Last updated: 2021-07-13
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Knit directory: muse/
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File | Version | Author | Date | Message |
---|---|---|---|---|
Rmd | 88ec168 | Dave Tang | 2021-07-13 | Add title |
html | 45e2b81 | Dave Tang | 2021-06-15 | Build site. |
Rmd | 83190de | Dave Tang | 2021-06-15 | Own column order |
html | d8e64e3 | Dave Tang | 2021-04-14 | Build site. |
Rmd | 500529b | Dave Tang | 2021-04-14 | https://davetang.org/muse/2018/05/15/making-a-heatmap-in-r-with-the-pheatmap-package/#comment-8339 |
html | c54efbf | Dave Tang | 2020-11-27 | Build site. |
Rmd | 4da96c0 | Dave Tang | 2020-11-27 | More clusters |
html | 2db13ea | davetang | 2020-11-10 | Build site. |
Rmd | 268312f | davetang | 2020-11-10 | wflow_publish(files = c(“analysis/index.Rmd”, “analysis/google_trends.Rmd”, |
html | 586b91f | Dave Tang | 2020-07-12 | Build site. |
Rmd | b1d6edd | Dave Tang | 2020-07-12 | pheatmap |
Making a heatmap using the pheatmap
package.
example_file <- "https://davetang.org/file/TagSeqExample.tab"
data <- read.delim(example_file, header = TRUE, row.names = "gene")
data_subset <- as.matrix(data[rowSums(data)>50000,])
Default heatmap using pheatmap
.
pheatmap(data_subset)
cal_z_score <- function(x){
(x - mean(x)) / sd(x)
}
data_subset_norm <- t(apply(data_subset, 1, cal_z_score))
pheatmap(data_subset_norm)
Using scale produces the same heatmap as using cal_z_score
.
pheatmap(data_subset, scale = "row")
Add a title using main
.
pheatmap(data_subset, main = "My title")
Add a title using textGrob
; you will need the grid
and gridExtra
packages.
my_title <- textGrob("My title", gp = gpar(fontsize = 21, fontface = "bold"))
one <- pheatmap(data_subset, silent = TRUE)
grid.arrange(grobs = list(my_title, one[[4]]), heights = c(0.1, 1))
Two heatmaps.
one <- pheatmap(data_subset, silent = TRUE)
two <- pheatmap(data_subset, silent = TRUE)
grid.arrange(grobs = list(one[[4]], two[[4]]))
Reproduce the gene dendrogram.
par(mar = c(3.1, 2.1, 1.1, 5.1))
my_hclust_gene <- hclust(dist(data_subset), method = "complete")
my_hclust_gene$height
[1] 2502.208 3771.244 4252.402 4366.211 4700.444 5069.851 5208.367
[8] 6439.545 6474.863 6938.482 7983.369 8141.632 9198.185 9849.175
[15] 10818.256 10868.066 11127.621 11168.654 12699.557 12871.187 13511.763
[22] 13549.622 14483.876 14856.478 14860.904 15033.046 16304.877 16574.315
[29] 16935.384 17713.534 18798.131 18904.899 20250.185 22302.634 22512.593
[36] 24345.199 29826.722 30846.374 31530.137 31849.145 40048.202 43714.148
[43] 47029.264 48908.962 56038.953 67891.667 74124.247 95015.400
as.dendrogram(my_hclust_gene) %>%
plot(horiz = TRUE)
Obtaining the gene IDs as per the order of the dendrogram (from top to bottom).
rev(row.names(data_subset)[my_hclust_gene$order])
[1] "Gene_08819" "Gene_08743" "Gene_12940" "Gene_13540" "Gene_12804"
[6] "Gene_11672" "Gene_16632" "Gene_17743" "Gene_07390" "Gene_16114"
[11] "Gene_00562" "Gene_14672" "Gene_08694" "Gene_14450" "Gene_09238"
[16] "Gene_08042" "Gene_03194" "Gene_02420" "Gene_11002" "Gene_05960"
[21] "Gene_03450" "Gene_02800" "Gene_09969" "Gene_07404" "Gene_08576"
[26] "Gene_09610" "Gene_03852" "Gene_12318" "Gene_04164" "Gene_15334"
[31] "Gene_09952" "Gene_10924" "Gene_12834" "Gene_03861" "Gene_13444"
[36] "Gene_06899" "Gene_17849" "Gene_07132" "Gene_05761" "Gene_02296"
[41] "Gene_09505" "Gene_12576" "Gene_17992" "Gene_15286" "Gene_17865"
[46] "Gene_10648" "Gene_05004" "Gene_14928" "Gene_02115"
Reproduce the sample dendrogram.
my_hclust_sample <- hclust(dist(t(data_subset)), method = "complete")
as.dendrogram(my_hclust_sample) %>%
plot()
Add annotations.
my_gene_col <- cutree(tree = as.dendrogram(my_hclust_gene), k = 2)
my_gene_col <- data.frame(cluster = ifelse(test = my_gene_col == 1, yes = "cluster 1", no = "cluster 2"))
my_sample_col <- data.frame(sample = rep(c("tumour", "normal"), c(4,2)))
row.names(my_sample_col) <- colnames(data_subset)
set.seed(1984)
my_random <- as.factor(sample(x = 1:2, size = nrow(my_gene_col), replace = TRUE))
my_gene_col$random <- my_random
pheatmap(data_subset, annotation_row = my_gene_col, annotation_col = my_sample_col)
Define your own column order by modifying data_subset
and setting cluster_cols
to FALSE.
my_col_order <- c("N2", "T1a", "N1", "T1b", "T2", "T3")
pheatmap(data_subset[, my_col_order],
annotation_col = my_sample_col,
cluster_cols = FALSE
)
More clusters.
my_gene_col <- cutree(tree = as.dendrogram(my_hclust_gene), k = 6)
my_gene_col <- data.frame(cluster = paste0("cluster ", my_gene_col), row.names = names(my_gene_col))
my_sample_col <- data.frame(sample = rep(c("tumour", "normal"), c(4,2)))
row.names(my_sample_col) <- colnames(data_subset)
set.seed(1984)
my_random <- as.factor(sample(x = 1:2, size = nrow(my_gene_col), replace = TRUE))
my_gene_col$random <- my_random
pheatmap(data_subset, annotation_row = my_gene_col, annotation_col = my_sample_col)
Change annotation colours and ordering.
my_gene_col <- cutree(tree = as.dendrogram(my_hclust_gene), k = 2)
my_gene_col <- data.frame(cluster = ifelse(test = my_gene_col == 1, yes = "cluster1", no = "cluster2"))
my_sample_col <- data.frame(sample = rep(c("tumour", "normal"), c(4,2)))
row.names(my_sample_col) <- colnames(data_subset)
# change order
my_sample_col$sample <- factor(my_sample_col$sample, levels = c("normal", "tumour"))
set.seed(1984)
my_random <- as.factor(sample(x = c("random1", "random2"), size = nrow(my_gene_col), replace = TRUE))
my_gene_col$random <- my_random
my_colour = list(
sample = c(normal = "#5977ff", tumour = "#f74747"),
random = c(random1 = "#82ed82", random2 = "#9e82ed"),
cluster = c(cluster1 = "#e89829", cluster2 = "#cc4ee0")
)
p <- pheatmap(data_subset,
annotation_colors = my_colour,
annotation_row = my_gene_col,
annotation_col = my_sample_col,
cellheight = 7,
cellwidth = 18)
save_pheatmap_png <- function(x, filename, width=1200, height=1000, res = 150) {
png(filename, width = width, height = height, res = res)
grid::grid.newpage()
grid::grid.draw(x$gtable)
dev.off()
}
# not run
# save_pheatmap_png(p, "heatmap_colour.png")
Introduce breaks by cutting the dendrogram.
pheatmap(data_subset,
annotation_row = my_gene_col,
annotation_col = my_sample_col,
cutree_rows = 2,
cutree_cols = 2)
Dendrogram results from pheatmap().
par(mar = c(3.1, 2.1, 1.1, 5.1))
my_heatmap <- pheatmap(data_subset, silent = TRUE)
names(my_heatmap)
[1] "tree_row" "tree_col" "kmeans" "gtable"
my_heatmap$tree_row %>%
as.dendrogram() %>%
plot(horiz = TRUE)
sessionInfo()
R version 4.0.5 (2021-03-31)
Platform: x86_64-w64-mingw32/x64 (64-bit)
Running under: Windows 10 x64 (build 19043)
Matrix products: default
locale:
[1] LC_COLLATE=English_Australia.1252 LC_CTYPE=English_Australia.1252
[3] LC_MONETARY=English_Australia.1252 LC_NUMERIC=C
[5] LC_TIME=English_Australia.1252
system code page: 932
attached base packages:
[1] grid stats graphics grDevices utils datasets methods
[8] base
other attached packages:
[1] gridExtra_2.3 dendextend_1.15.1 pheatmap_1.0.12 workflowr_1.6.2
loaded via a namespace (and not attached):
[1] Rcpp_1.0.6 highr_0.9 pillar_1.6.1 compiler_4.0.5
[5] later_1.2.0 RColorBrewer_1.1-2 git2r_0.28.0 viridis_0.6.1
[9] tools_4.0.5 digest_0.6.27 viridisLite_0.4.0 evaluate_0.14
[13] lifecycle_1.0.0 tibble_3.1.1 gtable_0.3.0 pkgconfig_2.0.3
[17] rlang_0.4.11 DBI_1.1.1 yaml_2.2.1 xfun_0.22
[21] dplyr_1.0.6 stringr_1.4.0 knitr_1.33 generics_0.1.0
[25] fs_1.5.0 vctrs_0.3.8 tidyselect_1.1.1 rprojroot_2.0.2
[29] glue_1.4.2 R6_2.5.0 fansi_0.4.2 rmarkdown_2.8
[33] farver_2.1.0 purrr_0.3.4 ggplot2_3.3.3 magrittr_2.0.1
[37] whisker_0.4 scales_1.1.1 promises_1.2.0.1 ellipsis_0.3.2
[41] htmltools_0.5.1.1 assertthat_0.2.1 colorspace_2.0-1 httpuv_1.6.1
[45] utf8_1.2.1 stringi_1.5.3 munsell_0.5.0 crayon_1.4.1