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Published in PLOS ONE. Phage-host interaction prediction tool that uses protein language models to represent the receptor-binding proteins of phages. It presents improvements over using handcrafted sequence properties and eliminates the need to manually extract and select features from phage sequences

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PHIEmbed (Phage-Host Interaction Prediction with Protein Embeddings)

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PHIEmbed is a phage-host interaction prediction tool that uses protein language models to represent the receptor-binding proteins of phages. It presents improvements over using handcrafted (manually feature-engineered) sequence properties and eliminates the need to manually extract and select features from phage sequences.

Paper: https://doi.org/10.1371/journal.pone.0289030

If you find our work useful, please consider citing:

@article{10.1371/journal.pone.0289030,
    doi = {10.1371/journal.pone.0289030},
    author = {Gonzales, Mark Edward M. AND Ureta, Jennifer C. AND Shrestha, Anish M. S.},
    journal = {PLOS ONE},
    publisher = {Public Library of Science},
    title = {Protein embeddings improve phage-host interaction prediction},
    year = {2023},
    month = {07},
    volume = {18},
    url = {https://doi.org/10.1371/journal.pone.0289030},
    pages = {1-22},
    number = {7}
}

You can also find PHIEmbed on bio.tools.

Table of Contents

πŸ“° News

  • 01 Sep 2024 - We created a Google Colab notebook for running our tool. Instructions here.

  • 24 Apr 2024 - We added scripts to simplify running and training our tool. Instructions here.

  • 23 Feb 2024 - We presented our work at the eAsia AMR Workshop 2024 held virtually and in person in Tokyo, Japan, and attended by antimicrobial resistance (AMR) researchers from Thailand, USA, Australia, Japan, and the Philippines. Slides here.

  • 01 Dec 2023 - Presenting this work, the lead author (Mark Edward M. Gonzales) won 2nd Prize at the 2023 Magsaysay Future Engineers/Technologists Award. This award is conferred by the National Academy of Science and Technology, the highest recognition and scientific advisory body of the Philippines, to recognize outstanding research outputs on engineering and technology at the collegiate level. Presentation here (29:35–39:51) and slides here.

  • 07 Jul 2023 - Our paper was accepted for publication in PLOS ONE.

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♾️ Run on Google Colab

Colab

You can readily run PHIEmbed on Google Colab, without the need to install anything on your own computer: http://phiembed.bioinfodlsu.com

πŸš€ Installation & Usage

Operating System: Windows, Linux, or macOS

Clone the repository:

git clone https://github.com/bioinfodlsu/phage-host-prediction
cd phage-host-prediction

Create a virtual environment with all the necessary dependencies installed via Conda (we recommend using Miniconda):

conda env create -f environment.yaml

Activate this environment by running:

conda activate PHIEmbed

Running PHIEmbed

python3 phiembed.py --input <input_fasta> --model <model_joblib> --output <results_dir>
  • Replace <input_fasta> with the path to the FASTA file containing the receptor-binding protein sequences. A sample FASTA file is provided here.
  • Replace <model_joblib> with the path to the trained model (recognized format: joblib or compressed joblib, framework: scikit-learn). Download our trained model from this link. No need to uncompress, but doing so will speed up loading the model albeit at the cost of additional storage requirements. Refer to this guide for the list of accepted compressed formats.
  • Replace <results_dir> with the path to the directory to which the results of running PHIEmbed will be written. The results of running PHIEmbed on the sample FASTA file are provided here.

The results for each protein are written to a CSV file (without a header row). Each row contains two comma-separated values: a host genus and the corresponding prediction score (class probability). The rows are sorted in order of decreasing prediction score. Hence, the first row pertains to the top-ranked prediction.

Under the hood, this script first converts each sequence into a protein embedding using ProtT5 (the top-performing protein language model based on our experiments) and then passes the embedding to a random forest classifier trained on our entire dataset. If your machine has a GPU, it will automatically be used to accelerate the protein embedding generation step.

Note: Running this script for the first time may take a few extra minutes since it involves downloading a model (ProtT5, around 2 GB) from Hugging Face.

Training PHIEmbed

python3 train.py --input <training_dataset>
  • Replace <training_dataset> with the path to the training dataset. A sample can be downloaded here.
  • The number of threads to be used for training can be specified using --threads. By default, it is set to -1 (that is, all threads are to be used).

The training dataset should be formatted as a CSV file (without a header row) where each row corresponds to a training sample. The first column is for the protein IDs, the second column is for the host genera, and the next 1,024 columns are for the components of the ProtT5 embeddings.

This script will output a gzip-compressed, serialized version of the trained model with filename phiembed_trained.joblib.gz.

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πŸ“š Description

Motivation: With the growing interest in using phages to combat antimicrobial resistance, computational methods for predicting phage-host interactions have been explored to help shortlist candidate phages. Most existing models consider entire proteomes and rely on manual feature engineering, which poses difficulty in selecting the most informative sequence properties to serve as input to the model.

Method: In this paper, we framed phage-host interaction prediction as a multiclass classification problem that takes as input the embeddings of a phage's receptor-binding proteins, which are known to be the key machinery for host recognition, and predicts the host genus. We explored different protein language models to automatically encode these protein sequences into dense embeddings without the need for additional alignment or structural information.

Results: We show that the use of embeddings of receptor-binding proteins presents improvements over handcrafted genomic and protein sequence features. The highest performance was obtained using the transformer-based protein language model ProtT5, resulting in a 3% to 4% increase in weighted F1 and recall scores across different prediction confidence thresholds, compared to using selected handcrafted sequence features.

Teaser Figure

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πŸ§ͺ Reproducing Our Results

Project Structure

The experiments folder contains the files and scripts for reproducing our results. Note that additional (large) files have to be downloaded (or generated) following the instructions in the Jupyter notebooks.

Click here to show/hide the list of directories, Jupyter notebooks, and Python scripts, as well as the folder structure.

Directories

Directory Description
inphared Contains the list of phage-host pairs in TSV format. The GenBank and FASTA files with the genomic and protein sequences of the phages, the embeddings of the receptor-binding proteins, and the phage-host-features CSV files should also be saved in this folder
preprocessing Contains text files related to the preprocessing of host information and the selection of annotated RBPs
rbp_prediction Contains the JSON file of the trained XGBoost model proposed by Boeckaerts et al. (2022) for the computational prediction of receptor-binding proteins. Downloaded from this repository (under the MIT License)
temp Contains intermediate output files during preprocessing and performance evaluation

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Jupyter Notebooks

Each notebook provides detailed instructions related to the required and output files, including the download links and where to save them.

Notebook Description Required Files Output Files
1. Sequence Preprocessing.ipynb Preprocessing of host information and selection of annotated receptor-binding proteins GenomesDB (Partial. Complete populating following the instructions in the notebook),
GenBank file of phage genomes and/or proteomes
FASTA files of genomic and protein sequences
2. Exploratory Data Analysis.ipynb Exploratory data analysis Protein embeddings (Part 1 and Part 2),
Phage-host-features CSV files
–
3. RBP Computational Prediction.ipynb Computational prediction of receptor-binding proteins Protein embeddings (Part 1 and Part 2) Protein embeddings (Part 1 and Part 2)
3.1. RBP FASTA Generation.ipynb Generation of the FASTA files containing the RBP protein sequences Protein embeddings (Part 1 and Part 2) FASTA files of genomic and protein sequences
4. Protein Embedding Generation.ipynb Generation of protein embeddings FASTA files of genomic and protein sequences Protein embeddings (Part 1 and Part 2)
5. Data Consolidation.ipynb Generation of phage-host-features CSV files FASTA files of genomic and protein sequences,
Protein embeddings (Part 1 and Part 2)
Phage-host-features CSV files
6. Classifier Building & Evaluation.ipynb Construction of phage-host interaction model and performance evaluation Phage-host-features CSV files Trained models
6.1. Additional Model Evaluation (Specificity + PR Curve).ipynb Addition of metrics for model evaluation Phage-host-features CSV files –
7. Visualization.ipynb Plotting of t-SNE and UMAP projections Phage-host-features CSV files –

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Python Scripts

Script Description
ClassificationUtil.py Contains the utility functions for the generation of the phage-host-features CSV files, construction of the phage-host interaction model, and performance evaluation
ConstantsUtil.py Contains the constants used in the notebooks and scripts
EDAUtil.py Contains the utility functions for exploratory data analysis
RBPPredictionUtil.py Contains the utility functions for the computational prediction of receptor-binding proteins
SequenceParsingUtil.py Contains the utility functions for preprocessing host information and selecting annotated receptor-binding proteins
boeckaerts.py Contains the utility functions written by Boeckaerts et al. (2021) for running their phage-host interaction prediction tool (with which we benchmarked our model). Downloaded from this repository (under the MIT License)

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Folder Structure

Once you have cloned this repository and finished downloading (or generating) all the additional required files following the instructions in the Jupyter notebooks, your folder structure should be similar to the one below:

  • phage-host-prediction (root)
    • datasets
      • inphared
        • inphared
          • GenomesDB (Downoad partial. Complete populating following the instructions here)
            • AB002632
            • ...
    • experiments
      • inphared
        • data (Download)
          • rbp.csv
          • rbp_embeddings_esm.csv
          • ...
        • embeddings (Download Part 1 and Part 2)
          • esm
          • esm1b
          • ...
        • fasta (Download)
          • complete
          • hypothetical
          • nucleotide
          • rbp
        • 16Sep2022_data_excluding_refseq.tsv
        • 16Sep2022_phages_downloaded_from_genbank.gb (Download)
      • models (Download)
        • boeckaerts.joblib
        • esm.joblib
        • ...
      • preprocessing
      • rbp_prediction
      • temp
      • 1. Sequence Preprocessing.ipynb
      • ...
      • ClassificationUtil.py
      • ...

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Dependencies

Operating System: Windows, Linux, or macOS

Create a virtual environment with all the necessary dependencies installed via Conda (we recommend using Miniconda):

conda env create -f environment_experiments.yaml

Activate this environment by running:

conda activate PHIEmbed-experiments

Thanks to Dr. Paul K. Yu for sharing his environment configuration.

Click here to show/hide note on running the notebook for protein embedding generation.

The notebook 4. Protein Embedding Generation.ipynb has a dependency (bio_embeddings) that requires it to be run on Unix or a Unix-like operating system. If you are using Windows, consider using Windows Subsystem for Linux (WSL) or a virtual machine. We did not include bio_embeddings in environment_experiments.yaml to maintain cross-platform compatibility; you have to install it following the instructions here.

Moreover, generating protein embeddings should ideally be done on a machine with a GPU. The largest (and best-performing) protein language model that we used, ProtT5, consumes 5.9 GB of GPU memory. If your local machine does not have a GPU or if its GPU has insufficient memory, we recommend using a cloud GPU platform.

UPDATE (12 Jun 2023): In May 2023, Google Colab upgraded its Python runtime, resulting in compatibility issues with bio_embeddings. An alternative cloud GPU platform is Paperspace, which provides a PyTorch 1.12 runtime that is compatible with bio_embeddings.

Click here to show/hide the complete list of Python libraries and modules used in this project (excluding those that are part of the Python Standard Library).
Library/Module Description License
pyyaml Supports standard YAML tags and provides Python-specific tags that allow to represent an arbitrary Python object MIT License
jsonnet Domain-specific language for JSON Apache License 2.0
protobuf Google's language-neutral, platform-neutral, extensible mechanism for serializing structured data BSD 3-Clause "New" or "Revised" License
regex Provides additional functionality over the standard re module while maintaining backwards-compatibility Apache License 2.0
nltk Provides interfaces to corpora and lexical resources, along with a suite of text processing libraries for classification, tokenization, stemming, tagging, parsing, and semantic reasoning Apache License 2.0
biopython Provides tools for computational molecular biology Biopython License Agreement, BSD 3-Clause License
ete3 Provides functions for automated manipulation, analysis, and visualization of phylogenetic trees GNU General Public License v3.0
pandas Provides functions for data analysis and manipulation BSD 3-Clause "New" or "Revised" License
numpy Provides a multidimensional array object, various derived objects, and an assortment of routines for fast operations on arrays BSD 3-Clause "New" or "Revised" License
scipy Provides efficient numerical routines, such as those for numerical integration, interpolation, optimization, linear algebra, and statistics BSD 3-Clause "New" or "Revised" License
scikit-learn Provides efficient tools for predictive data analysis BSD 3-Clause "New" or "Revised" License
xgboost Implements machine learning algorithms under the gradient boosting framework Apache License 2.0
imbalanced-learn Provides tools when dealing with classification with imbalanced classes MIT License
joblib Provides tools for lightweight pipelining in Python BSD 3-Clause "New" or "Revised" License
cudatoolkit Parallel computing platform and programming model for general computing on GPUs NVIDIA Software License
bio_embeddings Provides an interface for the use of language model-based biological sequence representations for transfer-learning MIT License
torch Optimized tensor library for deep learning using GPUs and CPUs BSD 3-Clause "New" or "Revised" License
transformers Provides pretrained models to perform tasks on different modalities such as text, vision, and audio Apache License 2.0
sentencepiece Unsupervised text tokenizer and detokenizer mainly for neural network-based text generation systems Apache License 2.0
matplotlib Provides functions for creating static, animated, and interactive visualizations Matplotlib License (BSD-Compatible)
umap-learn Implements uniform manifold approximation and projection, a dimensionality reduction technique BSD 3-Clause "New" or "Revised" License

The descriptions are taken from their respective websites.

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πŸ’» Authors

This is a research project under the Bioinformatics Laboratory, Advanced Research Institute for Informatics, Computing and Networking, De La Salle University, Philippines.

This research was partly funded by the Department of Science and Technology – Philippine Council for Health Research and Development (DOST-PCHRD) under the e-Asia JRP 2021 Alternative therapeutics to tackle AMR pathogens (ATTACK-AMR) program. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

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Published in PLOS ONE. Phage-host interaction prediction tool that uses protein language models to represent the receptor-binding proteins of phages. It presents improvements over using handcrafted sequence properties and eliminates the need to manually extract and select features from phage sequences

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