Bottom-Up Construction of an Adaptive Enzymatic Reaction Network.

The reproduction of emergent behaviors in nature using reaction networks is an important objective in synthetic biology and systems chemistry. Herein, the first experimental realization of an enzymatic reaction network capable of an adaptive response is reported. The design is based on the dual activity of trypsin, which activates chymotrypsin while at the same time generating a fluorescent output from a fluorogenic substrate.

Preprogramming Complex Hydrogel Responses using Enzymatic Reaction Networks.

The creation of adaptive matter is heavily inspired by biological systems. However, it remains challenging to design complex material responses that are governed by reaction networks, which lie at the heart of cellular complexity. The main reason for this slow progress is the lack of a general strategy to integrate reaction networks with materials.

Influence of molecular structure on the properties of out-of-equilibrium oscillating enzymatic reaction networks.

Our knowledge of the properties and dynamics of complex molecular reaction networks, for example those found in living systems, considerably lags behind the understanding of elementary chemical reactions. In part, this is because chemical reactions networks are nonlinear systems that operate under conditions far from equilibrium. Of particular interest is the role of individual reaction rates on the stability of the network output.

Rational design of functional and tunable oscillating enzymatic networks.

Life is sustained by complex systems operating far from equilibrium and consisting of a multitude of enzymatic reaction networks. The operating principles of biology's regulatory networks are known, but the in vitro assembly of out-of-equilibrium enzymatic reaction networks has proved challenging, limiting the development of synthetic systems showing autonomous behaviour. Here, we present a strategy for the rational design of programmable functional reaction networks that exhibit dynamic behaviour.

Fluorescent hydrogels for studying Ca(2+)-dependent reaction-diffusion processes.

Here, we report a convenient experimental platform to study the diffusion of Ca(2+) in the presence of a Ca(2+)-binding protein (Calbindin D28k). This work opens up new possibilities to elucidate the physical chemistry of complex Ca(2+)-dependent reaction-diffusion networks that are abundant in living cells.