A Machine Learning Model of Perturb-Seq Data for use in Space Flight Gene Expression Profile Analysis

Liam Fitzpatric Johnson (18437556)

27 April 2024

<p dir="ltr">The genetic perturbations caused by spaceflight on biological systems tend to have a system-wide effect which is often difficult to deconvolute into individual signals with specific points of origin. Single cell multi-omic data can provide a profile of the perturbational effects but does not necessarily indicate the initial point of interference within a network. The objective of this project is to take advantage of large scale and genome-wide perturbational or Perturb-Seq datasets by using them to pre-train a generalist machine learning model that is capable of predicting the effects of unseen perturbations in new data. Perturb-Seq datasets are large libraries of single cell RNA sequencing data collected from CRISPR knock out screens in cell culture. The advent of generative machine learning algorithms, particularly transformers, make it an ideal time to re-assess large scale data libraries in order to grasp cell and even organism-wide genomic expression motifs. By tailoring an algorithm to learn the downstream effects of the genetic perturbations, we present a pre-trained generalist model capable of predicting the effects of multiple perturbations in combination, locating points of origin for perturbation in new datasets, predicting the effects of known perturbations in new datasets, and annotation of large-scale network motifs. We demonstrate the utility of this model by identifying key perturbational signatures in RNA sequencing data from spaceflown biological samples from the NASA Open Science Data Repository.</p>

Bioinformatic methods development

Genomics and transcriptomics

Modelling and simulation

Neural networks

Perturb-Seq

Machine Learning

scRNA-seq

GSEA

RNA-seq

Multi-Layer Perceptron

Convolutional Neural Network

Random Forest

multi-class classification

multi-label multi-class classification

UMAP

Leiden clustering

K562 cell line

RPE1 cell line

spaceflight

space environment effects

differentially expressed gene (DGE)

machine learning prediction models

gene expression

transcriptomics