Introduction to dotplots in R
Nathan Brouwer
10/21/2021
Sequence dotplots in R
By: Avril Coghlan.
Adapted, edited and expanded: Nathan Brouwer under the Creative Commons 3.0 Attribution License (CC BY 3.0).
NOTE: I’ve added some new material that is rather terse and lacks explication.
Good sources of more info: https://omicstutorials.com/interpreting-dot-plot-bioinformatics-with-an-example/
As a first step in comparing two protein, RNA or DNA sequences, it is a good idea to make a dotplot. A dotplot is a graphical method that allows the comparison of two protein or DNA sequences and identify regions of close similarity between them. A dotplot is essentially a two-dimensional matrix (like a grid), which has the sequences of the proteins being compared along the vertical and horizontal axes.
In order to make a simple dotplot to represent of the similarity between two sequences, individual cells in the matrix can be shaded black if residues are identical, so that matching sequence segments appear as runs of diagonal lines across the matrix. Identical proteins will have a line exactly on the main diagonal of the dotplot, that spans across the whole matrix.
For proteins that are not identical, but share regions of similarity, the dotplot will have shorter lines that may be on the main diagonal, or off the main diagonal of the matrix. In essence, a dotplot will reveal if there are any regions that are clearly very similar in two protein (or DNA) sequences.
Preliminaries
library(compbio4all)
library(rentrez)Visualzing two identical sequences
To help build our intuition about dotplots we’ll first look at some artificial examples. First, we’ll see what happens when we make a dotplot comparing the alphabet versus itself. The build-in LETTERS object in R contains the alphabet from A to Z. This is a sequence with no repeats.
#LETTERS
seqinr::dotPlot(LETTERS , LETTERS) # add code
What we get is a perfect diagonal line.
Visualizing repeats
This chunk is plotting the LETTERS object twice on the horizontal axis against itself twice on the vertical axis.
LETTERS.2.times <- c(LETTERS , LETTERS)# add code
seqinr::dotPlot(LETTERS.2.times,
LETTERS.2.times)
This chunk creates a dotplot with the LETTERS object three times on the horizontal and vertical axis.
LETTERS.3.times <- c(LETTERS, LETTERS, LETTERS) # add code
seqinr::dotPlot(LETTERS.3.times, LETTERS.3.times)# add code
This chunk creates a sequence “seq.repeat” that is repeated three times on the horizontal and vertical axis, much like the LETTERS.3.times example
seq.repeat <- c("A","C","D","E","F","G","H","I")
# add code
seq1 <- rep(seq.repeat, 3)Make the dotplot
seqinr::dotPlot(seq1, seq1)
seqinr::dotPlot(seq1, seq1, main = "Seq1 vs. Seq1 3x")
The rev() function reverses the sequence to simulate an inversion. “invert” means “inversion”
LETTERS.3.times.with.invert <- c(LETTERS,
rev(LETTERS), LETTERS) # add code
seqinr::dotPlot(LETTERS.3.times.with.invert, LETTERS.3.times.with.invert)
# add codeTODO: explain this
This chunk breaks up the sequence into three subsequences that are then placed out of order to simulate a translocation of the original sequence.
seg1 <- LETTERS[1:8]
seg2 <- LETTERS[9:18] # add code
seg3 <- LETTERS[19:26] # add code
#translocation
LETTERS.with.transloc <- c(seg1, seg3, seg2) # add code
seqinr::dotPlot(LETTERS.with.transloc, LETTERS.with.transloc) # add code
seqinr::dotPlot(LETTERS.with.transloc, LETTERS.with.transloc, main = "Translocation Dotplot")
Sample function takes a random selection from data “LETTERS”, 26 times, and each time the sample taken is replaced before another selection is made.
sample(x = LETTERS, size = 26, replace = T)## [1] "R" "T" "O" "T" "W" "G" "L" "O" "T" "O" "R" "M" "H" "V" "W" "S" "S" "H" "K"
## [20] "R" "B" "H" "F" "U" "M" "H"letters.rand1 <- sample(x = LETTERS, size = 26, replace = F)# add code
letters.rand2 <- sample(x = LETTERS, size = 26, replace = F)# add code
seqinr::dotPlot(letters.rand1, letters.rand2
)# add code
Download sequences
Now we’ll make a real dotplot of the chorismate lyase proteins from two closely related species, Mycobacterium leprae and Mycobacterium ulcerans.
Note - these are protein sequences so db = “protein”
The first step is downloading the FASTA sequences of each protein and the second step is cleaing the sequences for alignment.
# sequence 1: Q9CD83
leprae_fasta <- rentrez::entrez_fetch(db = "protein",# add code
id = "Q9CD83",
rettype = "fasta")
# sequence 2: OIN17619.1
ulcerans_fasta <- rentrez::entrez_fetch(db ="protein", # add code
id = "OIN17619.1",
rettype = "fasta")
# add code
leprae_vector <- compbio4all::fasta_cleaner(leprae_fasta) # add code
ulcerans_vector <- compbio4all::fasta_cleaner(ulcerans_fasta) # add codeWe can create a dotplot for two sequences using the dotPlot() function in the seqinr package.
First, let’s look at a dotplot created using only a single sequence. This is frequently done to investigate a sequence for the presence of repeats.
(Note - and older version of this exercise stated this kind of anlysis wasn’t normally done; this was written last year before I knew of the use of dotplots for investigating sequence repeats.)
seqinr::dotPlot(leprae_vector, ulcerans_vector, main = "Dotplot of Leprae and Ulcerans Proteins") # add code
There is a lot of consensus along the diagonal and possibly a short repeat of a few amino acids throughout the sequences.
In the dotplot above, the M. leprae sequence is plotted along the x-axis (horizontal axis), and the M. ulcerans sequence is plotted along the y-axis (vertical axis). The dotplot displays a dot at points where there is an identical amino acid in the two sequences.
For example, if amino acid 53 in the M. leprae sequence is the same amino acid (eg. “W”) as amino acid 70 in the M. ulcerans sequence, then the dotplot will show a dot the position in the plot where x =50 and y =53.
In this case you can see a lot of dots along a diagonal line, which indicates that the two protein sequences contain many identical amino acids at the same (or very similar) positions along their lengths. This is what you would expect, because we know that these two proteins are homologs (related proteins) because they share a close evolutionary history.