Benedikt Rieß scite author profile

Many biological materials exist in non-equilibrium states driven by the irreversible consumption of high-energy molecules like ATP or GTP. These energy-dissipating structures are governed by kinetics and are thus endowed with unique properties including spatiotemporal control over their presence. Here we show man-made equivalents of materials driven by the consumption of high-energy molecules and explore their unique properties. A chemical reaction network converts dicarboxylates into metastable anhydrides driven by the irreversible consumption of carbodiimide fuels. The anhydrides hydrolyse rapidly to the original dicarboxylates and are designed to assemble into hydrophobic colloids, hydrogels or inks. The spatiotemporal control over the formation and degradation of materials allows for the development of colloids that release hydrophobic contents in a predictable fashion, temporary self-erasing inks and transient hydrogels. Moreover, we show that each material can be re-used for several cycles.

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The Design of Dissipative Molecular Assemblies Driven by Chemical Reaction Cycles

Rieß

Grötsch

Boekhoven

2020

Chem

208

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The field of supramolecular chemistry and molecular self-assembly has entered a new phase in which the use of chemical reactions to create out-of-equilibrium molecular assemblies is becoming more common. These dynamic assemblies have vastly different properties than their in-equilibrium counterparts, which include the ability to be controlled over space and time or the ability to selfreplicate. Such behaviors would set significant steps toward the synthesis of artificial life. However, a limiting factor toward the revolution of the field is the lack of clear definitions and design rules for such systems. In this review, we explain the core principles that help to design energy-dissipating chemical reaction cycles that can drive molecular assemblies. We discuss strategies for coupling these reaction cycles to building blocks for the materials. We conclude with an outlook for the field of dissipative self-assembly and its potential role as a material or model for life.

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Self-selection of dissipative assemblies driven by primitive chemical reaction networks

Tena‐Solsona

Wanzke²,

Rieß³

et al. 2018

Nat Commun

190

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Life is a dissipative nonequilibrium structure that requires constant consumption of energy to sustain itself. How such an unstable state could have selected from an abiotic pool of molecules remains a mystery. Here we show that liquid phase-separation offers a mechanism for the selection of dissipative products from a library of reacting molecules. We bring a set of primitive carboxylic acids out-of-equilibrium by addition of high-energy condensing agents. The resulting anhydrides are transiently present before deactivation via hydrolysis. We find the anhydrides that phase-separate into droplets to protect themselves from hydrolysis and to be more persistent than non-assembling ones. Thus, after several starvation-refueling cycles, the library self-selects the phase-separating anhydrides. We observe that the self-selection mechanism is more effective when the library is brought out-of-equilibrium by periodic addition of batches as opposed to feeding it continuously. Our results suggest that phase-separation offers a selection mechanism for energy dissipating assemblies.

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Chemogenomic Profiling of Human and Microbial FK506-Binding Proteins

et al. 2018

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FK506-binding proteins (FKBPs) are evolutionarily conserved proteins that display peptidyl-prolyl isomerase activities and act as coreceptors for immunosuppressants. Microbial macrophage-infectivity-potentiator (Mip)-type FKBPs can enhance infectivity. However, developing druglike ligands for FKBPs or Mips has proven difficult, and many FKBPs and Mips still lack biologically useful ligands. To explore the scope and potential of C-substituted [4.3.1]-aza-bicyclic sulfonamides as a broadly applicable class of FKBP inhibitors, we developed a new synthesis method for the bicyclic core scaffold and used it to prepare an FKBP- and Mip-focused library. This allowed us to perform a systematic structure-activity-relationship analysis across key human FKBPs and microbial Mips, yielding highly improved inhibitors for all the FKBPs studied. A cocrystal structure confirmed the molecular-binding mode of the core structure and explained the affinity gained as a result of the preferred substituents. The best FKBP and Mip ligands showed promising antimalarial, antileginonellal, and antichlamydial properties in cellular models of infectivity, suggesting that substituted [4.3.1]-aza-bicyclic sulfonamides could be a novel class of anti-infectives.

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Dissipative assemblies that inhibit their deactivation

et al. 2018

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Dissipative self-assembly is a process in which energy-consuming chemical reaction networks drive the assembly of molecules. Prominent examples from biology include the GTP-fueled microtubule and ATP-driven actin assembly. Pattern formation and oscillatory behavior are some of the unique properties of the emerging assemblies. While artificial counterparts exist, researchers have not observed such complex responses. One reason for the missing complexity is the lack of feedback mechanisms of the assemblies on their chemical reaction network. In this work, we describe the dissipative self-assembly of colloids that protect the hydrolysis of their building blocks. The mechanism of inhibition is generalized and explored for other building blocks. We show that we can tune the level of inhibition by the assemblies. Finally, we show that the robustness of the assemblies towards starvation is affected by the degree of inhibition.

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Benedikt Rieß

Non-equilibrium dissipative supramolecular materials with a tunable lifetime

The Design of Dissipative Molecular Assemblies Driven by Chemical Reaction Cycles

Self-selection of dissipative assemblies driven by primitive chemical reaction networks

Chemogenomic Profiling of Human and Microbial FK506-Binding Proteins

Dissipative assemblies that inhibit their deactivation

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