_ex7)
nchar(cds_seq)
width(tx_1)
## The length should be identical:
checkEquals(sum(nchar(cds_seq)), sum(width(tx_1)), checkNames = FALSE)
## OK; so WHAT???
sum(width(tx_1)) / 3
## So, start codon is encoded into a methionine.
## Stop codon is either a TAA, TGA or TAG. UAG can be encoded into Sec (U), UAG into Pyl (O)
library(Biostrings)
dna_s <- DNAString(paste0(cds_ex1, cds_ex2, cds_ex3, cds_ex4, cds_ex5, cds_ex6, cds_ex7))
translate(dna_s)
## Look at that!
translate(DNAString("TAA")) ## -> translates into *
translate(DNAString("TGA")) ## -> translates into *
translate(DNAString("TAG")) ## -> translates into *
translate(DNAString("ATG")) ## -> translates into M
## Assumption:
## If the mRNA ends with a TAA, the protein sequence will be 1aa shorter than
## length(CDS)/3.
## If the mRNA ends with a TAG, UAG the AA length is length(CDS)/3
## Check one of the mRNA where it fits:
tx_2 <- tx_cds[!diff_width][1]
prots[!diff_width][1]
## AA is 137 long, ends with I.
sum(width(tx_2)) / 3 ## OK
## Check Ensembl:
tx_2_1 <- "ATGCTAAAACTG"
tx_2_2 <- "TATGCAATGTTTCTGACTCTCGTTTTTTTGGTCGAACTGGTCGCTGCCATCGTAGGATTTGTTTTCAGACATGAG"
tx_2_3 <- "ATTAAGAACAGCTTTAAGAATAATTATGAGAAGGCTTTGAAGCAGTATAACTCTACAGGAGATTATAGAAGCCATGCAGTAGACAAGATCCAAAATACG"
tx_2_4 <- "TTGCATTGTTGTGGTGTCACCGATTATAGAGATTGGACAGATACTAATTATTACTCAGAAAAAGGATTTCCTAAGAGTTGCTGTAAACTTGAAGATTGTACTCCACAGAGAGATGCAGACAAAGTAAACAATGAA"
tx_2_5 <- "GGTTGTTTTATAAAGGTGATGACCATTATAGAGTCAGAAATGGGAGTCGTTGCAGGAATTTCCTTTGGAGTTGCTTGCTTCCAA"
tx_2_6 <- "GACATT"
tx_2_cds <- paste0(tx_2_1, tx_2_2, tx_2_3, tx_2_4, tx_2_5, tx_2_6)
nchar(tx_2_cds)
sum(width(tx_2))
## OK.
translate(DNAString(tx_2_cds))
## Next assumption:
## If we don't have a 3' UTR the AA sequence corresponds to length(CDS)/3
tx_cds <- cdsBy(edb, by = "tx", filter = SeqNameFilter(c(1:22, "X", "Y")),
columns = c("tx_seq_start", "tx_seq_end", "tx_cds_seq_start",
"tx_cds_seq_end"))
prots <- proteins(edb, filter = TxIdFilter(names(tx_cds)),
return.type = "AAStringSet")
checkTrue(all(names(tx_cds) %in% mcols(prots)$tx_id))
tx_cds <- tx_cds[mcols(prots)$tx_id]
## Calculate the CDS width.
tx_cds_width <- sum(width(tx_cds))
txs <- transcripts(edb, filter = TxIdFilter(names(tx_cds)))
txs <- txs[names(tx_cds)]
## Subtract 3 from the width if we've got an 3'UTR.
to_subtract <- rep(3, length(tx_cds_width))
to_subtract[((end(txs) == txs$tx_cds_seq_end) &
as.logical(strand(txs) == "+"))
| ((start(txs) == txs$tx_cds_seq_start)
& as.logical(strand(txs) == "-"))] <- 0
tx_cds_width <- tx_cds_width - to_subtract
## Check that the length of the protein sequence is length of CDS/3
diff_width <- tx_cds_width != width(prots) * 3
## Why??? I've got some many differences here???
sum(diff_width)
length(diff_width)
## AAAA, still have some that don't fit!!!
tx_3 <- tx_cds[diff_width][1]
prots[diff_width][1]
## AA is 259aa long, ends with T., TX is: ENST00000371584
## WTF, we've got no START CODON!!!
sum(width(tx_3)) / 3 ## OMG!!!
## Now, exclude those without a 5' UTR:
no_five <- ((start(txs) == txs$tx_cds_seq_start) &
as.logical(strand(txs) == "+")) |
((end(txs) == txs$tx_cds_seq_end) &
as.logical(strand(txs) == "-"))
still_prot <- (diff_width & !no_five)
}
notrun_test_getGenomeFaFile <- function(){
library(EnsDb.Hsapiens.v82)
edb <- EnsDb.Hsapiens.v82
## We know that there is no Fasta file for that Ensembl release available.
Fa <- getGenomeFaFile(edb)
## Got the one from Ensembl 81.
genes <- genes(edb, filter=SeqNameFilter("Y"))
geneSeqsFa <- getSeq(Fa, genes)
## Get the transcript sequences...
txSeqsFa <- extractTranscriptSeqs(Fa, edb, filter=SeqNameFilter("Y"))
## Get the TwoBitFile.
twob <- ensembldb:::getGenomeTwoBitFile(edb)
## Get thegene sequences.
## ERROR FIX BELOW WITH UPDATED VERSIONS!!!
geneSeqs2b <- getSeq(twob, genes)
## Have to fix the seqnames.
si <- seqinfo(twob)
sn <- unlist(lapply(strsplit(seqnames(si), split=" ", fixed=TRUE), function(z){
return(z[1])
}))
seqnames(si) <- sn
seqinfo(twob) <- si
## Do the same with the TwoBitFile
geneSeqsTB <- getSeq(twob, genes)
## Subset to all genes that are encoded on chromosomes for which
## we do have DNA sequence available.
genes <- genes[seqnames(genes) %in% seqnames(seqinfo(Dna))]
## Get the gene sequences, i.e. the sequence including the sequence of
## all of the gene's exons and introns.
geneSeqs <- getSeq(Dna, genes)
library(AnnotationHub)
ah <- AnnotationHub()
quer <- query(ah, c("release-", "Homo sapiens"))
## So, I get 2bit files and toplevel stuff.
Test <- ah[["AH50068"]]
}
notrun_test_extractTranscriptSeqs <- function(){
## Note: we can't run that by default as we can not assume everybody has
## AnnotationHub and the required ressource installed.
## That's how we want to test the transcript seqs.
genome <- getGenomeFaFile(edb)
ZBTB <- extractTranscriptSeqs(genome, edb, filter=GenenameFilter("ZBTB16"))
## Load the sequences for one ZBTB16 transcript from FA.
faf <- system.file("txt/ENST00000335953.fa.gz", package="ensembldb")
Seqs <- readDNAStringSet(faf)
tx <- "ENST00000335953"
## cDNA
checkEquals(unname(as.character(ZBTB[tx])),
unname(as.character(Seqs[grep(names(Seqs), pattern="cdna")])))
## CDS
cBy <- cdsBy(edb, "tx", filter=TxIdFilter(tx))
CDS <- extractTranscriptSeqs(genome, cBy)
checkEquals(unname(as.character(CDS)),
unname(as.character(Seqs[grep(names(Seqs), pattern="cds")])))
## 5' UTR
fBy <- fiveUTRsByTranscript(edb, filter=TxIdFilter(tx))
UTR <- extractTranscriptSeqs(genome, fBy)
checkEquals(unname(as.character(UTR)),
unname(as.character(Seqs[grep(names(Seqs), pattern="utr5")])))
## 3' UTR
tBy <- threeUTRsByTranscript(edb, filter=TxIdFilter(tx))
UTR <- extractTranscriptSeqs(genome, tBy)
checkEquals(unname(as.character(UTR)),
unname(as.character(Seqs[grep(names(Seqs), pattern="utr3")])))
## Another gene on the reverse strand:
faf <- system.file("txt/ENST00000200135.fa.gz", package="ensembldb")
Seqs <- readDNAStringSet(faf)
tx <- "ENST00000200135"
## cDNA
cDNA <- extractTranscriptSeqs(genome, edb, filter=TxIdFilter(tx))
checkEquals(unname(as.character(cDNA)),
unname(as.character(Seqs[grep(names(Seqs), pattern="cdna")])))
## do the same, but from other strand
exns <- exonsBy(edb, "tx", filter=TxIdFilter(tx))
cDNA <- extractTranscriptSeqs(genome, exns)
checkEquals(unname(as.character(cDNA)),
unname(as.character(Seqs[grep(names(Seqs), pattern="cdna")])))
strand(exns) <- "+"
cDNA <- extractTranscriptSeqs(genome, exns)
checkTrue(unname(as.character(cDNA)) !=
unname(as.character(Seqs[grep(names(Seqs), pattern="cdna")])))
## CDS
cBy <- cdsBy(edb, "tx", filter=TxIdFilter(tx))
CDS <- extractTranscriptSeqs(genome, cBy)
checkEquals(unname(as.character(CDS)),
unname(as.character(Seqs[grep(names(Seqs), pattern="cds")])))
## 5' UTR
fBy <- fiveUTRsByTranscript(edb, filter=TxIdFilter(tx))
UTR <- extractTranscriptSeqs(genome, fBy)
checkEquals(unname(as.character(UTR)),
unname(as.character(Seqs[grep(names(Seqs), pattern="utr5")])))
## 3' UTR
tBy <- threeUTRsByTranscript(edb, filter=TxIdFilter(tx))
UTR <- extractTranscriptSeqs(genome, tBy)
checkEquals(unname(as.character(UTR)),
unname(as.character(Seqs[grep(names(Seqs), pattern="utr3")])))
}
notrun_test_getCdsSequence <- function(){
## That's when we like to get the sequence from the coding region.
genome <- getGenomeFaFile(edb)
tx <- extractTranscriptSeqs(genome, edb, filter=SeqNameFilter("Y"))
cdsSeq <- extractTranscriptSeqs(genome, cdsBy(edb, filter=SeqNameFilter("Y")))
## that's basically to get the CDS sequence.
## UTR sequence:
tutr <- extractTranscriptSeqs(genome, threeUTRsByTranscript(edb, filter=SeqNameFilter("Y")))
futr <- extractTranscriptSeqs(genome, fiveUTRsByTranscript(edb, filter=SeqNameFilter("Y")))
theTx <- "ENST00000602770"
fullSeq <- as.character(tx[theTx])
## build the one from 5', cds and 3'
compSeq <- ""
if(any(names(futr) == theTx))
compSeq <- paste0(compSeq, as.character(futr[theTx]))
if(any(names(cdsSeq) == theTx))
compSeq <- paste0(compSeq, as.character(cdsSeq[theTx]))
if(any(names(tutr) == theTx))
compSeq <- paste(compSeq, as.character(tutr[theTx]))
checkEquals(unname(fullSeq), compSeq)
}
notrun_test_cds <- function(){
library(TxDb.Hsapiens.UCSC.hg19.knownGene)
txdb <- TxDb.Hsapiens.UCSC.hg19.knownGene
cds <- cds(txdb)
cby <- cdsBy(txdb, by="tx")
gr <- cby[[7]][1]
seqlevels(gr) <- sub(seqlevels(gr), pattern="chr", replacement="")
tx <- transcripts(edb, filter=GRangesFilter(gr, condition="overlapping"))
cby[[7]]
## Note: so that fits! And we've to include the stop_codon feature for GTF import!
## Make an TxDb from GTF:
gtf <- "/Users/jo/Projects/EnsDbs/75/homo_sapiens/Homo_sapiens.GRCh37.75.gtf.gz"
library(GenomicFeatures)
Test <- makeTxDbFromGFF(gtf, format="gtf", organism="Homo sapiens")
scds <- cdsBy(Test, by="tx")
gr <- scds[[7]][1]
tx <- transcripts(edb, filter=GRangesFilter(gr, condition="overlapping"))
scds[[7]]
## Compare:
## TxDb form GTF has: 865692 879533
## EnsDb: 865692 879533
## Next test:
gr <- scds[[2]][1]
tx <- transcripts(edb, filter=GRangesFilter(gr, condition="overlapping"))
tx
scds[[2]]
## start_codon: 367659 367661, stop_codon: 368595 368597 CDS: 367659 368594.
## TxDb from GTF includes the stop_codon!
}
dontrun_benchmark_ordering_genes <- function() {
.withR <- function(x, ...) {
ensembldb:::orderResultsInR(x) <- TRUE
genes(x, ...)
}
.withSQL <- function(x, ...) {
ensembldb:::orderResultsInR(x) <- FALSE
genes(x, ...)
}
library(microbenchmark)
microbenchmark(.withR(edb), .withSQL(edb), times = 10) ## same
microbenchmark(.withR(edb, columns = c("gene_id", "tx_id")),
.withSQL(edb, columns = c("gene_id", "tx_id")),
times = 10) ## R slightly faster.
microbenchmark(.withR(edb, columns = c("gene_id", "tx_id"),
SeqNameFilter("Y")),
.withSQL(edb, columns = c("gene_id", "tx_id"),
SeqNameFilter("Y")),
times = 10) ## same.
}
## We aim to fix issue #11 by performing the ordering in R instead
## of SQL. Thus, we don't want to run this as a "regular" test
## case.
dontrun_test_ordering_cdsBy <- function() {
doBench <- FALSE
if (doBench)
library(microbenchmark)
.withR <- function(x, ...) {
ensembldb:::orderResultsInR(x) <- TRUE
cdsBy(x, ...)
}
.withSQL <- function(x, ...) {
ensembldb:::orderResultsInR(x) <- FALSE
cdsBy(x, ...)
}
res_sql <- .withSQL(edb)
res_r <- .withR(edb)
checkEquals(res_sql, res_r)
if (dobench)
microbenchmark(.withSQL(edb), .withR(edb),
times = 3) ## R slightly faster.
res_sql <- .withSQL(edb, filter = SeqNameFilter("Y"))
res_r <- .withR(edb, filter = SeqNameFilter("Y"))
checkEquals(res_sql, res_r)
if (dobench)
microbenchmark(.withSQL(edb, filter = SeqNameFilter("Y")),
.withR(edb, filter = SeqNameFilter("Y")),
times = 10) ## R 6x faster.
}
dontrun_test_ordering_exonsBy <- function() {
doBench <- FALSE
if (doBench)
library(microbenchmark)
.withR <- function(x, ...) {
ensembldb:::orderResultsInR(x) <- TRUE
exonsBy(x, ...)
}
.withSQL <- function(x, ...) {
ensembldb:::orderResultsInR(x) <- FALSE
exonsBy(x, ...)
}
res_sql <- .withSQL(edb)
res_r <- .withR(edb)
checkEquals(res_sql, res_r)
if (doBench)
microbenchmark(.withSQL(edb), .withR(edb),
times = 3) ## about the same; R slightly faster.
## with using a SeqNameFilter in addition.
res_sql <- .withSQL(edb, filter = SeqNameFilter("Y"))
res_r <- .withR(edb, filter = SeqNameFilter("Y")) ## query takes longer.
checkEquals(res_sql, res_r)
if (doBench)
microbenchmark(.withSQL(edb, filter = SeqNameFilter("Y")),
.withR(edb, filter = SeqNameFilter("Y")),
times = 3) ## SQL twice as fast.
## Now getting stuff by gene
res_sql <- .withSQL(edb, by = "gene")
res_r <- .withR(edb, by = "gene")
## checkEquals(res_sql, res_r) ## Differences due to ties
if (doBench)
microbenchmark(.withSQL(edb, by = "gene"),
.withR(edb, by = "gene"),
times = 3) ## SQL faster; ???
## Along with a SeqNameFilter
res_sql <- .withSQL(edb, by = "gene", filter = SeqNameFilter("Y"))
res_r <- .withR(edb, by = "gene", filter = SeqNameFilter("Y"))
## Why does the query take longer for R???
## checkEquals(res_sql, res_r) ## Differences due to ties
if (doBench)
microbenchmark(.withSQL(edb, by = "gene", filter = SeqNameFilter("Y")),
.withR(edb, by = "gene", filter = SeqNameFilter("Y")),
times = 3) ## SQL faster.
## Along with a GeneBiotypeFilter
if (doBench)
microbenchmark(.withSQL(edb, by = "gene", filter = GeneBiotypeFilter("protein_coding"))
, .withR(edb, by = "gene", filter = GeneBiotypeFilter("protein_coding"))
, times = 3)
}
dontrun_test_ordering_transcriptsBy <- function() {
.withR <- function(x, ...) {
ensembldb:::orderResultsInR(x) <- TRUE
transcriptsBy(x, ...)
}
.withSQL <- function(x, ...) {
ensembldb:::orderResultsInR(x) <- FALSE
transcriptsBy(x, ...)
}
res_sql <- .withSQL(edb)
res_r <- .withR(edb)
checkEquals(res_sql, res_r)
microbenchmark(.withSQL(edb), .withR(edb), times = 3) ## same speed
res_sql <- .withSQL(edb, filter = SeqNameFilter("Y"))
res_r <- .withR(edb, filter = SeqNameFilter("Y"))
checkEquals(res_sql, res_r)
microbenchmark(.withSQL(edb, filter = SeqNameFilter("Y")),
.withR(edb, filter = SeqNameFilter("Y")),
times = 3) ## SQL slighly faster.
}
dontrun_query_tune <- function() {
## Query tuning:
library(RSQLite)
con <- dbconn(edb)
Q <- "select distinct tx2exon.exon_id,exon.exon_seq_start,exon.exon_seq_end,gene.seq_name,tx2exon.tx_id,gene.seq_strand,tx2exon.exon_idx from gene join tx on (gene.gene_id=tx.gene_id) join tx2exon on (tx.tx_id=tx2exon.tx_id) join exon on (tx2exon.exon_id=exon.exon_id) where gene.seq_name = 'Y'"
system.time(dbGetQuery(con, Q))
Q2 <- "select distinct tx2exon.exon_id,exon.exon_seq_start,exon.exon_seq_end,gene.seq_name,tx2exon.tx_id,gene.seq_strand,tx2exon.exon_idx from exon join tx2exon on (tx2exon.exon_id = exon.exon_id) join tx on (tx2exon.tx_id = tx.tx_id) join gene on (gene.gene_id=tx.gene_id) where gene.seq_name = 'Y'"
system.time(dbGetQuery(con, Q2))
Q3 <- "select distinct tx2exon.exon_id,exon.exon_seq_start,exon.exon_seq_end,gene.seq_name,tx2exon.tx_id,gene.seq_strand,tx2exon.exon_idx from tx2exon join exon on (tx2exon.exon_id = exon.exon_id) join tx on (tx2exon.tx_id = tx.tx_id) join gene on (gene.gene_id=tx.gene_id) where gene.seq_name = 'Y'"
system.time(dbGetQuery(con, Q3))
Q4 <- "select distinct tx2exon.exon_id,exon.exon_seq_start,exon.exon_seq_end,gene.seq_name,tx2exon.tx_id,gene.seq_strand,tx2exon.exon_idx from tx2exon join exon on (tx2exon.exon_id = exon.exon_id) join tx on (tx2exon.tx_id = tx.tx_id) join gene on (gene.gene_id=tx.gene_id) where gene.seq_name = 'Y' order by tx.tx_id"
system.time(dbGetQuery(con, Q4))
Q5 <- "select distinct tx2exon.exon_id,exon.exon_seq_start,exon.exon_seq_end,gene.seq_name,tx2exon.tx_id,gene.seq_strand,tx2exon.exon_idx from tx2exon inner join exon on (tx2exon.exon_id = exon.exon_id) inner join tx on (tx2exon.tx_id = tx.tx_id) inner join gene on (gene.gene_id=tx.gene_id) where gene.seq_name = 'Y' order by tx.tx_id"
system.time(dbGetQuery(con, Q5))
Q6 <- "select distinct tx2exon.exon_id,exon.exon_seq_start,exon.exon_seq_end,gene.seq_name,tx2exon.tx_id,gene.seq_strand,tx2exon.exon_idx from gene inner join tx on (gene.gene_id=tx.gene_id) inner join tx2exon on (tx.tx_id=tx2exon.tx_id) inner join exon on (tx2exon.exon_id=exon.exon_id) where gene.seq_name = 'Y' order by tx.tx_id asc"
system.time(dbGetQuery(con, Q6))
}
## implement:
## .checkOrderBy: checks order.by argument removing columns that are
## not present in the database
## orderBy columns are added to the columns.
## .orderDataFrameBy: orders the dataframe by the specified columns.
notrun_test_protein_domains <- function() {
res <- ensembldb:::getWhat(edb, columns = c("protein_id", "tx_id", "gene_id",
"gene_name"),
filter = list(ProtDomIdFilter("PF00096")))
}
notrun_compare_full <- function(){
## That's on the full thing.
## Test if the result has the same ordering than the transcripts call.
allTx <- transcripts(edb)
txLen <- transcriptLengths(edb, with.cds_len=TRUE, with.utr5_len=TRUE,
with.utr3_len=TRUE)
checkEquals(names(allTx), rownames(txLen))
system.time(
futr <- fiveUTRsByTranscript(edb)
)
## 23 secs.
futrLen <- sum(width(futr)) ## do I need reduce???
checkEquals(unname(futrLen), txLen[names(futrLen), "utr5_len"])
## 3'
system.time(
tutr <- threeUTRsByTranscript(edb)
)
system.time(
tutrLen <- sum(width(tutr))
)
checkEquals(unname(tutrLen), txLen[names(tutrLen), "utr3_len"])
}
notrun_compare_to_genfeat <- function(){
library(TxDb.Hsapiens.UCSC.hg19.knownGene)
txdb <- TxDb.Hsapiens.UCSC.hg19.knownGene
system.time(
Len <- transcriptLengths(edb)
)
## Woa, 52 sec
system.time(
txLen <- lengthOf(edb, "tx")
)
## Faster, 31 sec
checkEquals(Len$tx_len, unname(txLen[rownames(Len)]))
system.time(
Len2 <- transcriptLengths(txdb)
)
## :) 2.5 sec.
## Next.
system.time(
Len <- transcriptLengths(edb, with.cds_len = TRUE)
)
## 56 sec
system.time(
Len2 <- transcriptLengths(txdb, with.cds_len=TRUE)
)
## 4 sec.
## Calling the transcriptLengths of GenomicFeatures on the EnsDb.
system.time(
Def <- GenomicFeatures::transcriptLengths(edb)
) ## 26.5 sec
system.time(
WithCds <- GenomicFeatures::transcriptLengths(edb, with.cds_len=TRUE)
) ## 55 sec
system.time(
WithAll <- GenomicFeatures::transcriptLengths(edb, with.cds_len=TRUE,
with.utr5_len=TRUE,
with.utr3_len=TRUE)
) ## 99 secs
## Get my versions...
system.time(
MyDef <- ensembldb:::.transcriptLengths(edb)
) ## 31 sec
system.time(
MyWithCds <- ensembldb:::.transcriptLengths(edb, with.cds_len=TRUE)
) ## 44 sec
system.time(
MyWithAll <- ensembldb:::.transcriptLengths(edb, with.cds_len=TRUE,
with.utr5_len=TRUE,
with.utr3_len=TRUE)
) ## 63 sec
## Should be all the same!!!
rownames(MyDef) <- NULL
checkEquals(Def, MyDef)
##
rownames(MyWithCds) <- NULL
MyWithCds[is.na(MyWithCds$cds_len), "cds_len"] <- 0
checkEquals(WithCds, MyWithCds)
##
rownames(MyWithAll) <- NULL
MyWithAll[is.na(MyWithAll$cds_len), "cds_len"] <- 0
MyWithAll[is.na(MyWithAll$utr3_len), "utr3_len"] <- 0
MyWithAll[is.na(MyWithAll$utr5_len), "utr5_len"] <- 0
checkEquals(WithAll, MyWithAll)
}
YTLogos/ensembldb documentation built on May 3, 2019, 9:03 p.m.
R Package Documentation
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Note that we can't provide technical support on individual packages. You should contact the package authors for that.
## This script comprises extended tests.
##*****************************************************************
## Gviz stuff
notrun_test_genetrack_df <- function(){
do.plot <- FALSE
if(do.plot){
##library(Gviz)
options(ucscChromosomeNames=FALSE)
data(geneModels)
geneModels$chromosome <- 7
chr <- 7
start <- min(geneModels$start)
end <- max(geneModels$end)
myGeneModels <- getGeneRegionTrackForGviz(edb, chromosome=chr,
start=start,
end=end)
## chromosome has to be the same....
gtrack <- GenomeAxisTrack()
gvizTrack <- GeneRegionTrack(geneModels, name="Gviz")
ensdbTrack <- GeneRegionTrack(myGeneModels, name="ensdb")
plotTracks(list(gtrack, gvizTrack, ensdbTrack))
plotTracks(list(gtrack, gvizTrack, ensdbTrack), from=26700000,
to=26780000)
## Looks very nice...
}
## Put the stuff below into the vignette:
## Next we get all lincRNAs on chromosome Y
Lncs <- getGeneRegionTrackForGviz(edb,
filter=list(SeqNameFilter("Y"),
GeneBiotypeFilter("lincRNA")))
Prots <- getGeneRegionTrackForGviz(edb,
filter=list(SeqNameFilter("Y"),
GeneBiotypeFilter("protein_coding")))
if(do.plot){
plotTracks(list(gtrack, GeneRegionTrack(Lncs, name="lincRNAs"),
GeneRegionTrack(Prots, name="proteins")))
plotTracks(list(gtrack, GeneRegionTrack(Lncs, name="lincRNAs"),
GeneRegionTrack(Prots, name="proteins")),
from=5000000, to=7000000, transcriptAnnotation="symbol")
}
## is that the same than:
TestL <- getGeneRegionTrackForGviz(edb,
filter=list(GeneBiotypeFilter("lincRNA")),
chromosome="Y", start=5000000, end=7000000)
TestP <- getGeneRegionTrackForGviz(edb,
filter=list(GeneBiotypeFilter("protein_coding")),
chromosome="Y", start=5000000, end=7000000)
if(do.plot){
plotTracks(list(gtrack, GeneRegionTrack(Lncs, name="lincRNAs"),
GeneRegionTrack(Prots, name="proteins"),
GeneRegionTrack(TestL, name="compareL"),
GeneRegionTrack(TestP, name="compareP")),
from=5000000, to=7000000, transcriptAnnotation="symbol")
}
expect_true(all(TestL$exon %in% Lncs$exon))
expect_true(all(TestP$exon %in% Prots$exon))
## Crazy amazing stuff
## system.time(
## All <- getGeneRegionTrackForGviz(edb)
## )
}
notrun_test_getSeqlengthsFromMysqlFolder <- function() {
## Test this for some more seqlengths.
library(EnsDb.Rnorvegicus.v79)
db <- EnsDb.Rnorvegicus.v79
seq_info <- seqinfo(db)
seq_lengths <- ensembldb:::.getSeqlengthsFromMysqlFolder(
organism = "Rattus norvegicus", ensembl = 79,
seqnames = seqlevels(seq_info))
sl <- seqlengths(seq_info)
sl_2 <- seq_lengths$length
names(sl_2) <- rownames(seq_lengths)
checkEquals(sl, sl_2)
## Mus musculus
}
notrun_test_ensDbFromGtf_Gff_AH <- function() {
gtf <- paste0("/Users/jo/Projects/EnsDbs/80/caenorhabditis_elegans/",
"Caenorhabditis_elegans.WBcel235.80.gtf.gz")
outf <- tempfile()
db <- ensDbFromGtf(gtf = gtf, outfile = outf)
## use Gff
gff <- paste0("/Users/jo/Projects/EnsDbs/84/canis_familiaris/gff3/",
"Canis_familiaris.CanFam3.1.84.gff3.gz")
outf <- tempfile()
db <- ensDbFromGff(gff, outfile = outf)
## Checking one from ensemblgenomes:
gtf <- paste0("/Users/jo/Projects/EnsDbs/ensemblgenomes/30/",
"solanum_lycopersicum/",
"Solanum_lycopersicum.GCA_000188115.2.30.chr.gtf.gz"
)
outf <- tempfile()
db <- ensDbFromGtf(gtf = gtf, outfile = outf)
gtf <- paste0("/Users/jo/Projects/EnsDbs/ensemblgenomes/30/",
"solanum_lycopersicum/",
"Solanum_lycopersicum.GCA_000188115.2.30.gtf.gz"
)
outf <- tempfile()
db <- ensDbFromGtf(gtf = gtf, outfile = outf)
## AH
library(AnnotationHub)
ah <- AnnotationHub()
query(ah, c("release-83", "gtf"))
ah_1 <- ah["AH50418"]
db <- ensDbFromAH(ah_1, outfile = outf)
ah_2 <- ah["AH50352"]
db <- ensDbFromAH(ah_2, outfile = outf)
}
notrun_test_builds <- function(){
input <- "/Users/jo/Projects/EnsDbs/83/Homo_sapiens.GRCh38.83.gtf.gz"
fromGtf <- ensDbFromGtf(input, outfile=tempfile())
## provide wrong ensembl version
fromGtf <- ensDbFromGtf(input, outfile=tempfile(), version="75")
## provide wrong genome version
fromGtf <- ensDbFromGtf(input, outfile=tempfile(), genomeVersion="75")
EnsDb(fromGtf)
## provide wrong organism
fromGtf <- ensDbFromGtf(input, outfile=tempfile(), organism="blalba")
EnsDb(fromGtf)
## GFF
input <- "/Users/jo/Projects/EnsDbs/83/Homo_sapiens.GRCh38.83.chr.gff3.gz"
fromGff <- ensDbFromGff(input, outfile=tempfile())
EnsDb(fromGff)
fromGff <- ensDbFromGff(input, outfile=tempfile(), version="75")
EnsDb(fromGff)
fromGff <- ensDbFromGff(input, outfile=tempfile(), genomeVersion="bla")
EnsDb(fromGff)
fromGff <- ensDbFromGff(input, outfile=tempfile(), organism="blabla")
EnsDb(fromGff)
## AH
library(AnnotationHub)
ah <- AnnotationHub()
fromAh <- ensDbFromAH(ah["AH47963"], outfile=tempfile())
EnsDb(fromAH)
fromAh <- ensDbFromAH(ah["AH47963"], outfile=tempfile(), version="75")
EnsDb(fromAH)
fromAh <- ensDbFromAH(ah["AH47963"], outfile=tempfile(), genomeVersion="bla")
EnsDb(fromAH)
fromAh <- ensDbFromAH(ah["AH47963"], outfile=tempfile(), organism="blabla")
EnsDb(fromAH)
}
notrun_test_ensdbFromGFF <- function(){
library(ensembldb)
##library(rtracklayer)
## VERSION 83
gtf <- "/Users/jo/Projects/EnsDbs/83/Homo_sapiens.GRCh38.83.gtf.gz"
fromGtf <- ensDbFromGtf(gtf, outfile=tempfile())
egtf <- EnsDb(fromGtf)
gff <- "/Users/jo/Projects/EnsDbs/83/Homo_sapiens.GRCh38.83.gff3.gz"
fromGff <- ensDbFromGff(gff, outfile=tempfile())
egff <- EnsDb(fromGff)
## Compare EnsDbs
ensembldb:::compareEnsDbs(egtf, egff)
## OK, only Entrezgene ID "problems"
## Compare with the one built with the Perl API
library(EnsDb.Hsapiens.v83)
db <- EnsDb.Hsapiens.v83
ensembldb:::compareEnsDbs(egtf, edb)
ensembldb:::compareEnsDbs(egff, edb)
## OK, I get different genes...
genes1 <- genes(egtf)
genes2 <- genes(edb)
only2 <- genes2[!(genes2$gene_id %in% genes1$gene_id)]
## That below was before the fix to include feature type start_codon and stop_codon
## to the CDS type.
## Identify which are the different transcripts:
txGtf <- transcripts(egtf)
txGff <- transcripts(egff)
commonIds <- intersect(names(txGtf), names(txGff))
haveCds <- commonIds[!is.na(txGtf[commonIds]$tx_cds_seq_start) & !is.na(txGff[commonIds]$tx_cds_seq_start)]
diffs <- haveCds[txGtf[haveCds]$tx_cds_seq_start != txGff[haveCds]$tx_cds_seq_start]
head(diffs)
## What could be reasons?
## 1) alternative CDS?
## Checking the GTF:
## tx ENST00000623834: start_codon: 195409 195411.
## first CDS: 195259 195411.
## last CDS: 185220 185350.
## stop_codon: 185217 185219.
## So, why the heck is the stop codon OUTSIDE the CDS???
## library(rtracklayer)
## theGtf <- import(gtf, format="gtf")
## ## Apparently, the GTF contains the additional elements start_codon/stop_codon.
## theGff <- import(gff, format="gff3")
## transcripts(egtf, filter=TxIdFilter(diffs[1]))
## transcripts(egff, filter=TxIdFilter(diffs[1]))
## VERSION 81
## Try to get the same via AnnotationHub
gff <- "/Users/jo/Projects/EnsDbs/81/homo_sapiens/Homo_sapiens.GRCh38.81.gff3.gz"
fromGff <- ensDbFromGff(gff, outfile=tempfile())
egff <- EnsDb(fromGff)
gtf <- "/Users/jo/Projects/EnsDbs/81/homo_sapiens/Homo_sapiens.GRCh38.81.gtf.gz"
fromGtf <- ensDbFromGtf(gtf, outfile=tempfile())
egtf <- EnsDb(fromGtf)
## Compare those two:
ensembldb:::compareEnsDbs(egff, egtf)
## Why are there some differences in the transcripts???
trans1 <- transcripts(egff)
trans2 <- transcripts(egtf)
onlyInGtf <- trans2[!(trans2$tx_id %in% trans1$tx_id)]
##gtfGRanges <- ah["AH47963"]
library(AnnotationHub)
ah <- AnnotationHub()
fromAh <- ensDbFromAH(ah["AH47963"], outfile=tempfile()) ## That's human...
eah <- EnsDb(fromAh)
## Compare it to gtf:
ensembldb:::compareEnsDbs(eah, egtf)
## OK. Same cds starts and cds ends.
## Compare it to gff:
ensembldb:::compareEnsDbs(eah, egff)
## hm.
## Compare to EnsDb
library(EnsDb.Hsapiens.v81)
edb <- EnsDb.Hsapiens.v81
ensembldb:::compareEnsDbs(edb, egtf)
## Problem with CDS
ensembldb:::compareEnsDbs(edb, egff)
## That's fine.
## Summary:
## GTF and AH are the same.
## GFF and Perl API are the same.
## OLD STUFF BELOW.
##fromAh <- EnsDbFromAH(ah["AH47963"], outfile=tempfile(), organism="Homo sapiens", version=81)
## Try with a fancy species:
gff <- "/Users/jo/Projects/EnsDbs/83/gadus_morhua/Gadus_morhua.gadMor1.83.gff3.gz"
fromGtf <- ensDbFromGff(gff, outfile=tempfile())
gff <- "/Users/jo/Projects/EnsDbs/83/rattus_norvegicus/Rattus_norvegicus.Rnor_6.0.83.gff3.gz"
fromGff <- ensDbFromGff(gff, outfile=tempfile())
## That works.
## Try with a file from AnnotationHub: Gorilla gorilla.
library(AnnotationHub)
ah <- AnnotationHub()
ah <- ah["AH47962"]
res <- ensDbFromAH(ah, outfile=tempfile())
edb <- EnsDb(res)
genes(edb)
## ensRel <- query(ah, c("GTF", "ensembl"))
## gtf <- "/Users/jo/Projects/EnsDbs/83/Homo_sapiens.GRCh38.83.gtf.gz"
## ## GTF
## dir.create("/tmp/fromGtf")
## fromGtf <- ensDbFromGtf(gtf, path="/tmp/fromGtf", verbose=TRUE)
## ## GFF
## dir.create("/tmp/fromGff")
## fromGff <- ensembldb:::ensDbFromGff(gff, path="/tmp/fromGff", verbose=TRUE)
## ## ZBTB16:
## ## exon: ENSE00003606532 is 3rd exon of tx: ENST00000335953
## ## exon: ENSE00003606532 is 3rd exon of tx: ENST00000392996
## ## the Ensembl GFF has 2 entries for this exon.
}
############################################################
## Can not perform these tests right away, as they require a
## working MySQL connection.
library(EnsDb.Hsapiens.v75)
edb <- EnsDb.Hsapiens.v75
dontrun_test_useMySQL <- function() {
edb_mysql <- useMySQL(edb, user = "anonuser", host = "localhost", pass = "")
}
dontrun_test_connect_EnsDb <- function() {
library(RMySQL)
con <- dbConnect(MySQL(), user = "anonuser", host = "localhost", pass = "")
ensembldb:::listEnsDbs(dbcon = con)
## just with user.
ensembldb:::listEnsDbs(user = "anonuser", host = "localhost", pass = "",
port = 3306)
## Connecting directly to a EnsDb MySQL database.
con <- dbConnect(MySQL(), user = "anonuser", host = "localhost", pass = "",
dbname = "ensdb_hsapiens_v75")
edb_mysql <- EnsDb(con)
}
notrun_compareEnsDbs <- function() {
res <- ensembldb:::compareEnsDbs(edb, edb)
}
############################################################
## Massive test validating the cds:
## compare the length of the CDS with the length of the encoded protein.
## Get the CDS sequence, translate that and compare to protein sequence.
notrun_massive_cds_test <- function() {
## Get all CDS:
tx_cds <- cdsBy(edb, by = "tx", filter = SeqNameFilter(c(1:22, "X", "Y")))
prots <- proteins(edb, filter = TxIdFilter(names(tx_cds)),
return.type = "AAStringSet")
checkTrue(all(names(tx_cds) %in% mcols(prots)$tx_id))
tx_cds <- tx_cds[mcols(prots)$tx_id]
## Check that the length of the protein sequence is length of CDS/3
diff_width <- sum(width(tx_cds)) != width(prots) * 3
## Why??? I've got some many differences here???
sum(diff_width)
## Check some of them manually in Ensembl
## 1st: - strand.
tx_1 <- tx_cds[diff_width][1]
## Protein: 245aa
prots[diff_width][1]
## OK.
## Tx 2206bp:
exns <- exonsBy(edb, filter = TxIdFilter(names(tx_1)))
sum(width(exns))
## OK.
## Now to the CDS:
cds_ex1 <- "ATGGCGTCCCCGTCTCGGAGACTGCAGACTAAACCAGTCATTACTTGTTTCAAGAGCGTTCTGCTAATCTACACTTTTATTTTCTGG"
cds_ex2 <- "ATCACTGGCGTTATCCTTCTTGCAGTTGGCATTTGGGGCAAGGTGAGCCTGGAGAATTACTTTTCTCTTTTAAATGAGAAGGCCACCAATGTCCCCTTCGTGCTCATTGCTACTGGTACCGTCATTATTCTTTTGGGCACCTTTGGTTGTTTTGCTACCTGCCGAGCTTCTGCATGGATGCTAAAACTG"
cds_ex3 <- "TATGCAATGTTTCTGACTCTCGTTTTTTTGGTCGAACTGGTCGCTGCCATCGTAGGATTTGTTTTCAGACATGAG"
cds_ex4 <- "ATTAAGAACAGCTTTAAGAATAATTATGAGAAGGCTTTGAAGCAGTATAACTCTACAGGAGATTATAGAAGCCATGCAGTAGACAAGATCCAAAATACG"
cds_ex5 <- "TTGCATTGTTGTGGTGTCACCGATTATAGAGATTGGACAGATACTAATTATTACTCAGAAAAAGGATTTCCTAAGAGTTGCTGTAAACTTGAAGATTGTACTCCACAGAGAGATGCAGACAAAGTAAACAATGAA"
cds_ex6 <- "GGTTGTTTTATAAAGGTGATGACCATTATAGAGTCAGAAATGGGAGTCGTTGCAGGAATTTCCTTTGGAGTTGCTTGCTTCCAA"
cds_ex7 <- "CTGATTGGAATCTTTCTCGCCTACTGCCTCTCTCGTGCCATAACAAATAACCAGTATGAGATAGTGTAA"
cds_seq <- c(cds_ex1, cds_ex2, cds_ex3, cds_ex4, cds_ex5, cds_ex6, cds_ex7)
nchar(cds_seq)
width(tx_1)
## The length should be identical:
checkEquals(sum(nchar(cds_seq)), sum(width(tx_1)), checkNames = FALSE)
## OK; so WHAT???
sum(width(tx_1)) / 3
## So, start codon is encoded into a methionine.
## Stop codon is either a TAA, TGA or TAG. UAG can be encoded into Sec (U), UAG into Pyl (O)
library(Biostrings)
dna_s <- DNAString(paste0(cds_ex1, cds_ex2, cds_ex3, cds_ex4, cds_ex5, cds_ex6, cds_ex7))
translate(dna_s)
## Look at that!
translate(DNAString("TAA")) ## -> translates into *
translate(DNAString("TGA")) ## -> translates into *
translate(DNAString("TAG")) ## -> translates into *
translate(DNAString("ATG")) ## -> translates into M
## Assumption:
## If the mRNA ends with a TAA, the protein sequence will be 1aa shorter than
## length(CDS)/3.
## If the mRNA ends with a TAG, UAG the AA length is length(CDS)/3
## Check one of the mRNA where it fits:
tx_2 <- tx_cds[!diff_width][1]
prots[!diff_width][1]
## AA is 137 long, ends with I.
sum(width(tx_2)) / 3 ## OK
## Check Ensembl:
tx_2_1 <- "ATGCTAAAACTG"
tx_2_2 <- "TATGCAATGTTTCTGACTCTCGTTTTTTTGGTCGAACTGGTCGCTGCCATCGTAGGATTTGTTTTCAGACATGAG"
tx_2_3 <- "ATTAAGAACAGCTTTAAGAATAATTATGAGAAGGCTTTGAAGCAGTATAACTCTACAGGAGATTATAGAAGCCATGCAGTAGACAAGATCCAAAATACG"
tx_2_4 <- "TTGCATTGTTGTGGTGTCACCGATTATAGAGATTGGACAGATACTAATTATTACTCAGAAAAAGGATTTCCTAAGAGTTGCTGTAAACTTGAAGATTGTACTCCACAGAGAGATGCAGACAAAGTAAACAATGAA"
tx_2_5 <- "GGTTGTTTTATAAAGGTGATGACCATTATAGAGTCAGAAATGGGAGTCGTTGCAGGAATTTCCTTTGGAGTTGCTTGCTTCCAA"
tx_2_6 <- "GACATT"
tx_2_cds <- paste0(tx_2_1, tx_2_2, tx_2_3, tx_2_4, tx_2_5, tx_2_6)
nchar(tx_2_cds)
sum(width(tx_2))
## OK.
translate(DNAString(tx_2_cds))
## Next assumption:
## If we don't have a 3' UTR the AA sequence corresponds to length(CDS)/3
tx_cds <- cdsBy(edb, by = "tx", filter = SeqNameFilter(c(1:22, "X", "Y")),
columns = c("tx_seq_start", "tx_seq_end", "tx_cds_seq_start",
"tx_cds_seq_end"))
prots <- proteins(edb, filter = TxIdFilter(names(tx_cds)),
return.type = "AAStringSet")
checkTrue(all(names(tx_cds) %in% mcols(prots)$tx_id))
tx_cds <- tx_cds[mcols(prots)$tx_id]
## Calculate the CDS width.
tx_cds_width <- sum(width(tx_cds))
txs <- transcripts(edb, filter = TxIdFilter(names(tx_cds)))
txs <- txs[names(tx_cds)]
## Subtract 3 from the width if we've got an 3'UTR.
to_subtract <- rep(3, length(tx_cds_width))
to_subtract[((end(txs) == txs$tx_cds_seq_end) &
as.logical(strand(txs) == "+"))
| ((start(txs) == txs$tx_cds_seq_start)
& as.logical(strand(txs) == "-"))] <- 0
tx_cds_width <- tx_cds_width - to_subtract
## Check that the length of the protein sequence is length of CDS/3
diff_width <- tx_cds_width != width(prots) * 3
## Why??? I've got some many differences here???
sum(diff_width)
length(diff_width)
## AAAA, still have some that don't fit!!!
tx_3 <- tx_cds[diff_width][1]
prots[diff_width][1]
## AA is 259aa long, ends with T., TX is: ENST00000371584
## WTF, we've got no START CODON!!!
sum(width(tx_3)) / 3 ## OMG!!!
## Now, exclude those without a 5' UTR:
no_five <- ((start(txs) == txs$tx_cds_seq_start) &
as.logical(strand(txs) == "+")) |
((end(txs) == txs$tx_cds_seq_end) &
as.logical(strand(txs) == "-"))
still_prot <- (diff_width & !no_five)
}
notrun_test_getGenomeFaFile <- function(){
library(EnsDb.Hsapiens.v82)
edb <- EnsDb.Hsapiens.v82
## We know that there is no Fasta file for that Ensembl release available.
Fa <- getGenomeFaFile(edb)
## Got the one from Ensembl 81.
genes <- genes(edb, filter=SeqNameFilter("Y"))
geneSeqsFa <- getSeq(Fa, genes)
## Get the transcript sequences...
txSeqsFa <- extractTranscriptSeqs(Fa, edb, filter=SeqNameFilter("Y"))
## Get the TwoBitFile.
twob <- ensembldb:::getGenomeTwoBitFile(edb)
## Get thegene sequences.
## ERROR FIX BELOW WITH UPDATED VERSIONS!!!
geneSeqs2b <- getSeq(twob, genes)
## Have to fix the seqnames.
si <- seqinfo(twob)
sn <- unlist(lapply(strsplit(seqnames(si), split=" ", fixed=TRUE), function(z){
return(z[1])
}))
seqnames(si) <- sn
seqinfo(twob) <- si
## Do the same with the TwoBitFile
geneSeqsTB <- getSeq(twob, genes)
## Subset to all genes that are encoded on chromosomes for which
## we do have DNA sequence available.
genes <- genes[seqnames(genes) %in% seqnames(seqinfo(Dna))]
## Get the gene sequences, i.e. the sequence including the sequence of
## all of the gene's exons and introns.
geneSeqs <- getSeq(Dna, genes)
library(AnnotationHub)
ah <- AnnotationHub()
quer <- query(ah, c("release-", "Homo sapiens"))
## So, I get 2bit files and toplevel stuff.
Test <- ah[["AH50068"]]
}
notrun_test_extractTranscriptSeqs <- function(){
## Note: we can't run that by default as we can not assume everybody has
## AnnotationHub and the required ressource installed.
## That's how we want to test the transcript seqs.
genome <- getGenomeFaFile(edb)
ZBTB <- extractTranscriptSeqs(genome, edb, filter=GenenameFilter("ZBTB16"))
## Load the sequences for one ZBTB16 transcript from FA.
faf <- system.file("txt/ENST00000335953.fa.gz", package="ensembldb")
Seqs <- readDNAStringSet(faf)
tx <- "ENST00000335953"
## cDNA
checkEquals(unname(as.character(ZBTB[tx])),
unname(as.character(Seqs[grep(names(Seqs), pattern="cdna")])))
## CDS
cBy <- cdsBy(edb, "tx", filter=TxIdFilter(tx))
CDS <- extractTranscriptSeqs(genome, cBy)
checkEquals(unname(as.character(CDS)),
unname(as.character(Seqs[grep(names(Seqs), pattern="cds")])))
## 5' UTR
fBy <- fiveUTRsByTranscript(edb, filter=TxIdFilter(tx))
UTR <- extractTranscriptSeqs(genome, fBy)
checkEquals(unname(as.character(UTR)),
unname(as.character(Seqs[grep(names(Seqs), pattern="utr5")])))
## 3' UTR
tBy <- threeUTRsByTranscript(edb, filter=TxIdFilter(tx))
UTR <- extractTranscriptSeqs(genome, tBy)
checkEquals(unname(as.character(UTR)),
unname(as.character(Seqs[grep(names(Seqs), pattern="utr3")])))
## Another gene on the reverse strand:
faf <- system.file("txt/ENST00000200135.fa.gz", package="ensembldb")
Seqs <- readDNAStringSet(faf)
tx <- "ENST00000200135"
## cDNA
cDNA <- extractTranscriptSeqs(genome, edb, filter=TxIdFilter(tx))
checkEquals(unname(as.character(cDNA)),
unname(as.character(Seqs[grep(names(Seqs), pattern="cdna")])))
## do the same, but from other strand
exns <- exonsBy(edb, "tx", filter=TxIdFilter(tx))
cDNA <- extractTranscriptSeqs(genome, exns)
checkEquals(unname(as.character(cDNA)),
unname(as.character(Seqs[grep(names(Seqs), pattern="cdna")])))
strand(exns) <- "+"
cDNA <- extractTranscriptSeqs(genome, exns)
checkTrue(unname(as.character(cDNA)) !=
unname(as.character(Seqs[grep(names(Seqs), pattern="cdna")])))
## CDS
cBy <- cdsBy(edb, "tx", filter=TxIdFilter(tx))
CDS <- extractTranscriptSeqs(genome, cBy)
checkEquals(unname(as.character(CDS)),
unname(as.character(Seqs[grep(names(Seqs), pattern="cds")])))
## 5' UTR
fBy <- fiveUTRsByTranscript(edb, filter=TxIdFilter(tx))
UTR <- extractTranscriptSeqs(genome, fBy)
checkEquals(unname(as.character(UTR)),
unname(as.character(Seqs[grep(names(Seqs), pattern="utr5")])))
## 3' UTR
tBy <- threeUTRsByTranscript(edb, filter=TxIdFilter(tx))
UTR <- extractTranscriptSeqs(genome, tBy)
checkEquals(unname(as.character(UTR)),
unname(as.character(Seqs[grep(names(Seqs), pattern="utr3")])))
}
notrun_test_getCdsSequence <- function(){
## That's when we like to get the sequence from the coding region.
genome <- getGenomeFaFile(edb)
tx <- extractTranscriptSeqs(genome, edb, filter=SeqNameFilter("Y"))
cdsSeq <- extractTranscriptSeqs(genome, cdsBy(edb, filter=SeqNameFilter("Y")))
## that's basically to get the CDS sequence.
## UTR sequence:
tutr <- extractTranscriptSeqs(genome, threeUTRsByTranscript(edb, filter=SeqNameFilter("Y")))
futr <- extractTranscriptSeqs(genome, fiveUTRsByTranscript(edb, filter=SeqNameFilter("Y")))
theTx <- "ENST00000602770"
fullSeq <- as.character(tx[theTx])
## build the one from 5', cds and 3'
compSeq <- ""
if(any(names(futr) == theTx))
compSeq <- paste0(compSeq, as.character(futr[theTx]))
if(any(names(cdsSeq) == theTx))
compSeq <- paste0(compSeq, as.character(cdsSeq[theTx]))
if(any(names(tutr) == theTx))
compSeq <- paste(compSeq, as.character(tutr[theTx]))
checkEquals(unname(fullSeq), compSeq)
}
notrun_test_cds <- function(){
library(TxDb.Hsapiens.UCSC.hg19.knownGene)
txdb <- TxDb.Hsapiens.UCSC.hg19.knownGene
cds <- cds(txdb)
cby <- cdsBy(txdb, by="tx")
gr <- cby[[7]][1]
seqlevels(gr) <- sub(seqlevels(gr), pattern="chr", replacement="")
tx <- transcripts(edb, filter=GRangesFilter(gr, condition="overlapping"))
cby[[7]]
## Note: so that fits! And we've to include the stop_codon feature for GTF import!
## Make an TxDb from GTF:
gtf <- "/Users/jo/Projects/EnsDbs/75/homo_sapiens/Homo_sapiens.GRCh37.75.gtf.gz"
library(GenomicFeatures)
Test <- makeTxDbFromGFF(gtf, format="gtf", organism="Homo sapiens")
scds <- cdsBy(Test, by="tx")
gr <- scds[[7]][1]
tx <- transcripts(edb, filter=GRangesFilter(gr, condition="overlapping"))
scds[[7]]
## Compare:
## TxDb form GTF has: 865692 879533
## EnsDb: 865692 879533
## Next test:
gr <- scds[[2]][1]
tx <- transcripts(edb, filter=GRangesFilter(gr, condition="overlapping"))
tx
scds[[2]]
## start_codon: 367659 367661, stop_codon: 368595 368597 CDS: 367659 368594.
## TxDb from GTF includes the stop_codon!
}
dontrun_benchmark_ordering_genes <- function() {
.withR <- function(x, ...) {
ensembldb:::orderResultsInR(x) <- TRUE
genes(x, ...)
}
.withSQL <- function(x, ...) {
ensembldb:::orderResultsInR(x) <- FALSE
genes(x, ...)
}
library(microbenchmark)
microbenchmark(.withR(edb), .withSQL(edb), times = 10) ## same
microbenchmark(.withR(edb, columns = c("gene_id", "tx_id")),
.withSQL(edb, columns = c("gene_id", "tx_id")),
times = 10) ## R slightly faster.
microbenchmark(.withR(edb, columns = c("gene_id", "tx_id"),
SeqNameFilter("Y")),
.withSQL(edb, columns = c("gene_id", "tx_id"),
SeqNameFilter("Y")),
times = 10) ## same.
}
## We aim to fix issue #11 by performing the ordering in R instead
## of SQL. Thus, we don't want to run this as a "regular" test
## case.
dontrun_test_ordering_cdsBy <- function() {
doBench <- FALSE
if (doBench)
library(microbenchmark)
.withR <- function(x, ...) {
ensembldb:::orderResultsInR(x) <- TRUE
cdsBy(x, ...)
}
.withSQL <- function(x, ...) {
ensembldb:::orderResultsInR(x) <- FALSE
cdsBy(x, ...)
}
res_sql <- .withSQL(edb)
res_r <- .withR(edb)
checkEquals(res_sql, res_r)
if (dobench)
microbenchmark(.withSQL(edb), .withR(edb),
times = 3) ## R slightly faster.
res_sql <- .withSQL(edb, filter = SeqNameFilter("Y"))
res_r <- .withR(edb, filter = SeqNameFilter("Y"))
checkEquals(res_sql, res_r)
if (dobench)
microbenchmark(.withSQL(edb, filter = SeqNameFilter("Y")),
.withR(edb, filter = SeqNameFilter("Y")),
times = 10) ## R 6x faster.
}
dontrun_test_ordering_exonsBy <- function() {
doBench <- FALSE
if (doBench)
library(microbenchmark)
.withR <- function(x, ...) {
ensembldb:::orderResultsInR(x) <- TRUE
exonsBy(x, ...)
}
.withSQL <- function(x, ...) {
ensembldb:::orderResultsInR(x) <- FALSE
exonsBy(x, ...)
}
res_sql <- .withSQL(edb)
res_r <- .withR(edb)
checkEquals(res_sql, res_r)
if (doBench)
microbenchmark(.withSQL(edb), .withR(edb),
times = 3) ## about the same; R slightly faster.
## with using a SeqNameFilter in addition.
res_sql <- .withSQL(edb, filter = SeqNameFilter("Y"))
res_r <- .withR(edb, filter = SeqNameFilter("Y")) ## query takes longer.
checkEquals(res_sql, res_r)
if (doBench)
microbenchmark(.withSQL(edb, filter = SeqNameFilter("Y")),
.withR(edb, filter = SeqNameFilter("Y")),
times = 3) ## SQL twice as fast.
## Now getting stuff by gene
res_sql <- .withSQL(edb, by = "gene")
res_r <- .withR(edb, by = "gene")
## checkEquals(res_sql, res_r) ## Differences due to ties
if (doBench)
microbenchmark(.withSQL(edb, by = "gene"),
.withR(edb, by = "gene"),
times = 3) ## SQL faster; ???
## Along with a SeqNameFilter
res_sql <- .withSQL(edb, by = "gene", filter = SeqNameFilter("Y"))
res_r <- .withR(edb, by = "gene", filter = SeqNameFilter("Y"))
## Why does the query take longer for R???
## checkEquals(res_sql, res_r) ## Differences due to ties
if (doBench)
microbenchmark(.withSQL(edb, by = "gene", filter = SeqNameFilter("Y")),
.withR(edb, by = "gene", filter = SeqNameFilter("Y")),
times = 3) ## SQL faster.
## Along with a GeneBiotypeFilter
if (doBench)
microbenchmark(.withSQL(edb, by = "gene", filter = GeneBiotypeFilter("protein_coding"))
, .withR(edb, by = "gene", filter = GeneBiotypeFilter("protein_coding"))
, times = 3)
}
dontrun_test_ordering_transcriptsBy <- function() {
.withR <- function(x, ...) {
ensembldb:::orderResultsInR(x) <- TRUE
transcriptsBy(x, ...)
}
.withSQL <- function(x, ...) {
ensembldb:::orderResultsInR(x) <- FALSE
transcriptsBy(x, ...)
}
res_sql <- .withSQL(edb)
res_r <- .withR(edb)
checkEquals(res_sql, res_r)
microbenchmark(.withSQL(edb), .withR(edb), times = 3) ## same speed
res_sql <- .withSQL(edb, filter = SeqNameFilter("Y"))
res_r <- .withR(edb, filter = SeqNameFilter("Y"))
checkEquals(res_sql, res_r)
microbenchmark(.withSQL(edb, filter = SeqNameFilter("Y")),
.withR(edb, filter = SeqNameFilter("Y")),
times = 3) ## SQL slighly faster.
}
dontrun_query_tune <- function() {
## Query tuning:
library(RSQLite)
con <- dbconn(edb)
Q <- "select distinct tx2exon.exon_id,exon.exon_seq_start,exon.exon_seq_end,gene.seq_name,tx2exon.tx_id,gene.seq_strand,tx2exon.exon_idx from gene join tx on (gene.gene_id=tx.gene_id) join tx2exon on (tx.tx_id=tx2exon.tx_id) join exon on (tx2exon.exon_id=exon.exon_id) where gene.seq_name = 'Y'"
system.time(dbGetQuery(con, Q))
Q2 <- "select distinct tx2exon.exon_id,exon.exon_seq_start,exon.exon_seq_end,gene.seq_name,tx2exon.tx_id,gene.seq_strand,tx2exon.exon_idx from exon join tx2exon on (tx2exon.exon_id = exon.exon_id) join tx on (tx2exon.tx_id = tx.tx_id) join gene on (gene.gene_id=tx.gene_id) where gene.seq_name = 'Y'"
system.time(dbGetQuery(con, Q2))
Q3 <- "select distinct tx2exon.exon_id,exon.exon_seq_start,exon.exon_seq_end,gene.seq_name,tx2exon.tx_id,gene.seq_strand,tx2exon.exon_idx from tx2exon join exon on (tx2exon.exon_id = exon.exon_id) join tx on (tx2exon.tx_id = tx.tx_id) join gene on (gene.gene_id=tx.gene_id) where gene.seq_name = 'Y'"
system.time(dbGetQuery(con, Q3))
Q4 <- "select distinct tx2exon.exon_id,exon.exon_seq_start,exon.exon_seq_end,gene.seq_name,tx2exon.tx_id,gene.seq_strand,tx2exon.exon_idx from tx2exon join exon on (tx2exon.exon_id = exon.exon_id) join tx on (tx2exon.tx_id = tx.tx_id) join gene on (gene.gene_id=tx.gene_id) where gene.seq_name = 'Y' order by tx.tx_id"
system.time(dbGetQuery(con, Q4))
Q5 <- "select distinct tx2exon.exon_id,exon.exon_seq_start,exon.exon_seq_end,gene.seq_name,tx2exon.tx_id,gene.seq_strand,tx2exon.exon_idx from tx2exon inner join exon on (tx2exon.exon_id = exon.exon_id) inner join tx on (tx2exon.tx_id = tx.tx_id) inner join gene on (gene.gene_id=tx.gene_id) where gene.seq_name = 'Y' order by tx.tx_id"
system.time(dbGetQuery(con, Q5))
Q6 <- "select distinct tx2exon.exon_id,exon.exon_seq_start,exon.exon_seq_end,gene.seq_name,tx2exon.tx_id,gene.seq_strand,tx2exon.exon_idx from gene inner join tx on (gene.gene_id=tx.gene_id) inner join tx2exon on (tx.tx_id=tx2exon.tx_id) inner join exon on (tx2exon.exon_id=exon.exon_id) where gene.seq_name = 'Y' order by tx.tx_id asc"
system.time(dbGetQuery(con, Q6))
}
## implement:
## .checkOrderBy: checks order.by argument removing columns that are
## not present in the database
## orderBy columns are added to the columns.
## .orderDataFrameBy: orders the dataframe by the specified columns.
notrun_test_protein_domains <- function() {
res <- ensembldb:::getWhat(edb, columns = c("protein_id", "tx_id", "gene_id",
"gene_name"),
filter = list(ProtDomIdFilter("PF00096")))
}
notrun_compare_full <- function(){
## That's on the full thing.
## Test if the result has the same ordering than the transcripts call.
allTx <- transcripts(edb)
txLen <- transcriptLengths(edb, with.cds_len=TRUE, with.utr5_len=TRUE,
with.utr3_len=TRUE)
checkEquals(names(allTx), rownames(txLen))
system.time(
futr <- fiveUTRsByTranscript(edb)
)
## 23 secs.
futrLen <- sum(width(futr)) ## do I need reduce???
checkEquals(unname(futrLen), txLen[names(futrLen), "utr5_len"])
## 3'
system.time(
tutr <- threeUTRsByTranscript(edb)
)
system.time(
tutrLen <- sum(width(tutr))
)
checkEquals(unname(tutrLen), txLen[names(tutrLen), "utr3_len"])
}
notrun_compare_to_genfeat <- function(){
library(TxDb.Hsapiens.UCSC.hg19.knownGene)
txdb <- TxDb.Hsapiens.UCSC.hg19.knownGene
system.time(
Len <- transcriptLengths(edb)
)
## Woa, 52 sec
system.time(
txLen <- lengthOf(edb, "tx")
)
## Faster, 31 sec
checkEquals(Len$tx_len, unname(txLen[rownames(Len)]))
system.time(
Len2 <- transcriptLengths(txdb)
)
## :) 2.5 sec.
## Next.
system.time(
Len <- transcriptLengths(edb, with.cds_len = TRUE)
)
## 56 sec
system.time(
Len2 <- transcriptLengths(txdb, with.cds_len=TRUE)
)
## 4 sec.
## Calling the transcriptLengths of GenomicFeatures on the EnsDb.
system.time(
Def <- GenomicFeatures::transcriptLengths(edb)
) ## 26.5 sec
system.time(
WithCds <- GenomicFeatures::transcriptLengths(edb, with.cds_len=TRUE)
) ## 55 sec
system.time(
WithAll <- GenomicFeatures::transcriptLengths(edb, with.cds_len=TRUE,
with.utr5_len=TRUE,
with.utr3_len=TRUE)
) ## 99 secs
## Get my versions...
system.time(
MyDef <- ensembldb:::.transcriptLengths(edb)
) ## 31 sec
system.time(
MyWithCds <- ensembldb:::.transcriptLengths(edb, with.cds_len=TRUE)
) ## 44 sec
system.time(
MyWithAll <- ensembldb:::.transcriptLengths(edb, with.cds_len=TRUE,
with.utr5_len=TRUE,
with.utr3_len=TRUE)
) ## 63 sec
## Should be all the same!!!
rownames(MyDef) <- NULL
checkEquals(Def, MyDef)
##
rownames(MyWithCds) <- NULL
MyWithCds[is.na(MyWithCds$cds_len), "cds_len"] <- 0
checkEquals(WithCds, MyWithCds)
##
rownames(MyWithAll) <- NULL
MyWithAll[is.na(MyWithAll$cds_len), "cds_len"] <- 0
MyWithAll[is.na(MyWithAll$utr3_len), "utr3_len"] <- 0
MyWithAll[is.na(MyWithAll$utr5_len), "utr5_len"] <- 0
checkEquals(WithAll, MyWithAll)
}
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