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【Nucleic Acids Research 2024】🧬RNA-MSM

Multiple sequence-alignment-based RNA language model and its application to structural inference
RNA-MSM Web Server | Paper | Report Bug | Citation

Table of Contents
  1. Updates
  2. About The Project
  3. Getting Started
  4. Online RNA-MSM Sever
  5. Citation
  6. Contact

📣 Updates

  • [2024/7/22]: We release the downstream task datasets along with its Multiple Sequence Alignment (MSA) searched by RNAcmap3. Included in this release is the split RNA ID, enabling you to utilize this dataset for replication or your own research.

📘 About The Project

This repository contains codes and pre-trained weight for MSA RNA language model (RNA-MSM) as well as RNA secondary structure and solvent accessibility tasks and corresponding RNA datasets.

RNA-MSM is the first unsupervised MSA RNA language model based on aligned homologous sequences that outputs both embedding and attention map to match different types of downstream tasks.

The resulting RNA-MSM model produced attention maps and embeddings that have direct correlations to RNA secondary structure and solvent accessibility without supervised training. Further supervised training led to predicted secondary structure and solvent accessibility that are significantly more accurate than current state-of-the-art techniques. Unlike many previous studies, we would like to emphasize that we were extremely careful in avoiding over training, a significant problem in applying deep learning to RNA by choosing validation and test sets structurally different from the training set.

RNA-MSM_Fig1

🚀 Getting Started

To get a local copy up and running follow these simple example steps.

Pre-requisites

Create Environment with Anaconda

Download this repository and create the RNA-MSM environment.

git clone [email protected]:yikunpku/RNA-MSM.git
cd ./RNA-MSM
conda env create -f environment.yml
conda activate RNA-MSM

Data Preparation

Pretrain Data

RNA-MSM model operate on RNA homologous sequences (multiple sequence alignment; MSA), which contains information about conserved properties, co-evolution and functional-species evolutionary relationships (phylogenetics) in the amino acid sequences of constituent RNAs.

The effectiveness of predictions made by the RNA-MSM model is largely dependent on the quantity and quality of MSAs. Therefore, we recommend utilizing our recently developed RNAcmap3 tool to search for homologous sequences of the target RNA sequences to serve as input for the RNA-MSM model.

You may also gain entry to our online web server, wherein you can provide the target sequence, and subsequently receive the MSA files and two downstream tasks prediction results located via email.

The input MSA file should be be situated within ./results folder, and its suffix ought to be .a2m_msa2.

Downstream Task Data

The training, validation, and testing datasets used for our downstream tasks are currently available to the public and can be downloaded via this Google Drive link or Baidu Netdisk Link.

Access Pre-trained Model

Download pre-trained models from and place the .ckpt files into the ./pretrained folder.

Inference

Feature Extraction

To following command can be used to extract target RNA sequence’s embedding and attention map feature:

python RNA_MSM_Inference.py \
data.root_path=./ \
data.MSA_path=./results \
data.model_path=./pretrained \
data.MSA_list=rna_id.txt 

Generated files are saved at data.root_path/data.MSA_path

RNA-MSM model inference results includes 2 files:

  1. *_atp.npy: Attention heads weights of the target RNA sequence generated by our RNA-MSM model with dimension (seq_len, seq_len, 120), saved as .npy format. You can apply this embedding feature to your own tasks.

  2. *_emb.npy: Embedding representation of the target RNA sequence generated by our RNA-MSM model with dimension (seq_len, 768), saved as .npy format. You can apply this embedding feature to your own tasks.

Downstream Prediction - RNA Secondary Structure (SS)

cd ./_downstream_tasks/SS
python predict.py \
--rnaid 2DRB_1 \
--device cpu \
--featdir ./results

In addition, the following arguments need to be specified:

--rnaid :target RNA name, eg: 2DRB_1

--device:inference on GPU or CPU

--featdir: inference output dir

Generated files are saved at data.root_path/data.MSA_path

RNA secondary structure prediction results include 3 files:

  1. *.ct: CT file. The connect format is column based. The first column specified the sequence index, starting at one. Columns 3, 4, and 6 redundantly give sequence indices (plus/minus one). The second column contains the base in one-letter notation. Column 4 specifies the pairing partner of this base if it involved in a base pair. If the base is unpaired, this column is zero.
  2. *.bpseq: The structural information in the bpseq format is denoted in three columns. The first column contains the sequence position, starting at one. The second column contains the base in one-letter notation. The third column contains the pairing partner of the base if the base is paired. If the base is unpaired, the third column is zero.
  3. *.prob:a 2-dimension matrix that contain the probability of all base-pairs.

Downstream Prediction - RNA Solvent Accessibility Prediction (RSA)

cd ./_downstream_tasks/RSA
python predict.py \
python predict.py \
--rnaid 2DRB_1 \
--device cpu \
--featdir ./results

Generated files are saved at data.root_path/data.MSA_path

Solvent accessibility prediction results include 6 files:

  1. *_asa.png: Graph of ASA predicted by ensemble model.
  2. *_rsa.png: Graph of RSA predicted by ensemble model.
  3. Results predicted by single model :model_0 is the best single model, other 2 files are remain models。
  4. Results predicted by ensemble model :ensemble is the results predicted by ensemble model.

Results

We show the final result directory as follow:

./results
|-- 2DRB_1.a2m_msa2
|-- 2DRB_1_atp.npy
|-- 2DRB_1_emb.npy
|-- RSA_result
|   |-- 2DRB_1_asa.png
|   |-- 2DRB_1_rsa.png
|   |-- ensemble
|   |   `-- 2DRB_1.txt
|   |-- model_0
|   |   `-- 2DRB_1.txt
|   |-- model_1
|   |   `-- 2DRB_1.txt
|   `-- model_2
|       `-- 2DRB_1.txt
`-- SS_result
    |-- 2DRB_1.bpseq
    |-- 2DRB_1.ct
    `-- 2DRB_1.prob

💻 Online RNA-MSM Sever

We also built a freely accessible web server for using the RNA-MSM models, You may effortlessly submit tasks onto the server and subsequently receive the outcomes via email, without the need to configure the environment or consume any computational resources.

As a preview, take a swift glance at the website:

image-20230315145444347

📌 Citation

If you find our work useful in your research or if you use parts of this code please consider citing our paper:

@article{10.1093/nar/gkad1031,
    author = {Zhang, Yikun and Lang, Mei and Jiang, Jiuhong and Gao, Zhiqiang and Xu, Fan and Litfin, Thomas and Chen, Ke and Singh, Jaswinder and Huang, Xiansong and Song, Guoli and Tian, Yonghong and Zhan, Jian and Chen, Jie and Zhou, Yaoqi},
    title = "{Multiple sequence alignment-based RNA language model and its application to structural inference}",
    journal = {Nucleic Acids Research},
    volume = {52},
    number = {1},
    pages = {e3-e3},
    year = {2023},
    month = {11},
    abstract = "{Compared with proteins, DNA and RNA are more difficult languages to interpret because four-letter coded DNA/RNA sequences have less information content than 20-letter coded protein sequences. While BERT (Bidirectional Encoder Representations from Transformers)-like language models have been developed for RNA, they are ineffective at capturing the evolutionary information from homologous sequences becauseĀ unlike proteins, RNA sequences are less conserved. Here, we have developed an unsupervised multiple sequence alignment-based RNA language model (RNA-MSM) by utilizing homologous sequences from an automatic pipeline, RNAcmap, as it can provide significantly more homologous sequences than manually annotated Rfam. We demonstrate that the resulting unsupervised, two-dimensional attention maps and one-dimensional embeddings from RNA-MSM contain structural information. In fact, they can be directly mapped with high accuracy to 2D base pairing probabilities and 1D solvent accessibilities, respectively. Further fine-tuning led to significantly improved performance on these two downstream tasks compared with existing state-of-the-art techniques including SPOT-RNA2 and RNAsnap2. By comparison, RNA-FM, a BERT-based RNA language model, performs worse than one-hot encoding with its embedding in base pair and solvent-accessible surface area prediction. We anticipate that the pre-trained RNA-MSM model can be fine-tuned on many other tasks related to RNA structure and function.}",
    issn = {0305-1048},
    doi = {10.1093/nar/gkad1031},
    url = {https://doi.org/10.1093/nar/gkad1031},
    eprint = {https://academic.oup.com/nar/article-pdf/52/1/e3/55443207/gkad1031.pdf},
}

☎️ Contact

Yikun Zhang - [email protected]