Deep model predictive control of gene expression in thousands of single cells.
Jean-Baptiste LugagneCaroline M BlassickMary J DunlopPublished in: Nature communications (2024)
Gene expression is inherently dynamic, due to complex regulation and stochastic biochemical events. However, the effects of these dynamics on cell phenotypes can be difficult to determine. Researchers have historically been limited to passive observations of natural dynamics, which can preclude studies of elusive and noisy cellular events where large amounts of data are required to reveal statistically significant effects. Here, using recent advances in the fields of machine learning and control theory, we train a deep neural network to accurately predict the response of an optogenetic system in Escherichia coli cells. We then use the network in a deep model predictive control framework to impose arbitrary and cell-specific gene expression dynamics on thousands of single cells in real time, applying the framework to generate complex time-varying patterns. We also showcase the framework's ability to link expression patterns to dynamic functional outcomes by controlling expression of the tetA antibiotic resistance gene. This study highlights how deep learning-enabled feedback control can be used to tailor distributions of gene expression dynamics with high accuracy and throughput without expert knowledge of the biological system.
Keyphrases
- gene expression
- induced apoptosis
- dna methylation
- cell cycle arrest
- machine learning
- escherichia coli
- deep learning
- single cell
- poor prognosis
- neural network
- genome wide
- endoplasmic reticulum stress
- healthcare
- stem cells
- oxidative stress
- big data
- binding protein
- signaling pathway
- cell death
- long non coding rna
- cystic fibrosis
- transcription factor
- high resolution
- biofilm formation
- mass spectrometry
- pi k akt
- candida albicans
- network analysis