TreeSummarizedExperiment 2.4.0
The TreeSummarizedExperiment
class is an extension of the
SingleCellExperiment
class (Lun and Risso 2020). It’s used to store rectangular data
of experimental results as in a SingleCellExperiment
, and also supports the
storage of a hierarchical structure and its link information to the rectangular
data.
Compared to the SingleCellExperiment
objects, TreeSummarizedExperiment
has
five additional slots:
rowTree
: the hierarchical structure on the rows of the assays
.rowLinks
: the link information between rows of the assays
and the rowTree
.colTree
: the hierarchical structure on the columns of the assays
.colLinks
: the link information between columns of the assays
and the
colTree
.referenceSeq
(optional): the reference sequence data per feature (row).The rowTree
and\(/\)or colTree
can be left empty (NULL
) if no trees are
available; in this case, the rowLinks
and\(/\)or colLinks
are also set to
NULL
. All other TreeSummarizedExperiment
slots are inherited from
SingleCellExperiment
.
The rowTree
and colTree
slots require the tree to be an object of the
phylo
class. If a tree is available in an alternative format, it can often be
converted to a phylo
object using dedicated R packages (e.g., r Biocpkg("treeio")
(Wang et al. 2019)).
The referenceSeq
slot is optional. It accepts the reference sequence data of
features either as DNAStringSet
or DNAStringSetList
. More details are in
2.4.3.
Functions in the TreeSummarizedExperiment package fall in two
main categories: operations on the TreeSummarizedExperiment
object or
operations on the tree (phylo
) objects. The former includes constructors and
accessors, and the latter serves as “pieces” to be assembled as accessors or
functions that manipulate the TreeSummarizedExperiment
object. Given that more
than 200 R packages make use of the phylo
class, there are many resources
(e.g., ape) for users to manipulate the small “pieces” in
addition to those provided in TreeSummarizedExperiment.
We generate a toy dataset that has observations of 6 entities collected from 4
samples as an example to show how to construct a TreeSummarizedExperiment
object.
library(TreeSummarizedExperiment)
# assays data (typically, representing observed data from an experiment)
assay_data <- rbind(rep(0, 4), matrix(1:20, nrow = 5))
colnames(assay_data) <- paste0("sample", 1:4)
rownames(assay_data) <- paste("entity", seq_len(6), sep = "")
assay_data
## sample1 sample2 sample3 sample4
## entity1 0 0 0 0
## entity2 1 6 11 16
## entity3 2 7 12 17
## entity4 3 8 13 18
## entity5 4 9 14 19
## entity6 5 10 15 20
The information of entities and samples are given in the row_data and col_data, respectively.
# row data (feature annotations)
row_data <- data.frame(Kingdom = "A",
Phylum = rep(c("B1", "B2"), c(2, 4)),
Class = rep(c("C1", "C2", "C3"), each = 2),
OTU = paste0("D", 1:6),
row.names = rownames(assay_data),
stringsAsFactors = FALSE)
row_data
## Kingdom Phylum Class OTU
## entity1 A B1 C1 D1
## entity2 A B1 C1 D2
## entity3 A B2 C2 D3
## entity4 A B2 C2 D4
## entity5 A B2 C3 D5
## entity6 A B2 C3 D6
# column data (sample annotations)
col_data <- data.frame(gg = c(1, 2, 3, 3),
group = rep(LETTERS[1:2], each = 2),
row.names = colnames(assay_data),
stringsAsFactors = FALSE)
col_data
## gg group
## sample1 1 A
## sample2 2 A
## sample3 3 B
## sample4 3 B
The hierarchical structure of the 6 entities and r ncol(assay_data)
samples are denoted as row_tree and col_tree,
respectively. The two trees are phylo
objects randomly created with rtree
from the package ape. Note that the row tree has 5 rather than 6
leaves; this is used later to show that multiple rows in the assays
are
allowed to map to a single node in the tree.
library(ape)
# The first toy tree
set.seed(12)
row_tree <- rtree(5)
# The second toy tree
set.seed(12)
col_tree <- rtree(4)
# change node labels
col_tree$tip.label <- colnames(assay_data)
col_tree$node.label <- c("All", "GroupA", "GroupB")
We visualize the tree using the package ggtree (Yu et al. 2017). Here, the internal nodes of the row_tree have no labels as shown in Figure 2.
library(ggtree)
library(ggplot2)
# Visualize the row tree
ggtree(row_tree, size = 2, branch.length = "none") +
geom_text2(aes(label = node), color = "darkblue",
hjust = -0.5, vjust = 0.7, size = 5.5) +
geom_text2(aes(label = label), color = "darkorange",
hjust = -0.1, vjust = -0.7, size = 5.5)
The col_tree has labels for internal nodes.
# Visualize the column tree
ggtree(col_tree, size = 2, branch.length = "none") +
geom_text2(aes(label = node), color = "darkblue",
hjust = -0.5, vjust = 0.7, size = 5.5) +
geom_text2(aes(label = label), color = "darkorange",
hjust = -0.1, vjust = -0.7, size = 5.5)+
ylim(c(0.8, 4.5)) +
xlim(c(0, 2.2))
TreeSummarizedExperiment
The TreeSummarizedExperiment
class is used to store the toy data generated in the previous section:
assay_data, row_data, col_data, col_tree and row_tree. To
correctly store data, the link information between the rows (or columns) of
assay_data and the nodes of the row_tree (or col_tree) can be provided via a character vector rowNodeLab
(or colNodeLab
), with length equal to the number of rows (or columns) of the assays
; otherwise the row (or column) names are used. Those columns
or rows with labels that are not present among the node labels of the tree are removed with
warnings. The link data between the assays
tables and the tree data is
automatically generated in the construction.
The row and column trees can be included simultaneously in the construction.
Here, the column names of assay_data can be found in the node labels of the
column tree, which enables the link to be created between the column dimension
of assay_data and the column tree col_tree. If the row names of
assay_data are not in the node labels of row_tree, we would need to
provide their corresponding node labels (row_lab) to rowNodeLab
in the
construction of the object. It is allowed to have multiple rows or/and columns
mapped to a node, for example, the same leaf label is used for the first two
rows in row_lab.
# all column names could be found in the node labels of the column tree
all(colnames(assay_data) %in% c(col_tree$tip.label, col_tree$node.label))
## [1] TRUE
# provide the node labels in rowNodeLab
tip_lab <- row_tree$tip.label
row_lab <- tip_lab[c(1, 1:5)]
row_lab
## [1] "t3" "t3" "t2" "t1" "t5" "t4"
both_tse <- TreeSummarizedExperiment(assays = list(Count = assay_data),
rowData = row_data,
colData = col_data,
rowTree = row_tree,
rowNodeLab = row_lab,
colTree = col_tree)
both_tse
## class: TreeSummarizedExperiment
## dim: 6 4
## metadata(0):
## assays(1): Count
## rownames(6): entity1 entity2 ... entity5 entity6
## rowData names(4): Kingdom Phylum Class OTU
## colnames(4): sample1 sample2 sample3 sample4
## colData names(2): gg group
## reducedDimNames(0):
## mainExpName: NULL
## altExpNames(0):
## rowLinks: a LinkDataFrame (6 rows)
## rowTree: 1 phylo tree(s) (5 leaves)
## colLinks: a LinkDataFrame (4 rows)
## colTree: 1 phylo tree(s) (4 leaves)
When printing out both_tse, we see a similar message as
SingleCellExperiment
with four additional lines for rowLinks
, rowTree
,
colLinks
and colTree
.
For slots inherited from the SingleCellExperiment
class, the accessors are
exactly the same as shown in SingleCellExperiment. These
accessors are both setters and getters.
# to get the first table in the assays
(count <- assays(both_tse)[[1]])
## sample1 sample2 sample3 sample4
## entity1 0 0 0 0
## entity2 1 6 11 16
## entity3 2 7 12 17
## entity4 3 8 13 18
## entity5 4 9 14 19
## entity6 5 10 15 20
# to get row data
rowData(both_tse)
## DataFrame with 6 rows and 4 columns
## Kingdom Phylum Class OTU
## <character> <character> <character> <character>
## entity1 A B1 C1 D1
## entity2 A B1 C1 D2
## entity3 A B2 C2 D3
## entity4 A B2 C2 D4
## entity5 A B2 C3 D5
## entity6 A B2 C3 D6
# to get column data
colData(both_tse)
## DataFrame with 4 rows and 2 columns
## gg group
## <numeric> <character>
## sample1 1 A
## sample2 2 A
## sample3 3 B
## sample4 3 B
# to get metadata: it's empty here
metadata(both_tse)
## list()
For new slots, we provide rowTree
(and colTree
) to retrieve the row (column)
trees, and rowLinks
(and colLinks
) to retrieve the link information between
assays
and nodes of the row (column) tree. If the tree is not available, the
corresponding link data is NULL
.
# get trees
rowTree(both_tse)
##
## Phylogenetic tree with 5 tips and 4 internal nodes.
##
## Tip labels:
## t3, t2, t1, t5, t4
##
## Rooted; includes branch lengths.
colTree(both_tse)
##
## Phylogenetic tree with 4 tips and 3 internal nodes.
##
## Tip labels:
## sample1, sample2, sample3, sample4
## Node labels:
## All, GroupA, GroupB
##
## Rooted; includes branch lengths.
rowTree
and colTree
can work not only as getters but also as setters. The
replacement requires that the row/col names of the TSE object can be matched
to node labels of the new row/col tree; otherwise changeTree
should be used
with rowNodeLab
or colNodeLab
available 2.6.
new_tse <- both_tse
# a new tree
new_tree <- rtree(nrow(new_tse))
new_tree$tip.label <- rownames(new_tse)
# the original row tree is replaced with the new tree
rowTree(new_tse) <- new_tree
identical(rowTree(new_tse), rowTree(both_tse))
## [1] FALSE
identical(rowTree(new_tse), new_tree)
## [1] TRUE
rowLinks
and colLinks
only work as getters.
# access the link data
(r_link <- rowLinks(both_tse))
## LinkDataFrame with 6 rows and 5 columns
## nodeLab nodeLab_alias nodeNum isLeaf whichTree
## <character> <character> <integer> <logical> <character>
## entity1 t3 alias_1 1 TRUE phylo
## entity2 t3 alias_1 1 TRUE phylo
## entity3 t2 alias_2 2 TRUE phylo
## entity4 t1 alias_3 3 TRUE phylo
## entity5 t5 alias_4 4 TRUE phylo
## entity6 t4 alias_5 5 TRUE phylo
(c_link <- colLinks(both_tse))
## LinkDataFrame with 4 rows and 5 columns
## nodeLab nodeLab_alias nodeNum isLeaf whichTree
## <character> <character> <integer> <logical> <character>
## sample1 sample1 alias_1 1 TRUE phylo
## sample2 sample2 alias_2 2 TRUE phylo
## sample3 sample3 alias_3 3 TRUE phylo
## sample4 sample4 alias_4 4 TRUE phylo
The link data objects are of the LinkDataFrame
class, which extends the DataFrame
class with the restriction that it has at least four columns:
nodeLab
: the labels of nodes on the treenodeLab_alias
: the alias labels of nodes on the treenodeNum
: the numbers of nodes on the treeisLeaf
: whether the node is a leaf nodewhichTree
: the name of the tree that is mapped to (See vignette 2).More details about
the DataFrame
class could be found in the S4Vectors R/Bioconductor package.
class(r_link)
## [1] "LinkDataFrame"
## attr(,"package")
## [1] "TreeSummarizedExperiment"
showClass("LinkDataFrame")
## Class "LinkDataFrame" [package "TreeSummarizedExperiment"]
##
## Slots:
##
## Name: rownames nrows elementType elementMetadata
## Class: character_OR_NULL integer character DataFrame_OR_NULL
##
## Name: metadata listData
## Class: list list
##
## Extends:
## Class "DFrame", directly
## Class "LinkDataFrame_Or_NULL", directly
## Class "DataFrame", by class "DFrame", distance 2
## Class "SimpleList", by class "DFrame", distance 2
## Class "RectangularData", by class "DFrame", distance 3
## Class "List", by class "DFrame", distance 3
## Class "DataFrame_OR_NULL", by class "DFrame", distance 3
## Class "Vector", by class "DFrame", distance 4
## Class "list_OR_List", by class "DFrame", distance 4
## Class "Annotated", by class "DFrame", distance 5
## Class "vector_OR_Vector", by class "DFrame", distance 5
The link data is automatically generated when constructing the
TreeSummarizedExperiment
object. We highly recommend users not to modify it
manually; otherwise the link might be broken. For R packages developers, we show
in the Section 2.9 about how to update the link.
In addition to tree data, reference sequence data can be stored per feature in
a TreeSummarizedExperiment
object.
refSeq <- DNAStringSet(rep("AGCT", nrow(both_tse)))
The data must match the number of rows in the object and can either be added to
the object upon creation or later on with the accessor function referenceSeq
.
referenceSeq(both_tse) <- refSeq
referenceSeq(both_tse)
## DNAStringSet object of length 6:
## width seq names
## [1] 4 AGCT entity1
## [2] 4 AGCT entity2
## [3] 4 AGCT entity3
## [4] 4 AGCT entity4
## [5] 4 AGCT entity5
## [6] 4 AGCT entity6
Both DNAStringSet
or DNAStringSetList
can be used, so that a single or
multiple sequences can be stored per feature.
Now, one new line in the message is shown for the referenceSeq
slot.
both_tse
## class: TreeSummarizedExperiment
## dim: 6 4
## metadata(0):
## assays(1): Count
## rownames(6): entity1 entity2 ... entity5 entity6
## rowData names(4): Kingdom Phylum Class OTU
## colnames(4): sample1 sample2 sample3 sample4
## colData names(2): gg group
## reducedDimNames(0):
## mainExpName: NULL
## altExpNames(0):
## rowLinks: a LinkDataFrame (6 rows)
## rowTree: 1 phylo tree(s) (5 leaves)
## colLinks: a LinkDataFrame (4 rows)
## colTree: 1 phylo tree(s) (4 leaves)
## referenceSeq: a DNAStringSet (6 sequences)
A TreeSummarizedExperiment
object can be subset in two different ways: [
to
subset by rows or columns, and subsetByNode
to subset by nodes of a tree. As
the numeric ID of a node changes with the cut of a phylo
tree, to keep track
of the original data, we do not update the tree structure in the subsetting.
sub_tse <- both_tse[1:2, 1]
sub_tse
## class: TreeSummarizedExperiment
## dim: 2 1
## metadata(0):
## assays(1): Count
## rownames(2): entity1 entity2
## rowData names(4): Kingdom Phylum Class OTU
## colnames(1): sample1
## colData names(2): gg group
## reducedDimNames(0):
## mainExpName: NULL
## altExpNames(0):
## rowLinks: a LinkDataFrame (2 rows)
## rowTree: 1 phylo tree(s) (5 leaves)
## colLinks: a LinkDataFrame (1 rows)
## colTree: 1 phylo tree(s) (4 leaves)
## referenceSeq: a DNAStringSet (2 sequences)
# The tree stays the same
identical(rowTree(sub_tse), rowTree(both_tse))
## [1] TRUE
rowData
, rowLinks
, colData
, and colLinks
are updated accordingly.
# the row data
rowData(sub_tse)
## DataFrame with 2 rows and 4 columns
## Kingdom Phylum Class OTU
## <character> <character> <character> <character>
## entity1 A B1 C1 D1
## entity2 A B1 C1 D2
# the row link data
rowLinks(sub_tse)
## LinkDataFrame with 2 rows and 5 columns
## nodeLab nodeLab_alias nodeNum isLeaf whichTree
## <character> <character> <integer> <logical> <character>
## entity1 t3 alias_1 1 TRUE phylo
## entity2 t3 alias_1 1 TRUE phylo
# The first four columns are from colLinks data and the others from colData
cbind(colLinks(sub_tse), colData(sub_tse))
## DataFrame with 1 row and 7 columns
## nodeLab nodeLab_alias nodeNum isLeaf whichTree gg
## <character> <character> <integer> <logical> <character> <numeric>
## sample1 sample1 alias_1 1 TRUE phylo 1
## group
## <character>
## sample1 A
To subset by nodes, we specify the node by its node label or node number. Here,
entity1 and entity2 are both mapped to the same node t3
, so both of them
are retained.
node_tse <- subsetByNode(x = both_tse, rowNode = "t3")
rowLinks(node_tse)
## LinkDataFrame with 2 rows and 5 columns
## nodeLab nodeLab_alias nodeNum isLeaf whichTree
## <character> <character> <integer> <logical> <character>
## entity1 t3 alias_1 1 TRUE phylo
## entity2 t3 alias_1 1 TRUE phylo
Subsetting simultaneously in both dimensions is also allowed.
node_tse <- subsetByNode(x = both_tse, rowNode = "t3",
colNode = c("sample1", "sample2"))
assays(node_tse)[[1]]
## sample1 sample2
## entity1 0 0
## entity2 1 6
The current tree can be replaced by a new one using changeTree
. If the
hierarchical information is available as a data.frame
with each column
representing a taxonomic level (e.g., row_data), we provide toTree
to
convert it into a phylo
object.
# The toy taxonomic table
(taxa <- rowData(both_tse))
## DataFrame with 6 rows and 4 columns
## Kingdom Phylum Class OTU
## <character> <character> <character> <character>
## entity1 A B1 C1 D1
## entity2 A B1 C1 D2
## entity3 A B2 C2 D3
## entity4 A B2 C2 D4
## entity5 A B2 C3 D5
## entity6 A B2 C3 D6
# convert it to a phylo tree
taxa_tree <- toTree(data = taxa)
# Viz the new tree
ggtree(taxa_tree)+
geom_text2(aes(label = node), color = "darkblue",
hjust = -0.5, vjust = 0.7, size = 5.5) +
geom_text2(aes(label = label), color = "darkorange",
hjust = -0.1, vjust = -0.7, size = 5.5) +
geom_point2()
A mapping to match nodes of the two trees is required if nodes are labeled differently.
taxa_tse <- changeTree(x = both_tse, rowTree = taxa_tree,
rowNodeLab = taxa[["OTU"]])
taxa_tse
## class: TreeSummarizedExperiment
## dim: 6 4
## metadata(0):
## assays(1): Count
## rownames(6): entity1 entity2 ... entity5 entity6
## rowData names(4): Kingdom Phylum Class OTU
## colnames(4): sample1 sample2 sample3 sample4
## colData names(2): gg group
## reducedDimNames(0):
## mainExpName: NULL
## altExpNames(0):
## rowLinks: a LinkDataFrame (6 rows)
## rowTree: 1 phylo tree(s) (6 leaves)
## colLinks: a LinkDataFrame (4 rows)
## colTree: 1 phylo tree(s) (4 leaves)
## referenceSeq: a DNAStringSet (6 sequences)
rowLinks(taxa_tse)
## LinkDataFrame with 6 rows and 5 columns
## nodeLab nodeLab_alias nodeNum isLeaf whichTree
## <character> <character> <integer> <logical> <character>
## entity1 D1 alias_1 1 TRUE phylo
## entity2 D2 alias_2 2 TRUE phylo
## entity3 D3 alias_3 3 TRUE phylo
## entity4 D4 alias_4 4 TRUE phylo
## entity5 D5 alias_5 5 TRUE phylo
## entity6 D6 alias_6 6 TRUE phylo
Since it may be of interest to report or analyze observed data on multiple
resolutions based on the provided tree, the TreeSummarizedExperiment
package
offers functionionality to flexibly aggregate data to different levels of a
tree.
Here, we show the aggregation along the column dimension. The desired
aggregation level is given in the colLevel
argument, which can be specified
via the node label (orange text in Figure 3) or the node
number (blue text in Figure 3). We could further specify how
to aggregate via the argument colFun
.
# use node labels to specify colLevel
agg_col <- aggTSE(x = taxa_tse,
colLevel = c("GroupA", "GroupB"),
colFun = sum)
# or use node numbers to specify colLevel
agg_col <- aggTSE(x = taxa_tse, colLevel = c(6, 7), colFun = sum)
assays(agg_col)[[1]]
## alias_6 alias_7
## entity1 0 0
## entity2 7 27
## entity3 9 29
## entity4 11 31
## entity5 13 33
## entity6 15 35
The rowData
does not change, but the colData
adjusts with the change of the
assays
table. For example, the column group has the A
value for
GroupA
because the descendant nodes of GroupA
all have the value A
; the
column gg has the NA
value for GroupA
because the descendant nodes of
GroupA
have different values, (1 and 2).
# before aggregation
colData(taxa_tse)
## DataFrame with 4 rows and 2 columns
## gg group
## <numeric> <character>
## sample1 1 A
## sample2 2 A
## sample3 3 B
## sample4 3 B
# after aggregation
colData(agg_col)
## DataFrame with 2 rows and 2 columns
## gg group
## <numeric> <character>
## alias_6 NA A
## alias_7 3 B
We can decide which columns of colData
to keep in the final output using
colDataCols
. In situation with big data, this can speed up the aggregation by
dropping data that is not relevant. More arguments for aggTSE
(e.g.,
whichAssay
, BPPARAM
) are available to customize the aggregation or to provide
parallel computation (?aggTSE
).
agg_col <- aggTSE(x = taxa_tse, colLevel = c(6, 7),
colFun = sum, colDataCols = "group")
colData(agg_col)
## DataFrame with 2 rows and 1 column
## group
## <character>
## alias_6 A
## alias_7 B
The colLinks
is updated to link the new rows of assays
tables and the column
tree.
# the link data is updated
colLinks(agg_col)
## LinkDataFrame with 2 rows and 5 columns
## nodeLab nodeLab_alias nodeNum isLeaf whichTree
## <character> <character> <integer> <logical> <character>
## alias_6 GroupA alias_6 6 FALSE phylo
## alias_7 GroupB alias_7 7 FALSE phylo
From Figure 3, nodes 6 and 7 are
labeled with GroupA
and GroupB
, respectively, which agrees with the
column link data.
Similarly, we could aggregate the data to the phylum level by providing the
names of the internal nodes that represent the phylum level (see taxa_one
below).
# the phylum level
taxa <- c(taxa_tree$tip.label, taxa_tree$node.label)
(taxa_one <- taxa[startsWith(taxa, "Phylum:")])
## [1] "Phylum:B1" "Phylum:B2"
# aggregation
agg_taxa <- aggTSE(x = taxa_tse, rowLevel = taxa_one, rowFun = sum)
assays(agg_taxa)[[1]]
## sample1 sample2 sample3 sample4
## alias_8 1 6 11 16
## alias_10 14 34 54 74
The user is nonetheless free to choose nodes from different taxonomic ranks. Note that not all rows in the original table are included in one of the aggregated rows. Similarly, it is possible for a row to contribute to multiple aggregated rows
# A mixed level
taxa_mix <- c("Class:C3", "Phylum:B1")
agg_any <- aggTSE(x = taxa_tse, rowLevel = taxa_mix, rowFun = sum)
rowData(agg_any)
## DataFrame with 2 rows and 4 columns
## Kingdom Phylum Class OTU
## <character> <character> <character> <logical>
## alias_12 A B2 C3 NA
## alias_8 A B1 C1 NA
The aggregation on both dimensions could be performed in one step using
aggTSE
. The aggregate functions for the row and the column are specificed via
rowFun
and colFun
, respectively. The aggregation order is determined using
rowFirst
. Here, we set rowFirst = FALSE
to firstly aggregate on the column
dimension, and then on the row dimension.
agg_both <- aggTSE(x = both_tse, colLevel = c(6, 7),
rowLevel = 7:9, rowFun = sum,
colFun = mean, rowFirst = FALSE)
As expected, we obtain a table with 3 rows (rowLevel = 7:9
) and 2 columns
(colLevel = c(6, 7)
).
assays(agg_both)[[1]]
## alias_6 alias_7
## alias_7 8.0 28.0
## alias_8 19.5 49.5
## alias_9 12.0 32.0
phylo
object.Next, we highlight some functions to manipulate and/or to extract information
from the phylo
object. Further operations can be found in other packages, such
as ape (Paradis and Schliep 2019), tidytree(Yu 2020). These
functions are useful when users want to customize functions for the
TreeSummarizedExperiment
class.
To show these functions, we use the tree shown in Figure 5.
data("tinyTree")
ggtree(tinyTree, branch.length = "none") +
geom_text2(aes(label = label), hjust = -0.1, size = 5.5) +
geom_text2(aes(label = node), vjust = -0.8,
hjust = -0.2, color = 'orange', size = 5.5)
The translation between the node labels and node numbers can be achieved by the function convertNode
.
convertNode(tree = tinyTree, node = c(12, 1, 4))
## [1] "Node_12" "t2" "t9"
convertNode(tree = tinyTree, node = c("t4", "Node_18"))
## t4 Node_18
## 5 18
To get descendants that are at the leaf level, we could set the argument
only.leaf = TRUE
for the function findDescendant
.
# only the leaf nodes
findDescendant(tree = tinyTree, node = 17, only.leaf = TRUE)
## $Node_17
## [1] 4 5 6
When only.leaf = FALSE
, all descendants are returned.
# all descendant nodes
findDescendant(tree = tinyTree, node = 17, only.leaf = FALSE)
## $Node_17
## [1] 4 5 6 18
We list some functions that might also be useful in Table 1. More are available in the package, and we encourage users to contribute their functions that might be helpful for others.
Functions | Goal |
---|---|
printNode | print out the information of nodes |
countNode | count the number of nodes |
distNode | give the distance between a pair of nodes |
matTree | list paths of a tree |
findAncestor | find ancestor nodes |
findChild | find child nodes |
findSibling | find sibling nodes |
shareNode | find the first node shared in the paths of nodes to the root |
unionLeaf | find the union of descendant leaves |
trackNode | track nodes by adding alias labels to a phylo object |
isLeaf | test whether a node is a leaf node |
TreeSummarizedExperiment
classHere, we show an example on how to write custom functions for
TreeSummarizedExperiment
objects. To extract data of specific leaves, we
created a function subsetByLeaf
by combining functions working on the phylo
class (e.g., convertNode
, keep.tip
, trackNode
, isLeaf
) with the accessor
function subsetByNode
. Here, convertNode
, trackNode
and isLeaf
are
available in TreeSummarizedExperiment
, and keep.tip
is from the r CRANpkg("ape")
package. Since the node number of a node is changed after
pruning a tree with keep.tip
, trackNode
is provided to track the node and
further update the link between the data and the new tree.
# tse: a TreeSummarizedExperiment object
# rowLeaf: specific leaves
subsetByLeaf <- function(tse, rowLeaf) {
# if rowLeaf is provided as node labels, convert them to node numbers
if (is.character(rowLeaf)) {
rowLeaf <- convertNode(tree = rowTree(tse), node = rowLeaf)
}
# subset data by leaves
sse <- subsetByNode(tse, rowNode = rowLeaf)
# update the row tree
## -------------- new tree: drop leaves ----------
oldTree <- rowTree(sse)
newTree <- ape::keep.tip(phy = oldTree, tip = rowLeaf)
## -------------- update the row link ----------
# track the tree
track <- trackNode(oldTree)
track <- ape::keep.tip(phy = track, tip = rowLeaf)
# row links
rowL <- rowLinks(sse)
rowL <- DataFrame(rowL)
# update the row links:
# 1. use the alias label to track and updates the nodeNum
# 2. the nodeLab should be updated based on the new tree using the new
# nodeNum
# 3. lastly, update the nodeLab_alias
rowL$nodeNum <- convertNode(tree = track, node = rowL$nodeLab_alias,
message = FALSE)
rowL$nodeLab <- convertNode(tree = newTree, node = rowL$nodeNum,
use.alias = FALSE, message = FALSE)
rowL$nodeLab_alias <- convertNode(tree = newTree, node = rowL$nodeNum,
use.alias = TRUE, message = FALSE)
rowL$isLeaf <- isLeaf(tree = newTree, node = rowL$nodeNum)
rowNL <- new("LinkDataFrame", rowL)
## update the row tree and links
BiocGenerics:::replaceSlots(sse,
rowLinks = rowNL,
rowTree = list(phylo = newTree))
}
The row tree is updated after the subsetting. It now has only two leaves, t2
and t3
.
(both_sse <- subsetByLeaf(tse = both_tse, rowLeaf = c("t2", "t3")))
## class: TreeSummarizedExperiment
## dim: 3 4
## metadata(0):
## assays(1): Count
## rownames(3): entity1 entity2 entity3
## rowData names(4): Kingdom Phylum Class OTU
## colnames(4): sample1 sample2 sample3 sample4
## colData names(2): gg group
## reducedDimNames(0):
## mainExpName: NULL
## altExpNames(0):
## rowLinks: a LinkDataFrame (3 rows)
## rowTree: 1 phylo tree(s) (2 leaves)
## colLinks: a LinkDataFrame (4 rows)
## colTree: 1 phylo tree(s) (4 leaves)
## referenceSeq: a DNAStringSet (3 sequences)
rowLinks(both_sse)
## LinkDataFrame with 3 rows and 5 columns
## nodeLab nodeLab_alias nodeNum isLeaf whichTree
## <character> <character> <integer> <logical> <character>
## entity1 t3 alias_1 1 TRUE phylo
## entity2 t3 alias_1 1 TRUE phylo
## entity3 t2 alias_2 2 TRUE phylo
sessionInfo()
## R version 4.2.0 RC (2022-04-19 r82224)
## Platform: x86_64-pc-linux-gnu (64-bit)
## Running under: Ubuntu 20.04.4 LTS
##
## Matrix products: default
## BLAS: /home/biocbuild/bbs-3.15-bioc/R/lib/libRblas.so
## LAPACK: /home/biocbuild/bbs-3.15-bioc/R/lib/libRlapack.so
##
## locale:
## [1] LC_CTYPE=en_US.UTF-8 LC_NUMERIC=C
## [3] LC_TIME=en_GB LC_COLLATE=C
## [5] LC_MONETARY=en_US.UTF-8 LC_MESSAGES=en_US.UTF-8
## [7] LC_PAPER=en_US.UTF-8 LC_NAME=C
## [9] LC_ADDRESS=C LC_TELEPHONE=C
## [11] LC_MEASUREMENT=en_US.UTF-8 LC_IDENTIFICATION=C
##
## attached base packages:
## [1] stats4 stats graphics grDevices utils datasets methods
## [8] base
##
## other attached packages:
## [1] ggplot2_3.3.5 ggtree_3.4.0
## [3] ape_5.6-2 TreeSummarizedExperiment_2.4.0
## [5] Biostrings_2.64.0 XVector_0.36.0
## [7] SingleCellExperiment_1.18.0 SummarizedExperiment_1.26.0
## [9] Biobase_2.56.0 GenomicRanges_1.48.0
## [11] GenomeInfoDb_1.32.0 IRanges_2.30.0
## [13] S4Vectors_0.34.0 BiocGenerics_0.42.0
## [15] MatrixGenerics_1.8.0 matrixStats_0.62.0
## [17] BiocStyle_2.24.0
##
## loaded via a namespace (and not attached):
## [1] sass_0.4.1 tidyr_1.2.0 jsonlite_1.8.0
## [4] bslib_0.3.1 assertthat_0.2.1 BiocManager_1.30.17
## [7] highr_0.9 yulab.utils_0.0.4 GenomeInfoDbData_1.2.8
## [10] yaml_2.3.5 pillar_1.7.0 lattice_0.20-45
## [13] glue_1.6.2 digest_0.6.29 colorspace_2.0-3
## [16] ggfun_0.0.6 htmltools_0.5.2 Matrix_1.4-1
## [19] pkgconfig_2.0.3 magick_2.7.3 bookdown_0.26
## [22] zlibbioc_1.42.0 purrr_0.3.4 patchwork_1.1.1
## [25] tidytree_0.3.9 scales_1.2.0 ggplotify_0.1.0
## [28] BiocParallel_1.30.0 tibble_3.1.6 farver_2.1.0
## [31] generics_0.1.2 ellipsis_0.3.2 withr_2.5.0
## [34] lazyeval_0.2.2 cli_3.3.0 magrittr_2.0.3
## [37] crayon_1.5.1 evaluate_0.15 fansi_1.0.3
## [40] nlme_3.1-157 tools_4.2.0 lifecycle_1.0.1
## [43] stringr_1.4.0 aplot_0.1.3 munsell_0.5.0
## [46] DelayedArray_0.22.0 compiler_4.2.0 jquerylib_0.1.4
## [49] gridGraphics_0.5-1 rlang_1.0.2 grid_4.2.0
## [52] RCurl_1.98-1.6 labeling_0.4.2 bitops_1.0-7
## [55] rmarkdown_2.14 gtable_0.3.0 DBI_1.1.2
## [58] R6_2.5.1 knitr_1.38 dplyr_1.0.8
## [61] fastmap_1.1.0 utf8_1.2.2 treeio_1.20.0
## [64] stringi_1.7.6 parallel_4.2.0 Rcpp_1.0.8.3
## [67] vctrs_0.4.1 tidyselect_1.1.2 xfun_0.30
Lun, Aaron, and Davide Risso. 2020. “SingleCellExperiment: S4 Classes for Single Cell Data.”
Paradis, E, and K Schliep. 2019. “ape 5.0: an environment for modern phylogenetics and evolutionary analyses in R.” Bioinformatics 35: 526–28.
Wang, Li-Gen, Tommy Tsan-Yuk Lam, Shuangbin Xu, Zehan Dai, Lang Zhou, Tingze Feng, Pingfan Guo, et al. 2019. “Treeio: An R Package for Phylogenetic Tree Input and Output with Richly Annotated and Associated Data.” Molecular Biology and Evolution 37 (2): 599–603. https://doi.org/10.1093/molbev/msz240.
Yu, Guangchuang. 2020. tidytree: A Tidy Tool for Phylogenetic Tree Data Manipulation.
Yu, Guangchuang, David K. Smith, Huachen Zhu, Yi Guan, and Tommy Tsan Yuk Lam. 2017. “Ggtree: An R Package for Visualization and Annotation of Phylogenetic Trees with Their Covariates and Other Associated Data.” Methods in Ecology and Evolution 8 (1): 28–36.