R/network_visualization.R
In almeidasilvaf/BioNERO: Biological Network Reconstruction Omnibus
Defines functions
plot_gcn
plot_grn
plot_ppi
detect_communities
Documented in
detect_communities
plot_gcn
plot_grn
plot_ppi
#' Detect communities in a network
#'
#' @param edgelist Data frame containing the network as an edge list.
#' First column must be node 1 and second column must be node 2.
#' Additional columns will be interpreted as edge attributes and will
#' be modified by this function.
#' @param method igraph function to be used for community detection.
#' Available functions are cluster_infomap, cluster_edge_betweenness,
#' cluster_fast_greedy, cluster_walktrap, cluster_spinglass,
#' cluster_leading_eigen, cluster_louvain, and cluster_label_prop.
#' Default is cluster_infomap.
#' @param directed Logical indicating whether the network is directed (GRN only)
#' or not (GCN and PPI networks). Default: TRUE.
#' @return A data frame containing node names in the first column, and
#' communities to which nodes belong in the second column.
#' @seealso
#' \code{\link[igraph]{cluster_infomap}},
#' \code{\link[igraph]{cluster_edge_betweenness}},
#' \code{\link[igraph]{cluster_fast_greedy}},
#' \code{\link[igraph]{cluster_walktrap}},
#' \code{\link[igraph]{cluster_spinglass}},
#' \code{\link[igraph]{cluster_leading_eigen}},
#' \code{\link[igraph]{cluster_louvain}},
#' \code{\link[igraph]{cluster_label_prop}}
#' @rdname detect_communities
#' @author Fabricio Almeida-Silva
#' @export
#' @importFrom igraph graph_from_data_frame simplify cluster_infomap
#' cluster_edge_betweenness cluster_fast_greedy
#' cluster_walktrap cluster_spinglass cluster_leading_eigen
#' cluster_louvain cluster_label_prop
#' @examples
#' data(filt.se)
#' tfs <- sample(rownames(filt.se), size=50, replace=FALSE)
#' grn_edges <- grn_infer(filt.se, method = "clr", regulators = tfs)
#' com <- detect_communities(grn_edges, directed=TRUE)
detect_communities <- function(edgelist,
method = igraph::cluster_infomap,
directed = TRUE) {
graph <- igraph::graph_from_data_frame(edgelist, directed = directed)
graph <- igraph::simplify(graph)
com <- method(graph, modularity = FALSE)
df_com <- as.data.frame(list(names = com$names, mem = com$membership))
return(df_com)
}
#' Plot protein-protein interaction network from edge list
#'
#' @param edgelist_int Data frame containing the edge list for the PPI network.
#' First column is the protein 1 and second column is the protein 2.
#' All other columns are interpreted as edge attributes.
#' @param color_by How should nodes be colored? It must be either "community" or
#' a 2-column data frame containing proteins in the first column and a
#' custom annotation in the second column. If "community", a clustering
#' algorithm will be applied. Default: "community".
#' @param clustering_method igraph function to be used for community detection.
#' Available functions are cluster_infomap, cluster_edge_betweenness,
#' cluster_fast_greedy, cluster_walktrap, cluster_spinglass,
#' cluster_leading_eigen, cluster_louvain, and cluster_label_prop.
#' Default is cluster_infomap.
#' @param show_labels Character indicating which nodes will be labeled.
#' One of "all", "allhubs", "tophubs", or "none".
#' @param top_n_hubs Number of top hubs to be labeled. It is only valid
#' if \code{show_labels} equals "tophubs". Default is 5.
#' @param add_color_legend Logical indicating whether to add a color legend
#' for nodes. Default: TRUE.
#' @param curvature Numeric indicating the amount of curvature in edges.
#' Negative values produce left-hand curves, positive values produce right-hand
#' curves, and zero produces a straight line. Default: 0.
#' @param interactive Logical indicating whether the network should be
#' interactive or not. Default is FALSE.
#' @param dim_interactive Numeric vector with width and height of window
#' for interactive plotting. Default: c(600,600).
#'
#' @return A ggplot object.
#' @rdname plot_ppi
#' @author Fabricio Almeida-Silva
#' @export
#' @importFrom igraph graph_from_data_frame degree simplify vcount
#' @importFrom ggnetwork ggnetwork geom_edges geom_nodes geom_nodetext
#' theme_blank geom_nodelabel_repel unit
#' @importFrom ggplot2 ggplot aes guides
#' @import intergraph
#' @examples
#' ppi_edges <- igraph::sample_pa(n = 500)
#' ppi_edges <- igraph::as_edgelist(ppi_edges)
#' p <- plot_ppi(ppi_edges, add_color_legend = FALSE)
plot_ppi <- function(edgelist_int, color_by = "community",
clustering_method = igraph::cluster_infomap,
show_labels = "tophubs",
top_n_hubs = 5,
add_color_legend=TRUE, curvature = 0,
interactive = FALSE, dim_interactive = c(600, 600)) {
requireNamespace("intergraph", quietly=TRUE)
# How should genes be colored?
if(is.data.frame(color_by)) {
prot_annotation <- color_by # color by custom annotation
} else {
prot_annotation <- detect_communities(edgelist_int,
method = clustering_method,
directed = FALSE)
}
# Get degree of nodes and find hubs
h <- get_hubs_ppi(edgelist_int, return_degree = TRUE)
# Create a data frame of nodes and node attributes
protIDs <- unique(c(as.character(edgelist_int[,1]), as.character(edgelist_int[,2])))
nod_at <- data.frame(Protein = protIDs)
nod_at$Class <- as.factor(prot_annotation[prot_annotation[,1] %in% nod_at$Protein, 2])
nod_at$Degree <- h$Degree$Degree[h$Degree$Protein %in% nod_at$Protein]
nod_at$isHub <- ifelse(nod_at$Protein %in% h$Hubs$Protein, TRUE, FALSE)
nod_at <- nod_at[order(nod_at$Class, -nod_at$Degree), ]
# Should the network be interactive?
if(interactive) {
if(!requireNamespace("networkD3", quietly = TRUE)) {
stop("`interactive = TRUE` requires the 'networkD3' package.")
}
graph <- igraph::graph_from_data_frame(d = edgelist_int,
vertices = nod_at, directed=FALSE)
graph <- igraph::simplify(graph)
graph_d3 <- networkD3::igraph_to_networkD3(graph, group = nod_at$Class)
graph_d3$nodes <- merge(
graph_d3$nodes, nod_at, by.x = "name", by.y = "Protein", sort = FALSE
)
d <- dim_interactive
p <- networkD3::forceNetwork(
Links = graph_d3$links, Nodes = graph_d3$nodes,
Source = 'source', Target = 'target',
NodeID = 'name', Group = 'group',
Nodesize = 'Degree', height = d[2], width = d[1],
opacity=0.8, zoom = TRUE, fontSize = 20
)
} else { #Static network
# Define plotting parameters
if(nlevels(nod_at$Class) <= 20) {
palette <- custom_palette(1)
} else {
n <- nlevels(nod_at$Class)
palette <- colorRampPalette(custom_palette(1))(n)
}
# Handle legend
if(add_color_legend) {
set_legend <- NULL
} else {
set_legend <- ggplot2::guides(color = "none")
}
# Handle node labeling based on which labels to display (top hubs, hubs or all genes)
if(show_labels == "all") {
nod_at$Degree2 <- nod_at$Degree * 0.4
add_nodelabel <- geom_nodetext(
aes(label = .data$name, size = .data$Degree2),
show.legend = FALSE
)
} else if(show_labels == "allhubs") {
add_nodelabel <- geom_nodelabel_repel(
aes(label = .data$name), color = "azure4",
box.padding = ggnetwork::unit(1, "lines"),
data = function(x) { x[ x$isHub, ]},
show.legend = FALSE, max.overlaps = Inf
)
} else if(show_labels == "tophubs") {
tophubs <- nod_at[nod_at$isHub == TRUE, 1][seq_len(top_n_hubs)]
nod_at$isTopHub <- ifelse(nod_at$Protein %in% tophubs, TRUE, FALSE)
add_nodelabel <- geom_nodelabel_repel(
aes(label = .data$name), color = "azure4",
box.padding = ggnetwork::unit(1, "lines"),
data = function(x) { x[ x$isTopHub, ]},
show.legend = FALSE, max.overlaps = Inf
)
} else if(show_labels == "none") {
add_nodelabel <- NULL
} else {
stop("Please, specify a valid option for 'show_labels'.")
}
# Create graph object
graph <- simplify(graph_from_data_frame(
d = edgelist_int, vertices = nod_at, directed = FALSE
))
n <- ggnetwork::ggnetwork(graph, arrow.gap = 0)
# Plot graph
p <- ggplot(
n, aes(x = .data$x, y = .data$y, xend = .data$xend, yend = .data$yend)
) +
geom_edges(
color = "grey75", alpha = 0.5, curvature = curvature,
show.legend = FALSE
) +
geom_nodes(aes(size = .data$Degree, color = .data$Class)) +
set_legend +
scale_color_manual(values = palette) +
add_nodelabel +
ggnetwork::theme_blank()
}
return(p)
}
#' Plot gene regulatory network from edge list
#'
#' @param edgelist_grn Data frame containing the edge list for the GRN network.
#' First column is the TF and second column is the target gene.
#' All other columns are interpreted as edge attributes.
#' @param show_labels Character indicating which nodes will be labeled.
#' One of "all", "allhubs", "tophubs", or "none".
#' @param top_n_hubs Number of top hubs to be labeled. It is only valid
#' if \code{show_labels} equals "tophubs". Default is 5.
#' @param interactive Logical indicating whether the network should be
#' interactive or not. Default is FALSE.
#' @param layout igraph function for the network layout. One of
#' with_dh, with_drl, with_gem, with_lgl, with_fr, with_graphopt,
#' with_kk and with_mds. Default is with_kk.
#' @param arrow.gap Numeric indicating the distance between nodes and arrows.
#' Default is 0.2.
#' @param ranked Logical indicating whether to treat third column of
#' the edge list (edge weights) as ranked values. Default: TRUE.
#' @param curvature Numeric indicating the amount of curvature in edges.
#' Negative values produce left-hand curves, positive values produce right-hand
#' curves, and zero produces a straight line. Default: 0.1.
#' @param dim_interactive Numeric vector with width and height of window
#' for interactive plotting. Default: c(600,600).
#'
#' @return A ggplot object containing the network.
#' @rdname plot_grn
#' @author Fabricio Almeida-Silva
#' @export
#' @import intergraph
#' @importFrom igraph graph_from_data_frame degree vcount
#' @importFrom ggplot2 ggplot aes arrow scale_color_manual guides
#' @importFrom ggnetwork geom_edges unit geom_nodes geom_nodetext theme_blank geom_nodelabel_repel
#' @examples
#' data(filt.se)
#' tfs <- sample(rownames(filt.se), size = 50, replace = FALSE)
#' grn_edges <- grn_infer(filt.se, method = "clr", regulators = tfs)
#' p <- plot_grn(grn_edges, ranked = FALSE)
plot_grn <- function(edgelist_grn, show_labels = "tophubs", top_n_hubs = 5,
layout = igraph::with_kk, arrow.gap = 0.01,
ranked = TRUE, curvature = 0.1,
interactive = FALSE, dim_interactive = c(600,600)) {
requireNamespace("intergraph", quietly = TRUE)
# Get degree of nodes and find hubs
h <- get_hubs_grn(edgelist_grn, return_degree = TRUE, ranked = ranked)
# Create a data frame of nodes and node attributes
geneIDs <- unique(c(as.character(edgelist_grn[,1]), as.character(edgelist_grn[,2])))
nod_at <- data.frame(Gene = geneIDs, stringsAsFactors = FALSE)
nod_at$Class <- ifelse(nod_at$Gene %in% edgelist_grn[,1], "Regulator", "Target")
nod_at$Degree <- h$Degree$Degree[h$Degree$Gene %in% nod_at$Gene]
nod_at$isHub <- ifelse(nod_at$Gene %in% h$Hubs$Gene, TRUE, FALSE)
nod_at <- nod_at[order(nod_at$Class, -nod_at$Degree), ]
# Should the network be interactive?
if(interactive) {
if(!requireNamespace("networkD3", quietly = TRUE)) {
stop("`interactive = TRUE` requires the 'networkD3' package.")
}
graph <- igraph::graph_from_data_frame(d = edgelist_grn,
vertices = nod_at, directed=TRUE)
graph <- igraph::simplify(graph)
graph_d3 <- networkD3::igraph_to_networkD3(graph, group = nod_at$Class)
graph_d3$nodes <- merge(graph_d3$nodes, nod_at, by.x="name", by.y="Gene", sort = FALSE)
my_color <- 'd3.scaleOrdinal() .domain(["Regulator", "Target"]) .range(["forestgreen", "orange"])'
d <- dim_interactive
p <- networkD3::forceNetwork(Links = graph_d3$links, Nodes = graph_d3$nodes,
Source = 'source', Target = 'target',
NodeID = 'name', Group = 'group',
colourScale = my_color,
Nodesize = 'Degree', height=d[2], width=d[1],
opacity=1, zoom = TRUE, fontSize = 20, legend=TRUE)
} else { #Static network
# Define plotting parameters
add_edges <- geom_edges(
color = "grey60", alpha = 0.3, arrow = ggplot2::arrow(
length = ggnetwork::unit(0.1, "lines"), type = "closed"
), curvature = curvature, show.legend = FALSE
)
# Handle node labeling based on which labels to display (top hubs, hubs or all genes)
if(show_labels == "all") {
nod_at$Degree2 <- nod_at$Degree * 0.4
add_nodelabel <- geom_nodetext(
aes(label = .data$name, size = .data$Degree2),
show.legend = FALSE)
} else if(show_labels == "allhubs") {
add_nodelabel <- geom_nodelabel_repel(
aes(label = .data$name), color = "azure4",
box.padding = ggnetwork::unit(1, "lines"),
data = function(x) { x[ x$isHub, ]},
show.legend = FALSE, max.overlaps = Inf
)
} else if(show_labels == "tophubs") {
tophubs <- nod_at[nod_at$isHub == TRUE, 1][seq_len(top_n_hubs)]
nod_at$isTopHub <- ifelse(nod_at$Gene %in% tophubs, TRUE, FALSE)
add_nodelabel <- geom_nodelabel_repel(
aes(label = .data$name), color = "azure4",
box.padding = ggnetwork::unit(1, "lines"),
data = function(x) { x[ x$isTopHub, ]},
show.legend = FALSE, max.overlaps = Inf
)
} else if(show_labels == "none") {
add_nodelabel <- NULL
} else {
stop("Please, specify a valid option for 'show_labels'.")
}
# Create graph object
graph <- graph_from_data_frame(
d = edgelist_grn, vertices = nod_at, directed = TRUE
)
graph <- igraph::simplify(graph)
n <- ggnetwork(graph, layout = layout(), arrow.gap = arrow.gap)
n$Class <- factor(n$Class, levels=c("Target", "Regulator"))
# Plot graph
p <- ggplot(
n, aes(x = .data$x, y = .data$y, xend = .data$xend, yend = .data$yend)
) +
add_edges +
geom_nodes(
aes(fill = .data$Class),
shape = 21, color = "gray40"
) +
scale_fill_manual(values = c("darkolivegreen3", "mediumpurple3")) +
add_nodelabel +
ggnetwork::theme_blank()
}
return(p)
}
#' Plot gene coexpression network from edge list
#'
#' @param edgelist_gcn Data frame containing the edge list for the GCN.
#' The edge list can be generated with \code{get_edge_list()}.
#' @param net List object returned by \code{exp2net}.
#' @param color_by How should nodes be colored? It must be either "module"
#' (nodes will have the colors of their modules) or a 2-column data frame
#' containing genes in the first column and a custom gene annotation
#' in the second column. Default: "module".
#' @param hubs Data frame containing hub genes in the first column,
#' their modules in the second column, and intramodular connectivity in
#' the third column.
#' @param show_labels Character indicating which nodes will be labeled.
#' One of "all", "allhubs", "tophubs", or "none". Default: tophubs.
#' @param top_n_hubs Number of top hubs to be labeled. It is only valid
#' if \code{show_labels} equals "tophubs". Default is 5.
#' @param curvature Numeric indicating the amount of curvature in edges.
#' Negative values produce left-hand curves, positive values produce right-hand
#' curves, and zero produces a straight line. Default: 0.1.
#' @param interactive Logical indicating whether the network should be
#' interactive or not. Default is FALSE.
#' @param dim_interactive Numeric vector with width and height of window
#' for interactive plotting. Default: c(600,600).
#'
#' @return A ggplot object.
#'
#' @rdname plot_gcn
#' @author Fabricio Almeida-Silva
#' @export
#' @importFrom igraph simplify graph_from_data_frame
#' @importFrom ggnetwork ggnetwork geom_edges geom_nodes geom_nodetext theme_blank geom_nodelabel_repel unit
#' @importFrom ggplot2 ggplot aes guides
#' @import intergraph
#' @examples
#' data(filt.se)
#' gcn <- exp2gcn(filt.se, SFTpower = 18, cor_method = "pearson")
#' gcn_edges <- get_edge_list(gcn, module="brown", filter=TRUE,
#' method="min_cor")
#' hubs <- get_hubs_gcn(filt.se, gcn)
#' p <- plot_gcn(gcn_edges, gcn, hubs = hubs)
plot_gcn <- function(edgelist_gcn, net, color_by = "module", hubs = NULL,
show_labels = "tophubs", top_n_hubs = 5,
curvature = 0,
interactive = FALSE, dim_interactive = c(600,600)) {
requireNamespace("intergraph", quietly=TRUE)
if(is.null(hubs) | is.null(edgelist_gcn)) {
stop("Arguments 'edgelist_gcn' and 'hubs' are mandatory for this network.")
}
# How should genes be colored?
if(is.data.frame(color_by)) {
gene_annotation <- color_by # color by custom annotation
} else {
gene_annotation <- net$genes_and_modules # color by module color
}
kIN <- net$kIN
# Create a data frame of nodes and node attributes
geneIDs <- unique(c(as.character(edgelist_gcn[,1]), as.character(edgelist_gcn[,2])))
nod_at <- data.frame(Gene = geneIDs, stringsAsFactors = FALSE)
nod_at <- merge(nod_at, gene_annotation, by = 1)
names(nod_at)[2] <- "Class"
nod_at$Class <- as.factor(nod_at$Class)
nod_at$Degree <- kIN$kWithin[rownames(kIN) %in% nod_at$Gene]
nod_at$isHub <- ifelse(nod_at$Gene %in% hubs[,1], TRUE, FALSE)
nod_at <- nod_at[order(nod_at$Class, -nod_at$Degree), ]
# Should the network be interactive?
if(interactive) {
if(!requireNamespace("networkD3", quietly = TRUE)) {
stop("`interactive = TRUE` requires the 'networkD3' package.")
}
graph <- igraph::simplify(igraph::graph_from_data_frame(d = edgelist_gcn, vertices = nod_at, directed=FALSE))
graph_d3 <- networkD3::igraph_to_networkD3(graph, group = nod_at$Class)
graph_d3$nodes <- merge(graph_d3$nodes, nod_at, by.x="name", by.y="Gene", sort = FALSE)
d <- dim_interactive
p <- networkD3::forceNetwork(Links = graph_d3$links, Nodes = graph_d3$nodes,
Source = 'source', Target = 'target',
NodeID = 'name', Group = 'group',
Nodesize = 'Degree', height=d[2], width=d[1],
opacity=0.8, zoom = TRUE, fontSize = 13)
} else {
# Handle gene coloring based on number of annotation classes
if(nlevels(nod_at$Class) == 1) {
nodecol <- levels(nod_at$Class)
add_nodes <- geom_nodes(
aes(size = .data$Degree, alpha = .data$Degree), color = nodecol
)
} else {
add_nodes <- geom_nodes(
aes(size = .data$Degree, alpha = .data$Degree, color = .data$Class)
)
}
if(is.data.frame(color_by)) {
palette <- custom_palette(1)[seq_len(nlevels(nod_at$Class))]
scale_color <- ggplot2::scale_color_manual(values = palette)
} else {
scale_color <- ggplot2::scale_color_manual(values = levels(nod_at$Class))
}
# Handle node labeling based on which labels to display (top hubs, hubs or all genes)
if(show_labels == "all") {
nod_at$Degree2 <- nod_at$Degree * 0.4
add_nodelabel <- ggnetwork::geom_nodetext(
aes(label = .data$name, size = .data$Degree2),
show.legend = FALSE
)
} else if(show_labels == "allhubs") {
add_nodelabel <- ggnetwork::geom_nodelabel_repel(
aes(label = .data$name), color = "azure4",
box.padding = ggnetwork::unit(1, "lines"),
data = function(x) { x[ x$isHub, ]},
show.legend = FALSE, max.overlaps = Inf
)
} else if(show_labels == "tophubs") {
tophubs <- nod_at[nod_at$isHub == TRUE, 1][seq_len(top_n_hubs)]
nod_at$isTopHub <- ifelse(nod_at$Gene %in% tophubs, TRUE, FALSE)
add_nodelabel <- geom_nodelabel_repel(
aes(label = .data$name), color = "azure4",
box.padding = ggnetwork::unit(1, "lines"),
data = function(x) { x[ x$isTopHub, ]},
show.legend = FALSE
)
} else if(show_labels == "none") {
add_nodelabel <- NULL
} else {
stop("Please, specify a valid option for 'show_labels'.")
}
# Create graph object
graph <- graph_from_data_frame(
d = edgelist_gcn, vertices = nod_at, directed = FALSE
)
n <- ggnetwork::ggnetwork(graph, arrow.gap=0)
# Plot graph
p <- ggplot(
n, aes(x = .data$x, y = .data$y, xend = .data$xend, yend = .data$yend)
) +
geom_edges(
color = "grey75", alpha = 0.5, curvature = curvature,
show.legend = FALSE
) +
add_nodes +
scale_color +
add_nodelabel +
ggnetwork::theme_blank()
}
return(p)
}
almeidasilvaf/BioNERO documentation built on March 25, 2024, 9:14 p.m.
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Defines functions plot_gcn plot_grn plot_ppi detect_communities
Documented in detect_communities plot_gcn plot_grn plot_ppi
#' Detect communities in a network
#'
#' @param edgelist Data frame containing the network as an edge list.
#' First column must be node 1 and second column must be node 2.
#' Additional columns will be interpreted as edge attributes and will
#' be modified by this function.
#' @param method igraph function to be used for community detection.
#' Available functions are cluster_infomap, cluster_edge_betweenness,
#' cluster_fast_greedy, cluster_walktrap, cluster_spinglass,
#' cluster_leading_eigen, cluster_louvain, and cluster_label_prop.
#' Default is cluster_infomap.
#' @param directed Logical indicating whether the network is directed (GRN only)
#' or not (GCN and PPI networks). Default: TRUE.
#' @return A data frame containing node names in the first column, and
#' communities to which nodes belong in the second column.
#' @seealso
#' \code{\link[igraph]{cluster_infomap}},
#' \code{\link[igraph]{cluster_edge_betweenness}},
#' \code{\link[igraph]{cluster_fast_greedy}},
#' \code{\link[igraph]{cluster_walktrap}},
#' \code{\link[igraph]{cluster_spinglass}},
#' \code{\link[igraph]{cluster_leading_eigen}},
#' \code{\link[igraph]{cluster_louvain}},
#' \code{\link[igraph]{cluster_label_prop}}
#' @rdname detect_communities
#' @author Fabricio Almeida-Silva
#' @export
#' @importFrom igraph graph_from_data_frame simplify cluster_infomap
#' cluster_edge_betweenness cluster_fast_greedy
#' cluster_walktrap cluster_spinglass cluster_leading_eigen
#' cluster_louvain cluster_label_prop
#' @examples
#' data(filt.se)
#' tfs <- sample(rownames(filt.se), size=50, replace=FALSE)
#' grn_edges <- grn_infer(filt.se, method = "clr", regulators = tfs)
#' com <- detect_communities(grn_edges, directed=TRUE)
detect_communities <- function(edgelist,
method = igraph::cluster_infomap,
directed = TRUE) {
graph <- igraph::graph_from_data_frame(edgelist, directed = directed)
graph <- igraph::simplify(graph)
com <- method(graph, modularity = FALSE)
df_com <- as.data.frame(list(names = com$names, mem = com$membership))
return(df_com)
}
#' Plot protein-protein interaction network from edge list
#'
#' @param edgelist_int Data frame containing the edge list for the PPI network.
#' First column is the protein 1 and second column is the protein 2.
#' All other columns are interpreted as edge attributes.
#' @param color_by How should nodes be colored? It must be either "community" or
#' a 2-column data frame containing proteins in the first column and a
#' custom annotation in the second column. If "community", a clustering
#' algorithm will be applied. Default: "community".
#' @param clustering_method igraph function to be used for community detection.
#' Available functions are cluster_infomap, cluster_edge_betweenness,
#' cluster_fast_greedy, cluster_walktrap, cluster_spinglass,
#' cluster_leading_eigen, cluster_louvain, and cluster_label_prop.
#' Default is cluster_infomap.
#' @param show_labels Character indicating which nodes will be labeled.
#' One of "all", "allhubs", "tophubs", or "none".
#' @param top_n_hubs Number of top hubs to be labeled. It is only valid
#' if \code{show_labels} equals "tophubs". Default is 5.
#' @param add_color_legend Logical indicating whether to add a color legend
#' for nodes. Default: TRUE.
#' @param curvature Numeric indicating the amount of curvature in edges.
#' Negative values produce left-hand curves, positive values produce right-hand
#' curves, and zero produces a straight line. Default: 0.
#' @param interactive Logical indicating whether the network should be
#' interactive or not. Default is FALSE.
#' @param dim_interactive Numeric vector with width and height of window
#' for interactive plotting. Default: c(600,600).
#'
#' @return A ggplot object.
#' @rdname plot_ppi
#' @author Fabricio Almeida-Silva
#' @export
#' @importFrom igraph graph_from_data_frame degree simplify vcount
#' @importFrom ggnetwork ggnetwork geom_edges geom_nodes geom_nodetext
#' theme_blank geom_nodelabel_repel unit
#' @importFrom ggplot2 ggplot aes guides
#' @import intergraph
#' @examples
#' ppi_edges <- igraph::sample_pa(n = 500)
#' ppi_edges <- igraph::as_edgelist(ppi_edges)
#' p <- plot_ppi(ppi_edges, add_color_legend = FALSE)
plot_ppi <- function(edgelist_int, color_by = "community",
clustering_method = igraph::cluster_infomap,
show_labels = "tophubs",
top_n_hubs = 5,
add_color_legend=TRUE, curvature = 0,
interactive = FALSE, dim_interactive = c(600, 600)) {
requireNamespace("intergraph", quietly=TRUE)
# How should genes be colored?
if(is.data.frame(color_by)) {
prot_annotation <- color_by # color by custom annotation
} else {
prot_annotation <- detect_communities(edgelist_int,
method = clustering_method,
directed = FALSE)
}
# Get degree of nodes and find hubs
h <- get_hubs_ppi(edgelist_int, return_degree = TRUE)
# Create a data frame of nodes and node attributes
protIDs <- unique(c(as.character(edgelist_int[,1]), as.character(edgelist_int[,2])))
nod_at <- data.frame(Protein = protIDs)
nod_at$Class <- as.factor(prot_annotation[prot_annotation[,1] %in% nod_at$Protein, 2])
nod_at$Degree <- h$Degree$Degree[h$Degree$Protein %in% nod_at$Protein]
nod_at$isHub <- ifelse(nod_at$Protein %in% h$Hubs$Protein, TRUE, FALSE)
nod_at <- nod_at[order(nod_at$Class, -nod_at$Degree), ]
# Should the network be interactive?
if(interactive) {
if(!requireNamespace("networkD3", quietly = TRUE)) {
stop("`interactive = TRUE` requires the 'networkD3' package.")
}
graph <- igraph::graph_from_data_frame(d = edgelist_int,
vertices = nod_at, directed=FALSE)
graph <- igraph::simplify(graph)
graph_d3 <- networkD3::igraph_to_networkD3(graph, group = nod_at$Class)
graph_d3$nodes <- merge(
graph_d3$nodes, nod_at, by.x = "name", by.y = "Protein", sort = FALSE
)
d <- dim_interactive
p <- networkD3::forceNetwork(
Links = graph_d3$links, Nodes = graph_d3$nodes,
Source = 'source', Target = 'target',
NodeID = 'name', Group = 'group',
Nodesize = 'Degree', height = d[2], width = d[1],
opacity=0.8, zoom = TRUE, fontSize = 20
)
} else { #Static network
# Define plotting parameters
if(nlevels(nod_at$Class) <= 20) {
palette <- custom_palette(1)
} else {
n <- nlevels(nod_at$Class)
palette <- colorRampPalette(custom_palette(1))(n)
}
# Handle legend
if(add_color_legend) {
set_legend <- NULL
} else {
set_legend <- ggplot2::guides(color = "none")
}
# Handle node labeling based on which labels to display (top hubs, hubs or all genes)
if(show_labels == "all") {
nod_at$Degree2 <- nod_at$Degree * 0.4
add_nodelabel <- geom_nodetext(
aes(label = .data$name, size = .data$Degree2),
show.legend = FALSE
)
} else if(show_labels == "allhubs") {
add_nodelabel <- geom_nodelabel_repel(
aes(label = .data$name), color = "azure4",
box.padding = ggnetwork::unit(1, "lines"),
data = function(x) { x[ x$isHub, ]},
show.legend = FALSE, max.overlaps = Inf
)
} else if(show_labels == "tophubs") {
tophubs <- nod_at[nod_at$isHub == TRUE, 1][seq_len(top_n_hubs)]
nod_at$isTopHub <- ifelse(nod_at$Protein %in% tophubs, TRUE, FALSE)
add_nodelabel <- geom_nodelabel_repel(
aes(label = .data$name), color = "azure4",
box.padding = ggnetwork::unit(1, "lines"),
data = function(x) { x[ x$isTopHub, ]},
show.legend = FALSE, max.overlaps = Inf
)
} else if(show_labels == "none") {
add_nodelabel <- NULL
} else {
stop("Please, specify a valid option for 'show_labels'.")
}
# Create graph object
graph <- simplify(graph_from_data_frame(
d = edgelist_int, vertices = nod_at, directed = FALSE
))
n <- ggnetwork::ggnetwork(graph, arrow.gap = 0)
# Plot graph
p <- ggplot(
n, aes(x = .data$x, y = .data$y, xend = .data$xend, yend = .data$yend)
) +
geom_edges(
color = "grey75", alpha = 0.5, curvature = curvature,
show.legend = FALSE
) +
geom_nodes(aes(size = .data$Degree, color = .data$Class)) +
set_legend +
scale_color_manual(values = palette) +
add_nodelabel +
ggnetwork::theme_blank()
}
return(p)
}
#' Plot gene regulatory network from edge list
#'
#' @param edgelist_grn Data frame containing the edge list for the GRN network.
#' First column is the TF and second column is the target gene.
#' All other columns are interpreted as edge attributes.
#' @param show_labels Character indicating which nodes will be labeled.
#' One of "all", "allhubs", "tophubs", or "none".
#' @param top_n_hubs Number of top hubs to be labeled. It is only valid
#' if \code{show_labels} equals "tophubs". Default is 5.
#' @param interactive Logical indicating whether the network should be
#' interactive or not. Default is FALSE.
#' @param layout igraph function for the network layout. One of
#' with_dh, with_drl, with_gem, with_lgl, with_fr, with_graphopt,
#' with_kk and with_mds. Default is with_kk.
#' @param arrow.gap Numeric indicating the distance between nodes and arrows.
#' Default is 0.2.
#' @param ranked Logical indicating whether to treat third column of
#' the edge list (edge weights) as ranked values. Default: TRUE.
#' @param curvature Numeric indicating the amount of curvature in edges.
#' Negative values produce left-hand curves, positive values produce right-hand
#' curves, and zero produces a straight line. Default: 0.1.
#' @param dim_interactive Numeric vector with width and height of window
#' for interactive plotting. Default: c(600,600).
#'
#' @return A ggplot object containing the network.
#' @rdname plot_grn
#' @author Fabricio Almeida-Silva
#' @export
#' @import intergraph
#' @importFrom igraph graph_from_data_frame degree vcount
#' @importFrom ggplot2 ggplot aes arrow scale_color_manual guides
#' @importFrom ggnetwork geom_edges unit geom_nodes geom_nodetext theme_blank geom_nodelabel_repel
#' @examples
#' data(filt.se)
#' tfs <- sample(rownames(filt.se), size = 50, replace = FALSE)
#' grn_edges <- grn_infer(filt.se, method = "clr", regulators = tfs)
#' p <- plot_grn(grn_edges, ranked = FALSE)
plot_grn <- function(edgelist_grn, show_labels = "tophubs", top_n_hubs = 5,
layout = igraph::with_kk, arrow.gap = 0.01,
ranked = TRUE, curvature = 0.1,
interactive = FALSE, dim_interactive = c(600,600)) {
requireNamespace("intergraph", quietly = TRUE)
# Get degree of nodes and find hubs
h <- get_hubs_grn(edgelist_grn, return_degree = TRUE, ranked = ranked)
# Create a data frame of nodes and node attributes
geneIDs <- unique(c(as.character(edgelist_grn[,1]), as.character(edgelist_grn[,2])))
nod_at <- data.frame(Gene = geneIDs, stringsAsFactors = FALSE)
nod_at$Class <- ifelse(nod_at$Gene %in% edgelist_grn[,1], "Regulator", "Target")
nod_at$Degree <- h$Degree$Degree[h$Degree$Gene %in% nod_at$Gene]
nod_at$isHub <- ifelse(nod_at$Gene %in% h$Hubs$Gene, TRUE, FALSE)
nod_at <- nod_at[order(nod_at$Class, -nod_at$Degree), ]
# Should the network be interactive?
if(interactive) {
if(!requireNamespace("networkD3", quietly = TRUE)) {
stop("`interactive = TRUE` requires the 'networkD3' package.")
}
graph <- igraph::graph_from_data_frame(d = edgelist_grn,
vertices = nod_at, directed=TRUE)
graph <- igraph::simplify(graph)
graph_d3 <- networkD3::igraph_to_networkD3(graph, group = nod_at$Class)
graph_d3$nodes <- merge(graph_d3$nodes, nod_at, by.x="name", by.y="Gene", sort = FALSE)
my_color <- 'd3.scaleOrdinal() .domain(["Regulator", "Target"]) .range(["forestgreen", "orange"])'
d <- dim_interactive
p <- networkD3::forceNetwork(Links = graph_d3$links, Nodes = graph_d3$nodes,
Source = 'source', Target = 'target',
NodeID = 'name', Group = 'group',
colourScale = my_color,
Nodesize = 'Degree', height=d[2], width=d[1],
opacity=1, zoom = TRUE, fontSize = 20, legend=TRUE)
} else { #Static network
# Define plotting parameters
add_edges <- geom_edges(
color = "grey60", alpha = 0.3, arrow = ggplot2::arrow(
length = ggnetwork::unit(0.1, "lines"), type = "closed"
), curvature = curvature, show.legend = FALSE
)
# Handle node labeling based on which labels to display (top hubs, hubs or all genes)
if(show_labels == "all") {
nod_at$Degree2 <- nod_at$Degree * 0.4
add_nodelabel <- geom_nodetext(
aes(label = .data$name, size = .data$Degree2),
show.legend = FALSE)
} else if(show_labels == "allhubs") {
add_nodelabel <- geom_nodelabel_repel(
aes(label = .data$name), color = "azure4",
box.padding = ggnetwork::unit(1, "lines"),
data = function(x) { x[ x$isHub, ]},
show.legend = FALSE, max.overlaps = Inf
)
} else if(show_labels == "tophubs") {
tophubs <- nod_at[nod_at$isHub == TRUE, 1][seq_len(top_n_hubs)]
nod_at$isTopHub <- ifelse(nod_at$Gene %in% tophubs, TRUE, FALSE)
add_nodelabel <- geom_nodelabel_repel(
aes(label = .data$name), color = "azure4",
box.padding = ggnetwork::unit(1, "lines"),
data = function(x) { x[ x$isTopHub, ]},
show.legend = FALSE, max.overlaps = Inf
)
} else if(show_labels == "none") {
add_nodelabel <- NULL
} else {
stop("Please, specify a valid option for 'show_labels'.")
}
# Create graph object
graph <- graph_from_data_frame(
d = edgelist_grn, vertices = nod_at, directed = TRUE
)
graph <- igraph::simplify(graph)
n <- ggnetwork(graph, layout = layout(), arrow.gap = arrow.gap)
n$Class <- factor(n$Class, levels=c("Target", "Regulator"))
# Plot graph
p <- ggplot(
n, aes(x = .data$x, y = .data$y, xend = .data$xend, yend = .data$yend)
) +
add_edges +
geom_nodes(
aes(fill = .data$Class),
shape = 21, color = "gray40"
) +
scale_fill_manual(values = c("darkolivegreen3", "mediumpurple3")) +
add_nodelabel +
ggnetwork::theme_blank()
}
return(p)
}
#' Plot gene coexpression network from edge list
#'
#' @param edgelist_gcn Data frame containing the edge list for the GCN.
#' The edge list can be generated with \code{get_edge_list()}.
#' @param net List object returned by \code{exp2net}.
#' @param color_by How should nodes be colored? It must be either "module"
#' (nodes will have the colors of their modules) or a 2-column data frame
#' containing genes in the first column and a custom gene annotation
#' in the second column. Default: "module".
#' @param hubs Data frame containing hub genes in the first column,
#' their modules in the second column, and intramodular connectivity in
#' the third column.
#' @param show_labels Character indicating which nodes will be labeled.
#' One of "all", "allhubs", "tophubs", or "none". Default: tophubs.
#' @param top_n_hubs Number of top hubs to be labeled. It is only valid
#' if \code{show_labels} equals "tophubs". Default is 5.
#' @param curvature Numeric indicating the amount of curvature in edges.
#' Negative values produce left-hand curves, positive values produce right-hand
#' curves, and zero produces a straight line. Default: 0.1.
#' @param interactive Logical indicating whether the network should be
#' interactive or not. Default is FALSE.
#' @param dim_interactive Numeric vector with width and height of window
#' for interactive plotting. Default: c(600,600).
#'
#' @return A ggplot object.
#'
#' @rdname plot_gcn
#' @author Fabricio Almeida-Silva
#' @export
#' @importFrom igraph simplify graph_from_data_frame
#' @importFrom ggnetwork ggnetwork geom_edges geom_nodes geom_nodetext theme_blank geom_nodelabel_repel unit
#' @importFrom ggplot2 ggplot aes guides
#' @import intergraph
#' @examples
#' data(filt.se)
#' gcn <- exp2gcn(filt.se, SFTpower = 18, cor_method = "pearson")
#' gcn_edges <- get_edge_list(gcn, module="brown", filter=TRUE,
#' method="min_cor")
#' hubs <- get_hubs_gcn(filt.se, gcn)
#' p <- plot_gcn(gcn_edges, gcn, hubs = hubs)
plot_gcn <- function(edgelist_gcn, net, color_by = "module", hubs = NULL,
show_labels = "tophubs", top_n_hubs = 5,
curvature = 0,
interactive = FALSE, dim_interactive = c(600,600)) {
requireNamespace("intergraph", quietly=TRUE)
if(is.null(hubs) | is.null(edgelist_gcn)) {
stop("Arguments 'edgelist_gcn' and 'hubs' are mandatory for this network.")
}
# How should genes be colored?
if(is.data.frame(color_by)) {
gene_annotation <- color_by # color by custom annotation
} else {
gene_annotation <- net$genes_and_modules # color by module color
}
kIN <- net$kIN
# Create a data frame of nodes and node attributes
geneIDs <- unique(c(as.character(edgelist_gcn[,1]), as.character(edgelist_gcn[,2])))
nod_at <- data.frame(Gene = geneIDs, stringsAsFactors = FALSE)
nod_at <- merge(nod_at, gene_annotation, by = 1)
names(nod_at)[2] <- "Class"
nod_at$Class <- as.factor(nod_at$Class)
nod_at$Degree <- kIN$kWithin[rownames(kIN) %in% nod_at$Gene]
nod_at$isHub <- ifelse(nod_at$Gene %in% hubs[,1], TRUE, FALSE)
nod_at <- nod_at[order(nod_at$Class, -nod_at$Degree), ]
# Should the network be interactive?
if(interactive) {
if(!requireNamespace("networkD3", quietly = TRUE)) {
stop("`interactive = TRUE` requires the 'networkD3' package.")
}
graph <- igraph::simplify(igraph::graph_from_data_frame(d = edgelist_gcn, vertices = nod_at, directed=FALSE))
graph_d3 <- networkD3::igraph_to_networkD3(graph, group = nod_at$Class)
graph_d3$nodes <- merge(graph_d3$nodes, nod_at, by.x="name", by.y="Gene", sort = FALSE)
d <- dim_interactive
p <- networkD3::forceNetwork(Links = graph_d3$links, Nodes = graph_d3$nodes,
Source = 'source', Target = 'target',
NodeID = 'name', Group = 'group',
Nodesize = 'Degree', height=d[2], width=d[1],
opacity=0.8, zoom = TRUE, fontSize = 13)
} else {
# Handle gene coloring based on number of annotation classes
if(nlevels(nod_at$Class) == 1) {
nodecol <- levels(nod_at$Class)
add_nodes <- geom_nodes(
aes(size = .data$Degree, alpha = .data$Degree), color = nodecol
)
} else {
add_nodes <- geom_nodes(
aes(size = .data$Degree, alpha = .data$Degree, color = .data$Class)
)
}
if(is.data.frame(color_by)) {
palette <- custom_palette(1)[seq_len(nlevels(nod_at$Class))]
scale_color <- ggplot2::scale_color_manual(values = palette)
} else {
scale_color <- ggplot2::scale_color_manual(values = levels(nod_at$Class))
}
# Handle node labeling based on which labels to display (top hubs, hubs or all genes)
if(show_labels == "all") {
nod_at$Degree2 <- nod_at$Degree * 0.4
add_nodelabel <- ggnetwork::geom_nodetext(
aes(label = .data$name, size = .data$Degree2),
show.legend = FALSE
)
} else if(show_labels == "allhubs") {
add_nodelabel <- ggnetwork::geom_nodelabel_repel(
aes(label = .data$name), color = "azure4",
box.padding = ggnetwork::unit(1, "lines"),
data = function(x) { x[ x$isHub, ]},
show.legend = FALSE, max.overlaps = Inf
)
} else if(show_labels == "tophubs") {
tophubs <- nod_at[nod_at$isHub == TRUE, 1][seq_len(top_n_hubs)]
nod_at$isTopHub <- ifelse(nod_at$Gene %in% tophubs, TRUE, FALSE)
add_nodelabel <- geom_nodelabel_repel(
aes(label = .data$name), color = "azure4",
box.padding = ggnetwork::unit(1, "lines"),
data = function(x) { x[ x$isTopHub, ]},
show.legend = FALSE
)
} else if(show_labels == "none") {
add_nodelabel <- NULL
} else {
stop("Please, specify a valid option for 'show_labels'.")
}
# Create graph object
graph <- graph_from_data_frame(
d = edgelist_gcn, vertices = nod_at, directed = FALSE
)
n <- ggnetwork::ggnetwork(graph, arrow.gap=0)
# Plot graph
p <- ggplot(
n, aes(x = .data$x, y = .data$y, xend = .data$xend, yend = .data$yend)
) +
geom_edges(
color = "grey75", alpha = 0.5, curvature = curvature,
show.legend = FALSE
) +
add_nodes +
scale_color +
add_nodelabel +
ggnetwork::theme_blank()
}
return(p)
}
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