A breakthrough in synthetic biology has enabled scientists to program cells to interpret and respond to multiple signals simultaneously. Researchers at Pohang University of Science and Technology (POSTECH) have developed a novel gene circuit platform called RATEX, which allows cells to read up to six different signals and initiate targeted responses. Published in Angewandte Chemie, the study outlines how this advancement marks a shift from traditional genetic engineering toward creating living systems that operate like biological computers. The RATEX platform leverages the ribosome, the molecular machine responsible for protein synthesis, to act as a decision-making switch. Normally, ribosomes translate RNA into proteins, but the research team enhanced their ability to detect and respond to molecular signals embedded within RNA transcripts. By modifying the ribosome’s behavior through specific RNA sequences, the scientists engineered a system where ribosomes pause at designated points along a gene when particular conditions are met. These pauses determine whether gene expression continues, effectively turning the ribosome into a programmable control element. This innovation addresses a key limitation in current genetic circuit designs. Most existing systems focus on either transcription or translation stages of gene expression, limiting their ability to handle complex, multi-level signaling. In contrast, the RATEX platform integrates signal processing across both stages. The core of the system is the Translation-to-Transcription Converter (TTC), which uses the output of translation to regulate transcription. This feedback mechanism allows the platform to dynamically adjust gene activity based on real-time environmental inputs. The researchers demonstrated that the RATEX system could manage up to six distinct RNA signals at once, significantly surpassing earlier capabilities. They also showed that the platform could combine RNA signals with metabolic cues, such as amino acid and vitamin concentrations. This dual-signal recognition expands the range of stimuli that cells can process, enabling more sophisticated decision-making at the molecular level. By integrating RATEX with CRISPR gene regulation and synthetic membraneless organelles, the team showcased the potential for precise cellular reprogramming. For instance, they altered cell shape and rearranged internal structures only after all predefined conditions were met. Such precision highlights the platform's versatility in controlling complex biological functions. Looking ahead, the implications of this work extend beyond laboratory settings. The RATEX platform offers a new framework for designing smart therapeutics, biosensors, and even bioengineered tissues. Its ability to process multiple signals simultaneously opens doors to applications in personalized medicine, environmental monitoring, and synthetic biology. As the field advances, researchers aim to refine these circuits further, making them more adaptable to diverse cellular environments and functional requirements.
★
Neka vijesti ostanu poštene.
ObjectiveNews financiraju čitatelji i bez oglasa je – pristranost vam pokazujemo, ne skrivamo. Podržite neovisno novinarstvo za 5 €/mjesec.
Postani podupiratelj