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Radical Chain-Growth Polymerization: Mechanism01:09

Radical Chain-Growth Polymerization: Mechanism

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The radical chain-growth polymerization mechanism consists of three steps: initiation, propagation, and termination of polymerization. The polymerization initiates when a free radical generated from the radical initiator adds to the unsaturated bond in the monomer. The unpaired electron of the free radical and one π electron in the unsaturated bond creates a σ bond between the free radical and the monomer. As a result, the other π electron in the unsaturated bond converts this...
3.9K
Diels–Alder Reaction Forming Bridged Bicyclic Products: Stereochemistry01:29

Diels–Alder Reaction Forming Bridged Bicyclic Products: Stereochemistry

6.7K
Diels–Alder reactions between cyclic dienes locked in an s-cis configuration and dienophiles yield bridged bicyclic products.
6.7K
Anionic Chain-Growth Polymerization: Mechanism01:04

Anionic Chain-Growth Polymerization: Mechanism

2.6K
The mechanism for anionic chain-growth polymerization involves initiation, propagation, and termination steps. In the initiation step, a nucleophilic anion, such as butyl lithium, initiates the polymerization process by attacking the π bond of the vinylic monomer. As a result, a carbanion, stabilized by the electron‐withdrawing group, is generated. The resulting carbanion acts as a Michael donor in the propagation step and attacks the second vinylic monomer, which acts as a Michael...
2.6K
SN2 Reaction: Stereochemistry02:23

SN2 Reaction: Stereochemistry

13.2K
In an SN2 reaction, the nucleophilic attack on the substrate and departure of the leaving group occurs simultaneously through a transition state. As the nucleophile approaches the substrate from the back-side, the configuration of the substrate carbon changes from tetrahedral to trigonal bipyramidal and then back to tetrahedral, leading to an inversion in the configuration of the product.
If the substrate is an achiral molecule at the α-carbon, the inversion of configuration is not...
13.2K
Cationic Chain-Growth Polymerization: Mechanism00:57

Cationic Chain-Growth Polymerization: Mechanism

3.1K
The cationic polymerization mechanism consists of three steps: initiation, propagation, and termination. In the initiation step of the polymerization process, the π bond of a monomer gets protonated by the Lewis acid catalyst, which is formed from boron trifluoride and water. The protonation of the π bond generates a carbocation stabilized by the electron‐donating group. In the propagation step, the π bond of the second monomer acts as a nucleophile and attacks the...
3.1K
Radical Chain-Growth Polymerization: Chain Branching01:17

Radical Chain-Growth Polymerization: Chain Branching

2.7K
The skeletal structure of polymers synthesized via radical polymerization is always branched. For example, the polymerization of ethylene by radical polymerization results in a low-density grade of polyethylene with a heavily branched skeletal structure. Here, the radical site abstracts hydrogen from the growing chain, and the radical site shifts from the end (a primary carbon center) to anywhere within the growing chain (a secondary carbon center). Consequently, the part of the chain from the...
2.7K

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Updated: Apr 16, 2026

Unraveling Entropic Rate Acceleration Induced by Solvent Dynamics in Membrane Enzymes
09:42

Unraveling Entropic Rate Acceleration Induced by Solvent Dynamics in Membrane Enzymes

Published on: January 16, 2016

9.5K

Divergencia controlada por el sustrato en la catálisis de la policetida sintasa.

Douglas A Hansen, Aaron A Koch, David H Sherman

    Journal of the American Chemical Society
    |March 3, 2015
    PubMed
    Resumen
    Este resumen es generado por máquina.

    Los investigadores diseñaron sustratos sintéticos para controlar las poliquetidas sintasas (PKS). Este enfoque de ingeniería de sustratos guió con precisión la catálisis de PKS, permitiendo la producción selectiva de los productos de macrolactona deseados para el biocatálisis.

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    A Customizable Approach for the Enzymatic Production and Purification of Diterpenoid Natural Products
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    Área de la Ciencia:

    • La bioquímica es la bioquímica.
    • Biología sintética Biología sintética.
    • Enzimología Enzimología.

    Sus antecedentes:

    • Las poliquetidas sintasas (PKS) son enzimas cruciales en la biosíntesis de productos naturales.
    • La caracterización de las PKS utiliza tradicionalmente los tioesters sintéticos de N-acetilcisteamina.
    • El control de los ciclos catalíticos de PKS a través de la ingeniería del sustrato está poco explorado.

    Objetivo del estudio:

    • Investigar la ingeniería de sustratos para controlar el resultado catalítico de los módulos PKS.
    • Examinar el efecto de los sustratos nativos de hexaketida activados alternativamente en la catálisis de PikAIV.

    Principales métodos:

    • Utilizó una serie de sustratos de hexaketida nativos activados alternativamente.
    • Examinó el resultado catalítico de PikAIV, un módulo PKS de la vía de la pikromicina.
    • Formación del producto analizado basado en la modificación del sustrato.

    Principales resultados:

    • Control selectivo demostrado sobre la catálisis de PKS utilizando sustratos de ingeniería.
    • Se logró una selectividad mayor a 10:1 para la catálisis de módulo completo (macrolactona de 14 miembros) o la ciclización directa (anillo de 12 miembros).
    • Mostró la ingeniería de sustratos como una estrategia viable para los estudios funcionales de PKS.

    Conclusiones:

    • La ingeniería de sustratos ofrece una poderosa herramienta para dirigir las vías catalíticas de PKS.
    • Los ésteres de hexaketida modificados permiten un control preciso de la formación de productos en la biocatálisis de PKS.
    • Este enfoque avanza en la comprensión funcional y la aplicación de las enzimas PKS.