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Tommi Suvitaival, Steno Diabetes Center Copenhagen, TSUV0001@RegionH.DK 2020-03-06
Create lipidome-wide heatmaps of statistics with the ‘lipidomeR’. The ‘lipidomeR’ provides a streamlined pipeline for the systematic interpretation of the lipidome through publication-ready visualizations of regression models fitted on lipidomics data. With ‘lipidomeR’, associations between covariates and the lipidome can be interpreted systematically and intuitively through heatmaps, where lipids are categorized by the lipid class and are presented on two-dimensional maps organized by the lipid size and level of saturation. This way, the ‘lipidomeR’ helps you gain an immediate understanding of the multivariate patterns in the lipidome already at first glance. You can create lipidome-wide heatmaps of statistical associations, changes, differences, variation, or other lipid-specific values. The heatmaps are provided with publication-ready quality and the results behind the visualizations are based on rigorous statistical models.
install.packages( "lipidomeR" )
library( "lipidomeR" )
# Load the humanlipidome data set.
data( lipidomeR::humanlipidome )
# Transform the concentrations into log-10 scale.
$'Concentration_log10_umol_per_mL' <-
humanlipidomelog10( humanlipidome$'Concentration' )
# Enumerate the lipid names into values.
<- map_lipid_names( x = humanlipidome$'Name' )
names.mapping
# Create the lipidomeR heatmap of lipid concentrations.
heatmap_lipidome(
x = humanlipidome[ , c( "Name", "Concentration_log10_umol_per_mL" ) ],
names.mapping = names.mapping,
class.facet = "wrap",
x.names = "Name",
fill.limits =
range(
x = humanlipidome$"Concentration_log10_umol_per_mL",
na.rm = TRUE
),fill.midpoint =
sum(
range(
x = humanlipidome$"Concentration_log10_umol_per_mL",
na.rm = TRUE
)/ 2,
) melt.value.name = "Concentration_umol_per_mL_log10",
scales = "free"
)
# Load the cancerlipidome data set.
data( lipidomeR::cancerlipidome )
# Convert the data into wide format, where each lipid is one column and
# each sample is one row.
<-
cancerlipidome.wide ::pivot_wider(
tidyrdata = cancerlipidome,
names_from = Lipid_Name,
values_from = Lipid_Level
)
# Inspect the data frame.
# View( cancerlipidome.wide )
# Create a mapping of the lipid names.
<-
names.mapping map_lipid_names( x = unique( cancerlipidome$"Lipid_Name" ) )
# Compute the regression models.
<-
result.limma compute_models_with_limma(
x = cancerlipidome.wide,
dependent.variables = names.mapping$"Name",
independent.variables = c( "Group" )
)
## Fitting models: ~ Group
# Create the figure of all lipids and factors.
<-
figure.output heatmap_lipidome_from_limma(
x = result.limma$"model",
names.mapping = names.mapping,
axis.x.carbons = FALSE,
class.facet = "row",
plot.all = TRUE,
plot.individual = FALSE,
print.figure = TRUE,
scales = "free",
space = "free"
)
# Create factor-specific figures.
<-
figure.output heatmap_lipidome_from_limma(
x = result.limma$"model",
names.mapping = names.mapping,
axis.x.carbons = FALSE,
class.facet = "wrap",
omit.class = "PA",
plot.all = FALSE,
plot.individual = TRUE,
print.figure = FALSE,
scales = "free",
space = "free"
)
# Print the figure of differences between cancer and benign tumors.
print( figure.output[[ "GroupCancer" ]] )
# Load the liverlipidome data set.
data( lipidomeR::liverlipidome )
# Convert the data into wide format, where each lipid is one column and
# each sample is one row.
<-
liverlipidome.wide ::pivot_wider(
tidyrdata = liverlipidome,
names_from = Lipid_Name,
values_from = Lipid_Level
)
# Create a mapping of the lipid names.
<-
names.mapping map_lipid_names( x = unique( liverlipidome$"Lipid_Name" ) )
# Compute the regression models.
<-
result.limma compute_models_with_limma(
x = liverlipidome.wide,
dependent.variables = names.mapping$"Name",
independent.variables = c( "Diagnosis" ),
F.test = TRUE # Compute an F-test for a factor variable.
)
## Fitting models: ~ Diagnosis
# Compute the F-test.
<-
result.limma compute_F_test_with_limma(
x = result.limma,
print.table = FALSE
)
# Print a figure of the F-test.
<-
figure.output heatmap_lipidome_from_limma(
x = result.limma,
names.mapping = names.mapping,
F.test = TRUE,
axis.x.carbons = FALSE,
class.facet = "wrap",
plot.all = FALSE,
plot.individual = TRUE,
scales = "free",
space = "free"
)
# Compute pairwise post-hoc comparisons between the factor levels for
# the dependent variables (i.e., lipids) with a significant F-test result.
<-
result.limma compute_post_hoc_test_with_limma(
x = result.limma,
remap.level.names = TRUE
)
# Print a figure of all post-hoc comparisons.
<-
figure.output heatmap_lipidome_from_limma(
x = result.limma$"result.post.hoc.test",
names.mapping = names.mapping,
axis.x.carbons = FALSE,
plot.all = TRUE,
plot.individual = FALSE,
scales = "free",
space = "free"
)
# Specify the contrasts of the post-hoc comparison that will be included
# in the figure.
<-
contrasts.included c( "DiagnosisSteatosis", "DiagnosisNASH", "DiagnosisCirrhosis" )
# Get the omitted contrasts based on the above definition.
<-
contrasts.omitted colnames( result.limma$"result.post.hoc.test"$"p.value" )[
!(
colnames( result.limma$"result.post.hoc.test"$"p.value" ) %in%
contrasts.included
)
]
# Find dependent variables (i.e., lipids) that have any significant
# difference.
<-
has.any.significant apply(
X =
$"result.post.hoc.test"$"p.value"[
result.limma
,
contrasts.included
],MAR = 2,
FUN = p.adjust,
method = "BH"
)
<-
has.any.significant rownames(
has.any.significant[apply(
X = has.any.significant < 0.05,
MAR = 1,
FUN = any
),
]
)
# Include in the figure only lipid classes that have at least four
# significant differences.
<-
classes.included names(
which(
table(
names.mapping[make.names( has.any.significant ), "Class"
]> 3
)
)
)
<- unique( names.mapping$"Class" )
classes.omitted <-
classes.omitted !( classes.omitted ) %in% classes.included ]
classes.omitted[
# Print a figure of the selected post-hoc-comparisons.
<-
figure.output heatmap_lipidome_from_limma(
x = result.limma$"result.post.hoc.test",
names.mapping = names.mapping,
axis.x.carbons = FALSE,
omit.class = classes.omitted,
omit.factor = contrasts.omitted,
plot.all = TRUE,
plot.individual = FALSE,
scales = "free",
space = "free"
)
::sessionInfo() utils
## R version 3.6.1 (2019-07-05)
## Platform: x86_64-pc-linux-gnu (64-bit)
## Running under: CentOS Linux 7 (Core)
##
## Matrix products: default
## BLAS/LAPACK: /services/tools/intel/perflibs/2019_update5/compilers_and_libraries_2019.5.281/linux/mkl/lib/intel64_lin/libmkl_gf_lp64.so
##
## locale:
## [1] LC_CTYPE=en_US.UTF-8 LC_NUMERIC=C
## [3] LC_TIME=en_US.UTF-8 LC_COLLATE=en_US.UTF-8
## [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] stats graphics grDevices utils datasets methods base
##
## loaded via a namespace (and not attached):
## [1] Rcpp_1.0.3 compiler_3.6.1 pillar_1.4.3 RColorBrewer_1.1-2
## [5] plyr_1.8.5 tools_3.6.1 digest_0.6.25 jsonlite_1.6.1
## [9] evaluate_0.14 lifecycle_0.1.0 tibble_2.1.3 gtable_0.3.0
## [13] pkgconfig_2.0.3 rlang_0.4.4 rstudioapi_0.11 curl_4.3
## [17] yaml_2.2.1 xfun_0.12 dplyr_0.8.4 DiagrammeR_1.0.5
## [21] stringr_1.4.0 knitr_1.28 vctrs_0.2.3 htmlwidgets_1.5.1
## [25] tidyselect_1.0.0 grid_3.6.1 glue_1.3.1 R6_2.4.1
## [29] DiagrammeRsvg_0.1 rmarkdown_2.1 limma_3.42.2 tidyr_1.0.2
## [33] farver_2.0.3 purrr_0.3.3 ggplot2_3.2.1 reshape2_1.4.3
## [37] magrittr_1.5 ellipsis_0.3.0 scales_1.1.0 htmltools_0.4.0
## [41] assertthat_0.2.1 colorspace_1.4-1 labeling_0.3 rsvg_1.3
## [45] V8_3.0.1 stringi_1.4.6 visNetwork_2.0.9 lazyeval_0.2.2
## [49] munsell_0.5.0 crayon_1.3.4
These binaries (installable software) and packages are in development.
They may not be fully stable and should be used with caution. We make no claims about them.
Health stats visible at Monitor.