Expanding the Enzymatic Polymerization Landscape by Lipid Mesophase Soft Nanoconfinement

zu Verbundenen Objekten

Abstract: Soft nanoconfinement can increase chemical reactivity in nature and has therefore led to considerable interest in transferring this universal feature to artificial biological systems. However, little is known about the underlying principles of soft nanoconfinement responsible for the enhancement of biochemical reactions. Herein we demonstrate how enzymatic polymerization can be expanded, optimized, and engineered when carried out under soft nanoconfinement mediated by lipidic mesophases. By systematically varying the water content in the mesophase and thus the diameter of the confined water nanochannels, we show higher efficiency, turnover rate, and degrees of polymerization as compared to the bulk aqueous solution, all controlled by soft nanoconfinement effects. Furthermore, we exploit the unique properties of unfreezing soft nanoconfined water to perform the first enzymatic polymerization at −20 °C in pure aqueous media. These results underpin lipidic mesophases as a versatile host system for chemical reactions and promote them as an original and unexplored platform for enzymatic polymerization.

Standort
Deutsche Nationalbibliothek Frankfurt am Main
Umfang
Online-Ressource
Sprache
Englisch

Erschienen in
Expanding the Enzymatic Polymerization Landscape by Lipid Mesophase Soft Nanoconfinement ; day:29 ; month:11 ; year:2023 ; extent:9
Angewandte Chemie / International edition. International edition ; (29.11.2023) (gesamt 9)

Urheber
Züblin, Patrick
Zeller, Adrian
Moulis, Claire
Remaud‐Simeon, Magali
Yao, Yang
Mezzenga, Raffaele

DOI
10.1002/anie.202312880
URN
urn:nbn:de:101:1-2023113014154364603964
Rechteinformation
Open Access; Der Zugriff auf das Objekt ist unbeschränkt möglich.
Letzte Aktualisierung
15.08.2025, 07:29 MESZ

Datenpartner

Dieses Objekt wird bereitgestellt von:
Deutsche Nationalbibliothek. Bei Fragen zum Objekt wenden Sie sich bitte an den Datenpartner.
Original beim Datenpartner anzeigen

Beteiligte

  • Züblin, Patrick
  • Zeller, Adrian
  • Moulis, Claire
  • Remaud‐Simeon, Magali
  • Yao, Yang
  • Mezzenga, Raffaele

Ähnliche Objekte (12)

Expanding the Enzymatic Polymerization Landscape by Lipid Mesophase Soft Nanoconfinement

Expanding the Enzymatic Polymerization Landscape by Lipid Mesophase Soft Nanoconfinement

Enzymatic Reaction Network‐Driven Polymerization‐Induced Transient Coacervation

Enzymatic Reaction Network‐Driven Polymerization‐Induced Transient Coacervation

Amyloglucosidase enzymatic reactivity inside lipid vesicles

Amyloglucosidase enzymatic reactivity inside lipid vesicles

Effect of enzymatic polymerization on the thermal stability of flavonoids

Effect of enzymatic polymerization on the thermal stability of flavonoids

Enzymatic polymerization of dimethyl 2,5-furandicarboxylate and heteroatom diamines

Enzymatic polymerization of dimethyl 2,5-furandicarboxylate and heteroatom diamines

Self-decorating cells via surface-initiated enzymatic controlled radical polymerization

Self-decorating cells via surface-initiated enzymatic controlled radical polymerization

The expanding CML treatment landscape: an introspective commentary

The expanding CML treatment landscape: an introspective commentary

Capping protein-controlled actin polymerization shapes lipid membranes

Capping protein-controlled actin polymerization shapes lipid membranes

Capping protein-controlled actin polymerization shapes lipid membranes

Capping protein-controlled actin polymerization shapes lipid membranes

Unraveling The Impact of Isomerism on Enzymatic Polymerization of Furanic Polyesters

Unraveling The Impact of Isomerism on Enzymatic Polymerization of Furanic Polyesters

Near‐Infrared Light‐Induced Reversible Deactivation Radical Polymerization: Expanding Frontiers in Photopolymerization

Near‐Infrared Light‐Induced Reversible Deactivation Radical Polymerization: Expanding Frontiers in Photopolymerization

X-ray-activated polymerization expanding the frontiers of deep-tissue hydrogel formation

X-ray-activated polymerization expanding the frontiers of deep-tissue hydrogel formation

Verbundene Objekte