Litcius/Paper detail

Reinforcement learning in synthetic gene circuits

Adrian Racovita, Alfonso Jaramillo

2020Biochemical Society Transactions11 citationsDOIOpen Access PDF

Abstract

Synthetic gene circuits allow programming in DNA the expression of a phenotype at a given environmental condition. The recent integration of memory systems with gene circuits opens the door to their adaptation to new conditions and their re-programming. This lays the foundation to emulate neuromorphic behaviour and solve complex problems similarly to artificial neural networks. Cellular products such as DNA or proteins can be used to store memory in both digital and analog formats, allowing cells to be turned into living computing devices able to record information regarding their previous states. In particular, synthetic gene circuits with memory can be engineered into living systems to allow their adaptation through reinforcement learning. The development of gene circuits able to adapt through reinforcement learning moves Sciences towards the ambitious goal: the bottom-up creation of a fully fledged living artificial intelligence.

Topics & Concepts

Reinforcement learningSynthetic biologyComputer scienceNeuromorphic engineeringElectronic circuitAdaptation (eye)Genetic programmingArtificial intelligenceBiological neural networkGene expression programmingArtificial neural networkComputer architectureNeuroscienceMachine learningBiologyEngineeringComputational biologyElectrical engineeringAdvanced Memory and Neural ComputingGene Regulatory Network AnalysisCRISPR and Genetic Engineering
Reinforcement learning in synthetic gene circuits | Litcius