Explainable Multilayer Graph Neural Network for Cancer Gene Prediction
- URL: http://arxiv.org/abs/2301.08831v2
- Date: Wed, 3 May 2023 12:28:52 GMT
- Title: Explainable Multilayer Graph Neural Network for Cancer Gene Prediction
- Authors: Michail Chatzianastasis, Michalis Vazirgiannis, Zijun Zhang
- Abstract summary: We introduce an Explainable Multilayer Graph Neural Network (EMGNN) approach to identify cancer genes.
Unlike conventional graph learning on a single biological network, EMGNN uses a multilayered graph neural network to learn from multiple biological networks for accurate cancer gene prediction.
Our method consistently outperforms all existing methods, with an average 7.15% improvement in area under the precision-recall curve (AUPR) over the current state-of-the-art method.
- Score: 21.83218536069088
- License: http://creativecommons.org/licenses/by-sa/4.0/
- Abstract: The identification of cancer genes is a critical yet challenging problem in
cancer genomics research. Existing computational methods, including deep graph
neural networks, fail to exploit the multilayered gene-gene interactions or
provide limited explanation for their predictions. These methods are restricted
to a single biological network, which cannot capture the full complexity of
tumorigenesis. Models trained on different biological networks often yield
different and even opposite cancer gene predictions, hindering their
trustworthy adaptation. Here, we introduce an Explainable Multilayer Graph
Neural Network (EMGNN) approach to identify cancer genes by leveraging multiple
genegene interaction networks and pan-cancer multi-omics data. Unlike
conventional graph learning on a single biological network, EMGNN uses a
multilayered graph neural network to learn from multiple biological networks
for accurate cancer gene prediction. Our method consistently outperforms all
existing methods, with an average 7.15% improvement in area under the
precision-recall curve (AUPR) over the current state-of-the-art method.
Importantly, EMGNN integrated multiple graphs to prioritize newly predicted
cancer genes with conflicting predictions from single biological networks. For
each prediction, EMGNN provided valuable biological insights via both
model-level feature importance explanations and molecular-level gene set
enrichment analysis. Overall, EMGNN offers a powerful new paradigm of graph
learning through modeling the multilayered topological gene relationships and
provides a valuable tool for cancer genomics research.
Related papers
- Predicting Genetic Mutation from Whole Slide Images via Biomedical-Linguistic Knowledge Enhanced Multi-label Classification [119.13058298388101]
We develop a Biological-knowledge enhanced PathGenomic multi-label Transformer to improve genetic mutation prediction performances.
BPGT first establishes a novel gene encoder that constructs gene priors by two carefully designed modules.
BPGT then designs a label decoder that finally performs genetic mutation prediction by two tailored modules.
arXiv Detail & Related papers (2024-06-05T06:42:27Z) - Pathology-genomic fusion via biologically informed cross-modality graph learning for survival analysis [7.996257103473235]
We propose Pathology-Genome Heterogeneous Graph (PGHG) that integrates whole slide images (WSI) and bulk RNA-Seq expression data with heterogeneous graph neural network for cancer survival analysis.
The PGHG consists of biological knowledge-guided representation learning network and pathology-genome heterogeneous graph.
We evaluate the model on low-grade gliomas, glioblastoma, and kidney renal papillary cell carcinoma datasets from the Cancer Genome Atlas.
arXiv Detail & Related papers (2024-04-11T09:07:40Z) - IGCN: Integrative Graph Convolution Networks for patient level insights and biomarker discovery in multi-omics integration [2.0971479389679337]
We introduce a novel integrative neural network approach for cancer molecular subtype and biomedical classification applications.
IGCN can identify which types of omics receive more emphasis for each patient to predict a certain class.
IGCN has the capability to pinpoint significant biomarkers from a range of omics data types.
arXiv Detail & Related papers (2024-01-31T05:52:11Z) - Cancer-Net PCa-Gen: Synthesis of Realistic Prostate Diffusion Weighted
Imaging Data via Anatomic-Conditional Controlled Latent Diffusion [68.45407109385306]
In Canada, prostate cancer is the most common form of cancer in men and accounted for 20% of new cancer cases for this demographic in 2022.
There has been significant interest in the development of deep neural networks for prostate cancer diagnosis, prognosis, and treatment planning using diffusion weighted imaging (DWI) data.
In this study, we explore the efficacy of latent diffusion for generating realistic prostate DWI data through the introduction of an anatomic-conditional controlled latent diffusion strategy.
arXiv Detail & Related papers (2023-11-30T15:11:03Z) - Single-Cell Deep Clustering Method Assisted by Exogenous Gene
Information: A Novel Approach to Identifying Cell Types [50.55583697209676]
We develop an attention-enhanced graph autoencoder, which is designed to efficiently capture the topological features between cells.
During the clustering process, we integrated both sets of information and reconstructed the features of both cells and genes to generate a discriminative representation.
This research offers enhanced insights into the characteristics and distribution of cells, thereby laying the groundwork for early diagnosis and treatment of diseases.
arXiv Detail & Related papers (2023-11-28T09:14:55Z) - Machine Learning Methods for Cancer Classification Using Gene Expression
Data: A Review [77.34726150561087]
Cancer is the second major cause of death after cardiovascular diseases.
Gene expression can play a fundamental role in the early detection of cancer.
This study reviews recent progress in gene expression analysis for cancer classification using machine learning methods.
arXiv Detail & Related papers (2023-01-28T15:03:03Z) - Relation Embedding based Graph Neural Networks for Handling
Heterogeneous Graph [58.99478502486377]
We propose a simple yet efficient framework to make the homogeneous GNNs have adequate ability to handle heterogeneous graphs.
Specifically, we propose Relation Embedding based Graph Neural Networks (RE-GNNs), which employ only one parameter per relation to embed the importance of edge type relations and self-loop connections.
arXiv Detail & Related papers (2022-09-23T05:24:18Z) - Simple and Efficient Heterogeneous Graph Neural Network [55.56564522532328]
Heterogeneous graph neural networks (HGNNs) have powerful capability to embed rich structural and semantic information of a heterogeneous graph into node representations.
Existing HGNNs inherit many mechanisms from graph neural networks (GNNs) over homogeneous graphs, especially the attention mechanism and the multi-layer structure.
This paper conducts an in-depth and detailed study of these mechanisms and proposes Simple and Efficient Heterogeneous Graph Neural Network (SeHGNN)
arXiv Detail & Related papers (2022-07-06T10:01:46Z) - Multi-modal learning for predicting the genotype of glioma [14.93152817415408]
The isocitrate dehydrogenase (IDH) gene mutation is an essential biomarker for the diagnosis and prognosis of glioma.
It is promising to better predict glioma genotype by integrating focal tumor image and geometric features with brain network features derived from MRI.
We propose a multi-modal learning framework using three separate encoders to extract features of focal tumor image, tumor geometrics and global brain networks.
arXiv Detail & Related papers (2022-03-21T10:20:04Z) - Collaborative learning of images and geometrics for predicting
isocitrate dehydrogenase status of glioma [8.262398325144774]
Gold standard of IDH mutation detection requires tumour tissue obtained via invasive approaches and is usually expensive.
Recent advancement in radiogenomics provides a non-invasive approach for predicting IDH mutation based on MRI.
Here we propose a collaborative learning framework that learns both tumor images and tumor geometrics using convolutional neural networks (CNN) and graph neural networks (GNN)
Our results show that the proposed model outperforms the baseline model of 3D-DenseNet121.
arXiv Detail & Related papers (2022-01-14T15:58:07Z) - VEGN: Variant Effect Prediction with Graph Neural Networks [19.59965282985234]
We propose VEGN, which models variant effect prediction using a graph neural network (GNN) that operates on a heterogeneous graph with genes and variants.
The graph is created by assigning variants to genes and connecting genes with an gene-gene interaction network.
VeGN improves the performance of existing state-of-the-art models.
arXiv Detail & Related papers (2021-06-25T13:51:46Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.