--- title: '*TreeAndLeaf*: A graph layout strategy for binary trees with focus on the leaves' author: 'Milena A Cardoso, Luis E A Rizzardi, Leonardo W Kume, Sheyla Trefflich, Clarice Groeneveld, Mauro A A Castro' date: "`r BiocStyle::doc_date()`" abstract: "The **TreeAndLeaf** package combines tree and force-directed layout algorithms for drawing binary trees, aiming to represent multiple layers of information onto the leaves." package: "`r BiocStyle::pkg_ver('TreeAndLeaf')`" output: BiocStyle::html_document: css: custom.css vignette: > %\VignetteIndexEntry{TreeAndLeaf: an graph layout to dendrograms.} %\VignetteEngine{knitr::rmarkdown} %\VignetteEncoding{UTF-8} --- ```{r, include = FALSE} knitr::opts_chunk$set( collapse = TRUE, comment = "#>" ) ``` # Overview A dendrogram diagram displays binary trees focused on representing hierarchical relations between the tree elements. A dendrogram contains nodes, branches (edges), a root, and leaves (**Figure 1A**). The root is where the branches and nodes come from, indicating the direction to the leaves, *i.e.*, the terminal nodes. Most of the space of a dendrogram layout is used to arrange branches and inner nodes, with limited space to the leaves. For large dendrograms, the leaf labels are often squeezed to fit into small slots. Therefore, a dendrogram may not provide the best layout when the information to be displayed should highlight the leaves. The **TreeAndLeaf** package aims to improve the visualization of the dendrogram leaves by combining tree and force-directed layout algorithms, shifting the focus of analysis to the leaves (**Figure 1B**). The package's workflow is summarized in **Figure 1C**.

**Figure 1**. **TreeAndLeaf** workflow summary. **(A,B)** The dendrogram in A is used to construct the graph in B. **(C)** The main input for the **TreeAndLeaf** package consists of a dendrogram, and then the package transforms the dendrogram into a graph representation. The finest graph layout is achieved by a two-steps process, starting with an unrooted tree diagram, which is subsequently relaxed by a force-directed algorithm applied to the terminal nodes of the tree. The final *tree-and-leaf* layout varies depending on the initial state, which can be obtained by other tree layout algorithms (see *section 3* for examples using *ggtree* layouts to setup the initial state). # Quick Start This section provides a basic example using the R built-in `USArrests` dataset. The `USArrests` is a dataframe available in the user's workspace. To know more about this dataframe, please query `?USArrests` in the R console. We will build a dendrogram from the `USArrests` dataset, then transform the dendrogram into a *tree-and-leaf* diagram, and the result will be visualized in the **RedeR** application. ## Package and data requirements ```{r, eval=TRUE, message=FALSE} #-- Libraries required in this section: #-- TreeAndLeaf(>=1.4.2), RedeR(>=1.40.4), Bioconductor >= 3.13 (R >= 4.0) # BiocManager::install(c("TreeAndLeaf","RedeR")) # install.packages(c("igraph","RColorBrewer")) #-- Load packages library("TreeAndLeaf") library("RedeR") library("igraph") library("RColorBrewer") ``` ```{r, eval=TRUE, message=FALSE} #-- Check data dim(USArrests) head(USArrests) ``` ## Building a dendrogram example In order to build a dendrogram from the `USArrests` dataset, we need a distance matrix. We will use the default "euclidean distance" method from the `dist()` function, and then the "average" method from `hclust()` function to create the dendrogram. ```{r, eval=TRUE, message=FALSE} hc <- hclust(dist(USArrests), "ave") plot(hc, main="Dendrogram for the 'USArrests' dataset", xlab="", sub="") ``` ## Converting the *hclust* object into a *tree-and-leaf* object The `treeAndLeaf` function will transform the *hclust* into an *igraph* object, including some basic graph attributes to display in the **RedeR** application. ```{r, eval=FALSE} #-- Convert the 'hclust' object into a 'tree-and-leaf' object tal <- treeAndLeaf(hc) ``` ## Setting graph attributes The `att.mapv()` function can be used to add external annotations to an *igraph* object, for example, mapping new variables to the graph vertices. We will add all `USArrests` variables to the `tal` object. To map one object to another it is essential to use the same mapping IDs, set by the `refcol` parameter, which points to a column in the input annotation dataset. In this example, `refcol = 0` indicates that the `USArrests` rownames will be used as mapping IDs. To check the IDs in the *igraph* vertices, please type `V(tal)$name` in the R console. ```{r, eval=FALSE} #--- Map attributes to the tree-and-leaf #Note: 'refcol = 0' indicates that 'dat' rownames will be used as mapping IDs tal <- att.mapv(g = tal, dat = USArrests, refcol = 0) ``` Now we use the `att.setv()` wrapper function to set attributes in the *tree-and-leaf* diagram. To see all attributes available to display in the **RedeR** application, please type `?addGraph` in the R console. The graph attributes can also be customized following **igraph** syntax rules. ```{r, eval=FALSE} #--- Set graph attributes using the 'att.setv' wrapper function pal <- brewer.pal(9, "Reds") tal <- att.setv(g = tal, from = "Murder", to = "nodeColor", cols = pal, nquant = 5) tal <- att.setv(g = tal, from = "UrbanPop", to = "nodeSize", xlim = c(10, 50, 5), nquant = 5) #--- Set graph attributes using 'att.addv' and 'att.adde' functions tal <- att.addv(tal, "nodeFontSize", value = 15, index = V(tal)$isLeaf) tal <- att.adde(tal, "edgeWidth", value = 3) ``` ## Plotting a *tree-and-leaf* diagram The next steps will call the **RedeR** application, and then display the *tree-and-leaf* diagram in an interactive R/Java interface. The initial layout will show an unrooted tree diagram, which will be subsequently relaxed by a force-directed algorithm applied to the terminal nodes of the tree. ```{r, eval=FALSE} #--- Call RedeR application rdp <- RedPort() calld(rdp) resetd(rdp) ``` ```{r, eval=FALSE} #--- Send the tree-and-leaf to the interactive R/Java interface addGraph(obj = rdp, g = tal, gzoom=75) #--- Call 'relax' to fine-tune the leaf nodes relax(rdp, p1=25, p2=200, p3=5, p5=5, ps=TRUE) ``` At this point, the user can interact with the layout process to achieve the best or desired layout; we suggest fine-tuning the force-directed algorithm parameters, either through the R/Java interface or the command line relaxation function. Note that the unroot tree diagram represents the initial state; then a relaxing process should start until the finest graph layout is achieved. The final layout varies depending on the initial state, which can also be adjusted by providing more or less room for the spatial configuration (*e.g.* via `gzoom` parameter). ```{r, eval=FALSE} #--- Add legends addLegend.color(obj = rdp, tal, title = "Murder Rate", position = "topright") addLegend.size(obj = rdp, tal, title = "Urban Population Size", position = "bottomright") ```

# Setting the initial *tree-and-leaf* state with *ggtree* layouts The tree diagram represents the initial state of a *tree-and-leaf*, which is then relaxed by a force-directed algorithm applied to the terminal nodes. Therefore, the final *tree-and-leaf* layout varies depending on the initial state. The **treeAndLeaf** package also accepts `ggtree` layouts to setup the initial state. For example, next we show a tree diagram generated by the **ggtree** package, and then we apply the *tree-and-leaf* transformation. ## Package and data requirements ```{r, eval=FALSE, message=FALSE} #-- Libraries required in this section: #-- TreeAndLeaf(>=1.4.2), RedeR(>=1.40.4), Bioconductor >= 3.13 (R >= 4.0) # BiocManager::install(c("TreeAndLeaf","RedeR","ggtree)) # install.packages(c("igraph","ape", "dendextend", "dplyr", # "ggplot2", "RColorBrewer")) #-- Load packages library("TreeAndLeaf") library("RedeR") library("igraph") library("ape") library("ggtree") library("dendextend") library("dplyr") library("ggplot2") library("RColorBrewer") ``` ## Building and plotting a *phylo* tree with *ggtree* layouts ```{r, eval=FALSE} #--- Generate a random phylo tree phylo_tree <- rcoal(300) #--- Set groups and node sizes group <- size <- dendextend::cutree(phylo_tree, 10) group[] <- LETTERS[1:10][group] size[] <- sample(size) group.df <- data.frame(label=names(group), group=group, size=size) phylo_tree <- dplyr::full_join(phylo_tree, group.df, by='label') #--- Generate a ggtree with 'daylight' layout pal <- brewer.pal(10, "Set3") ggt <- ggtree(phylo_tree, layout = 'daylight', branch.length='none') #--- Plot the ggtree ggt + geom_tippoint(aes(color=group, size=size)) + scale_color_manual(values=pal) + scale_y_reverse() ``` ## Applying *tree-and-leaf* transformation to *ggtree* layouts ```{r, eval=FALSE} #-- Convert the 'ggtree' object into a 'tree-and-leaf' object tal <- treeAndLeaf(ggt) #--- Map attributes to the tree-and-leaf #Note: 'refcol = 1' indicates that 'dat' col 1 will be used as mapping IDs tal <- att.mapv(g = tal, dat = group.df, refcol = 1) #--- Set graph attributes using the 'att.setv' wrapper function tal <- att.setv(g = tal, from = "group", to = "nodeColor", cols = pal) tal <- att.setv(g = tal, from = "size", to = "nodeSize", xlim = c(10, 50, 5)) #--- Set graph attributes using 'att.addv' and 'att.adde' functions tal <- att.addv(tal, "nodeFontSize", value = 1) tal <- att.addv(tal, "nodeLineWidth", value = 0) tal <- att.addv(tal, "nodeColor", value = "black", index=!V(tal)$isLeaf) tal <- att.adde(tal, "edgeWidth", value = 3) tal <- att.adde(tal, "edgeColor", value = "black") ``` ```{r, eval=FALSE} #--- Call RedeR application rdp <- RedPort() calld(rdp) resetd(rdp) ``` ```{r, eval=FALSE} #--- Send the tree-and-leaf to the interactive R/Java interface addGraph(obj = rdp, g = tal, gzoom=50) #--- Select inner nodes, preventing them from relaxing selectNodes(rdp, V(tal)$name[!V(tal)$isLeaf], anchor=TRUE) #--- Call 'relax' to fine-tune the leaf nodes relax(rdp, p1=25, p2=100, p3=5, p5=1, p8=5, ps=TRUE) #--- Add legends addLegend.color(obj = rdp, tal, title = "Group", position = "topright",vertical=T) addLegend.size(obj = rdp, tal, title = "Size", position = "topleft", vertical=T, dxtitle=10) ```

# Case Study 1: visualizing a large dendrogram ## Context This section follows the same steps described in the *Quick Start*, but using a larger dendrogram derived from the R built-in `quakes` dataset. The `quakes` is a dataframe available in the user's workspace. To know more about this dataframe, please query `?quakes` in the R console. We will build a dendrogram from the `quakes` dataset, then transform the dendrogram into a *tree-and-leaf* diagram, and the result will be visualized in the **RedeR** application. ## Package and data requirements ```{r, eval=FALSE, message=FALSE} #-- Libraries required in this section: #-- TreeAndLeaf(>=1.4.2), RedeR(>=1.40.4), Bioconductor >= 3.13 (R >= 4.0) # BiocManager::install(c("TreeAndLeaf","RedeR")) # install.packages(c("igraph", "RColorBrewer")) #-- Load packages library(TreeAndLeaf) library(RedeR) library(igraph) library(RColorBrewer) ``` ```{r echo=TRUE} #-- Check data dim(quakes) head(quakes) ``` ```{r, eval=TRUE, message=FALSE} #-- Building a large dendrogram hc <- hclust(dist(quakes), "ave") plot(hc, main="Dendrogram for the 'quakes' dataset", xlab="", sub="") ``` ## Building and plotting a large *tree-and-leaf* diagram ```{r, eval=FALSE} #-- Convert the 'hclust' object into a 'tree-and-leaf' object tal <- treeAndLeaf(hc) ``` ```{r, eval=FALSE} #--- Map attributes to the tree-and-leaf #Note: 'refcol = 0' indicates that 'dat' rownames will be used as mapping IDs tal <- att.mapv(tal, quakes, refcol = 0) #--- Set graph attributes using the 'att.setv' wrapper function pal <- brewer.pal(9, "Greens") tal <- att.setv(g = tal, from = "mag", to = "nodeColor", cols = pal, nquant = 10) tal <- att.setv(g = tal, from = "depth", to = "nodeSize", xlim = c(40, 120, 20), nquant = 5) #--- Set graph attributes using 'att.addv' and 'att.adde' functions tal <- att.addv(tal, "nodeFontSize", value = 1) tal <- att.adde(tal, "edgeWidth", value = 10) ``` The next steps will call the **RedeR** application, and then display the *tree-and-leaf* diagram in an interactive R/Java interface. The initial layout will show an unrooted tree diagram, which will be subsequently relaxed by a force-directed algorithm applied to the terminal nodes of the tree. ```{r, eval=FALSE} #--- Call RedeR application rdp <- RedPort() calld(rdp) resetd(rdp) ``` ```{r, eval=FALSE} #--- Send the tree-and-leaf to the interactive R/Java interface addGraph(obj = rdp, g = tal, gzoom=10) #--- Call 'relax' to fine-tune the leaf nodes relax(rdp, p1=25, p2=200, p3=10, p4=100, p5=10, ps=TRUE) ``` ```{r, eval=FALSE} #--- Add legends addLegend.color(obj = rdp, tal, title = "Richter Magnitude", position = "bottomright") addLegend.size(obj = rdp, tal, title = "Depth (km)") ```

# Case Study 2: visualizing a phylogenetic tree ## Context This section generates a *tree-and-leaf* diagram from a pre-computed `phylo` tree object. We will use a phylogenetic tree listing 121 eukaryotes, available from the **geneplast** package. ## Package and data requirements ```{r, eval=TRUE, message=FALSE} #-- Libraries required in this section: #-- TreeAndLeaf(>=1.4.2), RedeR(>=1.40.4), Bioconductor >= 3.13 (R >= 4.0) # BiocManager::install(c("TreeAndLeaf","RedeR","geneplast)) # install.packages(c("igraph","ape", "RColorBrewer")) #-- Load packages library(TreeAndLeaf) library(RedeR) library(igraph) library(ape) library(geneplast) library(RColorBrewer) ``` ```{r, eval=TRUE, message=FALSE} #-- Load data and plot the phylogenetic tree data("spdata") data("gpdata.gs") plot(phyloTree) ``` ## Building and plotting a *tree-and-leaf* from a phylogenetic tree ```{r, eval=FALSE} #--- Drop organisms not listed in the 'spdata' annotation phyloTree$tip.label <- as.character(phyloTree$tip.label) tokeep <- phyloTree$tip.label %in% spdata$tax_id pruned.phylo <- drop.tip(phyloTree, phyloTree$tip.label[!tokeep]) ``` ```{r, eval=FALSE} #-- Convert the phylogenetic tree into a 'tree-and-leaf' object tal <- treeAndLeaf(pruned.phylo) #--- Map attributes to the tree-and-leaf #Note: 'refcol = 1' indicates that 'dat' col 1 will be used as mapping IDs tal <- att.mapv(g = tal, dat = spdata, refcol = 1) #--- Set graph attributes using the 'att.setv' wrapper function pal <- brewer.pal(9, "Purples") tal <- att.setv(g = tal, from = "genome_size_Mb", to = "nodeSize", xlim = c(120, 250, 1), nquant = 5) tal <- att.setv (g = tal, from = "proteins", to = "nodeColor", nquant = 5, cols = pal, na.col = "black") ``` ```{r, eval=FALSE} #--- Add graph attributes using 'att.adde' and 'att.addv' functions tal <- att.addv(tal, "nodeFontSize", value = 10) tal <- att.adde(tal, "edgeWidth", value = 20) # Set species names to 'nodeAlias' attribute tal <- att.setv(tal, from = "sp_name", to = "nodeAlias") # Select a few names to highlight in the graph tal <- att.addv(tal, "nodeFontSize", value = 100, filter=list('name'=sample(pruned.phylo$tip.label,30))) tal <- att.addv(tal, "nodeFontSize", value = 100, filter=list('name'="9606")) #Homo sapiens ``` ```{r, eval=FALSE} # Call RedeR rdp <- RedPort() calld(rdp) resetd(rdp) #--- Send the tree-and-leaf to the interactive R/Java interface addGraph(obj = rdp, g = tal, gzoom=10) #--- Call 'relax' to fine-tune the leaf nodes relax(rdp, ps=TRUE) ``` ```{r, eval=FALSE} #--- Add legends addLegend.color(rdp, tal, title = "Proteome Size (n)") addLegend.size(rdp, tal, title = "Genome Size (Mb)") ```

# Case Study 3: visualizing a non-binary tree ## Context The **TreeAndLeaf** package is designed to layout binary trees, but it can also layout other graph configurations. To exemplify this case, we will use a larger phylogenetic tree available from the **geneplast** package, and for which some inner nodes have more than two children, or non-binary nodes. ## Package and data requirements ```{r, eval=FALSE} #-- Libraries required in this section: #-- TreeAndLeaf(>=1.4.2), RedeR(>=1.40.4), Bioconductor >= 3.13 (R >= 4.0) # BiocManager::install(c("TreeAndLeaf","RedeR","geneplast)) # install.packages(c("igraph","ape", "RColorBrewer")) #-- Load packages library(TreeAndLeaf) library(RedeR) library(igraph) library(ape) library(geneplast) library(RColorBrewer) ``` ```{r, eval=FALSE, message=FALSE} #-- Load data data("spdata") data("phylo_tree") ``` ```{r, eval=FALSE, message=FALSE} #--- Drop organisms not listed in the 'spdata' annotation tokeep <- phylo_tree$tip.label %in% spdata$tax_id pruned.phylo <- drop.tip(phylo_tree, phylo_tree$tip.label[!tokeep]) ``` ## Building and plotting a *tree-and-leaf* for a non-binary tree ```{r, eval=FALSE} #-- Convert the phylogenetic tree into a 'tree-and-leaf' object tal <- treeAndLeaf(pruned.phylo) ``` ```{r, eval=FALSE} #--- Map attributes to the tree-and-leaf using "%>%" operator tal <- tal %>% att.mapv(dat = spdata, refcol = 1) %>% att.setv(from = "genome_size_Mb", to = "nodeSize", xlim = c(120, 250, 1), nquant = 5) %>% att.setv(from = "proteins", to = "nodeColor", nquant = 5, cols = brewer.pal(9, "Blues"), na.col = "black") %>% att.setv(from = "sp_name", to = "nodeAlias") %>% att.adde(to = "edgeWidth", value = 20) %>% att.addv(to = "nodeFontSize", value = 10) %>% att.addv(to = "nodeFontSize", value = 100, filter = list("name" = sample(pruned.phylo$tip.label, 30))) %>% att.addv(to = "nodeFontSize", value = 100, filter = list("name" = "9606")) ``` ```{r, eval=FALSE} # Call RedeR rdp <- RedPort() calld(rdp) resetd(rdp) #--- Send the tree-and-leaf to the interactive R/Java interface addGraph(obj = rdp, g = tal, gzoom=5) #--- Call 'relax' to fine-tune the leaf nodes relax(rdp, ps=TRUE) ``` ```{r, eval=FALSE} #--- Add legends addLegend.color(rdp, tal, title = "Proteome Size (n)") addLegend.size(rdp, tal, title = "Genome size (Mb)") ```

# Session information ```{r label='Session information', eval=TRUE, echo=FALSE} sessionInfo() ```