I have a matrix data, and want to visualize it with heatmap. The rows are species, so I want visualize the phylogenetic tree aside the rows and reorder the rows of the heatmap according the tree. I know the heatmap
function in R can create the hierarchical clustering heatmap, but how can I use my phylogenetic clustering instead of the default created distance clustering in the plot?
First you need to use package ape
to read in your data as a phylo
object.
library(ape)
dat < read.tree(file="your/newick/file")
#or
dat < read.tree(text="((A:4.2,B:4.2):3.1,C:7.3);")
The following only works if your tree is ultrametric.
The next step is to transform your phylogenetic tree into class dendrogram
.
Here is an example:
data(bird.orders) #This is already a phylo object
hc < as.hclust(bird.orders) #Compulsory step as as.dendrogram doesn't have a method for phylo objects.
dend < as.dendrogram(hc)
plot(dend, horiz=TRUE)
mat < matrix(rnorm(23*23),nrow=23, dimnames=list(sample(bird.orders$tip, 23), sample(bird.orders$tip, 23))) #Some random data to plot
First we need to order the matrix according to the order in the phylogenetic tree:
ord.mat < mat[bird.orders$tip,bird.orders$tip]
Then input it to heatmap
:
heatmap(ord.mat, Rowv=dend, Colv=dend)
Edit: Here is a function to deal with ultrametric and nonultrametric trees.
heatmap.phylo < function(x, Rowp, Colp, ...){
# x numeric matrix
# Rowp: phylogenetic tree (class phylo) to be used in rows
# Colp: phylogenetic tree (class phylo) to be used in columns
# ... additional arguments to be passed to image function
x < x[Rowp$tip, Colp$tip]
xl < c(0.5, ncol(x)+0.5)
yl < c(0.5, nrow(x)+0.5)
layout(matrix(c(0,1,0,2,3,4,0,5,0),nrow=3, byrow=TRUE),
width=c(1,3,1), height=c(1,3,1))
par(mar=rep(0,4))
plot(Colp, direction="downwards", show.tip.label=FALSE,
xlab="",ylab="", xaxs="i", x.lim=xl)
par(mar=rep(0,4))
plot(Rowp, direction="rightwards", show.tip.label=FALSE,
xlab="",ylab="", yaxs="i", y.lim=yl)
par(mar=rep(0,4), xpd=TRUE)
image((1:nrow(x))0.5, (1:ncol(x))0.5, x,
xaxs="i", yaxs="i", axes=FALSE, xlab="",ylab="", ...)
par(mar=rep(0,4))
plot(NA, axes=FALSE, ylab="", xlab="", yaxs="i", xlim=c(0,2), ylim=yl)
text(rep(0,nrow(x)),1:nrow(x),Rowp$tip, pos=4)
par(mar=rep(0,4))
plot(NA, axes=FALSE, ylab="", xlab="", xaxs="i", ylim=c(0,2), xlim=xl)
text(1:ncol(x),rep(2,ncol(x)),Colp$tip, srt=90, pos=2)
}
Here is with the previous (ultrametric) example:
heatmap.phylo(mat, bird.orders, bird.orders)
And with a nonultrametric:
cat("owls(((Strix_aluco:4.2,Asio_otus:4.2):3.1,Athene_noctua:7.3):6.3,Tyto_alba:13.5);",
file = "ex.tre", sep = "\n")
tree.owls < read.tree("ex.tre")
mat2 < matrix(rnorm(4*4),nrow=4,
dimnames=list(sample(tree.owls$tip,4),sample(tree.owls$tip,4)))
is.ultrametric(tree.owls)
[1] FALSE
heatmap.phylo(mat2,tree.owls,tree.owls)

interesting
heatmap.phylo
function! new approach independent from the deprogram concept! I am pretty sure transpose it to the grid world! +10! I am pretty sure I can trsnpose it to the grid package(lattice and grid not sure for ggplot2) – agstudy Mar 1 '13 at 13:18 
yes. without limitation to ultrametric trees. This is excellent. thanks, plannapus! – RNA Mar 1 '13 at 20:38

a following question, I met error:
Error in image.default((1:ncol(x))  0.5, (1:nrow(x))  0.5, x, xaxs = "i", : dimensions of z are not length(x)(1) times length(y)(1)
runningheatmap.phylo(c, d1, d2)
on my own data. I checked that the matrix dimension and the lengths of tips of the two trees definitely agree. Do you have idea what could be the problem? Thanks. – RNA Mar 1 '13 at 22:01 
i actually sovled it. In your
heatmap.phylo()
, the ncol and nrow were switched in theimage
function. I corrected it. – RNA Mar 2 '13 at 0:18
First, I create a reproducible example. Without data we can just guess what you want. So please try to do better next time(specially you are confirmed user). For example you can do this to create your tree in newick format:
tree.text='(((XXX:4.2,ZZZ:4.2):3.1,HHH:7.3):6.3,AAA:13.6);'
Like @plannpus, I am using ape
to converts this tree to a hclust class. Unfortunatlty, it looks that we can do the conversion only for ultrametric tree: the distance from the root to each tip is the same.
library(ape)
tree < read.tree(text='(((XXX:4.2,ZZZ:4.2):3.1,HHH:7.3):6.3,AAA:13.6);')
is.ultrametric(tree)
hc < as.hclust.phylo(tree)
Then I am using dendrogramGrob from latticeExtra
to plot my tree. and levelplot
from lattice
to draw the heatmap.
library(latticeExtra)
dd.col < as.dendrogram(hc)
col.ord < order.dendrogram(dd.col)
mat < matrix(rnorm(4*4),nrow=4)
colnames(mat) < tree$tip.label
rownames(mat) < tree$tip.label
levelplot(mat[tree$tip,tree$tip],type=c('g','p'),
aspect = "fill",
colorkey = list(space = "left"),
legend =
list(right =
list(fun = dendrogramGrob,
args =
list(x = dd.col,
side = "right",
size = 10))),
panel=function(...){
panel.fill('black',alpha=0.2)
panel.levelplot.points(...,cex=12,pch=23)
}
)

+1 As usual, very nice. I'll try to see if I can find an easy workaround for nonultrametric trees, when I'll have some time later on. – plannapus Mar 1 '13 at 11:56


I adapted plannapus' answer to deal with more than one tree (also cutting out some options I didn't need in the process):
library(ape)
heatmap.phylo < function(x, Rowp, Colp, breaks, col, denscol="cyan", respect=F, ...){
# x numeric matrix
# Rowp: phylogenetic tree (class phylo) to be used in rows
# Colp: phylogenetic tree (class phylo) to be used in columns
# ... additional arguments to be passed to image function
scale01 < function(x, low = min(x), high = max(x)) {
x < (x  low)/(high  low)
x
}
col.tip < Colp$tip
n.col < 1
if (is.null(col.tip)) {
n.col < length(Colp)
col.tip < unlist(lapply(Colp, function(t) t$tip))
col.lengths < unlist(lapply(Colp, function(t) length(t$tip)))
col.fraction < col.lengths / sum(col.lengths)
col.heights < unlist(lapply(Colp, function(t) max(node.depth.edgelength(t))))
col.max_height < max(col.heights)
}
row.tip < Rowp$tip
n.row < 1
if (is.null(row.tip)) {
n.row < length(Rowp)
row.tip < unlist(lapply(Rowp, function(t) t$tip))
row.lengths < unlist(lapply(Rowp, function(t) length(t$tip)))
row.fraction < row.lengths / sum(row.lengths)
row.heights < unlist(lapply(Rowp, function(t) max(node.depth.edgelength(t))))
row.max_height < max(row.heights)
}
cexRow < min(1, 0.2 + 1/log10(n.row))
cexCol < min(1, 0.2 + 1/log10(n.col))
x < x[row.tip, col.tip]
xl < c(0.5, ncol(x)+0.5)
yl < c(0.5, nrow(x)+0.5)
screen_matrix < matrix( c(
0,1,4,5,
1,4,4,5,
0,1,1,4,
1,4,1,4,
1,4,0,1,
4,5,1,4
) / 5, byrow=T, ncol=4 )
if (respect) {
r < grconvertX(1, from = "inches", to = "ndc") / grconvertY(1, from = "inches", to = "ndc")
if (r < 1) {
screen_matrix < screen_matrix * matrix( c(r,r,1,1), nrow=6, ncol=4, byrow=T)
} else {
screen_matrix < screen_matrix * matrix( c(1,1,1/r,1/r), nrow=6, ncol=4, byrow=T)
}
}
split.screen( screen_matrix )
screen(2)
par(mar=rep(0,4))
if (n.col == 1) {
plot(Colp, direction="downwards", show.tip.label=FALSE,xaxs="i", x.lim=xl)
} else {
screens < split.screen( as.matrix(data.frame( left=cumsum(col.fraction)col.fraction, right=cumsum(col.fraction), bottom=0, top=1)))
for (i in 1:n.col) {
screen(screens[i])
plot(Colp[[i]], direction="downwards", show.tip.label=FALSE,xaxs="i", x.lim=c(0.5,0.5+col.lengths[i]), y.lim=col.max_height+col.heights[i]+c(0,col.max_height))
}
}
screen(3)
par(mar=rep(0,4))
if (n.col == 1) {
plot(Rowp, direction="rightwards", show.tip.label=FALSE,yaxs="i", y.lim=yl)
} else {
screens < split.screen( as.matrix(data.frame( left=0, right=1, bottom=cumsum(row.fraction)row.fraction, top=cumsum(row.fraction))) )
for (i in 1:n.col) {
screen(screens[i])
plot(Rowp[[i]], direction="rightwards", show.tip.label=FALSE,yaxs="i", x.lim=c(0,row.max_height), y.lim=c(0.5,0.5+row.lengths[i]))
}
}
screen(4)
par(mar=rep(0,4), xpd=TRUE)
image((1:nrow(x))0.5, (1:ncol(x))0.5, x, xaxs="i", yaxs="i", axes=FALSE, xlab="",ylab="", breaks=breaks, col=col, ...)
screen(6)
par(mar=rep(0,4))
plot(NA, axes=FALSE, ylab="", xlab="", yaxs="i", xlim=c(0,2), ylim=yl)
text(rep(0,nrow(x)),1:nrow(x),row.tip, pos=4, cex=cexCol)
screen(5)
par(mar=rep(0,4))
plot(NA, axes=FALSE, ylab="", xlab="", xaxs="i", ylim=c(0,2), xlim=xl)
text(1:ncol(x),rep(2,ncol(x)),col.tip, srt=90, adj=c(1,0.5), cex=cexRow)
screen(1)
par(mar = c(2, 2, 1, 1), cex = 0.75)
symkey < T
tmpbreaks < breaks
if (symkey) {
max.raw < max(abs(c(x, breaks)), na.rm = TRUE)
min.raw < max.raw
tmpbreaks[1] < max(abs(x), na.rm = TRUE)
tmpbreaks[length(tmpbreaks)] < max(abs(x), na.rm = TRUE)
} else {
min.raw < min(x, na.rm = TRUE)
max.raw < max(x, na.rm = TRUE)
}
z < seq(min.raw, max.raw, length = length(col))
image(z = matrix(z, ncol = 1), col = col, breaks = tmpbreaks,
xaxt = "n", yaxt = "n")
par(usr = c(0, 1, 0, 1))
lv < pretty(breaks)
xv < scale01(as.numeric(lv), min.raw, max.raw)
axis(1, at = xv, labels = lv)
h < hist(x, plot = FALSE, breaks = breaks)
hx < scale01(breaks, min.raw, max.raw)
hy < c(h$counts, h$counts[length(h$counts)])
lines(hx, hy/max(hy) * 0.95, lwd = 1, type = "s",
col = denscol)
axis(2, at = pretty(hy)/max(hy) * 0.95, pretty(hy))
par(cex = 0.5)
mtext(side = 2, "Count", line = 2)
close.screen(all.screens = T)
}
tree < read.tree(text = "(A:1,B:1);((C:1,D:2):2,E:1);((F:1,G:1,H:2):5,((I:1,J:2):2,K:1):1);", comment.char="")
N < sum(unlist(lapply(tree, function(t) length(t$tip))))
set.seed(42)
m < cor(matrix(rnorm(N*N), nrow=N))
rownames(m) < colnames(m) < LETTERS[1:N]
heatmap.phylo(m, tree, tree, col=bluered(10), breaks=seq(1,1,length.out=11), respect=T)
This exact application of a heatmap is already implemented in the plot_heatmap
function (based on ggplot2) in the phyloseq package, which is openly/freely developed on GitHub. Examples with complete code and results are included here:
http://joey711.github.io/phyloseq/plot_heatmapexamples
One caveat, and not what you are explicitly asking for here, but phyloseq::plot_heatmap
does not overlay a hierarchical tree for either axis. There is a good reason not to base your axis ordering on hierarchical clustering  and this is because of the way indices at the end of long branches can still be next to each other arbitrarily depending on how branches are rotated at the nodes. This point, and an alternative based on nonmetric multidimensional scaling is explained further in an article about the NeatMap package, which is also written for R and uses ggplot2. This dimensionreduction (ordination) approach to ordering the indices in a heatmap is adapted for phylogenetic abundance data in phyloseq::plot_heatmap
.

It seems like
plot_heatmap
will make a heatmap without a hierarchical clustering tree next to it, but cannot (as OP requested) cluster by phylogeny (or put a phylogenetic tree next to the plot to indicate that phylogeny). Does that sound right or am I missing something? – ohnoplus Dec 22 '17 at 22:47 
Actually since 2014
phyloseq::plot_heatmap
can order the taxa in the heatmap according to their order in the tree. This is accomplished through thetaxa.order
command, which can take either a taxonomic rank to cluster the indices, or an arbitrary order of the indices themselves. rdocumentation.org/packages/phyloseq/versions/1.16.2/topics/… github.com/joey711/phyloseq/issues/230 – Paul McMurdie Jan 8 '18 at 19:56 
Secondly, my point was that the OP probably overspecified their request, not understanding why ordering by a heatmap by a hierarchical or phylogenetic tree is probably not what they want, since is demonstrably less effective way to display structural patterns in the data. Hence my reference to NeatMap, etc. – Paul McMurdie Jan 8 '18 at 19:59
While my suggestion for phlyoseq::plot_heatmap
would get you part of the way there, the powerful "ggtree" package can do this, or more, if representing data on trees is really what you are going for.
Some examples are shown on the top of the following ggtree documentation page:
http://www.bioconductor.org/packages/3.7/bioc/vignettes/ggtree/inst/doc/advanceTreeAnnotation.html
Note that I am not affiliated with ggtree dev at all. Just a fan of the project and what it can already do.
reorderfun
in heatmap can aid in this... – Roman Luštrik Mar 1 '13 at 8:24dput(head(mymatrixdata))
will let people reconstruct a portion of your data easily and will make it easier for them to help you. – Simon O'Hanlon Mar 1 '13 at 8:28(A:0.1,B:0.2,(C:0.3,D:0.4):0.5);
– RNA Mar 1 '13 at 8:47