Read, write, and convert phylogenetic tree files using Biopython Bio.Phylo. Use when parsing Newick, Nexus, PhyloXML, or NeXML tree formats, converting between formats, or handling multiple trees.
Reference examples tested with: BioPython 1.83+, scanpy 1.10+
Before using code patterns, verify installed versions match. If versions differ:
pip show <package> then help(module.function) to check signaturesIf code throws ImportError, AttributeError, or TypeError, introspect the installed package and adapt the example to match the actual API rather than retrying.
"Read and convert my phylogenetic tree files" → Parse trees from Newick, Nexus, PhyloXML, or NeXML formats and convert between formats for use in different tools.
Bio.Phylo.read('tree.nwk', 'newick'), Bio.Phylo.convert()Parse, write, and convert phylogenetic tree files in various formats.
from Bio import Phylo
from io import StringIO
| Format | Extension | Description |
|---|---|---|
newick | .nwk, .tre, .tree | Standard format with branch lengths |
nexus | .nex, .nxs | Rich format with annotations (PAUP, MrBayes) |
phyloxml | .xml | XML format with metadata support |
nexml | .nexml | Modern XML format |
cdao | .rdf | RDF format (limited use) |
# Read single tree
tree = Phylo.read('tree.nwk', 'newick')
# Read multiple trees from file
trees = list(Phylo.parse('bootstrap_trees.nwk', 'newick'))
print(f'Loaded {len(trees)} trees')
# Read from string
tree_string = '((A:0.1,B:0.2):0.3,(C:0.4,D:0.5):0.6);'
tree = Phylo.read(StringIO(tree_string), 'newick')
# Read PhyloXML with metadata
tree = Phylo.read('annotated.xml', 'phyloxml')
# Read Nexus (often contains multiple trees)
trees = list(Phylo.parse('mrbayes.nex', 'nexus'))
# Write single tree
Phylo.write(tree, 'output.nwk', 'newick')
# Write multiple trees
Phylo.write(trees, 'all_trees.nwk', 'newick')
# Write to PhyloXML (preserves metadata)
Phylo.write(tree, 'output.xml', 'phyloxml')
# Write to Nexus
Phylo.write(tree, 'output.nex', 'nexus')
tree = Phylo.read('tree.nwk', 'newick')
# Get tree as string (useful for embedding, logging, or API responses)
newick_string = format(tree, 'newick')
print(newick_string) # ((A:0.1,B:0.2):0.3,(C:0.4,D:0.5):0.6);
# Alternative method
newick_string = tree.format('newick')
# Other formats work too
phyloxml_string = format(tree, 'phyloxml')
# Direct file conversion
Phylo.convert('input.nwk', 'newick', 'output.xml', 'phyloxml')
Phylo.convert('mrbayes.nex', 'nexus', 'trees.nwk', 'newick')
# Convert with processing
tree = Phylo.read('input.nwk', 'newick')
tree.ladderize() # Sort branches
Phylo.write(tree, 'sorted.nwk', 'newick')
tree = Phylo.read('tree.nwk', 'newick')
# Print ASCII representation
print(tree)
# ASCII tree diagram
Phylo.draw_ascii(tree)
# Basic tree properties
print(f'Total branch length: {tree.total_branch_length()}')
print(f'Number of terminals: {len(tree.get_terminals())}')
print(f'Is bifurcating: {tree.is_bifurcating()}')
# Get all terminal (leaf) nodes
terminals = tree.get_terminals()
for term in terminals:
print(f'{term.name}: branch_length={term.branch_length}')
# Get all internal nodes
nonterminals = tree.get_nonterminals()
# Get all clades (nodes)
all_clades = list(tree.find_clades())
# Find specific clade by name
clade = tree.find_any(name='Human')
# Simple tree (no branch lengths)
tree = Phylo.read(StringIO('((A,B),(C,D));'), 'newick')
# With branch lengths
tree = Phylo.read(StringIO('((A:0.1,B:0.2):0.3,(C:0.4,D:0.5):0.6);'), 'newick')
# With internal node names
tree = Phylo.read(StringIO('((A,B)AB,(C,D)CD)root;'), 'newick')
# With bootstrap values (internal node names)
tree = Phylo.read(StringIO('((A:0.1,B:0.2)95:0.3,(C:0.4,D:0.5)80:0.6);'), 'newick')
# PhyloXML supports rich annotations
tree = Phylo.read('annotated.xml', 'phyloxml')
for clade in tree.find_clades():
if clade.confidences:
print(f'{clade.name}: confidence={clade.confidences[0].value}')
if hasattr(clade, 'taxonomy') and clade.taxonomy:
print(f'{clade.name}: taxonomy={clade.taxonomy.scientific_name}')
# Convert Newick to PhyloXML (adds metadata capabilities)
newick_tree = Phylo.read('simple.nwk', 'newick')
phyloxml_tree = newick_tree.as_phyloxml()
# Parse bootstrap or posterior trees
trees = list(Phylo.parse('bootstrap.nwk', 'newick'))
print(f'Loaded {len(trees)} bootstrap trees')
# Process each tree
for i, tree in enumerate(trees):
print(f'Tree {i}: {len(tree.get_terminals())} taxa')
# Write subset of trees
Phylo.write(trees[:100], 'first_100.nwk', 'newick')
# Memory-efficient iteration (doesn't load all trees at once)
for tree in Phylo.parse('large_file.nwk', 'newick'):
if tree.total_branch_length() > 1.0:
print(f'Long tree: {tree.total_branch_length()}')
| Input | Description |
|---|---|
(A,B,C); | Unrooted, no lengths |
((A,B),C); | Rooted topology |
(A:0.1,B:0.2); | With branch lengths |
((A,B)X,C); | Internal node named X |
((A,B):0.5[90],C); | Branch with bootstrap |
from Bio import Phylo
from io import StringIO
# Check for valid newick
tree_string = '((A,B),(C,D));'