Degradable linear and bottlebrush thioester-functional copolymers through atom transfer radical ring-opening copolymerization of a thionolactone

Nisa, Qamar un; Theobald, William; Hepburn, Kyle S.; Riddlestone, Ian M.; Bingham, Nathaniel M.; Kopec, Maciek; Roth, Peter J.

doi:10.26434/chemrxiv-2022-kpwtc

“…The latter oxidative treatment can be seen as an alternative to aqueous oxone recently used by the Roth group to cleave DOT-derived thioester linkages. 21…”

Section: Resultsmentioning

confidence: 99%

“…The latter oxidative treatment can be seen as an alternative to aqueous oxone recently used by the Roth group to cleave DOT-derived thioester linkages. 21 IPA is a weak nucleophile that is known to cleave the thioester links of TARO polymers 8,9,16,17 but is not expected to degrade thioacetal groups. Hence, KOH and bleach were tested as stronger degrading agents with potential to cleave both types of TLD units.…”

Section: Communicationmentioning

confidence: 99%

Lactide-derived monomers for radical thiocarbonyl addition ring-opening copolymerisation

Ivanchenko

¹

,

Mazières

²

,

Harrisson

³

et al. 2022

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“…Radical ring opening polymerization (rROP) has enabled the incorporation of numerous functional groups in the backbone of vinyl polymers. [12,13] A growing number of cyclic monomers based on ketene acetals [14,15] and thionolactones [16][17][18][19][20] have been developed to successfully incorporate esters and thioesters. Additionally, cyclic allylic sulfides [21][22][23][24][25][26] and sulfones, [27,28] as well as ring-opening and closing mechanisms [29,30] have been exploited to facilitate the ring opening of (macro)cycles in a ring-strain independent fashion.…”

mentioning

confidence: 99%

pH‐Controlled Reversible Folding of Copolymers via Formation of β‐sheet Secondary Structures

Sbordone,

Micallef,

Frisch

2024

Angewandte Chemie

0

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Protein functions are enabled by their perfectly arranged 3D structure, which is the result of a hierarchical intramolecular folding process. Sequence‐defined polypeptide chains form locally ordered secondary structures (i.e., α‐helix and β‐sheet) through hydrogen bonding between the backbone amides, shaping the overall tertiary structure. To generate similarly complex macromolecular architectures based on synthetic materials, a plethora of strategies have been developed to induce and control the folding of synthetic polymers. However, the degree of complexity of the structure‐ driving ensemble of interactions demonstrated by natural polymers is unreached, as synthesizing long sequence‐defined polymers with functional backbones remains a challenge. Herein, we report the synthesis of hybrid peptide‐DMA copolymers via radical Ring‐Opening Polymerization (rROP) of peptide containing macrocycles. The resulting synthetic polymers contain sequence‐defined regions of β‐sheet encoding amino acid sequences. Exploiting the pH responsiveness of the embedded sequences, protonation or deprotonation in water induces self‐assembly of the peptide strands at an intramacromolecular level, driving polymer chain folding via formation of β‐sheet secondary structures. We demonstrate that the folding behavior is sequence dependent and reversible.

show abstract

pH‐Controlled Reversible Folding of Copolymers via Formation of β‐sheet Secondary Structures

Sbordone,

Micallef,

Frisch

2024

Angew Chem Int Ed

4

0

View full text Add to dashboard Cite

Protein functions are enabled by their perfectly arranged 3D structure, which is the result of a hierarchical intramolecular folding process. Sequence‐defined polypeptide chains form locally ordered secondary structures (i.e., α‐helix and β‐sheet) through hydrogen bonding between the backbone amides, shaping the overall tertiary structure. To generate similarly complex macromolecular architectures based on synthetic materials, a plethora of strategies have been developed to induce and control the folding of synthetic polymers. However, the degree of complexity of the structure‐ driving ensemble of interactions demonstrated by natural polymers is unreached, as synthesizing long sequence‐defined polymers with functional backbones remains a challenge. Herein, we report the synthesis of hybrid peptide‐DMA copolymers via radical Ring‐Opening Polymerization (rROP) of peptide containing macrocycles. The resulting synthetic polymers contain sequence‐defined regions of β‐sheet encoding amino acid sequences. Exploiting the pH responsiveness of the embedded sequences, protonation or deprotonation in water induces self‐assembly of the peptide strands at an intramacromolecular level, driving polymer chain folding via formation of β‐sheet secondary structures. We demonstrate that the folding behavior is sequence dependent and reversible.

show abstract

Degradable linear and bottlebrush thioester-functional copolymers through atom transfer radical ring-opening copolymerization of a thionolactone

Cited by 3 publications

References 30 publications

Lactide-derived monomers for radical thiocarbonyl addition ring-opening copolymerisation

Lactide-derived monomers for radical thiocarbonyl addition ring-opening copolymerisation

pH‐Controlled Reversible Folding of Copolymers via Formation of β‐sheet Secondary Structures

pH‐Controlled Reversible Folding of Copolymers via Formation of β‐sheet Secondary Structures

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