LocTree2 - Protein sub-cellular localization prediction for all domains of life
Subcellular localization is one and easily definable aspect of protein function. Computational prediction of localization continues to provide an invaluable help especially in whole genome analyses and annotations. Several methods have been developed to predict localization, yet many challenges remain to be tackled.
We at RostLab developed a novel method, LocTree2 that predicts localization for all proteins in all domains of life. Similar to our previous method, LocTree, we incorporate a system of hierarchically organized Support Vector Machines to mimic the protein trafficking mechanism in cells. Please note that other than the hierarchy and the name LocTree and LocTree2 have nothing in common.
Amongst the novel aspects of LocTree2 are:
- the stunning number of 18 classes predicted for Eukaryota
- 6 classes for Bacteria and 3 classes for Archaea
- incorporation of no other information than evolutionary profiles
- very accurate in distinction: membrane/water-soluble globular proteins
- high robustness against sequencing errors
- top performance even for protein fragments
LocTree2 combines three different systems of classification trees to predict 3 localization classes in Archaea (cytosol, plasma membrane and extra-cellular), 6 classes in Bacteria (cytosol, plasma membrane, periplasmic space, outer membrane, fimbrium and extra-cellular) and 18 classes in Eukaryota (ER, Golgi, extra-cellular, vacuole, peroxisome, mitochondria, chloroplast, plastid, cytosol, nucleus, ER membrane, plasma membrane, Golgi membrane, nucleus membrane, vacuole membrane, peroxisome membrane, chloroplast membrane and mitochondria membrane) (Figure 1).
LocTree2 requires a .fasta file and a .profile file for each sequence to be predicted as input. A profile file can be obtained by e.g. using PSI-BLAST (Position-Specific Iterated BLAST). We built our profiles using an 80% non-redundant database combining SWISS-PROT, TrEMBL and PDB.
Example input files can be viewed here.
In order to assign a localization class to a query protein Support Vector Machines (SVMs; implemented as internal nodes in LocTree2 decision trees) take a protein in its input space (as a sequence-profile tuple) and map it to a higher dimensional feature space where it is represented as a feature vector. The vector of a query protein is then 'compared' to the vectors of proteins used for the training. The predicted localization class of a query protein is then the class of the most 'similar' vector of a protein used for training.
In our case, the mapping and the comparison are carried out by a string kernel function, called the Profile Kernel. A feature vector built by the The Profile Kernel is indexed by all possible subsequences of length k from the alphabet of 20 amino acids. Each element in the vector represents one particular k-mer with a score below a user-defined threshold sigma. This score is calculated as the ungapped cumulative substitution score in the corresponding sequence profile. The similarity between a training and a test protein is calculated as the dot product between their k-mer vector representations and is given as a single positive integer number.
In short, the Profile Kernel identifies sets of k-mers (stretches of k adjacent residues) that are most informative for the prediction of localization and then matches these in a query protein.
Additional information about the kernel function can be found in the LocTree2 manuscript and the corresponding Profile Kernel publication.
LocTree2 combines three different systems of decision trees, one for each domain of life (Figure 1). The trees were built by incorporating a hierarchical ontology of localization classes modeled onto the biological sorting mechanism in that domain. In eukaryotes pathways for membrane and non-membrane proteins are treated separately. The branches represent paths of the protein sorting, the leaves (rectangles) the final prediction of one localization class, and the internal nodes (circles) are the decision points along the path.
As in LocTree, biological similarities were incorporated from the description of cellular components provided by the Gene Ontology Consortium (GO). In cases of ambigous relations (e.g. PER, MIT, CHL) we explored different trees in which these classes were placed at different levels in the hierarchy and selected the hierarchy with the highest prediction performance. LOCtree2, was extremely successful at learning evolutionary similarities among subcellular localization classes and was significantly more accurate than other traditional networks at predicting localization.
Hierarchy of SVMs
The decision points along the path in the hierarchical trees were implemented as binary Support Vector Machines (SVMs). As the SVM model, we chose the WEKA version of Sequential Minimal Optimization. Each SVM was trained on a different set of proteins. For example, the SVM at the root node in the archeal tree (Fig. 1a) was trained on the full set of proteins (comprising cytoplasmic and non-cytoplasmic classes), while the SVM at a lower level in the tree was trained on plasma-membrane and extra-cellular proteins only.
In addition to the predicted localization class LocTree2 provides a Reliability Index (RI) measuring the strength of a prediction. For a predicted class (leaf node) the RI is compiled as the product over the reliabilities of all parental nodes. The RI is a value between 0 and 100, with 100 denoting the most confident predictions.
We rigorously evaluated the reliability of LocTree2 predictions on a non-redundant test set of proteins (Fig. 2). We observed that 50% of proteins with the highest reliability reached levels of overall accuracy Q6=98% for bacteria (gray arrow) and Q18=92% for eukaryota (black arrow). To pick another point, almost 40% of all eukaryotic proteins were predicted at RI greater than 85; for these, Q18 was above 95%. Thus, two in the top 40 predictions in 100 were wrong in one of 18 states (e.g. nuclear instead of nuclear membrane).
- Q6 is a six-state accuracy for predicting localization to six classes
- Q18 is an eighteen-state accuracy
Accuracy of localization prediction
- The program can be accessed online via the PredictProtein service
- Standalone version can be downloaded as a zip file here
Data sets used for development and evaluation of LocTree2 can be accessed here.
For questions, please contact email@example.com