The hardware and bandwidth for this mirror is donated by dogado GmbH, the Webhosting and Full Service-Cloud Provider. Check out our Wordpress Tutorial.
If you wish to report a bug, or if you are interested in having us mirror your free-software or open-source project, please feel free to contact us at mirror[@]dogado.de.
treestructure
Identification of hidden population structure in time-scaled phylogenies
Erik Volz, Carsten Wiuf, Yonatan Grad, Simon Frost, Ann Dennis, Xavier Didelot, bioRxiv 704528; https://doi.org/10.1101/704528
This example shows trestruct
applied to a simulated structured coalescent tree that includes samples from a large constant size population and samples from three small ‘outbreaks’ which are growing exponentially. These simulations were generated with the phydynR
package.
Load the tree:
( tree <- ape::read.tree( system.file('sim.nwk', package='treestructure') ) )
#>
#> Phylogenetic tree with 275 tips and 274 internal nodes.
#>
#> Tip labels:
#> 1, 1, 1, 1, 1, 1, ...
#>
#> Rooted; includes branch lengths.
Note that the tip labels corresponds to the deme of each sample. ‘1’ is the constant size reservoir, and ‘0’ is the exponentially growing deme.
This will run the treestructure algorithm under default setting:
s <- trestruct( tree )
#> Tree has NA or duplicated tip labels. Adding a unique id.
#> Finding splits under nodes: 276
#> Finding splits under nodes: 276 526
#> Finding splits under nodes: 276 421
#> Finding splits under nodes: 276 473
You can print the results:
print(s)
#> Call:
#> trestruct(tre = tree)
#>
#> Significance level: 0.01
#> Number of clusters: 4
#> Number of partitions: 2
#> Number of taxa in each cluster:
#>
#> 1 2 3 4
#> 25 25 200 25
#> Number of taxa in each partition:
#>
#> 1 2
#> 75 200
#> ...
#> For complete data, use `as.data.frame(...)`
The default plotting behavior uses the ggtree
package if available.
If not, or if desired, ape
plots are available
For subsequent analysis, you may want to turn the treestructure result into a dataframe:
structureData <- as.data.frame( s )
head( structureData )
#> taxon cluster partition
#> 1 1_1 3 2
#> 2 2_1 3 2
#> 3 3_1 3 2
#> 4 4_1 3 2
#> 5 5_1 3 2
#> 6 6_1 3 2
Each cluster and partition assignment is stored as a factor. You could use split
to get a data frame for each partition. Suppose we want a tree corresponding to partition 1:
with ( structureData,
ape::keep.tip(s$tree, taxon[ partition==1 ] )
) -> partition1
partition1
#>
#> Phylogenetic tree with 75 tips and 74 internal nodes.
#>
#> Tip labels:
#> 143_0, 144_0, 145_0, 146_0, 147_0, 148_0, ...
#>
#> Rooted; includes branch lengths.
plot(partition1)
Two parameters will have large influence on results:
level
is the significance level for subdividing a clade into a new cluster. To detect more clusters, increase p
, but note that this will also increase the false positive rate.minCladeSize
controls the smallest allowed cluster size in terms of the number of tips. With a smaller value, smaller clusters may be detected, but computation time will increase.Example:
trestruct( tree, level = .05, minCladeSize = 5 )
#> Tree has NA or duplicated tip labels. Adding a unique id.
#> Finding splits under nodes: 276
#> Finding splits under nodes: 276 526
#> Finding splits under nodes: 276 421
#> Finding splits under nodes: 276 473
#> Finding splits under nodes: 276 359
#> Finding splits under nodes: 276 277
#> Call:
#> trestruct(tre = tree, minCladeSize = 5, level = 0.05)
#>
#> Significance level: 0.05
#> Number of clusters: 6
#> Number of partitions: 2
#> Number of taxa in each cluster:
#>
#> 1 2 3 4 5 6
#> 25 25 25 6 29 165
#> Number of taxa in each partition:
#>
#> 1 2
#> 75 200
#> ...
#> For complete data, use `as.data.frame(...)`
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.