bch441-work-abc-units/BIN-SEQA-Composition.R

# tocID <- "BIN-SEQA-Composition.R"
#
# Purpose: A Bioinformatics Course:
#              R code accompanying the BIN-SEQA-Comparison unit
#
# Version: 1.2
#
# Date:    2017-11  -  2020-09
# Author:  Boris Steipe (boris.steipe@utoronto.ca)
#
#           1.2    2020 Maintenance
#           1.1    Change from require() to requireNamespace(),
#                      use <package>::<function>() idiom throughout,
#                      use Biocmanager:: not biocLite()
# Versions:
#           1.0    First live version 2017
#           0.1    First code copied from BCH441_A03_makeYFOlist.R
#
# TODO:
#
#
# == HOW TO WORK WITH LEARNING UNIT FILES ======================================
#
# DO NOT SIMPLY  source()  THESE FILES!
# If there are portions you don't understand, use R's help system, Google for an
# answer, or ask your instructor. Don't continue if you don't understand what's
#  going on. That's not how it works ...
#
# ==============================================================================


#TOC> ==========================================================================
#TOC> 
#TOC>   Section  Title                                      Line
#TOC> ----------------------------------------------------------
#TOC>   1        Preparation                                  48
#TOC>   2        Aggregate properties                         69
#TOC>   3        Sequence Composition Enrichment             113
#TOC>   3.1        Barplot, and side-by-side barplot         136
#TOC>   3.2        Plotting ratios                           171
#TOC>   3.3        Plotting log ratios                       188
#TOC>   3.4        Sort by frequency                         204
#TOC>   3.5        Color by amino acid type                  221
#TOC> 
#TOC> ==========================================================================


# =    1  Preparation  =========================================================

if (! requireNamespace("seqinr", quietly = TRUE)) {
  install.packages("seqinr")
}
# Package information:
#  library(help = seqinr)       # basic information
#  browseVignettes("seqinr")    # available vignettes
#  data(package = "seqinr")     # available datasets

# Load a reference sequence to work with:

# If you have done the BIN-Storing_data unit:
   source("makeProteinDB.R")
   sel <- which(myDB$protein$name == sprintf("MBP1_%s", biCode(MYSPE)))
   mySeq <- myDB$protein$sequence[sel]

# If not, use the yeast Mbp1 sequence:
   mySeq <- dbSanitizeSequence(fromJSON("./data/MBP1_SACCE.json")$sequence)


# =    2  Aggregate properties  ================================================


# Let's try a simple function from seqinr: computing the pI of the sequence
?seqinr::computePI

# This takes as input a vector of upper-case AA codes

# We can use the function strsplit() to split the string
# into single characters

(s <- strsplit(mySeq, "")) # splitting on the empty spring
                           # splits into single characters
s <- unlist(s)             # strsplit() returns a list! Why?
                           # (But we don't need a list now...)

# Alternatively, seqinr provides
# the function s2c() to convert strings into
# character vectors (and c2s to convert them back).

seqinr::s2c(mySeq)


seqinr::computePI(seqinr::s2c(mySeq))  # isoelectric point
seqinr::pmw(seqinr::s2c(mySeq))        # molecular weight
seqinr::AAstat(seqinr::s2c(mySeq))     # This also plots the distribution of
                                       # values along the sequence

# A true Labor of Love has gone into the
# compilation of the "aaindex" data:

?seqinr::aaindex
data(aaindex, package = "seqinr")  # "attach" the dataset - i.e. make it
                                   # accessible as an R object

length(aaindex)  # no seqinr:: needed for the dataset since we just
                 # "attached" it with data()

# Here are all the index descriptions
for (i in 1:length(aaindex)) {
  cat(paste(i, ": ", aaindex[[i]]$D, "\n", sep=""))
}


# =    3  Sequence Composition Enrichment  =====================================


# Lets use one of the indices to calculate and plot amino-acid
# composition enrichment:
aaindex[[459]]$D

#
# Let's construct an enrichment plot to compare average frequencies
# with the amino acid counts in our sequence.

(refData <- aaindex[[459]]$I)                # reference frequencies in %
names(refData) <- seqinr::a(names(refData))  # change names to single-letter
                                             # code using seqinr's "a()" function
sum(refData)
refData        # ... in %


# tabulate the amino acid counts in mySeq
(obsData <- table(seqinr::s2c(mySeq)))        # counts
(obsData <- 100 * (obsData / sum(obsData)))   # frequencies


# ==   3.1  Barplot, and side-by-side barplot  =================================

barplot(obsData, col = "#CCCCCC", cex.names = 0.7)
abline(h = 100/20, col="#BB0000")

barplot(refData, col = "#BB0000", cex.names = 0.7)
abline(h = 100/20, col="#555555")

# Ok: first problem - the values in obsData are in alphabetical order. But the
# values in refData are in alphabetical order of amino acid name: alanine,
# arginine, asparagine, aspartic acid ... A, R, N, D, E ... you will see this
# order a lot - one of the old biochemistry tropes in the field. So we need to
# re-order one of the vectors to match the other. That's easy though:
refData
(refData <- refData[names(obsData)])

barplot(refData, col = "#BB0000", cex.names = 0.7)
abline(h = 100/20, col="#555555")

# To compare the values, we want to see them in a barplot, side-by-side ...
barplot(rbind(obsData, refData),
        ylim = c(0, 12),
        beside = TRUE,
        col = c("#CCCCCC", "#BB0000"),
        cex.names = 0.7)
abline(h = 100/20, col="#00000044")

# ... and add a legend
legend (x = 1, y = 12,
        legend = c("mySeq", "Average composition"),
        fill = c("#CCCCCC", "#BB0000"),
        cex = 0.7,
        bty = "n")


# ==   3.2  Plotting ratios  ===================================================

# To better compare the values, we'll calculate ratios between
# obsData and refData

barplot(obsData / refData,
        col = "#CCCCCC",
        ylab = "Sequence / Average",
        ylim = c(0, 2.5),
        cex.names = 0.7)
abline(h = 1, col="#BB0000")
abline(h = c(1/2, 2), lty = 2, col="#BB000055")

# ... but  ratios are not very good here, since the difference in height on the
# plot now depends on the order we compare in: ratios of 1/2 and 2 (dotted
# lines) are exactly the same fold-difference !

# ==   3.3  Plotting log ratios  ===============================================

# A better way to display this
# is to plot log(ratios).

barplot(log(obsData / refData),
        col = "#CCCCCC",
        ylab = "log(Sequence / Average)",
        ylim = log(c(1/3, 3)),
        cex.names = 0.7)
abline(h = log(1), col="#BB0000")
abline(h = log(c(1/2, 2)), lty = 2, col="#BB000055")

# Note how the two-fold difference lines are now the same distance from the
# line of equal ratio.

# ==   3.4  Sort by frequency  =================================================

barplot(sort(log(obsData / refData), decreasing = TRUE),
        ylim = log(c(1/3, 3)),
        col = "#CCCCCC",
        ylab = "log(Sequence / Average)",
        cex.names = 0.7)
abline(h = log(1), col="#BB0000")
abline(h = log(c(1/2, 2)), lty = 2, col="#BB000055")

yTxt <- log(0.9)
arrows(4, yTxt, 0, yTxt, length = 0.07)
text(5.5, yTxt, "Enriched", cex = 0.7)
yTxt <- log(1.1)
arrows(20, yTxt, 24, yTxt, length = 0.07)
text(19.5, yTxt, "Depleted", pos = 2, cex = 0.7)

# ==   3.5  Color by amino acid type  ==========================================

# Color the bars by amino acid type. Use AACOLS , defined in the .utilities.R
# script, or define your own.

barplot(rep(1, 20), names.arg = names(AACOLS), col = AACOLS, cex.names = 0.5)

lR <- sort(log(obsData / refData), decreasing = TRUE)
barplot(lR,
        ylim = log(c(1/3, 3)),
        col = AACOLS[names(lR)],
        ylab = "log(Sequence / Average)",
        cex.names = 0.7)
abline(h = log(1), col="#00000055")
abline(h = log(c(1/2, 2)), lty = 2, col="#00000033")

yTxt <- log(0.9)
arrows(4, yTxt, 0, yTxt, length = 0.07)
text(5.5, yTxt, "Enriched", cex = 0.7)
yTxt <- log(1.1)
arrows(20, yTxt, 24, yTxt, length = 0.07)
text(19.5, yTxt, "Depleted", pos = 2, cex = 0.7)


# Task:
#   Interpret this plot. (Can you?) Which types of amino acids are enriched?
#   Depleted?


# [END]
Line termination change and old code. 2021-11-16 05:31:48 +00:00			`# tocID <- "BIN-SEQA-Composition.R"`
			`#`
			`# Purpose: A Bioinformatics Course:`
			`# R code accompanying the BIN-SEQA-Comparison unit`
			`#`
			`# Version: 1.2`
			`#`
			`# Date: 2017-11 - 2020-09`
			`# Author: Boris Steipe (boris.steipe@utoronto.ca)`
			`#`
			`# 1.2 2020 Maintenance`
			`# 1.1 Change from require() to requireNamespace(),`
			`# use <package>::<function>() idiom throughout,`
			`# use Biocmanager:: not biocLite()`
			`# Versions:`
			`# 1.0 First live version 2017`
			`# 0.1 First code copied from BCH441_A03_makeYFOlist.R`
			`#`
			`# TODO:`
			`#`
			`#`
			`# == HOW TO WORK WITH LEARNING UNIT FILES ======================================`
			`#`
			`# DO NOT SIMPLY source() THESE FILES!`
			`# If there are portions you don't understand, use R's help system, Google for an`
			`# answer, or ask your instructor. Don't continue if you don't understand what's`
			`# going on. That's not how it works ...`
			`#`
			`# ==============================================================================`


			`#TOC> ==========================================================================`
			`#TOC>`
			`#TOC> Section Title Line`
			`#TOC> ----------------------------------------------------------`
			`#TOC> 1 Preparation 48`
			`#TOC> 2 Aggregate properties 69`
			`#TOC> 3 Sequence Composition Enrichment 113`
			`#TOC> 3.1 Barplot, and side-by-side barplot 136`
			`#TOC> 3.2 Plotting ratios 171`
			`#TOC> 3.3 Plotting log ratios 188`
			`#TOC> 3.4 Sort by frequency 204`
			`#TOC> 3.5 Color by amino acid type 221`
			`#TOC>`
			`#TOC> ==========================================================================`


			`# = 1 Preparation =========================================================`

			`if (! requireNamespace("seqinr", quietly = TRUE)) {`
			`install.packages("seqinr")`
			`}`
			`# Package information:`
			`# library(help = seqinr) # basic information`
			`# browseVignettes("seqinr") # available vignettes`
			`# data(package = "seqinr") # available datasets`

			`# Load a reference sequence to work with:`

			`# If you have done the BIN-Storing_data unit:`
			`source("makeProteinDB.R")`
			`sel <- which(myDB$protein$name == sprintf("MBP1_%s", biCode(MYSPE)))`
			`mySeq <- myDB$protein$sequence[sel]`

			`# If not, use the yeast Mbp1 sequence:`
			`mySeq <- dbSanitizeSequence(fromJSON("./data/MBP1_SACCE.json")$sequence)`


			`# = 2 Aggregate properties ================================================`


			`# Let's try a simple function from seqinr: computing the pI of the sequence`
			`?seqinr::computePI`

			`# This takes as input a vector of upper-case AA codes`

			`# We can use the function strsplit() to split the string`
			`# into single characters`

			`(s <- strsplit(mySeq, "")) # splitting on the empty spring`
			`# splits into single characters`
			`s <- unlist(s) # strsplit() returns a list! Why?`
			`# (But we don't need a list now...)`

			`# Alternatively, seqinr provides`
			`# the function s2c() to convert strings into`
			`# character vectors (and c2s to convert them back).`

			`seqinr::s2c(mySeq)`


			`seqinr::computePI(seqinr::s2c(mySeq)) # isoelectric point`
			`seqinr::pmw(seqinr::s2c(mySeq)) # molecular weight`
			`seqinr::AAstat(seqinr::s2c(mySeq)) # This also plots the distribution of`
			`# values along the sequence`

			`# A true Labor of Love has gone into the`
			`# compilation of the "aaindex" data:`

			`?seqinr::aaindex`
			`data(aaindex, package = "seqinr") # "attach" the dataset - i.e. make it`
			`# accessible as an R object`

			`length(aaindex) # no seqinr:: needed for the dataset since we just`
			`# "attached" it with data()`

			`# Here are all the index descriptions`
			`for (i in 1:length(aaindex)) {`
			`cat(paste(i, ": ", aaindex[[i]]$D, "\n", sep=""))`
			`}`


			`# = 3 Sequence Composition Enrichment =====================================`


			`# Lets use one of the indices to calculate and plot amino-acid`
			`# composition enrichment:`
			`aaindex[[459]]$D`

			`#`
			`# Let's construct an enrichment plot to compare average frequencies`
			`# with the amino acid counts in our sequence.`

			`(refData <- aaindex[[459]]$I) # reference frequencies in %`
			`names(refData) <- seqinr::a(names(refData)) # change names to single-letter`
			`# code using seqinr's "a()" function`
			`sum(refData)`
			`refData # ... in %`


			`# tabulate the amino acid counts in mySeq`
			`(obsData <- table(seqinr::s2c(mySeq))) # counts`
			`(obsData <- 100 * (obsData / sum(obsData))) # frequencies`


			`# == 3.1 Barplot, and side-by-side barplot =================================`

			`barplot(obsData, col = "#CCCCCC", cex.names = 0.7)`
			`abline(h = 100/20, col="#BB0000")`

			`barplot(refData, col = "#BB0000", cex.names = 0.7)`
			`abline(h = 100/20, col="#555555")`

			`# Ok: first problem - the values in obsData are in alphabetical order. But the`
			`# values in refData are in alphabetical order of amino acid name: alanine,`
			`# arginine, asparagine, aspartic acid ... A, R, N, D, E ... you will see this`
			`# order a lot - one of the old biochemistry tropes in the field. So we need to`
			`# re-order one of the vectors to match the other. That's easy though:`
			`refData`
			`(refData <- refData[names(obsData)])`

			`barplot(refData, col = "#BB0000", cex.names = 0.7)`
			`abline(h = 100/20, col="#555555")`

			`# To compare the values, we want to see them in a barplot, side-by-side ...`
			`barplot(rbind(obsData, refData),`
			`ylim = c(0, 12),`
			`beside = TRUE,`
			`col = c("#CCCCCC", "#BB0000"),`
			`cex.names = 0.7)`
			`abline(h = 100/20, col="#00000044")`

			`# ... and add a legend`
			`legend (x = 1, y = 12,`
			`legend = c("mySeq", "Average composition"),`
			`fill = c("#CCCCCC", "#BB0000"),`
			`cex = 0.7,`
			`bty = "n")`


			`# == 3.2 Plotting ratios ===================================================`

			`# To better compare the values, we'll calculate ratios between`
			`# obsData and refData`

			`barplot(obsData / refData,`
			`col = "#CCCCCC",`
			`ylab = "Sequence / Average",`
			`ylim = c(0, 2.5),`
			`cex.names = 0.7)`
			`abline(h = 1, col="#BB0000")`
			`abline(h = c(1/2, 2), lty = 2, col="#BB000055")`

			`# ... but ratios are not very good here, since the difference in height on the`
			`# plot now depends on the order we compare in: ratios of 1/2 and 2 (dotted`
			`# lines) are exactly the same fold-difference !`

			`# == 3.3 Plotting log ratios ===============================================`

			`# A better way to display this`
			`# is to plot log(ratios).`

			`barplot(log(obsData / refData),`
			`col = "#CCCCCC",`
			`ylab = "log(Sequence / Average)",`
			`ylim = log(c(1/3, 3)),`
			`cex.names = 0.7)`
			`abline(h = log(1), col="#BB0000")`
			`abline(h = log(c(1/2, 2)), lty = 2, col="#BB000055")`

			`# Note how the two-fold difference lines are now the same distance from the`
			`# line of equal ratio.`

			`# == 3.4 Sort by frequency =================================================`

			`barplot(sort(log(obsData / refData), decreasing = TRUE),`
			`ylim = log(c(1/3, 3)),`
			`col = "#CCCCCC",`
			`ylab = "log(Sequence / Average)",`
			`cex.names = 0.7)`
			`abline(h = log(1), col="#BB0000")`
			`abline(h = log(c(1/2, 2)), lty = 2, col="#BB000055")`

			`yTxt <- log(0.9)`
			`arrows(4, yTxt, 0, yTxt, length = 0.07)`
			`text(5.5, yTxt, "Enriched", cex = 0.7)`
			`yTxt <- log(1.1)`
			`arrows(20, yTxt, 24, yTxt, length = 0.07)`
			`text(19.5, yTxt, "Depleted", pos = 2, cex = 0.7)`

			`# == 3.5 Color by amino acid type ==========================================`

			`# Color the bars by amino acid type. Use AACOLS , defined in the .utilities.R`
			`# script, or define your own.`

			`barplot(rep(1, 20), names.arg = names(AACOLS), col = AACOLS, cex.names = 0.5)`

			`lR <- sort(log(obsData / refData), decreasing = TRUE)`
			`barplot(lR,`
			`ylim = log(c(1/3, 3)),`
			`col = AACOLS[names(lR)],`
			`ylab = "log(Sequence / Average)",`
			`cex.names = 0.7)`
			`abline(h = log(1), col="#00000055")`
			`abline(h = log(c(1/2, 2)), lty = 2, col="#00000033")`

			`yTxt <- log(0.9)`
			`arrows(4, yTxt, 0, yTxt, length = 0.07)`
			`text(5.5, yTxt, "Enriched", cex = 0.7)`
			`yTxt <- log(1.1)`
			`arrows(20, yTxt, 24, yTxt, length = 0.07)`
			`text(19.5, yTxt, "Depleted", pos = 2, cex = 0.7)`


			`# Task:`
			`# Interpret this plot. (Can you?) Which types of amino acids are enriched?`
			`# Depleted?`




			`# [END]`