This vignette aims to be a short tutorial for the main functionalities of
SIAMCAT
. Examples of additional workflows or more detailed tutorials can
be found in other vignettes (see the
BioConductor page).
SIAMCAT
is part of the suite of computational microbiome analysis tools
hosted at EMBL by the groups of
Peer Bork and
Georg Zeller. Find
out more at EMBL-microbiome tools.
Associations between microbiome and host phenotypes are ideally described by
quantitative models able to predict host status from microbiome composition.
SIAMCAT
can do so for data from hundreds of thousands of microbial taxa, gene
families, or metabolic pathways over hundreds of samples. SIAMCAT
produces
graphical output for convenient assessment of the quality of the input data and
statistical associations, for model diagnostics and inference revealing the
most predictive microbial biomarkers.
For this vignette, we use an example dataset included in the SIAMCAT
package.
As example dataset we use the data from the publication of
Zeller et al, which demonstrated
the potential of microbial species in fecal samples to distinguish patients
with colorectal cancer (CRC) from healthy controls.
library("SIAMCAT")
data("feat_crc_zeller", package="SIAMCAT")
data("meta_crc_zeller", package="SIAMCAT")
First, SIAMCAT
needs a feature matrix (can be either a matrix
, a
data.frame
, or a phyloseq-otu_table
), which contains values of different
features (in rows) for different samples (in columns). For example, the
feature matrix included here contains relative abundances for bacterial
species calculated with the mOTU profiler for 141 samples:
feat.crc.zeller[1:3, 1:3]
## CCIS27304052ST-3-0 CCIS15794887ST-4-0
## UNMAPPED 0.589839 0.7142157
## Methanoculleus marisnigri [h:1] 0.000000 0.0000000
## Methanococcoides burtonii [h:10] 0.000000 0.0000000
## CCIS74726977ST-3-0
## UNMAPPED 0.7818674
## Methanoculleus marisnigri [h:1] 0.0000000
## Methanococcoides burtonii [h:10] 0.0000000
dim(feat.crc.zeller)
## [1] 1754 141
Please note that
SIAMCAT
is supposed to work with relative abundances. Other types of data (e.g. counts) will also work, but not all functions of the package will result in meaningful outputs.
Secondly, we also have metadata about the samples in another data.frame
:
head(meta.crc.zeller)
## Age BMI Gender AJCC_stage FOBT Group
## CCIS27304052ST-3-0 52 20 F -1 Negative CTR
## CCIS15794887ST-4-0 37 18 F -1 Negative CTR
## CCIS74726977ST-3-0 66 24 M -1 Negative CTR
## CCIS16561622ST-4-0 54 26 M -1 Negative CTR
## CCIS79210440ST-3-0 65 30 M -1 Positive CTR
## CCIS82507866ST-3-0 57 24 M -1 Negative CTR
In order to tell SIAMCAT
, which samples are cancer cases and which are
healthy controls, we can construct a label object from the Group
column in
the metadata.
label.crc.zeller <- create.label(meta=meta.crc.zeller,
label='Group', case='CRC')
## Label used as case:
## CRC
## Label used as control:
## CTR
## + finished create.label.from.metadata in 0.002 s
Now we have all the ingredients to create a SIAMCAT
object. Please have a
look at the vignette about input formats for more
information about supported formats and other ways to create a SIAMCAT
object.
sc.obj <- siamcat(feat=feat.crc.zeller,
label=label.crc.zeller,
meta=meta.crc.zeller)
## + starting validate.data
## +++ checking overlap between labels and features
## + Keeping labels of 141 sample(s).
## +++ checking sample number per class
## +++ checking overlap between samples and metadata
## + finished validate.data in 0.028 s
A few information about the SIAMCAT
object can be accessed with the show
function from phyloseq
(SIAMCAT
builds on the phyloseq
data structure):
show(sc.obj)
## siamcat-class object
## label() Label object: 88 CTR and 53 CRC samples
##
## contains phyloseq-class experiment-level object @phyloseq:
## phyloseq@otu_table() OTU Table: [ 1754 taxa and 141 samples ]
## phyloseq@sam_data() Sample Data: [ 141 samples by 6 sample variables ]
Since we have quite a lot of microbial species in the dataset at the moment, we
can perform unsupervised feature selection using the function filter.features
.
sc.obj <- filter.features(sc.obj,
filter.method = 'abundance',
cutoff = 0.001)
## Features successfully filtered
Associations between microbial species and the label can be tested
with the check.associations
function. The function computes for each species
the significance using a non-parametric Wilcoxon test and different effect
sizes for the association (e.g. AUC or fold change).
sc.obj <- check.associations(
sc.obj,
sort.by = 'fc',
alpha = 0.05,
mult.corr = "fdr",
detect.lim = 10 ^-6,
plot.type = "quantile.box",
panels = c("fc", "prevalence", "auroc"))
The function produces a pdf file as output, since the plot is optimized for a landscape DIN-A4 layout, but can also used to plot on an active graphic device, e.g. in RStudio. The resulting plot then looks like that:
As many biological and technical factors beyond the primary phenotype of
interest can influence microbiome composition, simple association studies may
suffer confounding by other variables, which can lead to spurious results.
The check.confounders
function provides the option to test the associated
metadata variables for potential confounding influence. No information is stored
in the SIAMCAT
object, but the different analyses are visualized and saved to
a combined pdf file for qualitative interpretation.
sc.obj <- check.confounders(
sc.obj,
fn.plot = 'confounder_plots.pdf',
meta.in = NULL,
feature.type = 'filtered'
)
The conditional entropy check primarily serves to remove nonsensical variables from subsequent checks. Conditional entropy quantifies the unique information contained in one variable (row) respective to another (column). Identical variables and derived variables which share the exact same information will have a value of zero. In this example, the label was derived from the Group variable which was determined from AJCC stage, so both are excluded.
To better quantify potential confounding effects of metadata variables on
individual microbial features, check.confounder
plots the variance explained
by the label in comparison with the variance explained by the metadata variable
for each individual feature. Variables with many features in the upper left
corner might be confounding the label associations.
One strength of SIAMCAT
is the versatile but easy-to-use interface for the
construction of machine learning models on the basis of microbial species.
SIAMCAT
contains functions for data normalization, splitting the data into
cross-validation folds, training the model, and making predictions based on
cross-validation instances and the trained models.
Data normalization is performed with the normalize.features
function. Here,
we use the log.unit
method, but several other methods and customization
options are available (please check the documentation).
sc.obj <- normalize.features(
sc.obj,
norm.method = "log.unit",
norm.param = list(
log.n0 = 1e-06,
n.p = 2,
norm.margin = 1
)
)
## Features normalized successfully.
Preparation of the cross-validation fold is a crucial step in machine learning.
SIAMCAT
greatly simplifies the set-up of cross-validation schemes, including
stratification of samples or keeping samples inseperable based on metadata.
For this small example, we choose a twice-repeated 5-fold cross-validation
scheme. The data-split will be saved in the data_split
slot of the SIAMCAT
object.
sc.obj <- create.data.split(
sc.obj,
num.folds = 5,
num.resample = 2
)
## Features splitted for cross-validation successfully.
The actual model training is performed using the function train.model
.
Again, multiple options for customization are available, ranging from the
machine learning method to the measure for model selection or customizable
parameter set for hyperparameter tuning.
sc.obj <- train.model(
sc.obj,
method = "lasso"
)
The models are saved in the model_list
slot of the SIAMCAT
object. The
model building is performed using the mlr
R package. All models can easily be
accessed.
# get information about the model type
model_type(sc.obj)
## [1] "lasso"
# access the models
models <- models(sc.obj)
models[[1]]
## Model for learner.id=classif.cvglmnet; learner.class=classif.cvglmnet
## Trained on: task.id = data; obs = 112; features = 207
## Hyperparameters: nlambda=100,alpha=1
Using the data-split and the models trained in previous step, we can use the
function make.predictions
in order to apply the models on the test instances
in the data-split. The predictions will be saved in the pred_matrix
slot of
the SIAMCAT
object.
sc.obj <- make.predictions(sc.obj)
pred_matrix <- pred_matrix(sc.obj)
head(pred_matrix)
## CV_rep1 CV_rep2
## CCIS27304052ST-3-0 0.06133438 0.04734542
## CCIS15794887ST-4-0 0.18626645 0.05338549
## CCIS74726977ST-3-0 0.29836857 0.50019920
## CCIS16561622ST-4-0 0.58237940 0.59731029
## CCIS79210440ST-3-0 0.26647927 0.21802187
## CCIS82507866ST-3-0 0.12706887 0.11028804
In the final part, we want to find out how well the model performed and which
microbial species had been selected in the model. In order to do so, we first
calculate how well the predictions fit the real data using the function
evaluate.predictions
. This function calculates the Area Under the Receiver
Operating Characteristic (ROC) Curve (AU-ROC) and the Precision Recall (PR)
Curve for each resampled cross-validation run.
sc.obj <- evaluate.predictions(sc.obj)
## Evaluated predictions successfully.
To plot the results of the evaluation, we can use the function
model.evaluation.plot
, which produces a pdf-file showing the ROC and PR
Curves for the different resamples runs as well as the mean ROC and PR Curve.
model.evaluation.plot(sc.obj)
The final plot produced by SIAMCAT
is the model interpretation plot, created
by the model.interpretation.plot
function. The plot shows for the top
selected features the
model weights (and how robust they are) as a barplot,
a heatmap with the z-scores or fold changes for the top selected features, and
a boxplot showing the proportions of weight per model which is captured by the top selected features.
Additionally, the distribution of metadata is shown in a heatmap below.
The function again produces a pdf-file optimized for a landscape DIN-A4 plotting region.
model.interpretation.plot(
sc.obj,
fn.plot = 'interpretation.pdf',
consens.thres = 0.5,
limits = c(-3, 3),
heatmap.type = 'zscore',
)
The resulting plot looks like this:
sessionInfo()
## R version 4.1.1 (2021-08-10)
## Platform: x86_64-pc-linux-gnu (64-bit)
## Running under: Ubuntu 20.04.3 LTS
##
## Matrix products: default
## BLAS: /home/biocbuild/bbs-3.14-bioc/R/lib/libRblas.so
## LAPACK: /home/biocbuild/bbs-3.14-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] stats graphics grDevices utils datasets methods base
##
## other attached packages:
## [1] ggpubr_0.4.0 SIAMCAT_1.14.0 phyloseq_1.38.0 mlr_2.19.0
## [5] ParamHelpers_1.14 forcats_0.5.1 stringr_1.4.0 dplyr_1.0.7
## [9] purrr_0.3.4 readr_2.0.2 tidyr_1.1.4 tibble_3.1.5
## [13] ggplot2_3.3.5 tidyverse_1.3.1 BiocStyle_2.22.0
##
## loaded via a namespace (and not attached):
## [1] readxl_1.3.1 backports_1.2.1 fastmatch_1.1-3
## [4] corrplot_0.90 plyr_1.8.6 igraph_1.2.7
## [7] splines_4.1.1 GenomeInfoDb_1.30.0 gridBase_0.4-7
## [10] digest_0.6.28 foreach_1.5.1 htmltools_0.5.2
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## [22] modelr_0.1.8 matrixStats_0.61.0 vroom_1.5.5
## [25] prettyunits_1.1.1 colorspace_2.0-2 rvest_1.0.2
## [28] haven_2.4.3 xfun_0.27 crayon_1.4.1
## [31] RCurl_1.98-1.5 jsonlite_1.7.2 survival_3.2-13
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## [46] infotheo_1.2.0 DBI_1.1.1 rstatix_0.7.0
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## [52] bit_4.0.4 stats4_4.1.1 glmnet_4.1-2
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