This vignette demonstrates how to analyse miRNA:Competing interactions via ceRNAnetsim
package. The perturbations in the miRNA:target interactions are handled step by step in ceRNAnetsim
. The package calculates and simulates regulation of miRNA:competing RNA interactions based on amounts of miRNA and the targets and interaction factors.
The ceRNAnetsim
works by executing following steps:
priming_graph()
function so that it’s converted into a graph. This function makes calculations that are depended on miRNA amount, target (competing) amount and the interaction factors. It determines the efficiency of miRNA to each target and saves that values as edge data. All calculations are performed in edge data. After that, results of calculations are used in node data.update_variables()
or update_how()
functions.update_nodes()
.simulate()
or simulate_vis()
.The workflow of ceRNAnetsim
are shown as following:
Below is the minimal data that can be used with ceRNAnetsim.
data("minsamp")
minsamp %>%
select(1:4)
#> competing miRNA Competing_expression miRNA_expression
#> 1 Gene1 Mir1 10000 1000
#> 2 Gene2 Mir1 10000 1000
#> 3 Gene3 Mir1 5000 1000
#> 4 Gene4 Mir1 10000 1000
#> 5 Gene4 Mir2 10000 2000
#> 6 Gene5 Mir2 5000 2000
#> 7 Gene6 Mir2 10000 2000
The table is actually constructed by merging three different tables:
So, the basic_data
table is constructed by merging following tables:
data("minsamp")
minsamp %>%
select(competing, Competing_expression) %>%
distinct() -> gene_expression
gene_expression
#> competing Competing_expression
#> 1 Gene1 10000
#> 2 Gene2 10000
#> 3 Gene3 5000
#> 4 Gene4 10000
#> 5 Gene5 5000
#> 6 Gene6 10000
Third table should contain miRNA:gene interactions per row. The ceRNAnetsim
will assume first column contains competing RNA names and second column to be miRNA names. If the order is different the user should indicate column names accordingly.
interaction_simple
#> competing miRNA
#> 1 Gene1 Mir1
#> 2 Gene2 Mir1
#> 3 Gene3 Mir1
#> 4 Gene4 Mir1
#> 5 Gene4 Mir2
#> 6 Gene5 Mir2
#> 7 Gene6 Mir2
The three tables can be joined in R (as shown below) or elsewhere to have interaction and expression data altogether in expected format.
interaction_simple %>%
inner_join(gene_expression, by = "competing") %>%
inner_join(mirna_expression, "miRNA") -> basic_data
basic_data
#> competing miRNA Competing_expression miRNA_expression
#> 1 Gene1 Mir1 10000 1000
#> 2 Gene2 Mir1 10000 1000
#> 3 Gene3 Mir1 5000 1000
#> 4 Gene4 Mir1 10000 1000
#> 5 Gene4 Mir2 10000 2000
#> 6 Gene5 Mir2 5000 2000
#> 7 Gene6 Mir2 10000 2000
minsamp
datasetceRNAnetsim processes your dataset as graph object and simulates competing behaviours of targets when steady-state is perturbed via expression level changes in one or more genes. Let’s go over three steps:
In first step, the expression and interaction table is converted into graph/network. tidygraph
is used importing the data thus both node and edge data are accessible as tables if needed. priming_graph
generates many columns in edge/node table which are mostly for internal use.
#Convertion of dataset to graph.
priming_graph(basic_data, competing_count = Competing_expression, miRNA_count =miRNA_expression)
#> Warning in priming_graph(basic_data, competing_count = Competing_expression, : First column is processed as competing and the second as miRNA.
#> # A tbl_graph: 8 nodes and 7 edges
#> #
#> # A rooted tree
#> #
#> # A tibble: 8 × 7
#> name type node_id initial_count count_pre count_current changes_variable
#> <chr> <chr> <int> <dbl> <dbl> <dbl> <chr>
#> 1 Gene1 Competing 1 10000 10000 10000 Competing
#> 2 Gene2 Competing 2 10000 10000 10000 Competing
#> 3 Gene3 Competing 3 5000 5000 5000 Competing
#> 4 Gene4 Competing 4 10000 10000 10000 Competing
#> 5 Gene5 Competing 5 5000 5000 5000 Competing
#> 6 Gene6 Competing 6 10000 10000 10000 Competing
#> # ℹ 2 more rows
#> #
#> # A tibble: 7 × 19
#> from to Competing_name miRNA_name Competing_expression miRNA_expression
#> <int> <int> <chr> <chr> <dbl> <dbl>
#> 1 1 7 Gene1 Mir1 10000 1000
#> 2 2 7 Gene2 Mir1 10000 1000
#> 3 3 7 Gene3 Mir1 5000 1000
#> # ℹ 4 more rows
#> # ℹ 13 more variables: dummy <dbl>, afff_factor <dbl>, degg_factor <dbl>,
#> # comp_count_list <list>, comp_count_pre <dbl>, comp_count_current <dbl>,
#> # mirna_count_list <list>, mirna_count_pre <dbl>, mirna_count_current <dbl>,
#> # mirna_count_per_dep <dbl>, effect_current <dbl>, effect_pre <dbl>,
#> # effect_list <list>
update_how
function can be used to simulate a change in the network. (If multiple chnages are aimed to be used as trigger, update_variables()
function should be used).
In the example below, expression level of “Gene2” is increased to two-fold.
priming_graph(basic_data, competing_count = Competing_expression,
miRNA_count =miRNA_expression) %>%
update_how(node_name = "Gene2", how=2)
#> Warning in priming_graph(basic_data, competing_count = Competing_expression, : First column is processed as competing and the second as miRNA.
#> # A tbl_graph: 8 nodes and 7 edges
#> #
#> # A rooted tree
#> #
#> # A tibble: 8 × 7
#> name type node_id initial_count count_pre count_current changes_variable
#> <chr> <chr> <int> <dbl> <dbl> <dbl> <chr>
#> 1 Gene1 Competing 1 10000 10000 10000 Competing
#> 2 Gene2 Competing 2 10000 10000 20000 Up
#> 3 Gene3 Competing 3 5000 5000 5000 Competing
#> 4 Gene4 Competing 4 10000 10000 10000 Competing
#> 5 Gene5 Competing 5 5000 5000 5000 Competing
#> 6 Gene6 Competing 6 10000 10000 10000 Competing
#> # ℹ 2 more rows
#> #
#> # A tibble: 7 × 19
#> from to Competing_name miRNA_name Competing_expression miRNA_expression
#> <int> <int> <chr> <chr> <dbl> <dbl>
#> 1 1 7 Gene1 Mir1 10000 1000
#> 2 2 7 Gene2 Mir1 10000 1000
#> 3 3 7 Gene3 Mir1 5000 1000
#> # ℹ 4 more rows
#> # ℹ 13 more variables: dummy <dbl>, afff_factor <dbl>, degg_factor <dbl>,
#> # comp_count_list <list>, comp_count_pre <dbl>, comp_count_current <dbl>,
#> # mirna_count_list <list>, mirna_count_pre <dbl>, mirna_count_current <dbl>,
#> # mirna_count_per_dep <dbl>, effect_current <dbl>, effect_pre <dbl>,
#> # effect_list <list>
You can see the current count of Gene2 node is 20000 and its change is denoted as “Up” in changes_variable
column in node table data.
Finally, with the help of simulate
function, the effect of expression change (i.e. the trigger) on overall network. The example code advances only for 5 cycles.
priming_graph(basic_data, competing_count = Competing_expression,
miRNA_count =miRNA_expression) %>%
update_how(node_name = "Gene2", how=2) %>%
simulate(cycle = 5)
#> Warning in priming_graph(basic_data, competing_count = Competing_expression, : First column is processed as competing and the second as miRNA.
#> # A tbl_graph: 8 nodes and 7 edges
#> #
#> # A rooted tree
#> #
#> # A tibble: 8 × 7
#> name type node_id initial_count count_pre count_current changes_variable
#> <chr> <chr> <int> <dbl> <dbl> <dbl> <chr>
#> 1 Gene1 Competing 1 10000 10062. 10062. Down
#> 2 Gene2 Competing 2 10000 19845. 19845. Down
#> 3 Gene3 Competing 3 5000 5031. 5031. Down
#> 4 Gene4 Competing 4 10000 10059. 10059. Up
#> 5 Gene5 Competing 5 5000 5001. 5001. Down
#> 6 Gene6 Competing 6 10000 10002. 10002. Down
#> # ℹ 2 more rows
#> #
#> # A tibble: 7 × 20
#> from to Competing_name miRNA_name Competing_expression miRNA_expression
#> <int> <int> <chr> <chr> <dbl> <dbl>
#> 1 1 7 Gene1 Mir1 10000 1000
#> 2 2 7 Gene2 Mir1 10000 1000
#> 3 3 7 Gene3 Mir1 5000 1000
#> # ℹ 4 more rows
#> # ℹ 14 more variables: dummy <dbl>, afff_factor <dbl>, degg_factor <dbl>,
#> # comp_count_list <list>, comp_count_pre <dbl>, comp_count_current <dbl>,
#> # mirna_count_list <list>, mirna_count_pre <dbl>, mirna_count_current <dbl>,
#> # mirna_count_per_dep <dbl>, effect_current <dbl>, effect_pre <dbl>,
#> # effect_list <list>, mirna_count_per_comp <dbl>
count_current
column indicate results after 5 cycle of calculations for each node. You can see the gene expression changes after this perturbation and simulation. This table can be obtained easily at following:
priming_graph(basic_data, competing_count = Competing_expression,
miRNA_count =miRNA_expression) %>%
update_how(node_name = "Gene2", how=2) %>%
simulate(cycle = 5)%>%
as_tibble()%>%
select(name, initial_count, count_current)
#> Warning in priming_graph(basic_data, competing_count = Competing_expression, : First column is processed as competing and the second as miRNA.
#> # A tibble: 8 × 3
#> name initial_count count_current
#> <chr> <dbl> <dbl>
#> 1 Gene1 10000 10062.
#> 2 Gene2 10000 19845.
#> 3 Gene3 5000 5031.
#> 4 Gene4 10000 10059.
#> 5 Gene5 5000 5001.
#> 6 Gene6 10000 10002.
#> 7 Mir1 1000 1000
#> 8 Mir2 2000 2000
ceRNAnetsim also provides the simulation of gene knockdown in the network. In normal conditions, when a gene is up or down regulated, it is considered that amounts of gene transcripts change depended on interactions. But, the transcripts of the gene are not observed in the system when it is knocked down. To achieve this case, you just need to define how
argument to 0 (zero) in update_how
function.
priming_graph(basic_data, competing_count = Competing_expression,
miRNA_count =miRNA_expression) %>%
update_how(node_name = "Gene2", how=0) %>%
simulate(cycle = 5)
#> Warning in priming_graph(basic_data, competing_count = Competing_expression, : First column is processed as competing and the second as miRNA.
#> # A tbl_graph: 8 nodes and 7 edges
#> #
#> # A rooted tree
#> #
#> # A tibble: 8 × 7
#> name type node_id initial_count count_pre count_current changes_variable
#> <chr> <chr> <int> <dbl> <dbl> <dbl> <chr>
#> 1 Gene1 Competing 1 10000 9886. 9886. Up
#> 2 Gene2 Competing 2 10000 0 0 Competing
#> 3 Gene3 Competing 3 5000 4943. 4943. Up
#> 4 Gene4 Competing 4 10000 9891. 9891. Down
#> 5 Gene5 Competing 5 5000 4998. 4998. Up
#> 6 Gene6 Competing 6 10000 9997. 9997. Up
#> # ℹ 2 more rows
#> #
#> # A tibble: 7 × 20
#> from to Competing_name miRNA_name Competing_expression miRNA_expression
#> <int> <int> <chr> <chr> <dbl> <dbl>
#> 1 1 7 Gene1 Mir1 10000 1000
#> 2 2 7 Gene2 Mir1 10000 1000
#> 3 3 7 Gene3 Mir1 5000 1000
#> # ℹ 4 more rows
#> # ℹ 14 more variables: dummy <dbl>, afff_factor <dbl>, degg_factor <dbl>,
#> # comp_count_list <list>, comp_count_pre <dbl>, comp_count_current <dbl>,
#> # mirna_count_list <list>, mirna_count_pre <dbl>, mirna_count_current <dbl>,
#> # mirna_count_per_dep <dbl>, effect_current <dbl>, effect_pre <dbl>,
#> # effect_list <list>, mirna_count_per_comp <dbl>
So, if Gene2 is knocked down, there will be more miRNA (Mir1 to be exact) available for Gene1, Gene3 and Gene4, thus lowering their transcript levels. Since Gene4 is has lower expression level, we can observe minute changes in Gene5 and Gene6 levels due to more miRNA (Mir2) being available for them. These changes can be observed in current_count
column.
Briefly, ceRNAnetsim utilizes the change(s) as trigger and calculates regulation of targets according to miRNA:target and target:total target ratios.
minsamp
datasetMinimal sample minsamp
is processed with priming_graph()
function in first step. This provides conversion of dataset from data frame to graph object. This step comprises of:
aff_factor
argument and any column that effects degradation of target RNA should be as a vector to deg_factor
argument.minsamp
#> competing miRNA Competing_expression miRNA_expression seed_type region energy
#> 1 Gene1 Mir1 10000 1000 0.43 0.30 -20
#> 2 Gene2 Mir1 10000 1000 0.43 0.01 -15
#> 3 Gene3 Mir1 5000 1000 0.32 0.40 -14
#> 4 Gene4 Mir1 10000 1000 0.23 0.50 -10
#> 5 Gene4 Mir2 10000 2000 0.35 0.90 -12
#> 6 Gene5 Mir2 5000 2000 0.05 0.40 -11
#> 7 Gene6 Mir2 10000 2000 0.01 0.80 -25
priming_graph(minsamp,
competing_count = Competing_expression,
miRNA_count = miRNA_expression,
aff_factor = c(energy, seed_type),
deg_factor = region)
#> Warning in priming_graph(minsamp, competing_count = Competing_expression, : First column is processed as competing and the second as miRNA.
#> # A tbl_graph: 8 nodes and 7 edges
#> #
#> # A rooted tree
#> #
#> # A tibble: 8 × 7
#> name type node_id initial_count count_pre count_current changes_variable
#> <chr> <chr> <int> <dbl> <dbl> <dbl> <chr>
#> 1 Gene1 Competing 1 10000 10000 10000 Competing
#> 2 Gene2 Competing 2 10000 10000 10000 Competing
#> 3 Gene3 Competing 3 5000 5000 5000 Competing
#> 4 Gene4 Competing 4 10000 10000 10000 Competing
#> 5 Gene5 Competing 5 5000 5000 5000 Competing
#> 6 Gene6 Competing 6 10000 10000 10000 Competing
#> # ℹ 2 more rows
#> #
#> # A tibble: 7 × 22
#> from to Competing_name miRNA_name Competing_expression miRNA_expression
#> <int> <int> <chr> <chr> <dbl> <dbl>
#> 1 1 7 Gene1 Mir1 10000 1000
#> 2 2 7 Gene2 Mir1 10000 1000
#> 3 3 7 Gene3 Mir1 5000 1000
#> # ℹ 4 more rows
#> # ℹ 16 more variables: energy <dbl>, seed_type <dbl>, region <dbl>,
#> # dummy <dbl>, afff_factor <dbl>, degg_factor <dbl>, comp_count_list <list>,
#> # comp_count_pre <dbl>, comp_count_current <dbl>, mirna_count_list <list>,
#> # mirna_count_pre <dbl>, mirna_count_current <dbl>,
#> # mirna_count_per_dep <dbl>, effect_current <dbl>, effect_pre <dbl>,
#> # effect_list <list>
In the processed data, the values are carried as node variables and many more columns are initialized which are to be used in subsequent steps.
In the steady-state, the miRNA degradation effect on gene expression is assumed to be stable (i.e. in equilibrium). But, if one or more nodes have altered expression level, the system tends to reach steady-state again.
The ceRNAnetsim
package utilizes two methods to simulate change in expression level, update_how()
and update_variables()
functions provide unstable state from which calculations are triggered to reach steady-state.
If updating expression level of single node is desired then update_how()
function should be used. In the example below, expression level of Gene4 is increased 2-fold.
minsamp %>%
priming_graph(competing_count = Competing_expression,
miRNA_count = miRNA_expression,
aff_factor = c(energy, seed_type),
deg_factor = region) %>%
update_how(node_name = "Gene4", how = 2) %>%
activate(edges)%>%
# following line is just for focusing on necessary
# columns to see the change in edge data
select(3:4,comp_count_pre,comp_count_current)
#> Warning in priming_graph(., competing_count = Competing_expression, miRNA_count = miRNA_expression, : First column is processed as competing and the second as miRNA.
#> # A tbl_graph: 8 nodes and 7 edges
#> #
#> # A rooted tree
#> #
#> # A tibble: 7 × 6
#> from to Competing_name miRNA_name comp_count_pre comp_count_current
#> <int> <int> <chr> <chr> <dbl> <dbl>
#> 1 1 7 Gene1 Mir1 10000 10000
#> 2 2 7 Gene2 Mir1 10000 10000
#> 3 3 7 Gene3 Mir1 5000 5000
#> 4 4 7 Gene4 Mir1 10000 20000
#> 5 4 8 Gene4 Mir2 10000 20000
#> 6 5 8 Gene5 Mir2 5000 5000
#> # ℹ 1 more row
#> #
#> # A tibble: 8 × 7
#> name type node_id initial_count count_pre count_current changes_variable
#> <chr> <chr> <int> <dbl> <dbl> <dbl> <chr>
#> 1 Gene1 Competing 1 10000 10000 10000 Competing
#> 2 Gene2 Competing 2 10000 10000 10000 Competing
#> 3 Gene3 Competing 3 5000 5000 5000 Competing
#> # ℹ 5 more rows
The update_variables()
function uses an external dataset which has number of rows equal to number of nodes in graph. The external dataset might include changed and unchanged expression values for each node.
Load the new_count
dataset (provided with package sample data) in which expression level of Gene2 is increased 2 fold (from 10,000 to 20,000). Note that variables of the dataset included updated variables must be named as “Competing”, “miRNA”, “miRNA_count” and “Competing_count”.
data(new_counts)
new_counts
#> Competing miRNA Competing_count miRNA_count
#> 1 Gene1 Mir1 10000 1000
#> 2 Gene2 Mir1 20000 1000
#> 3 Gene3 Mir1 5000 1000
#> 4 Gene4 Mir1 10000 1000
#> 5 Gene4 Mir2 10000 2000
#> 6 Gene5 Mir2 5000 2000
#> 7 Gene6 Mir2 10000 2000
update_variables()
function replaces the existing expression values with new values. The function checks for updates in all rows after importing expression values, thus it’s possible to introduce multiple changes at once.
minsamp %>%
priming_graph(competing_count = Competing_expression,
miRNA_count = miRNA_expression,
aff_factor = c(energy, seed_type),
deg_factor = region) %>%
update_variables(current_counts = new_counts)
#> Warning in priming_graph(., competing_count = Competing_expression, miRNA_count = miRNA_expression, : First column is processed as competing and the second as miRNA.
#> # A tbl_graph: 8 nodes and 7 edges
#> #
#> # A rooted tree
#> #
#> # A tibble: 8 × 7
#> name type node_id initial_count count_pre count_current changes_variable
#> <chr> <chr> <int> <dbl> <dbl> <dbl> <chr>
#> 1 Gene1 Competing 1 10000 10000 10000 Competing
#> 2 Gene2 Competing 2 10000 10000 20000 Up
#> 3 Gene3 Competing 3 5000 5000 5000 Competing
#> 4 Gene4 Competing 4 10000 10000 10000 Competing
#> 5 Gene5 Competing 5 5000 5000 5000 Competing
#> 6 Gene6 Competing 6 10000 10000 10000 Competing
#> # ℹ 2 more rows
#> #
#> # A tibble: 7 × 22
#> from to Competing_name miRNA_name Competing_expression miRNA_expression
#> <int> <int> <chr> <chr> <dbl> <dbl>
#> 1 1 7 Gene1 Mir1 10000 1000
#> 2 2 7 Gene2 Mir1 10000 1000
#> 3 3 7 Gene3 Mir1 5000 1000
#> # ℹ 4 more rows
#> # ℹ 16 more variables: energy <dbl>, seed_type <dbl>, region <dbl>,
#> # dummy <dbl>, afff_factor <dbl>, degg_factor <dbl>, comp_count_list <list>,
#> # comp_count_pre <dbl>, comp_count_current <dbl>, mirna_count_list <list>,
#> # mirna_count_pre <dbl>, mirna_count_current <dbl>,
#> # mirna_count_per_dep <dbl>, effect_current <dbl>, effect_pre <dbl>,
#> # effect_list <list>
The functions update_variables()
and update_how()
updates edge data. In these functions, update_nodes()
function is applied in order to reflect changes in edge data over to node data. In other words, if there’s a change in edge data, nodes can be updated accordingly with update_nodes()
function.
minsamp %>%
priming_graph(competing_count = Competing_expression,
miRNA_count = miRNA_expression,
aff_factor = c(energy, seed_type),
deg_factor = region) %>%
update_how("Gene4", how = 2)
#> Warning in priming_graph(., competing_count = Competing_expression, miRNA_count = miRNA_expression, : First column is processed as competing and the second as miRNA.
#> # A tbl_graph: 8 nodes and 7 edges
#> #
#> # A rooted tree
#> #
#> # A tibble: 8 × 7
#> name type node_id initial_count count_pre count_current changes_variable
#> <chr> <chr> <int> <dbl> <dbl> <dbl> <chr>
#> 1 Gene1 Competing 1 10000 10000 10000 Competing
#> 2 Gene2 Competing 2 10000 10000 10000 Competing
#> 3 Gene3 Competing 3 5000 5000 5000 Competing
#> 4 Gene4 Competing 4 10000 10000 20000 Up
#> 5 Gene5 Competing 5 5000 5000 5000 Competing
#> 6 Gene6 Competing 6 10000 10000 10000 Competing
#> # ℹ 2 more rows
#> #
#> # A tibble: 7 × 22
#> from to Competing_name miRNA_name Competing_expression miRNA_expression
#> <int> <int> <chr> <chr> <dbl> <dbl>
#> 1 1 7 Gene1 Mir1 10000 1000
#> 2 2 7 Gene2 Mir1 10000 1000
#> 3 3 7 Gene3 Mir1 5000 1000
#> # ℹ 4 more rows
#> # ℹ 16 more variables: energy <dbl>, seed_type <dbl>, region <dbl>,
#> # dummy <dbl>, afff_factor <dbl>, degg_factor <dbl>, comp_count_list <list>,
#> # comp_count_pre <dbl>, comp_count_current <dbl>, mirna_count_list <list>,
#> # mirna_count_pre <dbl>, mirna_count_current <dbl>,
#> # mirna_count_per_dep <dbl>, effect_current <dbl>, effect_pre <dbl>,
#> # effect_list <list>
# OR
# minsamp %>%
# priming_graph(competing_count = Competing_expression,
# miRNA_count = miRNA_expression,
# aff_factor = c(energy, seed_type),
# deg_factor = region) %>%
# update_variables(current_counts = new_counts)
Change in expression level of one or more nodes will trigger a perturbation in the system which will effect neighboring miRNA:target interactions. The effect will propagate and iterate over until it reaches steady-state.
With simulate()
function the changes in the system, are calculated iteratively. For example, in the example below, simulation will proceed ten cycles only. In simulation of the regulation, the important argument is threshold
which provides to specify absolute minimum amount of change required to be considered changed element as up or down.
minsamp %>%
priming_graph(competing_count = Competing_expression,
miRNA_count = miRNA_expression,
aff_factor = c(energy, seed_type),
deg_factor = region) %>%
update_how("Gene4", how = 2) %>%
simulate(cycle=10) #threshold with default 0.
#> Warning in priming_graph(., competing_count = Competing_expression, miRNA_count = miRNA_expression, : First column is processed as competing and the second as miRNA.
#> # A tbl_graph: 8 nodes and 7 edges
#> #
#> # A rooted tree
#> #
#> # A tibble: 8 × 7
#> name type node_id initial_count count_pre count_current changes_variable
#> <chr> <chr> <int> <dbl> <dbl> <dbl> <chr>
#> 1 Gene1 Competing 1 10000 10027. 10027. Competing
#> 2 Gene2 Competing 2 10000 10001. 10001. Competing
#> 3 Gene3 Competing 3 5000 5009. 5009. Competing
#> 4 Gene4 Competing 4 10000 19806. 19806. Competing
#> 5 Gene5 Competing 5 5000 5024. 5024. Competing
#> 6 Gene6 Competing 6 10000 10044. 10044. Competing
#> # ℹ 2 more rows
#> #
#> # A tibble: 7 × 23
#> from to Competing_name miRNA_name Competing_expression miRNA_expression
#> <int> <int> <chr> <chr> <dbl> <dbl>
#> 1 1 7 Gene1 Mir1 10000 1000
#> 2 2 7 Gene2 Mir1 10000 1000
#> 3 3 7 Gene3 Mir1 5000 1000
#> # ℹ 4 more rows
#> # ℹ 17 more variables: energy <dbl>, seed_type <dbl>, region <dbl>,
#> # dummy <dbl>, afff_factor <dbl>, degg_factor <dbl>, comp_count_list <list>,
#> # comp_count_pre <dbl>, comp_count_current <dbl>, mirna_count_list <list>,
#> # mirna_count_pre <dbl>, mirna_count_current <dbl>,
#> # mirna_count_per_dep <dbl>, effect_current <dbl>, effect_pre <dbl>,
#> # effect_list <list>, mirna_count_per_comp <dbl>
simulate()
saves the expression level of previous iterations in list columns in edge data. The changes in expression level throughout the simulate cycles are accessible with standard dplyr
functions. For example:
minsamp %>%
priming_graph(competing_count = Competing_expression,
miRNA_count = miRNA_expression,
aff_factor = c(energy, seed_type),
deg_factor = region) %>%
update_how("Gene4", how = 2) %>%
simulate(cycle=10) %>%
activate(edges) %>% #from tidygraph package
select(comp_count_list, mirna_count_list) %>%
as_tibble()
#> Warning in priming_graph(., competing_count = Competing_expression, miRNA_count = miRNA_expression, : First column is processed as competing and the second as miRNA.
#> # A tibble: 7 × 4
#> from to comp_count_list mirna_count_list
#> <int> <int> <list> <list>
#> 1 1 7 <dbl [11]> <dbl [11]>
#> 2 2 7 <dbl [11]> <dbl [11]>
#> 3 3 7 <dbl [11]> <dbl [11]>
#> 4 4 7 <dbl [11]> <dbl [11]>
#> 5 4 8 <dbl [11]> <dbl [11]>
#> 6 5 8 <dbl [11]> <dbl [11]>
#> 7 6 8 <dbl [11]> <dbl [11]>
Here, comp_count_list
and mirna_count_list
are list-columns which track changes in both competing RNA and miRNA levels. In the sample above, “Gene4” has initial expression level of 10000 (after trigger, it’s initial expression is 20000) and reached level of 19806 at 9th cycle (count_pre) and also stayed at 19806 in last cycle (count_current). The full history of expression level for Gene4 is as follows:
#> [1] 10000 19803 19806 19806 19806 19806 19806 19806 19806 19806 19806
Actually, Gene4 seems like reached steady-state in iteration 4. But, this approach is sensitive to even small decimal numbers. So, threshold argument could be used to ignore very small decimal numbers. With a threshold value the system can reach steady-state early, like following.
minsamp %>%
priming_graph(competing_count = Competing_expression,
miRNA_count = miRNA_expression,
aff_factor = c(energy, seed_type),
deg_factor = region) %>%
update_how("Gene4", how = 2) %>%
simulate(cycle=3, threshold = 1)
#> Warning in priming_graph(., competing_count = Competing_expression, miRNA_count = miRNA_expression, : First column is processed as competing and the second as miRNA.
#> # A tbl_graph: 8 nodes and 7 edges
#> #
#> # A rooted tree
#> #
#> # A tibble: 8 × 7
#> name type node_id initial_count count_pre count_current changes_variable
#> <chr> <chr> <int> <dbl> <dbl> <dbl> <chr>
#> 1 Gene1 Competing 1 10000 10027. 10027. Competing
#> 2 Gene2 Competing 2 10000 10001. 10001. Competing
#> 3 Gene3 Competing 3 5000 5009. 5009. Competing
#> 4 Gene4 Competing 4 10000 19806. 19806. Competing
#> 5 Gene5 Competing 5 5000 5024. 5024. Competing
#> 6 Gene6 Competing 6 10000 10044. 10044. Competing
#> # ℹ 2 more rows
#> #
#> # A tibble: 7 × 23
#> from to Competing_name miRNA_name Competing_expression miRNA_expression
#> <int> <int> <chr> <chr> <dbl> <dbl>
#> 1 1 7 Gene1 Mir1 10000 1000
#> 2 2 7 Gene2 Mir1 10000 1000
#> 3 3 7 Gene3 Mir1 5000 1000
#> # ℹ 4 more rows
#> # ℹ 17 more variables: energy <dbl>, seed_type <dbl>, region <dbl>,
#> # dummy <dbl>, afff_factor <dbl>, degg_factor <dbl>, comp_count_list <list>,
#> # comp_count_pre <dbl>, comp_count_current <dbl>, mirna_count_list <list>,
#> # mirna_count_pre <dbl>, mirna_count_current <dbl>,
#> # mirna_count_per_dep <dbl>, effect_current <dbl>, effect_pre <dbl>,
#> # effect_list <list>, mirna_count_per_comp <dbl>
The vis_graph()
function is used for visualization of the graph object. The initial graph object (steady-state) is visualized as following:
minsamp %>%
priming_graph(competing_count = Competing_expression,
miRNA_count = miRNA_expression,
aff_factor = c(energy, seed_type),
deg_factor = region) %>%
vis_graph(title = "Minsamp initial Graph")
Also, The graph can be visualized at any step of process, for example, after simulation of 3 cycles the graph will look like:
minsamp %>%
priming_graph(competing_count = Competing_expression,
miRNA_count = miRNA_expression,
aff_factor = c(energy, seed_type),
deg_factor = region) %>%
update_variables(current_counts = new_counts) %>%
simulate(3) %>%
vis_graph(title = "Minsamp Graph After 3 Iteration")
On the other hand, the network of each step can be plotted individually by using simulate_vis()
function. simulate_vis()
processes the given network just like simulate()
function does while saving image of each step.
minsamp %>%
priming_graph(competing_count = Competing_expression,
miRNA_count = miRNA_expression,
aff_factor = c(energy, seed_type),
deg_factor = region) %>%
update_variables(current_counts = new_counts) %>%
simulate_vis(3, title = "Minsamp Graph After Each Iteration")
Note: Animated gif above was generated by online service. Actually, workflow gives the frames which include condition of each iteration. Note that you must use a terminal or online service, if you want to generate the animated gif.
sessionInfo()
#> R version 4.3.0 RC (2023-04-13 r84269)
#> Platform: x86_64-pc-linux-gnu (64-bit)
#> Running under: Ubuntu 22.04.2 LTS
#>
#> Matrix products: default
#> BLAS: /home/biocbuild/bbs-3.17-bioc/R/lib/libRblas.so
#> LAPACK: /usr/lib/x86_64-linux-gnu/lapack/liblapack.so.3.10.0
#>
#> 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
#>
#> time zone: America/New_York
#> tzcode source: system (glibc)
#>
#> attached base packages:
#> [1] stats graphics grDevices utils datasets methods base
#>
#> other attached packages:
#> [1] ceRNAnetsim_1.12.0 tidygraph_1.2.3 dplyr_1.1.2
#>
#> loaded via a namespace (and not attached):
#> [1] viridis_0.6.2 sass_0.4.5 utf8_1.2.3 future_1.32.0
#> [5] generics_0.1.3 tidyr_1.3.0 listenv_0.9.0 digest_0.6.31
#> [9] magrittr_2.0.3 evaluate_0.20 grid_4.3.0 fastmap_1.1.1
#> [13] jsonlite_1.8.4 ggrepel_0.9.3 gridExtra_2.3 purrr_1.0.1
#> [17] fansi_1.0.4 viridisLite_0.4.1 scales_1.2.1 tweenr_2.0.2
#> [21] codetools_0.2-19 jquerylib_0.1.4 cli_3.6.1 graphlayouts_0.8.4
#> [25] rlang_1.1.0 polyclip_1.10-4 parallelly_1.35.0 munsell_0.5.0
#> [29] withr_2.5.0 cachem_1.0.7 yaml_2.3.7 tools_4.3.0
#> [33] parallel_4.3.0 colorspace_2.1-0 ggplot2_3.4.2 globals_0.16.2
#> [37] png_0.1-8 vctrs_0.6.2 R6_2.5.1 lifecycle_1.0.3
#> [41] MASS_7.3-59 furrr_0.3.1 ggraph_2.1.0 pkgconfig_2.0.3
#> [45] pillar_1.9.0 bslib_0.4.2 gtable_0.3.3 glue_1.6.2
#> [49] Rcpp_1.0.10 ggforce_0.4.1 highr_0.10 xfun_0.39
#> [53] tibble_3.2.1 tidyselect_1.2.0 knitr_1.42 farver_2.1.1
#> [57] htmltools_0.5.5 igraph_1.4.2 labeling_0.4.2 rmarkdown_2.21
#> [61] compiler_4.3.0
See the other vignettes for more information.