Unravelling Causal Genetic Biomarkers of Alzheimer's Disease via Neuron to Gene-token Backtracking in Neural Architecture: A Groundbreaking Reverse-Gene-Finder Approach

TL;DR

This paper introduces Reverse-Gene-Finder, a novel neural network approach that backtracks from causal neurons to identify genetic biomarkers of Alzheimer's Disease, enhancing interpretability and discovery of causal genes.

Contribution

The study presents a new neuron-to-gene backtracking method in neural networks to identify causal genetic biomarkers for Alzheimer's Disease, leveraging gene token representations and innovative backtracking techniques.

Findings

Identified novel causal genetic biomarkers for AD.

Demonstrated high interpretability and generalizability of the method.

Applicable to other disease scenarios beyond AD.

Abstract

Alzheimer's Disease (AD) affects over 55 million people globally, yet the key genetic contributors remain poorly understood. Leveraging recent advancements in genomic foundation models, we present the innovative Reverse-Gene-Finder technology, a ground-breaking neuron-to-gene-token backtracking approach in a neural network architecture to elucidate the novel causal genetic biomarkers driving AD onset. Reverse-Gene-Finder comprises three key innovations. Firstly, we exploit the observation that genes with the highest probability of causing AD, defined as the most causal genes (MCGs), must have the highest probability of activating those neurons with the highest probability of causing AD, defined as the most causal neurons (MCNs). Secondly, we utilize a gene token representation at the input layer to allow each gene (known or novel to AD) to be represented as a discrete and unique entity in the input space. Lastly, in contrast to the existing neural network architectures, which track neuron activations from the input layer to the output layer in a feed-forward manner, we develop an innovative backtracking method to track backwards from the MCNs to the input layer, identifying the Most Causal Tokens (MCTs) and the corresponding MCGs. Reverse-Gene-Finder is highly interpretable, generalizable, and adaptable, providing a promising avenue for application in other disease scenarios.