DNA circuits compatible encoder and demultiplexer based on a single biomolecular platform with DNA strands as outputs

A series of multiple logic circuits based on a single biomolecular platform is constructed to perform nonarithmetic and arithmetic functions, including 4-to-2 encoder, 1-to-2 demultiplexer, 1-to-4 demultiplexer, and multi-input OR gate. The encoder to a DNA circuit is the equivalent of a sensory receptor to a reflex arc. They all function to encode information from outside the pathway (DNA circuit or reflex arc) into a form that subsequent pathways can recognize and utilize. Current molecular encoders are based on optical or electrical signals as outputs, while DNA circuits are based on DNA strands as transmission signals. The output of existing encoders cannot be recognized by subsequent DNA circuits. It is the first time the DNA-based encoder with DNA strands as outputs can be truly applied to the DNA circuit, enabling the application of DNA circuits in non-binary biological environments. Another novel feature of the designed system is that the developed nanodevices all have a simple structure, low leakage and low crosstalk, which allows them to implement higher-level encoders and demultiplexers easily. Our work is based on the idea of complex functionality in a simple form, which will also provide a new route for developing advanced molecular logic circuits.

Automated summary

A series of multiple logic circuits based on a single biomolecular platform have been constructed, capable of performing various nonarithmetic and arithmetic functions. The DNA-based encoder, as the output of the DNA circuit, enables the application of DNA circuits in non-binary biological environments. The designed nanodevices have a simple structure, low leakage, and low crosstalk, allowing for easy implementation of higher-level encoders and demultiplexers.